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Lamb growth impacts muscle
oxidative capacity and meat quality
This thesis is presented for the degree of
Doctor of Philosophy of Murdoch University
Khama Kelman
B.Sc. (Veterinary Biology)
B.V.M.S. (Veterinary Medicine and Surgery)
M.A.C.V.Sc. (Small Animal Surgery)
B.Sc. (Mathematics and Statistics)
December 2014
II
Declaration
I declare that this thesis is my own account of my research and contains as its main content
work which has not previously been submitted for a degree at any tertiary education institution
……………………………
Khama Rhian Kelman
III
Summary
Genetic selection to increase lamb growth is advantageous in reducing the time it takes
for lambs to reach market weight. However the effects of rapid growth on muscle fibre
type, as indicated by oxidative capacity, is not clear. Muscle fibre type is intrinsically
linked with attributes of meat quality, which are becoming increasing important to
consumers. Therefore, changes to muscle fibre type through selection for growth may
impact meat quality.
Producers can impact lamb growth at any time during the growth period including the
weaning (100 days) and post weaning time points (150 days). As not all lambs were
weighed at these time points a growth curve was fitted to the live weight data of each
individual animal to allow weight to be estimated at any time point during the growth
period. Once estimates of weight and growth rate at the weaning and post weaning time
points were obtained, the impact of growth on muscle fibre type and meat quality traits
could be investigated.
In the first experiment growth curves were fitted to live weight data for 18,185 lambs
with weight data between birth and 300 days. Linear (cubic polynomial), nonlinear
(Brody) and random effects models were fitted and the characteristics of the residual
values examined to determine the best curve fit. The random effects model was
hypothesised to have the lowest residual values as it is based on a population, rather
than an individual fit, and is less biased when fitting growth curves to weight recordings
from animals with different durations of data collection. However, the cubic polynomial
fit had the lowest average residual values and the Brody fit had the highest. The
difference between the residual values for the fit of each function was relatively small
therefore the decision on which function to use was based on a variety of additional
IV
factors. As it is a population based fit, a random effects model accommodates missing
weight recordings and different durations of data collection, which are common with
industry data recording, without biasing the fit. A random effects model also allows
environmental effects specific to the time of recording to be accounted for and can
accommodate genetic differences in the shape of each animal’s growth curve. Based on
these characteristics the estimates of lamb weights and growth rates from the random
effects model were used in this thesis.
In the second experiment the impact of production factors on lamb weight at key time
points in production were analysed. While several studies have published information
on these effects the studies were generally small. Therefore, this analysis acted as a
benchmarking for the magnitude of the effects, based on large data. The full expression
of the post weaning weight breeding value is depressed with poor nutrition so an
analysis was performed to determine the extent to which other forms of nutritional
restriction, including lamb and dam factors such as birth type, dam breed and dam age,
moderate the expression of the growth breeding value. As expected, factors such as
multiple births, which act as a source of nutritional restriction, reduced the full
expression of the growth breeding value and hindered lambs reaching expected weights.
Muscle oxidative capacity is intrinsically linked to lamb growth and meat quality so in
the third experiment the influence of genetic selection for growth on muscle oxidative
capacity was examined. Oxidative capacity was indicated by the activity of the
oxidative enzyme isocitrate dehydrogenase as well as the concentration of myoglobin in
the muscle. As expected, genetic selection for growth reduced isocitrate dehydrogenase
activity and myoglobin concentration. The reduction in oxidative capacity with
increased growth was due to lambs tending toward a larger matures size and therefore
being physiologically less mature at a given weight
V
The impact of lamb growth on oxidative capacity and meat quality has previously been
estimated by the impact of the sire breeding value for growth on these traits or by using
hot carcass weight as a proxy for whole of life growth. However the accuracy of these
measures of growth is untested. The lamb weights and growth rates derived in the
second experiment were used to determine the real impact of growth on oxidative
capacity and meat quality. The impact of genetic selection on growth, or the use of hot
carcass weight as a proxy for the impact of growth on meat traits, were both shown to
be inadequate in quantifying the magnitude of the effect of growth on meat quality traits
and indicating how the effect of growth varied with time.
In the fourth experiment the impact of lamb growth on intramuscular fat, shear force
and consumer overall liking was examined. Intramuscular fat was increased and shear
force was reduced with lamb growth. Intramuscular fat and consumer overall liking
have a positive association however contrary to expectations growth had no impact on
overall liking. This is likely to be due to influences on overall liking other than
intramuscular fat.
In the final experiment the impact of lamb growth in isocitrate dehydrogenase activity,
myoglobin concentration, iron and zinc concentration and meat browning were
examined. As hypothesised, myoglobin, iron and zinc concentrations increased with
lamb growth. Contrary to expectations isocitrate dehydrogenase activity and meat
browning were reduced with lamb growth. Meat browning was thought to reduce due to
its strong association with oxidative capacity and thus the oxidative indicator enzyme
inverse isocitrate dehydrogenase.
These experiments have contributed to the sheep industry at a highly practical and
adoptable level showing why the full potential of genetic selection for growth may not
be realised and demonstrating the impact of growth on meat eating quality. Currently,
VI
increased growth in lambs, particularly in the early stages between birth and weaning
has positive effects on meat quality however lambs had few weights recorded between
these times so work needs to be done to characterise these associations.
VII
Acknowledgments
This journey has been filled with surprises, the greatest of which was meeting my
husband Richard. I did not know it was possible to be this happy. I am grateful for
meeting Meghan Cornelius when I started my thesis at Murdoch and for her introducing
the vegetarian city girl to the sheep farming country boy. We didn’t know this would
happen either, quite a lovely surprise.
I have had two great academic supervisors during my thesis, Associate Professor
Graham Gardner and Professor David Pethick. Their largest contribution has been to
teach me how to design every experiment with practical outcomes in mind for industry
adoption. They have provided both encouragement and opportunity to deliver these
outcomes in industry and scientific forums, allowing diverse and practical feedback.
These skills will set me in good stead as I continue my career.
I am especially grateful to Graham for his attention to detail and willingness to debate
the statistical nuances so integral to a thesis based on modelling. Our incongruous
opinions have largely been limited to less serious issues, such as colour schemes for
presentations and the variation in our desired amounts of personal space.
Dave has been incredibly helpful in seeing the broader picture, distilling practical
messages from a range of complex results. It was a difficult couple of years avoiding
telling Dave I’m actually a vegetarian, although he took the news gracefully.
The research would not have been possible without the support of the Sheep CRC in
terms of both funding and support. The annual Postgraduate Conference run by the
Sheep CRC has been a highlight of my candidature providing specific feedback from
industry experts which would not have been available in any other setting. Murdoch
VIII
University has also provided welcome support and it has been great to return home to
my alma mater. I cannot thank the Murdoch University Postgraduate Student
Association enough for their help in supporting all Murdoch postgraduate students with
in-house social events and conferences, and myself personally with travel and
completion scholarships.
The technical support provided by Mal Boyce, Ken Chong, Janice Stigwood, Rini
Margwani and Di Pethick have helped keep the whole project running smoothly. The
lab work would not have been possible on my own and I am so grateful for your help.
The statistical support from Clair Alton has given me further confidence in our analysis
and introduced me to the world of Bayes. With your help I am no longer bound only to
P values.
I have particularly loved the office I have shared with Fiona Anderson, Andrew
Williams, Linda Dawson and Sarah Stewart. Fiona has been a reassuring counterbalance
to the joys and frustrations of research as she underwent her own thesis journey and
Willo revolutionised our capacity for analysis with the automatic regression macro.
In addition to office friends it has been great to work with a large and supportive meat
science team of postgrads and postdocs. I am thankful to have also shared this journey
with Sarah Blumer, Sandra Corbett, Sarah Bonny, Peter McGilchrist, Liselotte Pannier,
Honor Calnan, who has always been ready to brunch, and Cam Jose who first
introduced me to Graham.
I am grateful to my family for their constant support. They mention that I’ve been
studying for a while. I know.
IX
Publications
Journal publications:
Kelman, K.R., Pannier, L., Pethick, D.W. and Gardner, G.E. (2014). Selection for lean
meat yield in lambs reduces indicators of oxidative metabolism in the longissimus
muscle. Meat Science. 96: 1058-1067.
Journal publications to be submitted:
Kelman, K.R., Alston, C., Pethick, D. W. and Gardner, G. E. (2016). Lamb birth and
rearing type influence growth and weight potential of progeny from high growth sires.
Kelman, K.R., Pannier, L., Pethick, D. W. and Gardner, G. E. (2016). Lamb growth
increases intramuscular fat levels and reduces shear force in the longissimus muscle.
Kelman, K.R., Pannier, L., Calnan, H., Pethick, D. W. and Gardner, G. E. (2016).
Lamb growth increases oxidative capacity and mineral content in the longissimus
muscle.
Kelman, K.R., Alston, C., Pethick, D. W. and Gardner, G. E. (2016). Comparison of
linear and nonlinear functions to estimate lamb growth.
Conference proceedings:
de Hollander, C.A, Moghaddar, N., Kelman, K.R., Gardner, G.E., van der Werf, J.
(2014) Is variation in growth trajectories genetically correlated with meat quality traits
in Australian terminal lambs? In ‘Proceedings of the 10th
World Congress on Genetics
Applied to Livestock Production’, Vancouver, Canada.
Kelman, K.R., Alston, C.L., Pethick, D.W. and Gardner, G.E. (2013) Multiple births
limit the advantage of using high growth sires – Dealing with large data sets. In
‘Proceedings of the 64th Annual Meeting of the European Federation of Animal
Production’. Nantes, France. Book of Abstracts No.19. p 620. (Wageningen Academic
Publishers).
X
Kelman, K.R., Alston, C.L., Pethick, D.W. and Gardner, G.E. (2013) Multiple births
limit the advantage of using high growth sires. In ‘Proceedings of the 59th
International
Congress of Meat Science and Technology’, Izmir, Turkey. (Eds M Serdaroglu, B
Oxturk, T Akcan.) Proceedings S3-2. (Ege University, Food Engineering
Development).
Kelman, K.R., Pethick, D.W. and Gardner, G.E. (2012) Multiple births and young
ewes limit the advantage of using high PWWT sires. In ‘Proceedings of Lambex 2012’.
Bendigo, Victoria. Proceedings p 38.
Kelman, K.R., Pannier, L., Pethick, D.W. and Gardner, G.E. (2012) Selection for
leanness decreases meat aerobicity. In ‘Proceedings of Sheep CRC Postgraduate
Student Conference’. Coffs Harbour, New South Wales.
Gardner, G.E., Anderson, F., Williams, A., Kelman, K.R., Pannier, L. and Pethick,
D.W. (2012) Growth breeding value redistributes weight to the saddle region of lamb
carcasses. In ‘Proceedings of the 63rd Annual Meeting of the European Federation of
Animal Production’, Bratislava, Slovakia. Book of Abstracts No.18 p 302. (Wageningen
Academic Publishers).
Kelman, K.R., Pethick, D.W. and Gardner, G.E. (2011) Selection for leanness
decreases isocitrate dehydrogenase activity. In ‘Proceedings of Sheep CRC
Postgraduate Student Conference’. Coffs Harbour, New South Wales.
Kelman, K.R., Pannier, L., Pethick, D.W. and Gardner, G.E. (2011) Selection for
reduced PFAT decreases Isocitrate Dehydrogenase activity. In ‘Proceedings of the 62rd
Annual Meeting of the European Federation of Animal Production’ Stavanger, Norway.
Book of Abstracts No.17, p 299. (Wageningen Academic Publishers).
Gardner, G.E., Pannier, L., Anderson, F., Kelman, K.R., Williams, A., Jacob, R.H.,
Ball, A.J. and Pethick, D.W. (2011) The impact of selection for leanness on lamb
carcase composition, intramuscular fat, and muscle metabolic type, is not influenced by
nutritional variation within Australian production systems. In ‘Proceedings of the 8th
International Symposium on the Nutrition of Herbivores Advances in Animal
Biosciences’. Aberystwyth, Wales. p 406.
XI
Kelman, K.R., Pethick, D.W. and Gardner, G.E. (2010) Determining lamb growth rate
during development. In ‘Proceedings of Cooperative Research Centre for Sheep
Industry Innovation Conference’. Adelaide, South Australia.
Kelman, K.R., Pethick, D.W. and Gardner, G.E. (2010) The impact of lamb growth
rate on Information Nucleus Flock slaughter traits. In ‘Proceedings of Sheep CRC
Postgraduate Student Conference’. Coffs Harbour, New South Wales.
XII
Abbreviations
AMSA American Meat Science Association
ASBV Australian sheep breeding value
ATP Adenosine triphosphate
CoA Co-enzyme A
HCWT Hot carcass weight
ICDH Isocitrate dehydrogenase
MSA Meat Standards Australia
NADH Nicotinamide adenine dinucleotide
NIR Near infrared
TAG Triacylglycerol
TCA Citric acid cycle
XIII
Enzymes
ATPase EC 3.6.1.3
Citrate synthase EC 2.3.3.1
Cytochrome-c oxidase EC 1.9.3.1
Glycogen phosphorylase EC 2.4.1.1
Glycogen synthase EC 2.4.1.11
Hexokinase EC 2.7.1.1
Hydroxyacyl-CoA dehydrogenase EC 1.1.1.35
Isocitrate dehydrogenase EC 1.1.1.41
Lactate dehydrogenase EC 1.1.1.27
Phosphofructokinase EC 2.7.1.11
XIV
XV
Table of contents
Declaration ........................................................................................................................................... II
Summary .............................................................................................................................................. III
Acknowledgments .............................................................................................................................. VII
Publications ......................................................................................................................................... IX
Abbreviations...................................................................................................................................... XII
Enzymes ............................................................................................................................................. XIII
Table of contents ................................................................................................................................ XV
List of figures...................................................................................................................................... XIX
List of tables ....................................................................................................................................... XXI
Chapter 1. Introduction ................................................................................................................... 1
Chapter 2. Literature Review ........................................................................................................... 5
2.1 Animal growth ................................................................................................................................... 5
2.2 Growth curves .................................................................................................................................... 6 2.2.1 Linear functions ......................................................................................................................... 7 2.2.2 Nonlinear functions ................................................................................................................... 8 2.2.3 Random Effects Model ....................................................................................................... 12 2.2.4 Residual weight ........................................................................................................................ 13
2.3 Growth and tissue differentiation ................................................................................................... 14
2.4 Production factors influencing growth ............................................................................................ 16 2.4.1 Sex ............................................................................................................................................ 16 2.4.2 Genetics ................................................................................................................................... 17 2.4.3 Nutritional restriction .............................................................................................................. 22 2.4.4 Birth type and rear type........................................................................................................... 24 2.4.5 Dam factors.............................................................................................................................. 24
2.5 Growth and fibre type ..................................................................................................................... 27 2.5.1 Muscle fibre classification ....................................................................................................... 27 2.5.2 Oxidative fibres ........................................................................................................................ 30 2.5.3 Glycolytic fibres ....................................................................................................................... 30 2.5.4 Muscle fibre development ....................................................................................................... 30 2.5.5 Production factors impacting fibre type .................................................................................. 32 2.5.6 Fibre type and meat quality ..................................................................................................... 35
2.6 Growth and meat quality ................................................................................................................ 35 2.6.1 Intramuscular fat ..................................................................................................................... 36 2.6.2 Shear force ............................................................................................................................... 43 2.6.3 Overall liking ............................................................................................................................ 47 2.6.4 Isocitrate dehydrogenase activity ............................................................................................ 50 2.6.5 Myoglobin concentration ........................................................................................................ 52 2.6.6 Iron and zinc concentration ..................................................................................................... 57 2.6.7 Meat browning ........................................................................................................................ 61
2.7 Hypothesis .................................................................................................................................... 65
XVI
Chapter 3. Comparison of linear and nonlinear functions to estimate lamb growth ...................... 69
3.1 Introduction ......................................................................................................................................69
3.2 Materials and Methods ....................................................................................................................71 3.2.1 Experimental Design ................................................................................................................71
3.3 Statistical Analysis ............................................................................................................................72 3.3.1 Data available ...........................................................................................................................72 3.3.2 Nonlinear curve fit....................................................................................................................73 3.3.3 Linear curve fit..........................................................................................................................74 3.3.4 Random effects model fit using Bayesian analysis ...................................................................74 3.3.5 Curve fitting comparisons ........................................................................................................74
3.4 Results ..............................................................................................................................................76 3.4.1 Nonlinear curve fit....................................................................................................................76 3.4.2 Linear curve fit..........................................................................................................................79 3.4.3 Bayesian random effects model fit ..........................................................................................81 3.4.4 Comparison of residual graphs over time ................................................................................83
3.5 Discussion .........................................................................................................................................84 3.5.1 Mean square error ...................................................................................................................84 3.5.2 Curve attributes .......................................................................................................................84 3.5.3 Residual weights .......................................................................................................................86 3.5.4 Random effects model .............................................................................................................87
3.6 Conclusion ........................................................................................................................................88
Chapter 4. Lamb birth and rearing type influence growth and weight potential of progeny from high growth sires ................................................................................................................................. 89
4.1 Introduction ......................................................................................................................................89
4.2 Materials and Methods ....................................................................................................................91 4.2.1 Experimental Design ................................................................................................................91 4.2.2 Lamb weights ...........................................................................................................................92 4.2.3 Data available ...........................................................................................................................92 4.2.4 Statistical analysis.....................................................................................................................93
4.3 Results ..............................................................................................................................................96 4.3.1 Actual birth weights .................................................................................................................96 4.3.2 Estimated live weights and growth rates at 100, 150 and 240 days ..................................... 103
4.4 Discussion ...................................................................................................................................... 111 4.4.1 Association between carcass breeding values and lamb weight and growth rate ............... 111 4.4.2 Production effects ................................................................................................................. 114
4.5 Conclusion ..................................................................................................................................... 120
Chapter 5. Selection for lean meat yield in lambs reduces indicators of oxidative metabolism in the longissimus muscle ............................................................................................................................ 121
5.1 Introduction ................................................................................................................................... 121
5.2 Materials and Methods ................................................................................................................. 123 5.2.1 Experimental Design ............................................................................................................. 123 5.2.2 Collection of phenotypic measurements .............................................................................. 124 5.2.3 Data available ........................................................................................................................ 125 5.2.4 Statistical analysis.................................................................................................................. 125
5.3 Results ........................................................................................................................................... 128 5.3.1 Isocitrate Dehydrogenase ..................................................................................................... 128 5.3.2 Myoglobin Concentration ..................................................................................................... 137
5.4 Discussion ...................................................................................................................................... 147 5.4.1 Association between carcass breeding values and oxidative capacity ................................. 147
XVII
5.4.2 Associations with carcass phenotypic measurements .......................................................... 149 5.4.3 Production effects ................................................................................................................. 151
5.5 Conclusion ...................................................................................................................................... 154
Chapter 6. Lamb growth increases intramuscular fat levels and reduces shear force in the longissimus muscle ............................................................................................................................ 155
6.1 Introduction ................................................................................................................................... 155
6.2 Materials and Methods ................................................................................................................. 156 6.2.1 Experimental Design .............................................................................................................. 156 6.2.2 Collection of phenotypic measurements ............................................................................... 157 6.2.3 Data available ........................................................................................................................ 158 6.2.4 Statistical analysis .................................................................................................................. 161
6.3 Results ........................................................................................................................................... 165 6.3.1 Intramuscular fat ................................................................................................................... 165 6.3.2 Shear force ............................................................................................................................. 167 6.3.3 Overall liking .......................................................................................................................... 170 6.3.4 Phenotypic correlations ......................................................................................................... 170
6.4 Discussion ...................................................................................................................................... 172 6.4.1 Intramuscular fat ................................................................................................................... 172 6.4.2 Shear force ............................................................................................................................. 174 6.4.3 Overall liking .......................................................................................................................... 176
6.5 Conclusion ...................................................................................................................................... 178
Chapter 7. Lamb growth increases oxidative capacity and mineral content in the longissimus muscle..............................................................................................................................................179
7.1 Introduction ................................................................................................................................... 179
7.2 Materials and Methods ................................................................................................................. 181 7.2.1 Experimental Design .............................................................................................................. 181 7.2.2 Collection of phenotypic measurements ............................................................................... 181 7.2.3 Data available ........................................................................................................................ 183 7.2.4 Statistical analysis .................................................................................................................. 186
7.3 Results ........................................................................................................................................... 188 7.3.1 Isocitrate Dehydrogenase ...................................................................................................... 188 7.3.2 Myoglobin Concentration ...................................................................................................... 192 7.3.3 Iron Concentration................................................................................................................. 195 7.3.4 Zinc Concentration ................................................................................................................. 197 7.3.5 Meat Browning ...................................................................................................................... 199 7.3.6 Phenotypic correlations ......................................................................................................... 200
7.4 Discussion ...................................................................................................................................... 202 7.4.1 Isocitrate dehydrogenase activity .......................................................................................... 202 7.4.2 Myoglobin concentration ...................................................................................................... 204 7.4.3 Iron and zinc concentration ................................................................................................... 206 7.4.4 Meat browning ...................................................................................................................... 208
7.5 Conclusion ...................................................................................................................................... 211
Chapter 8. General Discussion ...................................................................................................... 213
8.1 Benefits of lamb growth to industry .............................................................................................. 213
8.2 Brody function ............................................................................................................................... 214
8.3 Cubic polynomial function ............................................................................................................. 215
8.4 Random effects model ................................................................................................................... 216
8.5 Impact of environment on growth ................................................................................................. 218
XVIII
8.6 Impact of genetics on growth ....................................................................................................... 220
8.7 Fibre type and oxidative capacity ................................................................................................. 222
8.8 Impact of genetics on oxidative capacity ...................................................................................... 223
8.9 Impact of growth on oxidative capacity ........................................................................................ 224
8.10 Impact of growth on objective and subjective measures of eating quality ................................. 225
8.11 Impact of growth on mineral content of meat ............................................................................ 226
8.12 Impact of growth on meat browning .......................................................................................... 228
8.13 Impact of growth on meat traits ................................................................................................. 229
8.14 Adjustments to experimental design........................................................................................... 230
8.15 Future studies .............................................................................................................................. 232
References ......................................................................................................................................... 234
XIX
List of figures
Figure 2-1: A growth curve demonstrating the phases of growth with time: lag, exponential growth,
transitional diminishing growth and the stationary plateau at maturity ........................................................ 5
Figure 2-2 Graph of a linear (···) and cubic polynomial function (—) fitted to lamb live weight data (o) in
kilograms against time in days. .................................................................................................................... 7
Figure 2-3 A typical graphical representation of lamb live weight data with a Brody function fitted to
lamb live weight data (o) in kilograms against time in days. ..................................................................... 11
Figure 2-4 Change in carcass fat, muscle and bone as a portion of mature live weight during allometric
growth: Source (Butterfield et al., 1984) ................................................................................................... 14
Figure 2-5 Interpretation of an Australian Sheep Breeding Value (ASBV) for post weaning weight based
on value, trait, age and accuracy. Source: Sheep Genetics ......................................................................... 19
Figure 2-6 Selection index for rams (circled) based on Australian Sheep Breeding Value for weight
(PWT), muscle (PEMD) and fat (PFAT). Source: Sheep Genetics ............................................................ 20
Figure 2-7 Interconversions of myoglobin redox forms in fresh meat. Source: AMSA Color Measurement
Guidelines (AMSA, 2012) ......................................................................................................................... 54
Figure 3-1 Graph of the number of weight recordings against lamb age (in days) between 1 and 300 days.
.................................................................................................................................................................... 73
Figure 3-2 Graph of average residual weight (kg) per 10 day period with a Brody curve fit (-- -- -- --), a
cubic curve fit (- - - -) and a random effects model fit (····). The solid line at residual weight zero
represents the line the residuals would fall on if the random effects model were a perfect fit to the weight
data. ............................................................................................................................................................ 77
Figure 3-3 Histogram of the distribution of residual weight values (kg) against the percent frequency for
the Brody function fit. ................................................................................................................................ 79
Figure 3-4 Histogram of the distribution of residual weight values (kg) against the percent frequency for
the cubic function fit. ................................................................................................................................. 81
Figure 3-5 Histogram of the residual weight values (kg) against the percent frequency for the random
effects model fit.......................................................................................................................................... 83
Figure 4-1 Comparison of sire estimates for post weaning weight (PWWT) Australian Sheep Breeding
Values for Maternal, Merino and Terminal sires with predicted means for weight at 150 days. Lines
represent predicted means for weight (± s.e.) for each sire type. Symbols (∆,+,o) represent individual sire
estimates. .................................................................................................................................................. 107
XX
Figure 4-2 Comparison of sire estimates for post weaning fat depth (PFAT) Australian Sheep Breeding
Values for Maternal, Merino and Terminal sires with predicted means for weight at 150 days. Lines
represent predicted means for weight (± s.e.) for each sire type. Symbols (∆,+,o) represent individual sire
estimates. .................................................................................................................................................. 110
Figure 5-1 Linear relationship between muscle sample protein concentration (mg/g tissue) and isocitrate
dehydrogenase activity (± s.e.) in μmol/min/g tissue per gramme of protein. Each icon (o) represents an
individual lamb. ........................................................................................................................................ 127
Figure 5-2 The effect of site by year of birth on isocitrate dehydrogenase activity (μmol/min/g tissue) (±
s.e.) from the base model. ........................................................................................................................ 131
Figure 5-3 Linear relationship between isocitrate dehydrogenase activity (μmol/min/g tissue) (± s.e.) and
slaughter age in days. Symbols represent predicted means for kill groups. Lines represent predicted means
for age at slaughter (± s.e.) from base model with no kill group term. ..................................................... 132
Figure 5-4 Curvilinear relationship between intramuscular fat percentage and isocitrate dehydrogenase
activity (± s.e.) in μmol/min/g tissue. Symbols (o) represent individual lamb residuals from the
intramuscular fat model. ........................................................................................................................... 134
Figure 5-5 Relationship between sire estimates for isocitrate dehydrogenase activity (μmol/min/g tissue)
and subcutaneous post weaning c-site fat depth (PFAT) for Maternal, Merino and Terminal sires. Lines
represent predicted means for isocitrate dehydrogenase activity (± s.e.) for all sire types combined.
Symbols represent individual sire estimates. ............................................................................................ 135
Figure 5-6 The effect of site by year of birth on myoglobin concentration (mg/g tissue) (± s.e.) from the
base model. ............................................................................................................................................... 140
Figure 5-7 Linear relationship between myoglobin concentration (mg/g tissue) and slaughter age in days.
Symbols represent predicted means for kill groups. Lines represent predicted means for age at slaughter
(± s.e.) from base model with no kill group term. .................................................................................... 141
Figure 5-8 Curvilinear relationship between intramuscular fat percentage and myoglobin concentration (±
s.e.) in mg/g tissue. Symbols (o) represent individual lamb residuals from the intramuscular fat model. 143
Figure 5-9 Relationship between sire estimates for myoglobin concentration (mg/g tissue) and post
weaning eye muscle depth (PEMD) for Maternal, Merino and Terminal sires. Lines represent predicted
means for myoglobin concentration (± s.e.) for each sire type. Symbols (o) represent individual sire
estimates. .................................................................................................................................................. 146
XXI
List of tables
Table 2-1 Contractile and metabolic characteristics of individual fibre types. Adapted from Lefaucheur
(2010). ........................................................................................................................................................ 29
Table 3-1 Mean square error (MSE) ± standard error (kg2) for curve fits between 0 and 300 days and 90
and 160 days for Brody, Cubic, Random Effects Model and Random Effects Model with all data
(including animals with less than 4 live weight observations) curve fits. .................................................. 76
Table 3-2 Results of tests for the location of mu, normality, skewedness and kurtosis of the average
residual values from a Brody function fit to 17,377 animals. .................................................................... 78
Table 3-3 Results of test for the location of mu, skewedness, kurtosis and normality of the average
residual values from a cubic function fit to 17,382 animals. ...................................................................... 81
Table 3-4 Results of tests for the location of mu, skewedness, kurtosis and normality of the average
residual values from a random effects model fit to 17,382 animals. .......................................................... 83
Table 4-1 Actual birth weight (kg) ranges and estimated weight (kg) and growth rate (g/day) ranges at
100, 150 and 240 days. ............................................................................................................................... 92
Table 4-2 Phenotypic correlations (standard errors) of post weaning sire breeding values for weight, fat
depth and eye muscle depth among Maternal, Merino and Terminal sires. ............................................... 93
Table 4-3 Numerator and denominator degrees of freedom and F-values for the base models for birth
weight and estimated weights and growth rates at 100, 150 and 240 days. ............................................... 97
Table 4-4 Predicted means for birth weight (kg) and estimated weight at 100, 150 and 240 days for
different sexes, birth type-rear types, dam ages, sire types and dam breed within sire type combinations.99
Table 4-5 Magnitude of effect (difference between the highest and lowest values) for production or for
genetic effects on weight and growth rate. ............................................................................................... 100
Table 4-6 95% Confidence intervals of sire estimates for birth weight (kg) and estimated weights (kg) and
growth rates (g/day) at 100, 150 and 240 days. ........................................................................................ 101
Table 4-7 Regression coefficients for the relationship between sire ASBVs for growth and actual birth
weight (kg) or estimated weight and growth rate at 100, 150 and 240 days. ........................................... 102
Table 4-8 Predicted means for estimated growth rate at 100, 150 and 240 days for different sexes, birth
type-rear types, dam ages, sire types and dam breed within sire type combinations. .............................. 104
Table 4-9 Regression coefficients for the relationship between sire ASBVs for muscling and leanness and
estimated weight and growth rate at 100, 150 and 240 days. ................................................................... 109
XXII
Table 5-1 Numerator degrees of freedom, denominator degrees of freedom and F-values for the base
models for isocitrate dehydrogenase activity (μmol/min/g tissue) and myoglobin concentration (mg/g
tissue). ....................................................................................................................................................... 128
Table 5-2 Number of progeny at each site for year of birth, sex, sire type and dam breed within sire type
from the base ICDH activity model. ......................................................................................................... 129
Table 5-3 Raw mean ± standard deviation, and minimum to maximum value, for isocitrate dehydrogenase
activity and the phenotypic covariates tested within the base model. ....................................................... 130
Table 5-4 Number of sires and Australian Sheep Breeding Values mean (min, max) for each sire type
from the isocitrate dehydrogenase (ICDH) activity and myoglobin concentration data. .......................... 136
Table 5-5 Number of progeny at each site for year of birth, sex and sire type from the base myoglobin
concentration model.................................................................................................................................. 138
Table 5-6 Raw mean ± standard deviation and minimum to maximum values for myoglobin concentration
and the phenotypic covariates tested within the base model. .................................................................... 139
Table 6-1 Weight and growth rate ranges for intramuscular fat, shear force and overall liking. .............. 160
Table 6-2 Number of animals, years of data and number of sires available for intramuscular fat, shear
force and overall liking. ............................................................................................................................ 161
Table 6-3 Phenotypic correlations (standard errors) of post weaning sire breeding values for weight, fat
depth and eye muscle depth among Maternal, Merino and Terminal sires. .............................................. 161
Table 6-4 The magnitude of effect (difference between the highest and lowest values) of lamb weight and
growth rate on intramuscular fat or on shear force across the entire weight or growth rate range. .......... 165
Table 6-5 Variation in slopes between sire types for the impact of birth weight, weight at 100 days and
weight at 150 days on intramuscular fat. .................................................................................................. 166
Table 6-6 Phenotypic correlations of intramuscular fat, shear force and overall liking with lamb weight
and growth rate. Standard error values in brackets. Significant correlations are in bold. ......................... 171
Table 7-1 Weight and growth rate ranges for isocitrate dehydrogenase (ICDH) activity, myoglobin
concentration, iron concentration, zinc concentration and meat browning. .............................................. 184
Table 7-2 Number of animals, years of data and number of sires available for isocitrate dehydrogenase
(ICDH) activity, myoglobin concentration, iron concentration, zinc concentration and meat browning. 185
Table 7-3 Phenotypic correlations (standard errors) of post weaning sire breeding values for weight, fat
depth and eye muscle depth among Maternal, Merino and Terminal sires. .............................................. 186
XXIII
Table 7-4 The magnitude of effect (difference between the highest and lowest values) of lamb weight and
growth rate on isocitrate dehydrogenase activity, myoglobin concentration, iron concentration, zinc
concentration and meat browning. ........................................................................................................... 190
Table 7-5 Variation in slopes between sire types for the impact of birth weight, weight at 100 and 150
days, weight change between 100 and 150 days and growth rate at 100 and 150 days on myoglobin
concentration, iron concentration and zinc concentration. ....................................................................... 193
Table 7-6 Phenotypic correlations of isocitrate dehydrogenase (ICDH) activity, myoglobin concentration,
iron concentration, zinc concentration and meat browning with lamb weight and growth rate. Standard
error values in brackets. Significant correlations are in bold. .................................................................. 201
1
Chapter 1. Introduction
Lamb growth is a key profit driver for producers in the Australian Sheep Industry,
particularly with the fall in wool prices causing a shift toward meat production (Curtis
et al., 2006). Lambs with fast growth rates will reach market weights earlier, resulting
in an overall lower cost of production per lamb and an increase in farm profitability.
Australians have among the highest sheep meat consumption in the world with each
person consuming around 10 kg of lamb per year (MLA, 2013). This resulted in a
domestic expenditure on lamb of around $2 billion in the 2012-2013 financial year
(MLA, 2013). As demand for protein in the form of red meat is increasing worldwide,
increasing efficient lamb production is desirable.
Productivity in lamb production can be increased by optimising nutrition, and genetic
selection for improvement is becoming more widely adopted. Historically, increased
growth in progeny was achieved by cross breeding, or selecting animals with higher
weaning, post weaning or hogget weights. This caused some improvement due to the
heritability of weight (Safari and Fogarty, 2003). However, in recent times genetic
evaluation systems such as LAMBPLAN™ and MERINOSELECT™ have been
developed by Sheep Genetics to provide an objective measurement of important
production traits, including lamb growth. Producers are able to use the genetic estimates
to select sires with the desirable trait characteristic and based on the accuracies provided
have confidence that the progeny of that sire will inherit the benefits of that trait. More
recently, genomic testing has become available, which further aids producers when
selecting prospective sires.
2
However, selection for growth has raised a number of questions concerning its broader
impact on the physiology of the animal including the impact of selection for increased
growth on muscle fibre type. This is important as muscle fibre type is intrinsically
linked with both subjective and objective measures of meat quality (Calkins et al., 1981;
Calnan et al., 2014; Hocquette et al., 2010; Pearce et al., 2009). Subjective measures of
eating quality include customer rated tenderness, flavour, juiciness and overall liking
(Polkinghorne et al., 1999) while objective measures include intramuscular fat, shear
force, meat colour and mineral content. Therefore any impact of growth on muscle fibre
type could have correlated impacts on meat quality and consumer acceptability. The
meat quality traits of interests selected at the outset of this study were indicators of
eating quality (intramuscular fat, shear force and consumer overall liking), indicators of
meat nutrition (iron and zinc concentration) and indicators of retail shelf life (rate of
meat browning).
Production factors include the site of lamb rearing, year of birth, sex, age, dam breed,
dam age and sire type. These factors have been shown in a number of studies to impact
growth, however the results vary in magnitude due to small sample sizes. Therefore a
study needs to be undertaken to quantify the magnitude of the impact of production
factors on lamb growth, based on a large data set.
In addition to production factors influencing growth, genetic selection for growth using
Australian Sheep Breeding Values (ASBVs) also influence growth with lamb weight
increasing with selection for an increased post weaning weight (PWWT). However the
full impact is reduced by suboptimal ewe nutrition (Hegarty et al., 2006c). As
production factors such as dam breed, dam age and lamb birth type (single or multiple)
can act as a source of nutritional restriction, the impact of PWWT may vary with these
3
production factors. This is important to investigate so producers can temper their
expectations of lamb weights based on production factors when using ASBVs.
Impacts of genetic selection for increased growth using ASBVs on measures of meat
quality have been published. Selection for increased growth via an increased PWWT
has no impact on intramuscular fat (Pannier et al., 2014c), consumer overall liking
(Pannier et al., 2014a), iron and zinc concentration (Pannier et al., 2014b) or rate of
meat browning (Calnan et al., 2014). While these meat quality traits not impacted by
selection for increased growth via the PWWT ASBV, what remains to be investigated is
the impact of PWWT on indicators of oxidative capacity and thus fibre type.
Meat Standards Australia (MSA) is an eating quality program for beef and sheep meat,
based on extensive consumer research (MSA, 2012). All sheep meat which falls under
the banner of the MSA program has to meet strict criteria including a minimum weight
gain of 100-150 g/day, depending on breed, for 2 weeks prior to consignment. Thus
animals need to be fed to potential with appropriate nutrition to reach these growth
rates. As nutrition is an effect of environment, and the magnitude of the impact of
environment on meat traits in the studies above was larger than the magnitude of the
impact of genetic selection, growth itself may impact on meat traits. Hot carcass weight
has been used as a proxy for whole of life growth rate to indicate the association
between meat traits and growth (Calnan et al., 2014; Pannier et al., 2014a; Pannier et
al., 2014b; Pannier et al., 2014c). However, how carcass weight is dependent on age at
slaughter and is unlikely to be an accurate measure of whole of life growth rate. Rather
weight at a given age becomes less representative of growth and more representative of
environmental influences as animals get older. Furthermore, lamb growth is sigmoidal
while the association between hot carcass weight and growth indicates a linear
4
relationship. Therefore, the hot carcass weight effect cannot illustrate how the
association between growth and meat traits may vary across time.
The impact of lamb growth on meat traits needs to be investigated at key time points in
production such as birth, weaning and post weaning to determine whether growth
impacts meat traits and these time points and to quantify the magnitude of the effect.
This approach will also demonstrate how the association varies with time and show the
window of opportunity for the traits to be manipulated through growth.
Estimation of lamb growth at birth, weaning and post weaning time points is essential to
the implementation of appropriate management and feeding strategies to allow lambs to
grow to their full potential, increasing farm profitability. To sustain long term
profitability the potential impact of this growth on muscle fibre type and meat quality
needs to carefully examined as consumers are increasingly demanding, and willing to
pay for, increased eating quality (Pethick et al., 2006a). As lamb growth impacts the
economic viability of a production system the focus of these experiments was at a
highly practical and adoptable level for industry.
The Australian Cooperative Research Centre (CRC) for Sheep Industry Innovation
established an Information Nucleus Flock (INF) in 2007. It produced approximately
2,000 lambs for slaughter each year over a 5 year period. Objectives of the INF include
the measurement of a diverse range of phenotypic traits, including lamb weight,
estimation of the heritability of traits and estimation of genetic correlations between
traits (Mortimer et al., 2014). Information pertaining to genetic factors, such as sure
type and sire breeding values, and non-genetic factors such as site of rearing, year of
birth, sex, birth type-rear type combination, dam age and kill group were recorded or
calculated for each animal. The analysis and findings presented in this thesis are based
on date collected during the INF project.
5
Chapter 2. Literature Review
2.1 Animal growth
Animal growth is characterised by a change in live weight with time as animals follow a
trajectory to a final or mature size (Brody, 1945; Parks, 1982). This growth trajectory is
sigmoidal in nature (Figure 2-1) with an initial lag phase followed by the greatest
growth rate immediately after birth in the exponential phase. Growth rate then declines
as the animal nears its mature weight in the transitional phase which is followed by a
stable mature weight in the plateau or stationary phase after which further growth is
retarded (Hendrick et al., 1989).
Figure 2-1: A growth curve demonstrating the phases of growth with time: lag,
exponential growth, transitional diminishing growth and the stationary plateau at
maturity
Time
Wei
gh
t
6
Weight change measured over time results in longitudinal time series data.
Longitudinal data can be difficult to analyse, particularly if not all animals are weighed
at the time of interest. One option is to discard the weight information from animals not
weighed at the time of interest (Fitzhugh, 1976). However, incomplete weight data
recordings are common in industry therefore utilisation of the data that is available is
essential.
To overcome this, linear and nonlinear mathematical functions have been used to
estimate this sigmoidal shape based on available weight recordings. This results in the
ability to estimate weight for animals at times of interest, regardless of whether they
have been weighed at this time.
2.2 Growth curves
In an industry setting, animals are rarely weighed on a daily basis. In addition to the
labour and equipment required, weighing animals close to birth may increase the risk of
mis-mothering. Australian production systems are based on extensive grazing where
animals cannot practically be herded for weighing on a daily basis. Technologies such
as electronic identification and walk over weighing provide opportunities for the
collection of real time live weight measurements, however these technologies are still
being refined for use in extensive grazing systems (Brown et al., 2015; Scott, 2014).
A practical solution is the fitting of a growth function to available live weight data so
that weight can be estimated on a given day or across a time period of interest. This also
7
allows for the estimation of instantaneous growth rates which give an indication of how
the shape of the growth curve is changing.
Growth functions can be fitted on an individual or population basis using linear or
nonlinear functions. Each methodology has advantages and limitations, as outlined
below in Sections 2.2.1, 2.2.2 and 2.2.3.
2.2.1 Linear functions
A linear function is fitted on an individual animal basis and describes a simple
relationship where weight is a function of time only. This is true for polynomial
functions. Thus, linear, quadratic, cubic and quartic polynomials are all linear functions.
An example of first and third order polynomial functions fitted to lamb live weight data
is shown in Figure 2-2.
Figure 2-2 Graph of a linear (···) and cubic polynomial function (—) fitted to lamb live weight data (o) in
kilograms against time in days.
0
5
10
15
20
25
30
35
40
45
50
0 50 100 150 200 250 300 350
Wei
gh
t (k
g)
Age (days)
8
Initially, all animals have simple linear growth. However lambs often experience a
setback immediately after weaning (Atkins and Thompson, 1979) resulting in weight
loss, which is difficult to capture and quantify with a linear function (Emmans, 1997).
This results in an general lack of ability to describe growth over the entire range of life
from conception to adulthood (Taylor, 1978).
Linear functions are useful for the ability fit live weight data with ease, however there
are notable limitations to their use. When a linear function is used to model growth, the
curve parameters do not have biological interpretations, limiting the usefulness of the
information. Some linear functions also have unrealistic asymptotes, where weight
approaches but never reaches an extremely high or low weight value. For a cubic
polynomial, this can result in extreme overestimation of weight close to adulthood. This
effect is minimised when the function is fitted over a narrow range of weights where the
function has good fitting characteristics. For these reasons, individually fitted linear
functions are not used as commonly as nonlinear functions to model growth.
2.2.2 Nonlinear functions
Nonlinear functions are fitted on an individual basis and describe a relationship where
weight is a function of several parameters, one of which is time. Other parameters can
include birth weight, mature weight and growth rate, depending on the nonlinear
function used. Nonlinear functions are favoured as their parameters have simple
biological interpretations.
A number of nonlinear models are available with Parks (1982) demonstrating ten
nonlinear models that have been used to describe size-age relationships in animals. The
most commonly used functions are the Brody (1945), von Bertalanffy (1957), Richards
(1959), Logistic (Nelder, 1961), and Gompertz (Laird, 1965). These are based on
9
exponential functions, are sigmoidal in nature and reach an asymptotic value, equivalent
to an adult or mature weight, with time.
When the fit of nonlinear functions are compared, there is generally no one function
which fits best in all circumstances. Rather, the function that best fits live weight data
varies with both species and breed, as seen in Sections 2.2.2.1 and 2.2.2.2.
2.2.2.1 Nonlinear functions in sheep
The Gompertz function is empirically used to model growth in sheep in some studies,
without comparison with other functions. This is demonstrated in the Friggens et al.
(1997), Zygoyiannis et al. (1997) and Lewis et al. (2002) experiments.
However, each of the five functions mentioned in Section 2.2.2 has been assessed as the
best fit for sheep live weight data in at least one comparative study. The Brody function
demonstrated the best fit in the Gbangboche et al. (2008) experiment on West African
Dwarf sheep while the Logistic function had a superior fit for Brazilian sheep breeds in
both the McManus et al. (2003) and Malhado et al. (2009) experiments.
Richards and Gompertz functions were considered to have equally good curve fits for
Texel and Scottish Blackface lambs in the Lambe et al. (2006) experiment while in the
Topal et al. (2004) experiment the Gompertz function resulted in the best fit for the
Morkaraman breed, while the von Bertalanffy function was the best for the Awassi
breed.
The lack of a single nonlinear function which best fits live weight data is not unique to
sheep, with similar findings in cattle. With a lack of continuity in the best fitting
nonlinear function to use, factors such as ease of computation and proportions of
convergence become important considerations.
10
2.2.2.2 Nonlinear functions in cattle
A study in cattle showed that for two varying breeds, purebred Hereford and a
composite of Charolais, Angus and Galloway, the Richards function provided the best
overall fit to both sets of data (Goonewardene et al., 1981). The Richards function also
demonstrated the best fit in the Brown et al. (1976) and Denise and Brinks (1985)
experiments although it was noted in both experiments that the Brody function fit was
faster, computationally easier and resulted in similar estimated weights to the Richards
function. When Malhado et al. (2009) used the Richards function in sheep it had
difficulty converging limiting the usefulness of the function.
The Richards function, which is based on plant growth, is highly flexible however it has
no fixed inflection point which hinders the iterative process for the adjustment in the
function. Nonetheless, it has been used to describe growth in multiple species including
chickens (Gous et al., 1999; Hancock et al., 1995), pigs (Ferguson and Gous, 1993a,
1993b; Knap, 2000), quail (Akbas and Yaylak, 2000) and whales (Clark et al., 2000).
Despite the prevalence of the use of the Richards function it is not always the best
fitting function for live weight data with the Brody function (1945) having the best fit
for Angus cattle in the Beltrán et al. (1992) experiment and the von Bertalanffy function
(1957) function having the best fit in Retinta beef cattle in the López de Torre et al.
(1992) experiment.
2.2.2.3 Brody function
The Brody function (1945) has been used to model growth in sheep due to ease of
estimation, simplicity of interpretation (Bathaei and Leroy, 1996; Bathaei and Leroy,
1998; Topal et al., 2004) and its versatility (de Freitas, 2005).
11
Originally Brody (1945) intended the equation to be used after the point of inflection in
the self-inhibiting phase of growth, however no restrictions were placed on the values
for time (Doren et al., 1989). This may account of the tendency for the function for
overestimate early life growth. An example of the Brody function is shown in Figure
2-3.
Figure 2-3 A typical graphical representation of lamb live weight data with a Brody function fitted to
lamb live weight data (o) in kilograms against time in days.
In cattle the Brody function is also used to model weight (Doren et al., 1989) providing
the best fit between 18 months and maturity of Angus cattle in the Beltrán et al. (1992)
study. Before 18 months of age the Richards function gave the best fit due to the slight
overestimation of early weights with the Brody model, a fitting characteristic alluded to
previously.
A main disadvantage of the Brody function, and all functions fitted on an individual
basis, is the inability to accommodate different durations of data collection without
introducing bias estimating weights close to the edge of the available data. Population
0
5
10
15
20
25
30
35
40
45
0 50 100 150 200 250 300 350
Wei
gh
t (k
g)
Age (days)
12
based functions are less biased, accommodating different lengths as well as frequencies
of data.
2.2.3 Random Effects Model
A random effects model is a curve fitting methodology based on a population fit, with
the curve of each individual animal varying from the population curve. It is based on
polynomial functions with random coefficients, with orthogonal Legendre polynomials
chosen for their convergence properties (van der Werf and Schaeffer, 1997). A random
effects model is favoured for its ability to allow for variation in the covariance of weight
measurements with time.
Population based models have been widely used for the analysis of longitudinal data in
animals including live weight gain in pigs (Andersen and Pedersen, 1996), cattle
(Meyer, 1999; Meyer, 2000) and sheep (Fischer et al., 2004; Lewis and Brotherstone,
2002).
There are a number of important advantages, with the models able to be used for
animals with relatively few weight recordings or animals with records that are unevenly
distributed across ages of measurement (Fischer and Van der Werf, 2002). Therefore
random effects models can easily accommodate missing weight data from individual
animals, with the curve being informed by animals with similar genetic and
environmental effects (for example; sex, dam age and sire type). The ability to
accommodate different durations of data collection results in less biased estimates of
weight. The methodology also allows environmental effects specific to the time of
recording to be accounted for, and differences in the shape of each animals growth
curve can be accommodated (Lewis and Brotherstone, 2002).
13
A noted limitation is that nonlinear models cannot currently be accommodated (Lewis
and Brotherstone, 2002) so the coefficients do not have a clear biological interpretation.
Furthermore, when polynomials are used there is instability at the edges of the
trajectory (Fischer and Van der Werf, 2002; Meyer, 2002; van der Werf and Schaeffer,
1997) potentially leading to the overestimation of weight close to maturity.
The instability due to the use of polynomials is currently unresolved. Lewis and
Brotherstone (2002) proposed transforming nonlinear function into their linear analogue
(Portolano and Todaro, 1997) however this may require several transformations of the
nonlinear functions. Attempts to fit such a model have been problematic with difficulty
defining starting values and achieving convergence.
2.2.4 Residual weight
As the fit of a growth function appears to vary between breeds and experiments, it is
important to be able to compare different fits. Residual weight, the difference between
the estimated weight and the live weight recording, is commonly used as a measure of
curve fit as it is applicable to both linear and nonlinear curves. Average, squared or
summed residual weights have all been have been used to determine curve fit in sheep
(Topal et al., 2004) and cattle (Brown, 1970; Brown et al., 1976; Goonewardene et al.,
1981; Parks, 1982).
An advantage of the use of residual weights to determine curve fit is that residual
weight values are produced for each weight recording for each animal. Thus, curve fit
during different periods of growth can be determined by assessing residual weights
across the entire curve fit, as well as during the time period of interest.
14
2.3 Growth and tissue differentiation
The body is composed of bone, muscle, fat and viscera. Carcass composition refers to
the proportion of these tissues in the body (Berg and Butterfield, 1968). Bone, muscle
and fat vary in their rates of maturation (Berg and Butterfield, 1968; Butterfield, 1988).
During early growth muscle and bone growth predominate over fat deposition (Perry
and Thompson, 2005). As sheep mature, the proportion of bone declines, muscle
remains stable and the proportion of fat increases (Lewis et al., 2004; Thompson et al.,
1985a). Thus muscle and bone have been described as early maturing tissues and fat as
a late maturing tissue (Butterfield et al., 1983; Butterfield et al., 1984), as seen in Figure
2-4.
Figure 2-4 Change in carcass fat, muscle and bone as a portion of mature live weight during allometric
growth: Source (Butterfield et al., 1984)
15
An animal of large mature size takes a longer time to reach its mature weight than the
animal of small mature size. Differences in composition are evident when comparing
lambs tending toward different mature sizes. At a given age, the lamb tending toward a
large mature size will be less mature and therefore have a greater proportion of bone
and muscle than a lamb tending toward a smaller mature size which will be more
mature and have a greater proportion of fat (Berg and Butterfield, 1968; Butterfield et
al., 1984).
Mature size can vary with genotype, environment and production factors such as sex. In
the Australian lamb industry, selection pressure has been place on Terminal sire breeds
(Brown et al., 2007) for increased growth (Hall et al., 2002). This has resulted in leaner
carcasses at slaughter as the progeny of Terminal sires are reaching target market
weight when they are younger and less physiologically mature.
Despite selection pressures, when lambs do reach maturity they have similar
proportions of body tissues regardless of mature size (Thompson et al., 1985a).
Therefore there is no discernible difference between breeds of sheep in the rate of
maturation of bone, muscle and fat and breed differences in composition largely reflect
differences in maturity.
Mature size can vary with season. Between weaning and maturity, body composition is
subject to seasonal changes with Merino rams having increased fat weight during
summer and muscle weight during winter and Merino ewes having increased fat weight
during autumn in ewes (Ball et al., 1996).
Mature size also varies between sexes leading to variations in carcass composition at
maturity between rams, wethers and ewes despite similar patterns of maturation of
bone, muscle and fat. This was confirmed by Butterfield et al. (1984) who demonstrated
16
a greater proportion of muscle in rams and a greater proportion of carcass fat in wethers
and ewes.
2.4 Production factors influencing growth
Lamb growth is influenced by a variety of genetic and production factors. These factors
include sex, mature size, breed, nutrition, birth type and dam factors. An understanding
of the impact of these production factors on growth has specific advantages for
producers.
Producers are able to manipulate some production factors, such as breed and nutrition,
to achieve specific goals in lamb production including accelerated lamb growth. Other
factors, such as sex and birth type, are more difficult to manipulate, although an
understanding of how their impact on growth varies allows producers to moderate
expectations.
2.4.1 Sex
It is well established that male lambs have a heavier mature weight and are heavier than
female lambs at any given age (Gbangboche et al., 2008; Gbangboche et al., 2006b;
London and Weniger, 1994; Thompson et al., 1985a). Weight varies between male
lambs with entire male lambs heavier than castrate lambs. This is largely due to higher
levels of testosterone, a potent muscle growth stimulant, in entire male lambs
(Lawrence and Fowler, 2002). Thus, entire male lambs are heavier than castrate lambs
which are heavier than ewe lambs (Afolayan et al., 2007).
To achieve heavier weights, entire male lambs grow significantly faster than both
wether or ewe lambs (Lee et al., 1990). Likewise, Lee et al. (1990) found that wethers
17
grew faster than ewe lambs during early life growth, achieving heavier weights. Post
weaning, ewe lambs were found to grow faster than wether lambs although wether lamb
weights were not reached before lambs were slaughtered at six months of age.
While entire male lambs are faster growing and heavier than wether lambs it may not be
practical in a production setting to keep all male lambs entire. Ewe lambs are even
slower growing than wether lambs and will take longer than wether lambs to reach
target weights.
2.4.2 Genetics
2.4.2.1 Breed
In Australian sheep production sire types are classified by Sheep Genetics as Terminal,
Maternal or Merino (Brown et al., 2007). Terminal breed characteristics include rapid
lean growth of lambs, such as for prime lamb production. There are many Terminal
breeds, some of which include Suffolk, Texel and Poll Dorset. Maternal breeds such as
the Border Leicester and Dohne Merino have well developed reproductive and
mothering traits. Merino breed characteristics include superior wool production with
Merino breeds including Merino and Poll Merinos. Composite breeding has become
more common in the Australian sheep industry and when coupled with heterosis can
lead to increased fertility and litter size compared to the parental mean (Fogarty et al.,
1984).
Breeds differ in their mature weights and in the length of time taken to reach maturity
(Schreurs et al., 2008). The impact of sire and dam breeds on growth potential in their
progeny is largely a reflection of the mature size of the breed. Aligning with this,
progeny of Terminal breeds have been shown to be heavier than the progeny of
Maternal breeds at all ages (van der Werf and Wheaton, 1999). The progeny of breeds
18
with a larger mature size also have higher growth rates during all phases of growth than
the progeny of breeds with a smaller mature size (Perry and Thompson, 2005). This was
demonstrated by Thompson and Parks (1983) who showed food intake, efficiency and
consequent growth were largely functions of the mature size of the animal.
Ewe breed is a significant predictor of lamb birth weight (Afolayan et al., 2007; Holst et
al., 2002) which is positively correlated with adult or mature weight (Huisman and
Brown, 2008). A group of studies evaluating the impact of ewe breed on the weight and
growth rate of the progeny demonstrated that lambs from Border Leicester-Merino ewes
were both heavier than lambs from Merino ewes at birth (Holst et al., 2002) and had
higher pre weaning growth rates (Atkins, 1980; Atkins and Gilmour, 1981; Atkins and
Thompson, 1979). Specifically, Atkins and Thompson (1979) demonstrated a 40 gram
per day higher pre weaning growth rates in the progeny of Border Leicester-Merino
dams compared to the progeny of Merino dams.
Sire and dam breed both contribute to lamb growth and a change in genotype through
the introduction of a new breed or cross can impact lamb weights and growth rates in a
production system focused on high lamb growth.
2.4.2.2 ASBVs
Australian Sheep Breeding Values (ASBVs), developed by Sheep Genetics, are used to
make targeted genetic change within individual production systems within the
Australian sheep industry. Sheep Genetics analyses performance values, pedigree
information and relevant environmental and management information to determine
ASBVs for economically significant growth, wool, fertility, fitness and carcass traits
(Brown et al., 2007). There are several main components including LAMBPLAN™ for
Terminal and Maternal breeds and MERINOSELECT™ for Merino and Merino-based
breeds.
19
ASBVs are essentially an estimate of how that animals progeny will perform for a range
of traits (Brown et al., 2006) and contain information about the name of the trait, the
stage at which the effect is expected in progeny, an ASBV value and an accuracy, as
seen in Figure 2-5. Using ASBVs producers can select for increased growth in lambs.
This is achieved by selecting for a higher ASBV value for weight at the desired time
such as at birth, weaning or post weaning.
Figure 2-5 Interpretation of an Australian Sheep Breeding Value (ASBV) for post weaning weight based
on value, trait, age and accuracy. Source: Sheep Genetics
Producers are also able to select for changes in multiple traits at once using a selection
index. A selection index combines the values of ASBVs for several different traits into
one number. As can been seen in Figure 2-6 rams with differing ASBVs for weight,
muscle and fat may have a similar index value based on the weighting applied to each
individual ASBV. Indexes vary based on the breeding objective of the particular index.
20
For example, the Carcase Plus index has a 60% emphasis on increasing growth, 20% on
decreasing fat and 20% on increased eye muscle depth.
Figure 2-6 Selection index for rams (circled) based on Australian Sheep Breeding Value for weight
(PWT), muscle (PEMD) and fat (PFAT). Source: Sheep Genetics
With the fall in wool prices there is an increasing shift toward meat production (Banks,
2002; Curtis et al., 2006) and thus breeding for improved growth and carcass
characteristics. In Merinos, characteristics of live weight, fat depth and eye muscle
depth have been shown to be moderate to highly heritable. Therefore there is merit in
selection for these characteristics using breeding values (Clarke et al., 2003) with
ASBVs reliably predicting yearling and hogget weights in Merinos (Brown et al.,
2005).
Industry focus in on large, lean lambs with increased average slaughter weights (Hall et
al., 2002; Pethick et al., 2006a). This is achieved through multi trait selection to provide
simultaneous improvements in growth, fat depth and muscle depth (Banks et al., 2002).
21
Post weaning weight
Australian lamb producers select for lamb growth via an increased sire post weaning
weight (PWWT) ASBV. Selection for growth produces heavier lambs (Fogarty et al.,
1997; Hall et al., 2002) with increased mature size (Huisman and Brown, 2008), growth
rate (Thompson et al., 1985b), weight at slaughter and hot carcass weight (Gardner et
al., 2015; Gardner et al., 2010). Thus when lambs from high PWWT sires are compared
to lambs from low PWWT sires of the same age they are less physiologically mature.
The expression of the growth ASBVs in lambs, such as PWWT, is negatively impacted
by low nutrition of both the lamb (Hall et al., 2002; Hegarty et al., 2006b) and the ewe
(Hegarty et al., 2006c). In addition to environmental factors, production factors such as
multiple births, dam breed and dam age may restrict lamb nutrition.
Post weaning fat depth
Selection for a reduced post weaning fat depth (PFAT) in lambs reduces fat depth at the
c-site (5cm from the midline over the 12th
rib) in the loin (Hall et al., 2002; Hegarty et
al., 2006b), GR tissue depth (110 mm from the midline over the 12th
rib) (Hegarty et al.,
2006b) and loin fat weight (Gardner et al., 2010). The full expression of the PFAT
ASBV has been shown to be reduced with suboptimal lamb nutrition (Hegarty et al.,
2006b).
Post weaning eye muscle depth
Selection for increased post weaning eye muscle depth (PEMD) in lambs increases
muscle at the c-site in the loin (Hall et al., 2002; Hegarty et al., 2006a; Hegarty et al.,
2006b) by around 0.61 mm for each mm increase in sire PEMD ASBV irrespective of
plane of nutrition (Hegarty et al., 2006b). Selection for an increased PEMD and reduced
PFAT has been shown to increase lean meat yield in lambs (Gardner et al., 2010).
22
2.4.3 Nutritional restriction
Adequate nutrition is essential to maximise lamb growth potential. Lambs fed optimal
nutrition grow in a sigmoidal fashion whereas lambs with restricted nutrition have
fluctuations in their growth rate based on nutritional quality and availability. Producers
are able to mitigate some forms of nutritional restriction, such as restriction due to
seasonal pasture availability, through supplementary dam and lamb feeding to minimise
the impact on lamb growth where possible.
Environmental factors cause variation in lamb weights (Gbangboche et al., 2006a;
Gbangboche et al., 2008; Gbangboche et al., 2006b) with seasonal variation influencing
feed quality and availability (Perry and Thompson, 2005). Lambs born during high
rainfall seasons are less likely to experience nutritional restriction and are heavier and
faster growing than lambs born in dry seasons (Gbangboche et al., 2008; London and
Weniger, 1995). Nutritional restriction due to environmental and production factors can
also take place in-utero and pre weaning. When nutritional restriction is lifted post
weaning growth is accelerated, however additional nutritional and economic inputs may
be required to reach target weights after slow pre weaning growth (Greenwood et al.,
2009)
2.4.3.1 In-utero restriction
Animals have a predetermined mature size which is programmed during the early
embryonic stages of life however optimal nutrition is necessary for maximal expression
of genetic characteristics (Butterfield, 1988). In line with these findings Cafe et al.
(2006) found that plane of nutrition accounted for approximately 20% of the variation in
birth weight when comparing progeny of poorly fed and well fed Hereford cows.
23
The number of myofibres in each muscle is mostly determined prior to birth
(Greenwood et al., 2000a; Nissen et al., 2003). Malnutrition during the foetal period
may decrease the number of secondary fibres leading to a permanent reduction in
postnatal muscle growth potential (Hegarty and Allen, 1978; Wigmore and Stickland,
1983).
In line with these findings Fahey et al. (2005) found that restricted maternal nutrition
resulted in lambs developing fewer fast (glycolytic) fibres and more slow (oxidative)
fibres. This effect was seen when maternal nutrition was restricted before fibre
formation in lambs (days 30-70) but not with restriction after this period, highlighting
the importance of optimal maternal nutrition during early lamb growth in-utero.
2.4.3.3 Pre weaning restriction
Pre weaning, the dam provides the majority of the nutrition for the lamb through its
milk. However, when lactation declines the intake of pasture by the lamb increases
(Langlands, 1972). The main source of nutritional restriction during lactation occurs in
multiple birth lambs which experience sibling competition for available nutrition. Dam
milk volume increases by only 27% at peak yield in ewes with twin born lambs,
restricting milk volume on a per lamb basis (Morgan et al., 2006).
2.4.3.4 Post weaning restriction
In the post weaning phase, growing animals which have undergone any form of
restricted nutrition often experience accelerated growth when the restriction is lifted
(Berg and Butterfield, 1968; Hendrick et al., 1989). This has been demonstrated in
sheep (Thornton et al., 1979) and cattle (Brandstetter et al., 1998b) where growth was
depressed during a period of nutritional restriction followed by compensatory growth
upon restoration of nutrition.
24
2.4.4 Birth type and rear type
Number of lambs born per ewe, also defined as birth type, significantly impacts birth
weight at it acts as a form of in-utero nutritional restriction for multiple births. This
results in single born lambs being heavier than multiples (Yapi-Gnaorè et al., 1997)
such as twin born lambs (Gbangboche et al., 2008) and triplet born lambs (Afolayan et
al., 2007).
Gbangboche et al. (2008) hypothesised that the differential in weight in single versus
multiple birth types was due to a limited capacity for the dam to provide further in-utero
nourishment for the development of multiple foetuses and colostrum for new born
lambs. This pattern continues through to weaning where weight in multiple birth lambs
is further attenuated by increased rearing type (Afolayan et al., 2007). Hence, a lamb
born as a twin but raised as a single lamb is heavier than a lamb born and raised as a
twin.
Birth type is difficult to control in a production setting as many breeds of sheep have
high ovulation rates (Mulsant et al., 2001; Scaramuzzi and Radford, 1983). It is possible
to increase the ovulation rate (Juengel et al., 2004) however reducing the ovulation rate
is not easily achieved. Increased ewe and lamb nutrition is currently the most effective
and easily adoptable tool for optimising growth rates for multiple birth lambs.
2.4.5 Dam factors
The dam plays a significant role in lamb nutrition and growth being the sole source of
nutrition during early life growth. Multiple birth lambs are particularly susceptible to
factors which influence the ability of the dam to provide adequate nutrition to lambs.
These factors include dam nutrition, milk production and dam age.
25
2.4.5.1 Nutrition and feed restriction
While ewe nutrition is integral for the provision of lambs with adequate nutrition, the
significance of the nutritional restriction on progeny varies with the timing and duration
of the restriction. Short periods of nutritional restriction in Merino ewes during early
pregnancy did not significantly impact postnatal lamb growth if nutrition was adequate
in late pregnancy (Krausgrill et al., 1999). However, when ewe nutritional restriction
was sustained during lactation, subsequent underfeeding of lambs reduced the
expression of the genetic potential for growth in lambs (Hegarty et al., 2006b; Hegarty
et al., 2006c).
The sensitivity of lambs to dam nutrition varies when lambs are in-utero with triplet
born lambs more sensitive than twin born lambs. This was demonstrated by Everett-
Hincks et al. (2005) who showed that doubling pasture availability for ewes had no
effect on the birth weight of twin lambs while the birth weight and subsequently
survival of triplet lambs significantly increased.
2.4.5.2 Milk production
The maternal environment plays a role in determining birth weight and early life growth
of progeny, especially prior to weaning. Milk production by the dam is highly correlated
with lamb growth (Burris and Baugus, 1955). Therefore multiple birth lambs, which
have access to a reduced volume of milk per lamb compared to single born lambs
(Morgan et al., 2006), have reduced weight gain (Burris and Baugus, 1955). The
composition of milk is stable, despite multiple births, so volume is the limiting factor
(Burris and Baugus, 1955). Milk volume is a limiting factor regardless of multiple births
as single born lambs from ewes which produce high milk volumes grow faster than
single born lambs from ewes with low milk production (Burris and Baugus, 1955).
26
Ewe breed impacts milk production and lamb growth. Langlands (1972) showed that
lambs reared by Border Leicester ewes received more milk than lambs reared by Merino
ewes. The reduced milk production of Merino ewes was considered to be of secondary
significance if herbage was available ad libitum as lambs with high voluntary intakes
compensated for the lack of milk by consuming greater amounts of forage. However,
Merino lambs consumed less grass than Border Leicester lambs and grew more slowly
due to their lower overall voluntary food intake.
2.4.5.3 Dam age
As dam age and parity increases so does lamb birth weight (Gbangboche et al., 2008;
London and Weniger, 1995; Yapi-Gnaorè et al., 1997). This relationship is nonlinear
with a decline in lamb birth weight with increasingly older dams (Brown and Reverter,
2002; Huisman et al., 2008). In a study of 1-4 year old dams Afolayan et al. (2007)
demonstrated an average increase of 420 g in birth weight per year of increasing dam
age. The effect was considerably smaller in an earlier study by Ali et al. (2006) which
showed a 25 g increase in birth weight per year of increasing dam age. However, in this
study there was a larger range of dam ages, varying from 1 to 9 years old. In ewes aged
6 years and above, the effect of increasing birth weight was generally smaller and
occasionally negative, which may contribute to the lower average birth weight
compared to that found in the study by Afolayan et al. (2007). Borg et al. (2009) found
4-6 year old dams produced the heaviest lambs, although it was not possible to
determine whether the effect tapered beyond this age dams older than 6 years were not
included in the study. However, when considering these studies there was a trend for
lighter lambs to be born to younger and older dams.
Interestingly, a study on pregnant ewe lambs which were 7 months of age at
insemination showed that ewes fed to achieve moderate growth rates of 75g per day had
27
larger placental cotyledon mass and produced lambs with higher birth weights than
ewes fed to achieve higher growth rates on the same ration. Colostrum yield was also
lower in ewe lambs fed the greater volume of the same ration (Da Silva et al., 2001).
These findings seem counter-intuitive and the authors did not hypothesise why this may
have occurred. Furthermore, no information was provided on the amount (kg) of feed
offered or consumed by the high intake ewe group or expected and actual growth rates
in this group. Young, maiden ewes are known to lose more weight under conditions of
nutritional restriction than mature ewes, resulting in slower growth of progeny through
to slaughter (Hegarty et al., 2006b). However, when nutrition intake is high, the
influence on lambs is expected to be reduced. London and Weniger (1995) suggested
that since maiden ewes are generally still growing they are in competition for nutrients
with the foetus and this effect may be exaggerated in adolescent ewes.
2.5 Growth and fibre type
2.5.1 Muscle fibre classification
Skeletal muscle fibres make up 75-90% of skeletal muscle volume. They are classified
on the basis of several physical and metabolic properties, which include differences in
morphological traits, energy metabolism, contractile properties, metabolic properties
and colour (Lee et al., 2010; Lefaucheur, 2010; Picard et al., 2002).
Histochemical staining of skeletal muscle is a common procedure used to determine
fibre types by staining the contractile component of skeletal muscle, myosin. Myosin,
the major protein of skeletal muscle, is responsible for the contractile component of the
muscle fibres. It is composed of four light chains and two heavy chains (MHC), which
can exist in a number of different isoforms (Klont et al., 1998). The histochemical
28
classification is based on the MHC isoform and differentiates fibre types into type I, IIA
and IIB fibre types (Brooke and Kaiser, 1970).
The classification was revised to include a fourth fibre type when type IIX was
identified in several animals including mouse, rat, guinea pig and rabbit skeletal muscle
(Bär and Pette, 1988; Schiaffino et al., 1989). The IIX fibre type was later identified in
humans (Smerdu et al., 1994), pigs (Lefaucheur et al., 1998) and cattle (Tanabe et al.,
1998). The speed of contraction increases in the rank order I < IIA < IIX < IIB with type
I fibres considered slow twitch and type IIB fibres considered fast twitch (Schiaffino
and Reggiani, 1996).
The four muscle fibre types can also be identified according to their relative oxidative or
glycolytic metabolic characteristics. The metabolic types are differentiated by the
pathway used for regeneration of adenosine triphosphate (ATP) in the muscle
(Dubowitz and Pearse, 1960). The oxidative pathway, which oxidises glycogen,
glucose, lipids, ketone bodies and amino acids in the mitochondria, is aerobic with a
high oxygen requirement. The glycolytic pathway, through which glycogen is rapidly
converted to lactate, is anaerobic with no oxygen requirement (Lefaucheur, 2010).
Oxidative fibres are associated with higher levels of oxidative activity and thus
oxidative enzymes. Rate limiting mitochondrial enzymes such as citrate synthase and
isocitrate dehydrogenase are used to characterise the oxidative capacity of muscles
(Hocquette et al., 1998) with the relative expression of oxidative and glycolytic
enzymes used as an indicator of muscle fibre type in sheep (Gardner et al., 2007;
Gardner et al., 2006b; Lefaucheur, 2010).
The rate limiting enzymes of glycolysis, hexokinase, phosphofructokinase and lactate
dehydrogenase plus glycogen synthase and glycogen phosphorylase are commonly used
29
to qualitatively characterise the glycolytic activity of muscles (Hocquette et al., 1998).
Where oxidative and glycolytic fibres exist within the same muscle, the relative
composition of the muscle determines the predominance of the muscles metabolic
properties (Ozawa et al., 2000; Ryu and Kim, 2005).
The relative importance of these two metabolic pathways, as evidenced by ATPase
activity and enzyme expression (Barnard et al., 1971; Dubowitz and Pearse, 1960;
Engel, 1962; Peter et al., 1972), has been used to characterise muscle fibres as:
oxidative (type I, slow), oxido-glycolytic (type IIA, fast) and glycolytic (type IIX and
IIB, fast) (Ashmore and Doerr, 1971; Peter et al., 1972; Schiaffino and Reggiani, 1996).
In this thesis, metabolic characteristics will be used to define fibre type.
A summary of the contractile and metabolic characteristics, and the strength of
association, of each fibre type can be found in Table 2-1.
Fibre type I IIA IIX IIB
Contraction speed + +++ ++++ +++++
ATPase activity + +++ ++++ +++++
Oxidative metabolism +++++ ++++ ++ +
Glycolytic metabolism + ++++ ++++ +++++
+, very low; ++, low; +++, medium; ++++, high; +++++ very high.
Table 2-1 Contractile and metabolic characteristics of individual fibre types. Adapted from Lefaucheur
(2010).
30
2.5.2 Oxidative fibres
Oxidative fibres are red slow twitch type I fibres. These fibres require a high level of
oxygen and express large amounts of myoglobin for oxygen storage (Lefaucheur, 2010).
Due to the high myoglobin content and heme based pigments in mitochondria they
appear redder in colour (Murray et al., 1996). The mitochondria are also larger and
more populous (Klont et al., 1998) in oxidative compared to glycolytic muscle cells
(Hoppeler, 1985). Oxidative fibres have low ATPase activity, allowing for sustained
prolonged low power work (Lefaucheur, 2010). The ability to sustain low intensity
contractions for basic movements is facilitated by efficient vascularisation (Nelson and
Cox, 2005), small fibre diameter and a high Ca2+
sensitivity (Lefaucheur, 2010).
2.5.3 Glycolytic fibres
Glycolytic fibres are white, fast twitch type II fibres. When compared to oxidative fibres
they have a lower vascularisation, larger fibre diameter and fewer mitochondria (Nelson
and Cox, 2005), and are associated with lower levels of myoglobin, thus appearing paler
in colour. Type IIB glycolytic fibres were first demonstrated in the longissimus in cattle
by Picard and Cassar-Malek (2009). Glycolytic fibres have a high ATPase activity
(Ashmore and Doerr, 1971). These fibres use only glucose as an energy source (Murray
et al., 1996) and sustain brief and intense contractions (Lefaucheur, 2010).
2.5.4 Muscle fibre development
Muscle fibre development begins during early embryonic life when the myogenic
precursor cells (myoblasts) proliferate and fuse into myotubes. Myoblasts have been
isolated at different stages of development and are called embryonic, foetal and adult
myoblasts based on their distinct properties (Harris et al., 1989; Hoh et al., 1988;
Stockdale, 1992). Muscle fibres in adult animals are derived from different myoblast
31
populations (Harris et al., 1989; Vivarelli et al., 1988) and the regulation of this process
is complex (Stockdale, 1992).
In lambs there are three waves of myotube formation from myoblasts which
differentiate to form the origin of the different muscle fibre types. These are the
primary generation, which differentiates for form type I fibres, the secondary
generation, which differentiate to form type II fibres and the third generation which
differentiates to form both type I and type II fibres (Picard et al., 2002).
Muscle fibres express developmental MHC during gestation which is progressively
replaced by adult MHC (Picard et al., 1994; Robelin et al., 1993). Primary fibres in
sheep appear at 32 days of foetal life (Wilson et al., 1992). These fibres express the
slow MHC I isoform, characteristic of type I fibres (Cho et al., 1994; Condon et al.,
1990; Lyons et al., 1990; Picard et al., 1994; Robelin et al., 1993). Secondary fibres in
sheep appear at 38 days of foetal life (Wilson et al., 1992). Most of these develop into
type IIA, IIX or IIB fibres (Ashmore et al., 1972; Picard et al., 1994; Robelin et al.,
1990). Tertiary fibres in sheep appear between 62 and 76 days of foetal life (Wilson et
al., 1992). These develop into a mix of type I and type II fibres (Picard et al., 2002;
Picard et al., 1994).
Thus as developmental MHC expression reduces the proportion of adult MHC increases
resulting in the development of type I and type II fibres. In sheep, foetal MHC
disappears between 140 days of foetal life and 28 days after birth (Maier et al., 1992).
Fast adult MHC mostly occurs after birth in sheep with the proportion of type I fibres
increasing during the first 8 weeks after birth (Suzuki and Cassens, 1983).
Following the waves of myogenesis, the total number of fibres is fixed. In cattle this is
complete by the last third of gestation (Gagniere et al., 1999; Picard et al., 1994) and in
32
pigs by 80% gestation (Wigmore and Stickland, 1983). This is consistent with the
finding that muscle fibre numbers remain constant after birth in cattle (Joubert, 1956;
Robelin et al., 1990; Wegner et al., 2000). Therefore, increase in muscle volume is due
to the increase in size of the existing fibres (Hawkins et al., 1985; Wegner et al., 2000).
2.5.5 Production factors impacting fibre type
Lamb growth rate has a large impact on muscle fibre type. In addition to growth, muscle
fibre type is influenced by a variety of environmental, genetic and production factors.
These include sex, nutrition and breed. The response of fibre type to these factors varies
between different skeletal muscles. Unless stated otherwise the changes reported in
Section 2.5.5 occurred in the longissimus muscle, which is the focus of this thesis due to
its commercial value.
2.5.5.1 Age and growth rate
Change in muscle fibres characteristics is related to several factors however age has the
most significant impact on fibre type (Suzuki and Cassens, 1983; White et al., 1978).
Type I oxidative fibres and activity of oxidative enzyme isocitrate dehydrogenase have
been shown to increase with age in cattle (Brandstetter et al., 1998a) and sheep
(Greenwood et al., 2007; Suzuki and Cassens, 1983) while activity of the glycolytic
enzyme lactate dehydrogenase is reduced (Brandstetter et al., 1998a).
Muscle fibre characteristics also vary with growth rate. The comparison of extreme
genetic models of growth, such as wild compared to domesticated animals within
different species, suggests that selection for increase growth rates correlate with
increased myofibre diameter and a less oxidative metabolism (Ashmore, 1974; Rahelic
and Puac, 1981; Ruusunen and Puolanne, 2004; Solomon and West, 1985; Weiler et al.,
1995). These findings align with a shift between type IIA and IIB fibres with an
33
increased hot carcass weight (Hawkins et al., 1985), which is a proxy for increased
whole of life growth rate. However, the relationship varies within conventional
domestic species and increased growth rates in lambs did not impact the proportions of
muscle fibre types in the Arnold and Meyer (1988) study.
2.5.5.2 Sex
Ryu et al. (2008) found no difference in muscle fibre type proportions between the
sexes in pigs and there was no difference in total number of fibres in pigs (Staun, 1963)
or mice (Rowe and Goldspink, 1969). This is despite significantly larger muscle fibres
being found in female pigs (Larzul et al., 1999; Miller et al., 1975; Solomon et al.,
1990).
Several studies have found that castration has little impact on muscle fibre classification
in cattle (LaFlamme et al., 1973; Ockerman et al., 1984; Young and Bass, 1984).
However, previous work on the m. longissimus dorsi by Brandstetter et al. (1998b)
demonstrated an increase in the proportion of oxidative type I fibres in bulls and of
glycolytic type IIB fibres in steers at 12 months of age. Castration was thought to have
delayed the shift toward oxidative type I fibres that occurs with age by decelerating the
re-conversion process of type IIB to IIA to I which occurs after birth in cattle.
2.5.5.3 Nutrition and feed restriction
Under Australian extensive production systems, season fluctuations have an important
role in determining feed availability and feed intake. Variation in nutrition due to
different proportions of pasture or concentrate or varied protein content has been shown
to impact on muscle fibre type and enzymatic expression (Greenwood et al., 2006b;
Moody et al., 1980). However, the associations between nutrition and muscle fibre
types vary. Hocquette et al. (2001) suggested that oxidative muscles are more sensitive
34
to nutritional variation than glycolytic muscles. Gardner et al. (2006b) suggested that
changes in lamb nutrition may uncouple the link between muscle fibre type and
metabolic enzyme expression, although in contrast to the Hocquette et al. (2001)
findings this was less prevalent for oxidative enzyme expression.
Feed restriction has been shown to induce changes in muscle mass and the proportion of
oxidative fibre types in ruminants. In a study of two groups of lambs Solomon and
Lynch (1988) found that restricted lambs, who were fed a diet containing a third less
metabolisable energy, had a lower proportion of type IIB fibres and a higher proportion
of type IIA. The trend toward a more oxidative metabolism in animals experiencing
feed restriction was also demonstrated by Brandstetter et al. (1998b) in growing bulls
that had been restricted for 3 months. This effect reversed with re-feeding with the
activity of the oxidative enzyme isocitrate dehydrogenase lower in re-fed bulls
compared to bull calves fed a growth ration (Brandstetter et al., 1998b).
2.5.5.4 Breed and genetics
Genetic selection for post weaning growth, muscling and leanness has been shown to
impact on muscle fibre type. Previous work by Greenwood et al. (2006c) has
demonstrated that selection for increased muscling and leanness through the use of sires
with high PEMD and low PFAT, increases the percentage of glycolytic type 2B/X
myofibres. In the same study, selection for growth through the use of sires with high
PWWT had a smaller effect than selection for muscle and leanness (Greenwood et al.,
2006c).
There is evidence demonstrating that a similar effect is seen in beef cattle, with an
increase in muscle linked to an increase in glycolytic muscle fibres. Charolais bulls with
a high muscle growth index experienced muscle hypertrophy with growth, due to a
higher total number of fibres (Picard et al., 2006). These hypertrophied muscles have
35
fibres with the contractile and metabolic properties of type IIX fibres, suggesting that
bulls with high growth potential also have greater numbers of glycolytic fibres.
2.5.6 Fibre type and meat quality
Muscle fibre characteristics are an important determinant of meat quality (Joo et al.,
2013) through its associations with meat colour, intramuscular fat, mineral content and
changes to oxidative capacity (Kim et al., 2013; Lee et al., 2010; Maltin et al., 1998;
Valin, 1988; Valin et al., 1982) . These relationships are discussed in Section 2.6.
An example of the impact of fibre type on meat quality is seen in the selection for
increased muscle in cattle which reduces muscle oxidative capacity and increases the
glycolytic potential of the muscle. This is associated with in a reduced myoglobin
concentration, resulting in paler meat (Bailey et al., 1982; Clinquart et al., 1994), which
is less appealing to the consumer. Myoglobin content is also an important determinant
of the nutritional value of meat as reducing myoglobin concentration proportionately
reduces red meat iron concentration (Hazell, 1982) and negatively affects the nutritional
value of the meat product (Pethick et al., 2006a).
Selection for growth can impact muscle fibre type, and muscle fibre type is associated
with meat quality traits. Therefore growth can impact meat quality traits and the
magnitude of these impacts needs to be quantified.
2.6 Growth and meat quality
Genetic and phenotypic selection for growth is common to increase growth rates and
achieve target weights over a shorter time frame. Selection for increased growth rates
affects muscle fibre type, and muscle fibre type impacts meat quality. Furthermore,
36
early and late life growth have been shown to be different traits (Lewis and
Brotherstone, 2002) so the impact of selection for growth on fibre type and
subsequently meat quality may vary with time. Therefore, the associations between
growth, fibre type and meat quality need to be explored.
Meat quality relates to eating quality, nutritional value and meat colour (Warner et al.,
2010). Consumers demand a consistently high quality lamb product (Pethick et al.,
2005a) and are willing to pay a premium for a high quality product (Pethick et al.,
2006a).
While lamb growth influences a variety of traits, this thesis will be restricted to the
influence of lamb growth on muscle fibre type and the meat traits which are directly
linked to muscle fibre type: intramuscular fat, shear force, consumer overall liking,
isocitrate dehydrogenase activity, myoglobin concentration, iron concentration, zinc
concentration and meat browning.
2.6.1 Intramuscular fat
Animals have multiple fat depots with intramuscular fat being the adipose tissue
contained within muscles. It is comprised of adipocytes which are embedded in a
connective tissue matrix with triacylglycerol (TAG) being the major lipid component
(Murray et al., 2004b).
Intramuscular fat is an early maturing depot in relation to total carcass fat, increasing
only marginally as sheep mature (McPhee et al., 2008; Thompson et al., 1987).
Adipogenic and lipogenic genes are expressed during early life growth in cattle
indicating an early molecular changes associated with intramuscular fat content (Wang
et al., 2009). These findings are in line with studies which indicate the potential for
development of intramuscular fat is fixed during early life growth (Beaulieu et al.,
37
2010; Kirkland and Dobson, 1997; Pethick et al., 2004). Factors which influence
intramuscular fat levels in lambs may therefore exert a greater effect in the perinatal
period than when animals are more mature.
Intramuscular fat is measured by chemical determination using a near infrared (NIR)
procedure with readings validated with chemical fat determination using solvent
extraction (Perry et al., 2001). Measurements are commonly made in the m.
longissimus lumborum due to the economic value of the cut and the importance of
intramuscular fat in meat eating quality (Pannier et al., 2014c). Intramuscular fat can
also be estimated by evaluating the amount of fat visible within the muscle tissue of the
m. longissimus lumborum in cattle, although it is less visible in sheep. This portion of
intramuscular fat, visible at normal storage temperatures, is known as marbling.
Marbling is readily identifiable enabling its use by industry, for example for grading
beef carcasses under the Meat Standards Australia (Polkinghorne et al., 1999). Marbling
is also used by consumers as an indicator of high eating quality, but high levels of
intramuscular fat have adverse effects on consumer acceptability due to increased
visibility of fat in meat. Importantly however, a minimum level of intramuscular fat in
meat is essential due to its positive correlation with the subjective measures of eating
quality, tenderness, flavour, juiciness and consumer rated overall liking (Thompson,
2004).
Consumers rate their satisfaction with lamb based on flavour, tenderness, odour,
juiciness and overall liking (Pethick et al., 2006b). Intramuscular fat is positively
associated with flavour, juiciness, tenderness and overall liking in sheep (Hopkins et al.,
2006; Pannier et al., 2014c) and pigs (Murray et al., 2004a). In beef intramuscular fat is
positively associated with flavour and juiciness (Thompson, 2004) and accounts for up
to 15% of the variation in palatability in beef (Dikeman, 1987). A reduction in
38
intramuscular fat is detrimental to these organoleptic meat qualities (Hocquette et al.,
2010; Wood et al., 2008) including juiciness , flavour (Wood et al., 2008) and
tenderness (Dikeman, 1987). Thus intramuscular fat is a key determinant of eating
quality in red meat (Harper and Pethick, 2004) and in sheep explains more of the
variation in tenderness and overall liking than production factors such as sex and sire
type (Pannier et al., 2014a).
Reduced levels of intramuscular fat result in meat which is perceived by consumers as
dry and less tasty (Channon et al., 2001; McPhee et al., 2008). Acceptable levels in
beef, pork and lamb are quoted by Savell and Cross (1988) as 3-4% while Hopkins et
al. (2006) found a minimum level of 5% was required to achieve an average sensory
score for overall liking for sheep meat.
Oxidative muscle fibres are associated with higher levels of intramuscular fat (Picard et
al., 2002) and intramuscular fat has strong associations with eating quality. Therefore
the impact of growth on fibre type and thus intramuscular fat is likely to impact all of
the meat traits examined in this thesis.
2.6.1.1 Intramuscular fat and growth
Evidence exists for growth impacting intramuscular fat with the rate of accretion
slowing down as animals near their mature size (McPhee et al., 2008).
Nutrition during growth is important for intramuscular fat development. Nutritional
restriction in lambs results in slower growth and weight gain causing a reduction in
intramuscular fat (Murphy et al., 1994). Conversely, pigs with increased growth rates
due to higher protein diets had reduced intramuscular fat (Karlsson et al., 1993).
However this is likely due to reduced maturity at the time of slaughter rather than a
reduction in intramuscular fat deposition.
39
Hot carcass weight at slaughter can be used as a proxy for whole of life growth rate to
determine the impact of growth in intramuscular fat. This approach was taken by
Pannier et al. (2014c) and demonstrated an increase in intramuscular fat in lambs with
increased growth.
Breeding values can be used to select for growth and lean meat yield in lambs. Selection
for increased growth using the PWWT ASBV did not impact intramuscular fat (Pannier
et al., 2014c). Meanwhile, selection for leanness and muscle using the PFAT and
PEMD ASBVs reduced intramuscular fat (Pannier et al., 2014c). Genetic potential for
muscle growth in bulls was found to be correlated with reduction in activity of the
oxidative enzyme citrate synthase, and therefore an increased glycolytic capacity of the
muscle fibre types in bulls and as oxidative capacity is positively linked with
intramuscular fat, bulls with higher muscle growth had lower intramuscular fat
(Hocquette et al., 2012).
Existing evidence for the impact of growth on intramuscular fat therefore indicates that
slow growth due to feed restriction leads to reduced intramuscular fat while increased
growth leads to heavier hot carcass weights and increased intramuscular fat. Increased
growth rates may also be associated with reduced intramuscular fat if animals are
slaughtered when they reach target weights at younger ages when they are less
physiologically mature. The influence of prenatal muscle fibre development on
intramuscular fat (Picard et al., 2002) may also lead to animals with an increased
potential for muscle growth, leading to higher proportions of glycolytic muscle fibres,
having reduced levels of intramuscular fat.
2.6.1.2 Production factors which influence intramuscular fat
Intramuscular fat varies with production factors including age, nutrition, sex, and
genotype. The increase in intramuscular fat with age is well documented in sheep
40
(Hopkins et al., 2007; McPhee et al., 2008; Pannier et al., 2014c; Pethick et al., 2005c)
although the increase is quantitatively small and there is a large degree of overlap
between animals of differing ages (Hopkins et al., 2005).
Nutrition impacts intramuscular fat development however the effect in sheep is small
compared to genetic impacts (McPhee et al., 2008; Pannier et al., 2014c). The timing of
the restriction is important. In cattle, in-utero nutritional restriction has not been shown
to impact intramuscular fat development (Greenwood and Cafe, 2007; Greenwood et
al., 2006a) while a 30% feed restriction in pigs during the growing-finishing phase
caused a reduction in intramuscular fat (Čandek-Potokar et al., 1999). Since nutritional
restriction limits growth, the impact of restriction on intramuscular fat may be delivered
through its impact on growth.
Sex has been shown to influence levels of intramuscular fat. Ewe lambs have been
shown to have greater amounts of intramuscular fat then wether lambs (Pannier et al.,
2014c) and ram lambs (Craigie et al., 2012). While Tejeda et al. (2008) showed no
difference in intramuscular fat between ewe lambs and ram lambs this conclusion was
based on a relatively small study in Merino lambs (n = 48), compared to n = 208 Texel
lambs in the Craigie et al. (2012) study and n = 5,867 lambs from Terminal, Maternal
and Merino sires in the Pannier et al. (2014c) study. Thus the small sample size of the
Tejeda et al. (2008) study may not be sensitive enough to detect a significant effect
between sexes.
Age has also been found to reduce the sex effect on intramuscular fat. Muscle samples
from the m. longissimus dorsi analysed for intramuscular fat from mature sheep showed
no differences between entire and vasectomised rams or between wethers and ewes.
However, intramuscular fat of entire and vasectomised rams was significantly lower
than in either ewes or wethers (Okeudo and Moss, 2007).
41
Intramuscular fat varies with lamb genotype (Díaz et al., 2005). As mature size, and
thus growth rate to attain mature size, varies between breeds the variation in
intramuscular fat with genotype may simply reflect the impact of growth rate on
intramuscular fat rather than a specific breed difference.
Díaz et al. (2005) found that the variation in intramuscular fat between sheep breeds
was similar in magnitude to the variation found by McPhee et al. (2008), with Border
Leicester x Merino animals having the highest increase in intramuscular fat in the loin,
compared to other breeds. The impact of the Border Leicester genotype on
intramuscular fat is consistent with the increase in overall carcass fat levels (Hopkins
and Fogarty, 1998; Hopkins et al., 2007; Ponnampalam et al., 2007).
In a study by Wegner et al. (2000), the level of intramuscular fat did not vary between
four breeds of cattle; German Angus, Galloway and Holstein Friesian. In the same
experiment Belgian Blue cattle, which are selected for double muscling with a mutation
of the myostatin gene causing muscle hyperplasia, had comparatively lower levels of
intramuscular fat. Belgian blue cows within this study also had a greater proportion of
glycolytic type IIB fibres, which are associated with lower intramuscular fat levels
(Hwang et al., 2010). The effect of fibre type on intramuscular fat levels will be
discussed in Section 2.6.1.3.
2.6.1.3 Intramuscular fat and fibre type
The relationship between intramuscular fat and fibre type is not always simple or clear
(Hocquette et al., 2010; Lefaucheur, 2010) however intramuscular fat content is linked
to oxidative muscle fibre types and oxidative enzyme activity. As discussed below,
oxidative muscle fibres are generally associated with higher levels of intramuscular fat.
A notable exception is the study in bison with highly oxidative muscles and low levels
of intramuscular fat (Agabriel et al., 1998).
42
Intramuscular fat is positively correlated with the percentage of oxidative muscle fibres
(Essen-Gustavsson et al., 1992; Maltin et al., 1998) and negatively correlated with
glycolytic muscle fibres (Hwang et al., 2010). In support of these findings oxidative
enzyme activity is increased in oxidative fibres in cattle and in breeds of cattle that have
higher levels of intramuscular fat (Hocquette et al., 2003; Jurie et al., 2007), with
oxidative muscle fibres being associated with higher levels of intramuscular fat (Picard
et al., 2002).
Intramuscular fat content and proportions of myosin heavy chains I (slow) and IIA (fast
oxido-glycolytic) and enzymatic indicators of oxidative metabolism; citrate synthase,
isocitrate dehydrogenase (ICDH) and cytochrome-c oxidase and the expression of H-
fatty acid binding protein have been shown to be higher in the slow oxidative rectus
abdominis muscle compared to the fast glycolytic semitendinosus muscle (Hocquette et
al., 2012). Amongst oxidative metabolic markers cytochrome-c oxidase was better
correlated to TAG than enzymatic indicators within the mitochondrial matrix
(hydroxyacyl-CoA dehydrogenase, citrate synthase and ICDH) (Hocquette et al., 2012).
Genotypes characterised by a high oxidative muscle metabolism have increased levels
of intramuscular fat (Jurie et al., 2007). This is interesting considering high fatty acid
catabolism is a characteristic of oxidative muscles, although a high fatty acid turnover
may also favour fat deposition (Gondret et al., 2001). Jurie et al. (2007) found a high
correlation between TAG deposition and A-fatty acid binding protein, which is
expressed exclusively within adipocytes and not within muscle fibres indicating that
intramuscular adipocyte number (rather than intra fibre fat) is the major biological
mechanism that contributes to TAG accumulation.
Therefore, muscles with higher intramuscular fat levels have a greater number of
oxidative muscle fibres and a greater ability to break down intramuscular fat. This may
43
reflect a synergistic biological relationship between these two tissues as the oxidative
muscle uses the intramuscular fat breakdown products as fuel.
2.6.2 Shear force
Warner-Bratzler shear force is an objective measure of tenderness and describes the
force required, in Newtons or kilograms, to shear a cooked meat sample with a Warner-
Bratzler shear blade (Hopkins et al., 2010). Whilst objective measurements of meat
quality such as shear force and compression have the advantage of being cheaper than
sensory panel testing for tenderness, they are rather simplistic one-dimensional
measures of a complex set of interactions which occur when cooked meat is chewed and
masticated in the mouth (Perry et al., 2001; Watson et al., 2008). Furthermore, they are
destructive to the carcass and time consuming (Hwang et al., 2008; Watson et al.,
2008). Despite this, Huffman et al. (1996) reported that consumer ratings were
consistent with Warner–Bratzler shear values in beef and (Safari et al., 2001) advocated
the use of shear force as a criterion for determining consumer acceptability of loin from
lambs.
Sensory scores are rated out of 100 by consumers. They are subjective measurements of
meat eating quality and have a negative correlation with shear force. Increasing shear
force is associated with a reduction in tenderness, flavour, juiciness and overall liking
(Hopkins et al., 2006; Pannier et al., 2014a; Safari et al., 2001). In the Pannier et al.
(2014a) study sensory scores for tenderness, overall liking, juiciness and flavour
reduced by 11.6, 8.5, 7.6 and 7.4 respectively across the 37 N range in shear force.
The phenotypic correlation between intramuscular fat and shear force after 5 days of
ageing in lamb is -0.30 (Mortimer et al., 2014), suggesting selection for one will also
influence the other. There are similar findings in pigs, where there is also a negative
44
correlation between shear force and intramuscular fat (Karlsson et al., 1993). As shear
force is correlated with intramuscular fat both can be used as indirect predictors of
eating quality. Indirect predictors are useful as the cost of measuring sensory parameters
with taste panels is often prohibitive.
2.6.2.1 Shear force and growth
Growth rate can be difficult to directly quantify and carcass weight, average daily gain
and nutritional restriction are commonly used as proxies for growth rate to investigate
the impact of growth on shear force. In general, shear force does not vary with carcass
weight, average daily gain or growth rate, although there are some exceptions.
Lambs slaughtered at either medium or light live weights had no differences in shear
force, despite differences in carcass fatness between the two groups (Vergara et al.,
1999). This aligns with the findings of Kemp et al. (1980) which also demonstrated no
relationship existed between shear force and slaughter weight in lambs. Conversely,
there was a low negative correlation between hot carcass weight and shear force of -
0.15 found by Vergara et al. (1999), however this was not supported by a phenotypic
association in the same study. There are conflicting reports in beef with a reduction in
shear force seen in crossbred steers as carcass weights increased with age (Bouton et al.,
1978) but no relationship between shear force and carcass weight Japanese Black steers
(Ozawa et al., 2000).
Studies of average daily gain and shear force in cattle had varied results. A group of 48
bulls with average daily gains ranging from between -0.55 kg and 1.36 kg showed no
relationship between shear force and growth rate (Calkins et al., 1987). This aligns with
the findings of Perry and Thompson (2005) of no change in shear force with variations
in average daily gain and Greenwood et al. (2006a) of no influence of pre weaning
growth on shear force.
45
Meanwhile, Fishell et al. (1985) assigned 36 steers to one of three feeding regimes for
120 days pre slaughter. The unrestricted group had an average daily gain of 1.42 kg, the
moderately restricted had an average daily gain of 0.77 kg and the highest restricted
group had an average daily gain of 0.34 kg. In both the longissimus and
semimembranosus shear force was significantly lower in unrestricted animals with
faster growth rates compared to animals with restricted nutrition and slower growth
rates. This relationship is further evidenced by the negative phenotypic correlation
found between average daily gain and shear force in cattle (Shackelford et al., 1994).
The difference is in the Calkins et al. (1987) and Fishell et al. (1985) studies is unlikely
to be related to the effects of testosterone between bulls and steers with Moloney et al.
(2000) reporting no difference in shear force with growth rate in steers.
Evidence for the association between shear force and growth is not clear. While there
was a small negative correlation between carcass weight and shear force in lambs there
was no phenotypic association (Vergara et al., 1999). In cattle there was also a negative
correlation, between average daily gain and shear force (Shackelford et al., 1994),
however the phenotypic association was not present in all studies discussed above.
2.6.2.2 Production factors which influence shear force
Shear force varies with production factors including age, sex, and genotype with shear
force being increased in older sheep (Hopkins et al., 2007) and cattle (Shorthose and
Harris, 1990) demonstrating an increase in sheer force with age at slaughter in cattle due
to an increase in collagen crosslinking.
Unlike age, sex and genotype do not appear to have a significant impact on shear force
in lambs with Kemp et al. (1980) demonstrating no difference between the sexes.
46
Shear force in 60 lambs did not vary between common Australian genotypes for lambs
born to Texel, Poll Dorset, Border Leicester and Merino rams (Safari et al., 2001).
Likewise there was no relationship between shear force and genotype in the Hopkins
and Fogarty (1998) study which involved a total of 436 lambs nor the Speck et al.
(1997) study which examined shear force in New Zealand lambs of different genotypes.
In cattle, shear force does not vary with breed with Wegner et al. (2000) showing no
difference between shear force in German Angus, Galloway and Holstein Friesian
cattle.
While shear force varied with age, there was no variation with sex or genotype. As sex
and genotype can represent differences in growth rates these findings align with the lack
of a phenotypic association between shear force and growth in lambs.
2.6.2.3 Shear force and fibre type
Shear force did not correlate with muscle fibre traits (Wegner et al., 2000) of Holstein-
Friesian, Belgian Blue, German Angus and Galloway which have very different growth
potential.
Muscles with a large fibre size, especially glycolytic type IIB fibres, exhibit tougher
meat than muscles with a narrower fibre diameter in cattle (Renand et al., 2001) and in
pigs (Karlsson et al., 1993). Thus shear force is likely to be reduced as the proportion of
smaller oxidative fibres increases.
Considering the relationship between fibre type and intramuscular fat, as discussed in
Section 2.6.1.3., it follows that as intramuscular fat increases and the oxidative capacity
of muscle increases, the muscle fibre diameter will decrease and shear force is likely to
reduce. This aligns with the findings of Calkins et al. (1981) who showed that muscle
fibre type composition has a stronger relationship with marbling than with shear force.
47
2.6.3 Overall liking
Overall liking, also called overall acceptability, is a subjective measure of meat quality
based on consumer sensory testing. Sensory enjoyment strongly influences the demand
for lamb in Australia and the willingness to pay of consumers (Pethick et al., 2006a).
Untrained consumers assess lamb steaks for overall liking out of 100, with 100 being
the most preferred. Untrained consumer taste panels are used as they are an accurate
reflection of the actual consumer base, despite their greater variance (Hwang et al.,
2008).
Overall liking is highly correlated with tenderness, juiciness and flavour (Pannier et al.,
2014a) and is considered a good subjective measurement of meat quality. Therefore,
factors which influence overall liking, such as intramuscular fat (Hopkins et al., 2006;
Pannier et al., 2014a), will influence consumer acceptability of meat products.
2.6.3.1 Overall liking and growth
The impact of growth on overall liking has not specifically been studied however
relationships between overall liking and sensory traits which have an association with
overall liking, such as juiciness and tenderness, can give an indication of the impact of
growth on overall liking. Unfortunately the relationship between other sensory traits and
growth is also unclear.
For example, juiciness, which is highly correlated to overall liking (Pannier et al.,
2014a), was not affected by growth rate in cattle (Fishell et al., 1985) while tenderness,
which is also highly correlated to overall liking in lambs (Pannier et al., 2014a), was
increased in cattle with higher growth rates (Fishell et al., 1985).
48
Furthermore, there is no clear relationship between selection for growth using the
PWWT ASBV and overall liking. Selection for growth reduced overall liking at only
one of the eight research sites in the Pannier et al. (2014a) study.
Selection for increased muscle using the PEMD ASBV has been found to reduce overall
liking. This effect is independent of the phenotypic impact of intramuscular fat on
overall liking (Pannier et al., 2014a). Therefore, selection for increased PEMD may
negatively influence eating quality for consumers.
2.6.3.2 Production factors which influence overall liking
Overall liking varies with production factors including age, nutrition, sex, and genotype
with older sheep having reduced sensory scores including overall liking (Hopkins et al.,
2006; Pannier et al., 2014a; Pethick et al., 2005c).
Nutrition treatments may impact on the sensory traits such as overall liking. Recent
work by Resconi et al. (2009) found that meat from lambs fed a concentrate only diet
had the highest overall liking as rated by a trained consumer taste panel when compared
to pasture fed lambs or lambs fed a combination of concentrate and pasture and alfalfa
hay. In contrast, there was no difference in overall liking in studies where untrained
consumers rated lamb which was fed different rations (Pethick et al., 2005a). Pannier et
al. (2014a) found that overall liking varied between research sites at which lambs were
raised and the year of birth, reflecting the impact that environment and nutrition has on
consumer sensory scores.
Sex has either no influence (Tejeda et al., 2008) or a small, variable, influence on
sensory scores in lambs. In the Teixeira et al. (2005) study males had an overall liking
score less than one unit higher than female lambs while in the (Pannier et al., 2014a)
study overall liking was higher in female lambs than male lambs by 1.5 units. However,
49
this difference can in part be attributed to the increased amount of intramuscular fat,
0.15%, in the loin of female lambs compared to wether lambs (Pannier et al., 2014c).
There is a variable impact of genotype on overall acceptability of lamb meat reported in
the literature. A study based on 60 lambs from Texel, Poll Dorset, Border Leicester and
Merino sires found no effect of genotype (Safari et al., 2001). Conversely, in a much
larger study based on 210 animals, Hopkins et al. (2005) found meat from Merino
lambs generally have lower sensory scores than meat from Terminal first cross lambs.
Dam breed however appears to have the opposite effect to sire breed with overall liking
higher in lambs from Merino dams when compared to meat from Border Leicester x
Merino dams (Pannier et al., 2014a).
While overall liking reduced with age it varied with nutrition, sex and genotype. These
conflicting findings highlight the need for further work to better describe and quantify
the effect of genotype on overall liking and the mechanisms through which this effect is
mediated.
2.6.3.3 Overall liking and fibre type
There are no studies which directly link overall liking and fibre type. Nonetheless, the
positive relationship between intramuscular fat and overall liking (Pannier et al., 2014a)
can be used to infer a positive relationship between overall liking and the proportion of
oxidative fibre types. As intramuscular fat is associated with increased oxidative fibre
types (Hocquette et al., 2003), factors which cause a reduction in oxidative fibre types
are likely to reduce intramuscular fat and thus overall liking.
50
2.6.4 Isocitrate dehydrogenase activity
Isocitrate dehydrogenase (ICDH; EC 1.1.1.42) is a crucial enzyme in the oxygen-
dependant citric acid cycle of mitochondria, which are larger and more abundant in
oxidative muscle fibres (Hoppeler, 1985). Due to its high correlation with oxidative
metabolism, ICDH activity is used as a marker of oxidative capacity and thus fibre type
(Gardner et al., 2006b).
2.6.4.1 Isocitrate dehydrogenase activity and fibre type
Muscle oxidative capacity is intrinsically linked to fibre type (Brandstetter et al., 1998a;
Staron and Johnson, 1993) with type I fibres having a greater expression of oxidative
enzymes such as ICDH (Brandstetter et al., 1998a; Peter et al., 1972). This is in contrast
to type II fibres which express higher levels of glycolytic enzymes (Brandstetter et al.,
1998a) and reduced levels of oxidative enzymes (Gardner et al., 2007; Gardner et al.,
2006b).
In bulls the transition between fibre types is marked by changes in metabolic
metabolism. As the proportion of oxidative fibres reduce and glycolytic fibres increase
before puberty in cattle, ICDH reduces and the activity of glycolytic enzyme lactate
dehydrogenase increases (Schreurs et al., 2008). This reflects the use of glycolytic
metabolism to supply energy during periods of rapid growth before puberty
(Brandstetter et al., 1998a).
The high correlation between ICDH activity and TAG (Jurie et al., 2007) aligns with
the use of fatty acids as an energy source for oxidative metabolism (Ashmore, 1974).
Considering this relationship, it follows that as intramuscular fat increases, ICDH
activity is likely to increase. This aligns with the findings of Jurie et al. (2007) who
51
showed that ICDH activity is increased in genotypes of cattle which deposit greater
amounts of intramuscular fat.
2.6.4.2 Isocitrate dehydrogenase activity and growth
There is a limited amount of information on how growth impacts muscle ICDH activity
in sheep but work in rabbits and rats has demonstrated higher ICDH activity with
increased growth rates (Pascual and Pla, 2007). This aligns with the findings in sheep
where growth is restricted due to nutritional restriction, resulting in reduced ICDH
activity (Gardner et al., 2006b). These associations may be affected by maturity with no
difference in ICDH Activity in rabbits selected for growth when compared at a similar
degree of maturity (Hernández et al., 2004).
In ruminants the existing evidence does not give a clear association between ICDH
activity and growth however it may be inferred from the association between ICDH
activity and muscle fibre type. ICDH expression is higher with type I muscle fibres
(Brandstetter et al., 1998a) and these fibres increase as animals mature (Brandstetter et
al., 1998a; Greenwood and Cafe, 2007). Therefore, a fast growing animal tending
toward a larger mature size is likely to be less mature at a given age when compared to a
slower growing animal tending toward a small mature size, which is likely to result in
reduced ICDH activity.
Selection for increased muscle in sheep increases the expression of type IIX fibres
(Wegner et al., 2000) resulting in a reduced expression of ICDH activity (Gardner et al.,
2006b).
2.6.4.3 Production factors which influence isocitrate dehydrogenase activity
ICDH activity varies with production factors including age, sex, and genotype. ICDH
activity increases with age (Brandstetter et al., 1998a; Gardner et al., 2007; Jurie et al.,
52
2005) and maturity (Schreurs et al., 2008), most likely due to increased proportions of
type I muscle fibres (Brandstetter et al., 1998a).
There is a small variation in ICDH activity between sexes with activity being 2% higher
in wethers than ewes (Gardner et al., 2007). Castration has also been found to impact in
cattle, with bulls having higher ICDH activity than steers, which aligns with the
increase in oxidative type I muscle fibres (Brandstetter et al., 1998b). Bulls also have a
reduced lipid concentration and which is likely to be due to the use of fatty acids as an
energy source for oxidative metabolism (Ashmore, 1974).
Genotype impacted significantly on ICDH activity with Border Leicester x Merino
sheep having up to 30% lower ICDH activity than Poll Dorset x Merino sheep
depending on the age at which the comparison was made from 8 to 22 months of age
(Gardner et al., 2007). Genotypes which express higher levels of intramuscular fat have
increased ICDH activity in sheep (Pethick et al., 2005c), cattle (Hocquette et al., 2003;
Jurie et al., 2007; Pethick et al., 2005c), pigs (Essén-Gustavsson et al., 1994) and
rabbits (Gondret et al., 1998). Selection for leanness in lambs results in a reduction in
intramuscular fat (Pannier et al., 2014c) therefore a concurrent reduction in ICDH
activity (Gardner et al., 2007; Gardner et al., 2006b) was to be expected.
2.6.5 Myoglobin concentration
Myoglobin is the heme protein primarily responsible for the colour of meat (Fox and
Jay, 1966; Kim et al., 2010; Livingston and Brown, 1981). Meat colour is the most
important attribute influencing purchase decisions (Mancini and Hunt, 2005), with
deviations from the bright cherry red colour of meat responsible for product rejection
(Suman and Joseph, 2013). Therefore myoglobin concentration is an important
consumer trait. Myoglobin is the primary oxygen-carrying pigment of muscle tissues
53
supplying oxygen to the mitochondria within muscle fibres (Wittenberg and Wittenberg,
2007). Other heme proteins, including haemoglobin (Rickansrud and Henrickson, 1967)
and cytochrome-c (Girard et al., 1990) are present but unlike myoglobin have little
effect on the colour of meat (Ledward, 1992).
There are four major chemical forms of myoglobin which are responsible for meat
colour, oxymyoglobin, deoxymyoglobin, metmyoglobin and carboxymyoglobin
(Giddings and Solberg, 1977; Mancini and Hunt, 2005) with the relative proportions of
these forms of myoglobin determining the colour of fresh meat.
Oxymyoglobin has the characteristic cherry red colour that is seen when myoglobin is
exposed to oxygen in the atmosphere. Oxygen is required to maintain this state.
Deoxymyoglobin is the deoxygenated state of myoglobin with a purplish red colour
typically associated with muscle immediately after cutting. Low oxygen tension is
required to maintain this state. Metmyoglobin is brown in colour and is formed when
the ferrous iron in either oxymyoglobin or deoxymyoglobin oxidises to ferric iron
(Livingston and Brown, 1981; Wallace et al., 1982). Carboxymyoglobin is formed
when deoxymyoglobin binds with carbon monoxide forming a bright red colour. This
commonly occurs during packaging with low levels of carbon monoxide (Hunt et al.,
2004; Luno et al., 2000; Sørheim et al., 2001).
The chemical reactions of oxygenation, oxidation, reduction and
carboxymyoglobination cause myoglobin to move from one chemical form to another
(Figure 2-7). During oxygenation, myoglobin is exposed to oxygen causing
deoxymyoglobin to convert to oxymyoglobin (Reaction 1).
Over time, as the oxygen within meat is utilised, oxymyoglobin is deoxygenated back
into the less stable deoxymyoglobin, which then becomes oxidised to form
54
metmyoglobin with oxidative triggers such as low oxygen partial pressure, temperature
and pH (Mancini and Hunt, 2005) (Reaction 3). This is a two-step process as
oxymyoglobin does not convert to metmyoglobin directly (Reaction 2). Enzymatic and
non-enzymatic processes can reduce ferric metmyoglobin back into ferrous
deoxymyoglobin (Reaction 4) with oxygen consumption, metmyoglobin reducing
activity and nicotinamide adenine dinucleotide (NADH) availability significantly
influencing the reaction.
Carboxymyoglobination occurs when carbon monoxide binds to deoxymyoglobin
(Reaction 5). The chemistry of this reaction is not completely understood however
deoxymyoglobin is more readily converted to carboxymyoglobin than oxymyoglobin or
metmyoglobin are. When carboxymyoglobin is exposed to atmospheres free of carbon
monoxide the carbon monoxide will slowly dissociate from myoglobin (Mancini and
Hunt, 2005).
Figure 2-7 Interconversions of myoglobin redox forms in fresh meat. Source: AMSA Color Measurement
Guidelines (AMSA, 2012)
55
2.6.5.1 Myoglobin concentration and fibre type
Myoglobin concentration is linked to muscle fibre type with type I muscles having a
greater concentration of myoglobin (Pethick et al., 2005c). Therefore, along with ICDH
activity, myoglobin concentration can be used as an indicator of oxidative metabolism.
Furthermore, factors which influence oxidative capacity are likely to influence meat
traits linked to muscle fibre type.
The increase in myoglobin concentration with age (Gardner et al., 2007; Pethick et al.,
2005c) is in line with a change to an increasing proportion of type I muscle fibres and a
more oxidative muscle metabolism (Brandstetter et al., 1998a; Greenwood et al., 2007;
Suzuki and Cassens, 1983; White et al., 1978). As expected, higher levels of glycolytic
type IIX fibres are associated with a reduction in myoglobin concentration (Gardner et
al., 2007).
2.6.5.2 Myoglobin concentration and growth
Myoglobin concentration is reduced in slower growing breeds of lamb which are less
mature at a given age, such as Merinos (Gardner et al., 2007) and has been shown to be
higher in fast growing lamb which are likely to be closer to their mature size (Gardner et
al., 2007).
Nutrition has been shown to impact muscle fibre type (Greenwood et al., 2006b; Moody
et al., 1980), which may subsequently alter oxidative capacity including myoglobin
concentration. Nutritional restriction in lambs, which in turn will restrict growth rates,
has been shown to reduce myoglobin concentration with a magnitude of effect four
times greater than as genotypic effects (Gardner et al., 2006b).
Selection for increased muscle using ASBVs for increased PEMD has been shown to
increase the proportion of type IIX glycolytic fibres (Greenwood et al., 2006c; Wegner
56
et al., 2000) and reduce myoglobin concentration (Gardner et al., 2006b). However,
while selection for leanness using ASBVs for reduced PFAT also increased the
proportions of type IIX glycolytic fibres, an associated reduction in myoglobin
concentration was expected but not seen (Gardner et al., 2006b).
2.6.5.3 Production factors which influence myoglobin concentration
Myoglobin concentration is influenced by production factors including age, sex and
genotype. Age is a strong driver of myoglobin concentration in sheep with myoglobin
doubling in all muscles between 4 and 22 months of age in the Gardner et al. (2007)
study. In this study the greatest increase in myoglobin occurred between 4 and 8 months
of age. The increase in myoglobin with age is a consistent finding in sheep (Ledward
and Shorthose, 1971; Pethick et al., 2005b) with Jacob et al. (2007) demonstrating an
increase between 5 and 12 months of age. As with age, myoglobin concentration
increases as lambs approach maturity (Gardner et al., 2007). As higher myoglobin
concentrations are associated with increased redness in meat, at maturity animals have
redder meat (Hopkins et al., 2007).
The influence of sex on myoglobin concentration is not straightforward. Although
wether lambs have been shown to have reduced proportions of type IIX fibres than ewe
lambs (Greenwood et al., 2007) and thus greater oxidative metabolism, Ledward and
Shorthose (1971) showed that ewe lambs had 10% more myoglobin than wether lambs.
In contrast to these findings, and to the hypothesis based on fibre type, Gardner et al.
(2007) found no impact of age on myoglobin concentration (P > 0.05).
The impact of genotype on myoglobin concentration varies, with studies showing
reduced myoglobin concentration in slow growing Merinos compared to faster growing
breeds (Gardner et al., 2007; Gardner et al., 1999) while Hopkins et al. (2005) showed
no difference between Merinos and other genotypes.
57
The inconsistent variation between myoglobin concentration with sexes and genotypes
indicates that changes in fibre type with lamb growth do not explain the entire variation
in myoglobin concentration and further studies are needed to explain the associations.
2.6.6 Iron and zinc concentration
Iron and zinc are key nutrients for human health and consumers assess meat quality by
reliance quality traits which include nutrition (Pethick et al., 2006a; Troy and Kerry,
2010). Red meat is recognised as one of the best sources of iron and zinc because of
their high bioavailability in meat compared to plant sources (Linder, 1991). Australian
lamb is currently marketed as a good source of both minerals (Pannier et al., 2014b;
Pannier et al., 2010).
Iron and zinc concentration are higher in muscles with greater proportions of oxidative
fibres (Cassens et al., 1967) and have a positive association with intramuscular fat.
Therefore, factors which impact oxidative capacity may in turn influence iron and zinc
concentration in meat.
2.6.6.1 Iron and zinc concentration and growth
Iron and zinc concentration are influenced by growth with higher levels in lamb
(Pannier et al., 2014b) and cattle (Kirchgessner et al., 1994) with heavier hot carcass
weights. While a similar finding of increased zinc concentration with increased weight
was found in the Bellof et al. (2007) study in lambs, there was no increase in iron
concentration. The Bellof et al. (2007) study was based on the averaged iron and zinc
concentrations from the total muscle tissue however Lin et al. (1988) found that when
examining retail lamb cuts iron concentration was highest in the loin. The use of total
muscle tissue may explain the lack of alignment with mineral changes found in the loin
in the Bellof et al. (2007) study. In direct contrast to the findings above, Lin et al.
58
(1988) found a reduction in iron and zinc concentration with increasing carcass weight.
However, the magnitude of the effect was small with iron and zinc concentrations
influenced more by age than weight.
Selection for increased growth via the PWWT ASBV was expected to reduce iron and
zinc concentration in the (Pannier et al., 2014b) study however there was no
association. The hypothesis was based on progeny of high PWWT sires having an
increased mature size (Huisman and Brown, 2008) and therefore being less mature at
the same slaughter age. While age has a large impact on both iron and zinc
concentration (Pannier et al., 2014b) the variation in maturity at a given age with
differing PWWT may be too small to impact iron and zinc concentration.
2.6.6.2 Production factors which influence iron and zinc concentration
Iron and zinc concentrations vary with production factors including age, sex, and
genotype. Iron and zinc concentrations increase with age in lambs (Lin et al., 1988; Ono
et al., 1984; Pannier et al., 2010) while iron concentration increases with age in cattle
(Doornenbal and Murray, 1982; Kotula and Lusby, 1982) and zinc concentration
increases with age in pigs (Cassens et al., 1967).
Iron concentration was higher in ram lambs compared to ewe lambs in the Bellof et al.
(2007) study of 108 lambs. However, this association was only present in ram and ewe
lambs up to 30 kg body weight, after which there was no difference in iron
concentration between ram and ewe lambs. In the same study, zinc concentration was
also higher in ram lambs than ewe lambs, which aligns with greater proportion of
glycolytic type IIX fibres in ewe lambs (Greenwood et al., 2007). In contrast, iron
concentration was higher in ewe lambs compared to wether lambs in both the (Pannier
et al., 2014b) and (Pearce et al., 2009) studies, although the reason for this is unknown.
59
Animal breed can impact mineral levels (Underwood, 2012) and iron and zinc
concentration have been found to vary between some sire types. Pannier et al. (2014b)
found that Terminal sired lambs had the lowest iron concentration while it was
intermediate in Maternal sired lambs and highest in Merino sired lambs. Terminal sired
lambs have more glycolytic type IIX fibres (Greenwood et al., 2007) which may reflect
their lower iron levels. There was no difference in zinc concentration between lambs
from either Terminal or Merino sire types however lambs from Maternal sires had the
highest zinc concentrations (Pannier et al., 2014b). As there is no general alignment in
iron and zinc concentration of progeny of different sire types and between the sexes it is
unlikely that these effects are mediated by growth alone.
2.6.6.3 Iron and zinc concentration and fibre type
Iron and zinc concentrations are higher in muscles with greater oxidative, type I fibres
(Beecher et al., 1968; Cassens and Cooper, 1971; Cassens et al., 1967). Thus muscles
with reduced oxidative capacity have been shown to contain reduced iron and zinc
concentrations (Kondo et al., 1991; Pearce et al., 2009). Factors contributing to the
reduction of these minerals are likely to include lower concentrations of myoglobin, less
vascularisation (Choi and Kim, 2009; Lefaucheur, 2010) and fewer mitochondria
(Hoppeler, 1985).
Iron and zinc concentration increases with age (Pannier et al., 2014b) as does oxidative
fibre type (Brandstetter et al., 1998a). The strong association between iron and zinc
concentration and oxidative fibre type is due to the function of these minerals in
oxidative fibres. Iron is a component of myoglobin (Hazell, 1982) and zinc is associated
with antioxidant cascades and the electron transport chain (Powell, 2000) both of which
are also associated with more oxidative fibre types.
60
Given that ICDH activity and myoglobin concentration are indicators of oxidative
capacity, they have a positive association with iron and zinc concentration (Pannier et
al., 2014b). The magnitude of the association was greater for iron, which increased two-
fold more than zinc across the same range of ICDH activity and four-fold more across
the same range of myoglobin concentration, indicating a stronger alignment of iron
concentration with oxidative capacity. This was supported by stronger phenotypic and
genotypic correlations between ICDH activity and myoglobin concentration with iron
than with zinc (Mortimer et al., 2014).
Selection for leanness via a reduced PFAT ASBV has been shown to increase the
proportion of type IIX muscle fibres (Greenwood et al., 2006c), which results in
reduced oxidative capacity indicated by myoglobin levels (Gardner et al., 2006b) as
well as a reduction in iron levels (Pannier et al., 2014b). No association has been found
between selection for a reduced PFAT and zinc concentration (Pannier et al., 2014b).
Selection for an increase in muscle using the PEMD ASBV reduces the proportion of
oxidative muscle fibres (Greenwood et al., 2006c), which aligns with a reduced
myoglobin concentration in the Gardner et al. (2006b) study. Despite the strong
association between myoglobin concentration and iron concentration, Pannier et al.
(2014b) found no subsequent reduction in iron or zinc concentration.
As iron and zinc are highly linked to muscle fibre type, factors which influence muscle
oxidative capacity and fibre type are likely to impact iron and zinc concentrations. The
association between iron concentration and fibre type is stronger, likely to be due to the
direct involvement of iron as a key component of myoglobin, so impacts to fibre type
may be more strongly reflected in iron concentration than zinc concentration.
61
2.6.7 Meat browning
Lamb meat develops a desirable bright red colour after exposure to oxygen allows
myoglobin pigments to transform from the purple pigment deoxymyoglobin into the red
pigment oxymyoglobin. Meat browning then occurs over time on retail display as
oxymyoglobin auto-oxidises to form the brown pigment metmyoglobin
Consumers are able to detect this change in meat colour (Khliji et al., 2010) and
associate browning with a lack of freshness and quality (Faustman and Cassens, 1990)
leading to product rejection and revenue loss (Mancini and Hunt, 2005; Suman and
Joseph, 2013). Retail shelf life for lamb meat in Australia is currently 2 to 3 days
(Calnan et al., 2014; Jacob et al., 2007).
Price discounts due to meat browning in beef are estimated to total more than one
billion dollars in the United States each year (Smith et al., 2000) with an average loss of
meat sales due to colour deterioration estimated to be 3.7% (Williams et al., 1992). In
Australia this would equate to a loss of $353 million based on a slaughter value of
$9,541 million for beef and lamb in the 2009-2010 financial year. While the importance
of meat quality traits varies by country (Warner et al., 2010) a consumer survey carried
out in six European countries identified meat colour at retail display as the most
important intrinsic quality when purchasing beef, pork or chicken (Glitsch, 2000) and in
a Japanese survey 58% of participants identified meat colour as the most important
factor when selecting beef products (Sanders et al., 1997).
Meat colour can be measured using light wavelength reflectance with the ratio of
reflectance at 630 mm and 580 mm (R630/R580) representing the redness:brownness of
the meat surface. This measurement is also known as the oxy/met ratio (Hunt et al.,
2001). The ratio approaches a minimum value after 3 days of simulated retail display in
62
lamb meat (Jacob et al., 2014). The ratio needs to exceed 3.3 units for the average
consumer to deem lamb meat an acceptable red colour (Khliji et al., 2010).
Reducing the rate of meat browning relies on an understanding of oxygen diffusion and
consumption and the rate of auto-oxidation of myoglobin pigments into metmyoglobin
(Jose, 2011). The rate of metmyoglobin reduction may also be important (Faustman
and Cassens, 1990) however its importance remains unclear (Bekhit and Faustman,
2005). In cattle Bekhit et al. (2003) found that NADH, which is integral in
metmyoglobin reduction, was more important in governing meat colour than
metmyoglobin reducing activity. In sheep the importance of the reduction process has
not yet been established as studies in lamb loin have found no correlation between
metmyoglobin reducing ability and meat colour (Bekhit et al., 2001).
Strategies to reduce meat browning include packaging modification and the use of
dietary anti-oxidants supplementation (Mancini and Hunt, 2005). The antioxidant
Vitamin E has been used successfully in the finishing diet of animals to reducing the
rate of browning in beef (Faustman et al., 1989) and lamb (Strohecker et al., 1997).
2.6.7.1 Meat browning and fibre type
Meat browning is linked to fibre type as numerous studies have shown that muscle
oxidative capacity impacts the rate of meat browning (Calnan et al., 2014; Jeong et al.,
2009). More oxidative muscles are prone to more rapid meat browning than more
glycolytic muscles (O'keeffe and Hood, 1982; Renerre and Labas, 1987).
Oxidative, type I, muscle fibres are associated with greater concentrations of
mitochondria (Klont et al., 1998). Increased mitochondrial activity leads to increased
production of free radicals that trigger myoglobin oxidation. Thus, muscle fibre types
63
with high numbers of mitochondria, such as type I muscle fibres, can be detrimental and
accelerate meat browning (Sammel et al., 2002). .
Increased meat browning is also associated with increased intramuscular fat. The
reactive products of lipid oxidation accelerate the oxidation of myoglobin (Buckley et
al., 1995; Faustman et al., 1999) and thus browning. Therefore, strategies to inhibit
lipid oxidation also reduce meat browning (Faustman et al., 2010). Furthermore,
intramuscular fat is increased with oxidative fibre types (Hocquette et al., 2003; Jurie et
al., 2007) which also increase meat browning.
2.6.7.2 Meat browning and growth
Meat browning is influenced by weight and stage of maturity but not by genetic
selection for growth. In Australia the maturity of lambs at slaughter has been reduced
(Hall, 2000) by selection for sires with high post weaning weight progeny leading to
increased growth rates (Hall et al., 2002). Reduced maturity is associated with reduced
muscle oxidative capacity (Brandstetter et al., 1998a) thus the rate of meat browning
may be reduced with selection for growth.
Calnan et al. (2014) used hot carcass weight, as a proxy for whole of life growth rate, to
demonstrate an association between increased growth and a reduced rate of meat
browning. This association did not change with correction for the oxidative enzyme
ICDH activity. This indicated that the impact of phenotypic growth rate on meat
browning was not delivered through an altered oxidative capacity.
Although increased growth caused a reduction in meat browning, selection for increased
growth using the PWWT ASBV did not have any further impact on meat browning
(Calnan et al., 2014). Overall, the impact of growth on meat browning appears to be
independent of growth.
64
2.6.7.3 Production factors which influence meat browning
Environmental and production factors such as diet (Faustman and Cassens, 1990) and
genetics (King et al., 2010; Mortimer et al., 2010) can have an impact on meat
browning. Diet and genetics can increase growth and it is unknown based on current
literature whether the impact of these production factors are simply proxies for the
impact of growth on meat browning.
Calnan et al. (2014) reported an reduction in browning in meat from lambs born to
Terminal and Maternal sires compared to meat from progeny of Merino sires. Lambs
born to Terminal and Maternal sires have a greater potential for increased muscling,
which increases the expression of type IIX glycolytic muscle fibres, reducing muscle
oxidative capacity (Greenwood et al., 2006c; Greenwood et al., 2007) and reducing
meat browning.
While the proportion of type IIX fibres increase with selection for muscling (Wegner et
al., 2000), the proportion of type I oxidative fibres increase with age (Warner et al.,
2007) and maturity (Suzuki and Cassens, 1983; White et al., 1978). The increase in
oxidative fibres with age and maturity leads to increased browning (Renerre, 1990).
Consumers relate browning to meat from mature animals (Jeyamkondan et al., 2000).
While browning is generally more rapid in mature animals due to increased proportions
of oxidative fibres, meat browning can occur in meat from animals at any stage of
maturity.
Several authors have investigated the link between myoglobin concentration and meat
browning given that browning is caused by myoglobin oxidation. However, findings
have been mixed. O'keeffe and Hood (1982) speculated that muscles containing lower
myoglobin would brown faster because their myoglobin oxidised at a greater frequency.
65
However, this was not supported by the work of King et al. (2010) who found that
breeds with reduced myoglobin concentration had the reduced browning or the work of
McKenna et al. (2005) who found no relationship between myoglobin content and meat
colour across 19 muscles in beef.
There are a number of additional intrinsic and extrinsic factors beyond the scope of this
thesis that impact on meat browning including pH, rate of pH decline, temperature and
light, presence of antioxidants, lipid oxidation, bacterial contamination and packaging
(Lawrie, 1983; Mancini and Hunt, 2005; Suman et al., 2014; Warner et al., 2007).
Variation in the response of meat browning to changes in growth rate or with muscle
fibre type may be due in part to some of these factors.
2.7 Hypothesis
This thesis explores the effect of selection for increased growth in lambs on muscle
oxidative capacity and meat quality. The impact of weight and growth rate at key times
during production are investigated. These aspects are covered in the following chapters;
the hypotheses of which are outlined below:
Chapter 3: Comparison of linear and nonlinear functions to estimate lamb growth
The aim of this chapter is to determine the most appropriate method of fitting a growth
curve to lambs, based on residual weight values, to determine reliable estimates of
weight and growth rate at key time points during production.
The specific hypotheses tested were:
The mean squared error would be lowest for a random effects model curve fit rather
than a biologically based Brody curve fit or a cubic polynomial curve fit.
66
Chapter 4: Lamb birth and rearing type influence growth and weight potential of
progeny from high growth sires
The aim of this chapter was to determine the impact of nutritional restriction on growth
of lambs from high growth sires. In addition to environmental variation, sources of
nutritional restriction included both dam and lamb factors with reduced milk production
in some dam breeds and sibling competition in-utero and pre weaning. The impact of
these forms of nutritional restriction on progeny of high post weaning weight sires
achieving expected weights was also investigated. The impact of breeding values for
muscling and leanness on lamb weight were also investigated.
The specific hypotheses tested were:
The magnitude of the sire PWWT effect would vary between sites as nutrition
varies between sites
Lambs born and raised as multiples would have a reduced response to increased
sire PWWT
Lambs born to Merino dams would have a reduced response to increased sire
PWWT
Lambs from high PEMD sires and lambs from low PFAT sires would be heavier
Chapter 5: Selection for lean meat yield in lambs reduces indicators of oxidative
metabolism in the longissimus muscle
The aim of this chapter is to evaluate the impact of selection for lean meat yield on
muscle oxidative capacity. The activity of the oxidative enzyme isocitrate
dehydrogenase and the concentration of the red pigment of muscle myoglobin were
used as indicators of oxidative capacity. The impact of production factors on muscle
oxidative capacity was also investigated.
67
The specific hypotheses tested were:
Selection for leanness via increasing sire PEMD ASBVs and reducing sire PFAT
ASBVs would reduce oxidative capacity in the muscle of their progeny
Selection for growth via an increased sire PWWT ASBV would reduce oxidative
capacity in the muscle of their progeny
Muscle oxidative capacity would vary between sites
The magnitude of the effect of production factors on muscle oxidative capacity
would be greater than the magnitude of the genotypic effects
Chapter 6: Lamb growth increases intramuscular fat levels and reduces shear force in
the longissimus muscle
The aim of this chapter was to evaluate the impact of weight and growth rate on meat
quality traits of intramuscular fat, shear force and consumer overall liking. These traits
were selected due to the direct link with palatability and consumer acceptance of lamb
meat. Hot carcass weight is commonly used as a proxy for lamb growth however this
whole of life growth rate has not been verified as a good measure of lamb growth.
Furthermore, it cannot distinguish the impact of growth at important time points during
production such as weaning and post weaning. The impact of weight and growth rate on
these traits, at weaning and post weaning time points, is compared to the impact of hot
carcass weight on the same traits.
The specific hypotheses tested were:
Intramuscular fat and overall liking would increase with lamb growth
Shear force would reduce with lamb growth
Hot carcass weight would be a poor proxy for lamb growth
68
Chapter 7: Lamb growth increases oxidative capacity and mineral content in the
longissimus muscle
The aim of this chapter was to evaluate the impact of weight and growth rate on meat
quality traits related to oxidative capacity, mineral content and meat browning.
Specifically, isocitrate dehydrogenase activity and myoglobin concentration were
investigated as markers of oxidative capacity and iron and zinc concentration were the
minerals investigated. These meat traits were selected due to their strong links with
muscle fibre type and the impact that changes in fibre type can have on the nutritive
value and retail shelf life of lamb meat. For the reasons previously mentioned, these
impact of weight and growth rate on these traits is compared to the impact of hot carcass
weight on these traits, as in Chapter 6.
Oxidative capacity would increase with lamb growth
Iron and zinc concentration would increase with lamb growth
Lamb meat would brown more rapidly with lamb growth
Hot carcass weight would be a poor proxy for lamb growth
69
Chapter 3. Comparison of linear and nonlinear
functions to estimate lamb growth
3.1 Introduction
Lamb growth is modelled as a function of weight change between birth and maturity. It
follows a sigmoidal pattern with the greatest growth rate after birth in the exponential
phase, a declining growth rate as the animal nears its mature weight in the transitional
phase and a stable mature weight in the plateau phase (Hendrick et al., 1989). As
incomplete weight data recordings are common in industry utilisation of the data that is
available is essential. This requires the fitting of a growth curve to available weight data
so that weight and growth rate can be estimated at specific times of interest.
A variety of growth functions exist. They can be broadly grouped into linear and
nonlinear functions which can be fitted to individual animals or populations of animals.
The Brody function (Brody, 1945) is a nonlinear function which is fitted to the live
weight data of individual animals. It is utilized because of the easy biological
interpretation of the parameters with the shape of the curve being linked to the mature
weight and maximum growth rate of the sheep (Topal et al., 2004). However, the Brody
function tends to overestimate weight during early life growth (Beltrán et al., 1992;
Gbangboche et al., 2008) and gives biased estimates close to the edge of the available
data.
A second group of functions which are fitted to the weight data of individual animals
are polynomial functions. Unlike the Brody function, polynomials are linear functions.
They are attractive as the fit of these functions generally increases with the order of the
70
polynomial, with a third degree cubic polynomial often used to model weight data.
However, there is no biological basis to polynomial function and the asymptote can
cause overestimation of weight close to adulthood.
Random effects models are a population based curve fit which uses a fixed regression to
describe the average shape of a growth curve, and a random regression for each animal
to account for deviations from the fixed regression. With the ability to easily
accommodate missing weight data, overcoming the common difficulty of incomplete
weight data recording in an industry setting, it is a commonly used as a growth function
(Lewis and Brotherstone, 2002). As random effects models are based on a polynomial
function they have similar limitations. However, the ability to incorporate different
durations of data collection results in unbiased estimations of weight than from the
individual based curve fits.
Weight data recorded in an industry setting often differs in lengths with some animals
being weighed frequently for variable lengths of time (i.e. months to years), and others
being weighed less frequently and also for variable lengths of time. While random
effects model methodology is not biased by these differences in data availability,
functions such as the Brody’s are heavily influenced. Therefore, when functions are
fitted on an individual animal basis those animals with data collected for shorter periods
are likely to be somewhat biased for weights estimated at the edge of their available
data compared to those with weights collected for periods that extend well beyond this
point.
Assessment of residual weights (the difference between the estimated weight and the
recorded weight) after a growth function has been fitted is a useful way of assessing
curve fit. Specifically, the mean square error, which is the average value of the squared
residual weights, is commonly used (Topal et al., 2004). It is a useful measure of fit as it
71
can be compared across both linear and nonlinear curves and is not biased by the
number of weight recordings each animals has. As the fit of different functions may
vary with time, the residual weights can also be assessed during specific times of
interest for comparison between curves.
As linear and nonlinear functions are known to have limitations when estimating growth
and random effects models can accommodate missing weight data and different
durations of data collection, it is hypothesised that the fit of the random effects model
will have a lower mean square error.
3.2 Materials and Methods
3.2.1 Experimental Design
The Information Nucleus Flock experiment, from which lamb weight data was sourced,
was conducted at eight sites across Australia, representing a broad range of production
systems (Kirby NSW, Trangie NSW, Cowra NSW, Rutherglen VIC, Hamilton VIC,
Struan SA, Turretfield SA, and Katanning WA). These sites were a component of the
Sheep CRC’s Information Nucleus Flock the details of which were presented by
Fogarty et al. (2007) and van der Werf et al. (2010). A total of 18,185 lambs from
Maternal (n=3,633), Merino (n=6,895) and Terminal sires (n=7,657) were produced
between 2007 and 2011. Lambs were weighed at birth, at weaning (90 days of age) and
approximately every two weeks thereafter. A large proportion of lambs were
slaughtered at a target weight of 23 kg, as early as 145 days. However, some lambs
were retained and continued to have weights recorded. As the final weight recorded for
most lambs was within 300 days, a decision was made to restrict the weight recordings
72
used to 300 days. Lambs were reared under extensive pasture grazing conditions and fed
grain, hay or feedlot pellets when feed supply was limited (Ponnampalam et al., 2014b).
3.3 Statistical Analysis
3.3.1 Data available
Each of the 18,185 lambs had between 1 and 16 records, with an average of 8 records
per lamb. This resulted in 142,572 weight recordings. 18,139 lambs had weight
recordings on the day of birth. The distribution of weight recordings available between
day 1 and day 300 is presented in Figure 3-1. The Brody fit required at least three
weight recordings and the cubit fit required at least four weight recordings. For
comparison, all three functions were fitted to weight data for animals with four or more
live weight recordings. Lambs weights were incorrectly measured or recorded at the
Turretfield site during a 14 day period in 2011. Four hundred and thirty three weight
recordings from this period at the Turretfield site were removed before curve fitting.
This resulted in all three functions being fitted to 17,382 animals with 141,050 weight
recordings. As random effects models can accommodate animals with as little as one
weight recording, the model was also fitted to the entire population 18,185 lambs with
142,572 weight recordings.
Brody and Legendre cubic polynomial functions were fitted to the weight data of each
individual animal. A cubic Legendre polynomial was also fitted using a Bayesian
random effects model to the entire population.
73
Figure 3-1 Graph of the number of weight recordings against lamb age (in days) between 1 and 300 days.
3.3.2 Nonlinear curve fit
A Brody growth curve (Brody, 1945) was fitted to each individual animals weight. As
estimated values for initial weight and mature weight in the nonlinear growth formulas
are highly correlated (Cullis and McGilchrist, 1990; Lewis et al., 2002) the modified
formula, as derived by Doren et al. (1989) was used:
Wt[t] = A – (A – Wt0)e-kt
Where Wt[t] is the weight at time t, expressed in days, Wt0 is the observed birth weight,
A is the asymptotic limit of the weight when t approaches infinity, e is the base of
natural logarithm, and k is a curve parameter representing the ratio of maximum growth
rate to mature size, referred to as the maturing rate. Values for A were restricted to less
than 100 kg and values for k were restricted to lie between 0 and 1. The Brody curve
0
200
400
600
800
1000
1200
0 50 100 150 200 250 300
Nu
mb
er o
f w
eig
ht
reco
rdin
gs
Age (days)
74
was fitted using nonlinear regression with the NLIN procedure of SAS (SAS Version
9.1, SAS Institute, Cary, NC, USA) where the curve parameters A and k were
determined iteratively using a Gauss-Newton algorithm (Hartley, 1961). The curves of 5
animals did not converge. Outlier weights were identified by large residual values (> 15
kg), leading to the removal of a single weight recording from 13 different animals.
3.3.3 Linear curve fit
A third order orthogonal Legendre polynomial function was fitted to each individual
animals weight data:
Wt[t] = c0 + c1t + c2t2 + c3t
3
Where Wt[t] is the weight at time t, expressed in days, and c is the coefficient. The
cubic curve was fitted using the GLM procedure of SAS. Outlier weights were
identified by large residual values (> 15 kg) and a single weight recording was removed
from 4 animals.
3.3.4 Random effects model fit using Bayesian analysis
A Bayesian random effects model of third order polynomial was fitted to the weight
data of the population in R, with each individual animals curve deviating from the
population curve. Outlier weights were identified by large residual values (> 15 kg) and
a single weight recording was removed from 4 animals.
3.3.5 Curve fitting comparisons
Goodness of fit for each curve was assessed using the mean squared error (MSE), as
previously utilised for nonlinear growth curves in both sheep (Gbangboche et al., 2008;
Topal et al., 2004) and cattle (Brown et al., 1976; Goonewardene et al., 1981). A MSE
75
was calculated for the curve fit between 0 and 300 days. An MSE was also calculated
between 90 and 160 days as this captured the period where weights would be estimated,
at 100 and 150 days, from the most appropriately fitting curve. The coefficient of
determination R2 was not reported as it is an inadequate measure of the goodness of fit
in nonlinear models (Spiess and Neumeyer, 2010) therefore this could not be compared
across all three models.
The residual values from each curve fit (the difference between the estimated weight
and the live weight recording) were assessed for normality, skewedness and kurtosis
using the UNIVARIATE procedure of SAS. As there were greater than 2,000 weight
observations, the Kolmogorov-Smirnov rather than the Shapiro-Wilk test for normality
was used. The Kolmogorov-Smirnov test for normality (D) is based on the empirical
distribution function (Stephens, 1974). Small values of D (<0.05) lead to the rejection
of the null hypothesis that that the residuals are normally distributed (Ayyangar, 2007).
Skewedness was used to characterize whether the distribution of residuals is symmetric
(if skewedness = 0 the distribution is symmetrical). Kurtosis was used to characterize
the ‘peakedness’ of the distribution, where a normal distribution has a value of 0 (in
SAS) and smaller values correspond to thinner tails (less peakedness).
76
3.4 Results
3.4.1 Nonlinear curve fit
3.4.1.1 Mean square error
The correlation between the observed weight and the estimated weight was 0.99 and the
least squares estimates parameters for A was 63.92 ± 0.19 kg and for k was 0.008 ±
0.001. The MSE for the Brody curve fit is presented in Table 3-1 The MSE over the
period of interest (90-160 days) was 16% greater than over the whole range of the data
(0-300 days).
Table 3-1 Mean square error (MSE) ± standard error (kg2) for curve fits between 0 and 300 days and 90
and 160 days for Brody, Cubic, Random Effects Model and Random Effects Model with all data
(including animals with less than 4 live weight observations) curve fits.
MSE (0-300) MSE (90-160)
Brody 4.15 ± 0.03 4.82 ± 0.04
Cubic 2.18 ± 0.02 2.77 ± 0.03
Random Effects Model 3.07 ± 0.02 3.71 ± 0.04
Random Effects Model (all data) 3.25 ± 0.03 3.85 ± 0.04
3.4.1.2 Residual graph over time
The average residual value between birth and 300 days was -0.003 kg and residual
values varied between -13.95 and 12.66 kg. The average value of residuals for each 10
day increment was plotted against time (Figure 3-2). Within a 10 day time period, the
average positive residual value was as much as 1.65 kg while the average negative
residual value was as much as -1.35 kg. The average residual value with the Brody
curve fit varied from close to zero at birth to more than 1.5 kg close to the edge of the
77
recorded weights at 300 days. Between birth and 300 days the residual value fluctuated
between positive and negative values at five different ages. During early life growth the
Brody model was a less precise estimator of growth, with a large positive residual value
at around 5 weeks of age followed by a large negative value at around 6 weeks of age.
The fit was also less precise later in life, overestimating weight from 200 days onwards.
At weaning (100 days) the residual value was three quarters of a kilogram while post
weaning the residual value was negative by around 1 kg providing evidence of an
overestimation of weight at weaning and an underestimation of weight post weaning to
the 200 day time point.
Figure 3-2 Graph of average residual weight (kg) per 10 day period with a Brody curve fit (-- -- -- --), a
cubic curve fit (- - - -) and a random effects model fit (····). The solid line at residual weight zero
represents the line the residuals would fall on if the random effects model were a perfect fit to the weight
data.
-2
-1.5
-1
-0.5
0
0.5
1
1.5
2
0 50 100 150 200 250 300
Res
idu
al
va
lue
(kg
)
Age (days)
Brody CubicRandom Effects Model Zero Residual
78
3.4.1.3 Residual statistics – Normality, Skewedness and Kurtosis
A test of normality for the residual values and values for skewedness and kurtosis are
presented in Table 3-2 and a histogram for the residuals is presented in Figure 3-3. The
test for the location of mu (the mean of the residuals) indicated that the mean was not
significantly different than zero. The test of normality indicated that the distribution of
the residuals was not normal. Although the Kolmogorov-Smirnov test was used over the
Shapiro-Wilk Statistic due to the large sample size, increasingly small departures from
normality are detected as the sample size increases, so the test for normality was
interpreted in conjunction with the results for skewedness and kurtosis. The small
negative skewedness score indicated that the distribution of the residuals was skewed to
the right, indicating that the Brody function overestimated more weights than it
underestimated. The positive kurtosis score indicated that the tails of the distribution
were heavier than for a normal distribution, suggesting that there were more animals
with extreme residual values than expected.
Table 3-2 Results of tests for the location of mu, normality, skewedness and kurtosis of the average
residual values from a Brody function fit to 17,377 animals.
Test Statistic Result P value
Location of mu Students t-test t -0.55 0.58
Normality Kolmogorov-Smirnov D 0.07 <0.01
Skewedness Mardia - -0.18 -
Kurtosis Mardia - 1.75 -
79
Figure 3-3 Histogram of the distribution of residual weight values (kg) against the percent frequency for
the Brody function fit.
3.4.2 Linear curve fit
3.4.2.1 Mean square error
The correlation between the observed weight and the estimated weight was high at 0.99.
The MSE is reported in Table 3-1. The MSE over the period of interest (90-160 days)
was 27% greater than over the whole range of the data (0-300 days).
0
2
4
6
8
10
12
14
16
18
-14-13-12-11-10 -9 -8 -7 -6 -5 -4 -3 -2 -1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14
Fre
qu
ency
(%
)
Residual value (kg)
80
3.4.2.2 Residual graph over time
The average residual value between birth and 300 days was 5.67x10-16
kg and residual
values varied between -12.02 and 13.01 kg. The average value of residuals for each 10
day increment was plotted against time (Figure 3-2). Within a 10 day time period, the
average positive residual value was as much as 0.57 kg while the average negative
residual value was as much as -0.91 kg. Between birth and 300 days the curve fit
oscillated approximately every two months between underestimating and
overestimating weights. Early life weight was underestimated while at around 100
days, when lambs were weaned, weight was overestimated. This is followed by a
similar pattern during the post weaning and maturation phases. Overall, the
underestimation of weights during early and post weaning growth is larger in magnitude
than the overestimation during weaning and maturation.
3.4.2.3 Residual statistics – Normality, Skewedness and Kurtosis
A test of normality for the residual values and the values for skewedness and kurtosis
are presented in Table 3-3 and a histogram of the residuals is presented in Figure 3-4.
The mean of the residuals was not significantly different than zero, and the test of
normality indicated that the distribution of the residuals was not normal. The
distribution of residuals had a small negative skewedness, indicating the distribution
was skewed to the right. Therefore, the cubic function overestimated more weights than
it underestimated. A positive kurtosis indicated that the tails of the distribution are
heavier than for a normal distribution, so there were more animals with extreme residual
values than expected.
81
Table 3-3 Results of test for the location of mu, skewedness, kurtosis and normality of the average
residual values from a cubic function fit to 17,382 animals.
Test Statistic Result P value
Location of mu Students t-test t 0.00 0.99
Normality Kolmogorov-Smirnov D 0.06 <0.01
Skewedness Mardia - -0.15 -
Kurtosis Mardia - 2.66 -
Figure 3-4 Histogram of the distribution of residual weight values (kg) against the percent frequency for
the cubic function fit.
3.4.3 Bayesian random effects model fit
3.4.3.1 Mean square error
The mean square error for the random effects model fit between birth and 300 days, as
well as between 90 and 150 days is presented in Table 3-1. The MSE over the period of
0
2
4
6
8
10
12
14
16
18
20
-12 -11 -10 -9 -8 -7 -6 -5 -4 -3 -2 -1 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14
Fre
qu
ency
(%
)
Residual value (kg)
82
interest (90-160 days) was 21% greater than over the whole range of the data (0-300
days). When all live weight data, including animals with less than 4 weight recording,
was used the MSE increased by 5%.
3.4.3.2 Residual graph over time
The average residual value between birth and 300 days was -0.001 kg and residual
values varied between -13.84 and 13.95 kg. The average value of residuals for each 10
day increment was plotted against time (Figure 3-2). Within a 10 day time period, the
average positive residual value was as much as 0.67 kg while the average negative
residual value was as much as -1.63 kg. During early life growth the average residual
value with the random effects model fit was close to zero. At 50 days weight was vastly
underestimated. At weaning (100 days) the residual value was about half a kilogram
while post weaning the residual value was negative by close to 1 kg. This provides
evidence of an overestimation of weight at weaning and an underestimation of weight
post weaning to the 200 day time point. In general, each function overestimated weight
at weaning, and underestimated weight at the post weaning time point of 150 days, the
magnitude of the difference being largest with the Brody fit and similar with the cubic
and random effects model fits.
3.4.3.3 Residual statistics – Normality, Skewedness and Kurtosis
A test of normality for the residual values and values for skewedness and kurtosis are
presented in Table 3-4 and a histogram of the residuals is presented in Figure 3-5. The
mean of the residuals was not significantly different than zero. The test of normality
indicated that the distribution of the residuals was not normal. The distribution of
residuals had a negative skewedness, indicating the distribution was skewed to the right.
Therefore, the random effects model overestimated more weights than it
underestimated. A positive kurtosis indicates that the tails of the distribution were
83
heavier than for a normal distribution, so there were more animals with extreme residual
values than expected.
Table 3-4 Results of tests for the location of mu, skewedness, kurtosis and normality of the average
residual values from a random effects model fit to 17,382 animals.
Test Statistic Result P value
Location of mu Students t-test t -0.13 0.89
Normality Kolmogorov-Smirnov D 0.04 <0.01
Skewedness Mardia - -0.18 -
Kurtosis Mardia - 1.87 -
Figure 3-5 Histogram of the residual weight values (kg) against the percent frequency for the random
effects model fit.
3.4.4 Comparison of residual graphs over time
A graph of the residual values over time for all three curve fits is presented in Figure
3-2. From this graph it can be seen that during early life growth the random effects
0
2
4
6
8
10
12
14
-15
-14
-13
-12
-11
-10 -9 -8 -7 -6 -5 -4 -3 -2 -1 0 1 2 3 4 5 6 7 8 9
10
11
12
13
14
15
Fre
qu
ency
(%
)
Residual value (kg)
84
model fit was the best estimator of weight while the Brody curve fit was the poorest
with the largest residuals. Between 90 and 160 days all three curve fits were similar,
although the cubic and random effects model fits had slightly lower residual values.
During late life growth the Brody curve fit residual weights were as much as triple the
values for a cubic or random effects model fit.
3.5 Discussion
3.5.1 Mean square error
Contrary to our hypothesis, the MSE of the random effects model was not the lowest of
the three models tested. Instead it was between the MSE of the Brody model, which was
the highest, and the MSE of the cubic polynomial model which was the lowest. The
hypothesis was based on the ability of random effects model to accommodate different
durations of data collection. While the lower MSE for the cubic fit was unexpected it
was likely to be due to the relatively narrow spectrum of live weights over which the
function was fitted. When weights were not restricted to less than 300 days the MSE of
the cubic function increased significantly (data not shown) (MSE = 2.87).
3.5.2 Curve attributes
Linear models such as the cubic polynomial are uncommonly used as growth curves due
to the lack of biological meaning of the parameters and the inherent sigmoidal nature of
lamb growth. Furthermore, the fit of a polynomial will improve with the degree of the
polynomial however the number of live weight recordings per animal to fit the function
also increases. As industry data often varies in length and may not include a large
number of recordings per animal, linear functions such as polynomials are not
85
frequently used. Where a large number of live weight recordings exist, the increased fit
with the higher degree of polynomial will model factors which do not reflect the true
weight of the lamb, such as gut fill.
Meanwhile, nonlinear models are particularly appealing due to the ease of estimation
and simplicity of interpretation (Bathaei and Leroy, 1996; Bathaei and Leroy, 1998).
They can condense information contained in a data series into a few parameters with
biological meaning (Fitzhugh, 1976) and have been used to model growth in both sheep
(Gbangboche et al., 2008; Malhado et al., 2009) and cattle (Kaps et al., 2000).
Various nonlinear equations are available to estimate animal growth including the
biologically based Brody (1945), von Bertalanffy (1957), Richards (1959), Logistic
(Nelder, 1961) and Gompertz (Laird, 1965) models. Moore (1985) described an ideal
equation as one which adequately estimated the overall shape of a growth curve and can
be extended or modified to give greater flexibility and precision. Based on the
sigmoidal nature of growth it could be expected that the Gompertz curve would give a
better fit than an asymptotic curve such as Brody’s however the best fitting curve
actually varies between species (Brown, 1970; Brown et al., 1976; Malhado et al.,
2009) and even between breeds (Topal et al., 2004).
The lack of a single nonlinear curve to describe the growth of all animals is likely to be
due to the failure of animals to achieve their potential to grow due to inadequate
feeding, disease or adverse environments resulting in real growth data being
inadequately described by a smooth function. Therefore selection of the best nonlinear
function to describe growth in sheep is debatable and often made empirically (Fitzhugh,
1976). In this experiment the Brody function was chosen as the nonlinear model due to
its ability to converge easily and accommodate missing data points (Kaps et al., 1999,
2000), with the number of individual convergences in relation to the total sample size
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representing the best fit when comparing nonlinear models (Souza and Bianchini
Sobrinho, 1994).
3.5.3 Residual weights
Residual weights, the difference between the estimated and the recorded weights, have
been used as a measure of growth curve fit in both sheep (Lambe et al., 2006; Malhado
et al., 2009; Topal et al., 2004) and cattle (Brown, 1970; Brown et al., 1976). The
ability of each function to estimate lamb weight varied with time, as shown by the
residual weight graph (Figure 3-2). These variations in the residual weights from the
Brody fit mirrored the results in other studies of an underestimation of birth weight
(Malhado et al., 2009), an overestimation of weight during early life growth, including
the weaning period at around 100 days (Gbangboche et al., 2008; Malhado et al., 2009),
and an underestimation of weight during the post weaning period at around 150 days
(Gbangboche et al., 2008). In cattle Beltrán et al. (1992) found that the Brody model
overestimated weights before 18 months, which included overestimation at weaning, as
found in this study with lambs.
Residual weights were squared, summed and averaged in this study to determine the
mean squared error for the fit of each three curves. The MSE for the Brody function was
the highest, indicating the poorest fit to the data and was similar to the MSE reported by
Topal et al. (2004) in Morkaraman sheep. The cubic polynomial had the lowest MSE
although it can be seen from the residual weight graph (Figure 3-2) that the fit of the
cubic polynomial and random effects model is similar. Furthermore, during the period
of interest from 90 to 160 days, the MSE for the random effects model varied less from
the MSE for the whole curve fit than with the cubic fit, indicating the stability of the fit
varied little with time. The MSE for the cubic polynomial fit was lowest, however it had
the highest frequency of high residual weights of all three curve fits (Figure 3-4) and the
87
random effects model fit had the lowest (Figure 3-5). The residual weights for the
random effects model fit also displayed a similar skewedness but, as expected, lower
kurtosis than the cubic polynomial fit.
3.5.4 Random effects model
The random effects model methodology offers a more powerful and flexible means of
evaluating repeated live weight measures than a linear or nonlinear function including
the ability to accommodate missing data points and estimate a growth curve for animals
with as little as one weight recording. Environmental effects specific to the time of
recording can be accounted for and models can accommodates genetic differences in the
shape of each animal’s growth curve (Lewis and Brotherstone, 2002). This reduces
potential bias when weights are estimated near the edge of the available data. As
orthogonal forms of linear models are typically fitted with random effects models,
correlations between coefficients are generally lower than with ordinary polynomials.
While this is a desirable feature, there is no simple biological interpretation of the
growth function parameters.
At present only linear models can pragmatically be fitted with random effects models
although several authors have expressed the opinion that the use of nonlinear model
may have advantages (Lewis and Brotherstone, 2002).
88
3.6 Conclusion
This study demonstrated that the individually fitted cubic polynomial function and the
population based random effects model, which is based on polynomial functions,
provide a better fit to lamb live weight data than the individually fitted nonlinear Brody
function. The cubic polynomial had the lowest mean squared error, indicating the best
overall curve fit. However, the cubic polynomial also had the highest frequency of large
residual weights, while the frequency was lowest for the random effects model. The
ability of each function to estimate lamb weight varied with time although in general,
each function overestimated weight at weaning and underestimated weight at the post
weaning time point of 150 days, the magnitude of the difference being largest with the
Brody fit and similar with the cubic and random effects model fit. The random effects
model was subject to less bias and able to utilise data for a greater number of animals
due to its ability to accommodate data sets of differing sizes, which are common in an
industry setting, and infer information from animals with similar genetic and
environmental information. Therefore, the random effects model methodology offers a
more powerful and flexible means of evaluating repeated live weight measures.
89
Chapter 4. Lamb birth and rearing type influence
growth and weight potential of progeny from high
growth sires
4.1 Introduction
The ability to estimate lamb weights and growth rates at key time points is essential to
implementing appropriate management and feeding strategies. Therefore, factors which
influence lamb weights and growth rates have the potential to impact the economic
viability of a production system. Live weight has been shown previously to be
influenced by multiple births, by dam age and by the sex of the lamb. Thus ewe lambs,
lambs from 1 year old dams and multiple birth lambs tend to be lighter at birth
(Afolayan et al., 2007). Ewe nutrition is also important determinant of lamb weight with
lambs born to ewes with restricted nutrition being 34% lighter at birth (Schinckel and
Short, 1961). As birth weight is phenotypically correlated to adult weight (Huisman and
Brown, 2008) these lambs are likely to be lighter and grow slower throughout the early
life growth period.
Weights and growth rates in lambs can also be influenced by genetics. The Australian
sheep industry uses sire Australian Sheep Breeding Values (ASBVs) to select for
increased growth via an increased sire post weaning weight (PWWT) which has been
shown to correlate with an increased mature size (Huisman and Brown, 2008). The
magnitude of this response can be depressed by poor ewe nutrition (Hegarty et al.,
2006c). Therefore production factors which restrict lamb or ewe nutrition such as birth
90
type, rear type or dam breed may also depress the progeny response to increased sire
PWWT.
Lamb nutrition varies in-utero with the number of placentomes per foetus and the
relative placental weight per foetus declining as litter size increases (Greenwood et al.,
2000b). As placental weight is the largest determinant of foetal weight close to birth
(Greenwood et al., 2000b) placentally mediated foetal growth restriction due to multiple
births is likely to result in lighter lamb birth weights and a reduced capacity to express
the full PWWT potential. Furthermore, milk production has been shown to increase by
just 27% at peak yield in ewes with twin lambs (Morgan et al., 2006) representing a
nutritional restriction between birth and weaning for lambs raised as twins. Therefore
both birth and rearing type are likely to influence the expression of sire PWWT.
Milk production by the dam is highly correlated with lamb growth (Burris and Baugus,
1955; Snowder and Glimp, 1991) and milk yield is reduced in Merino dams compared
to Border Leicester-Merino cross dams (Kleemann et al., 1984) therefore we also expect
increased responses per kg of sire PWWT in lambs from Border Leicester-Merino cross
dams.
In addition to increased growth, ASBVs are used to select for increased muscling via an
increased post weaning eye muscle depth (PEMD) and leanness via a reduced post
weaning fat depth (PFAT) at the c-site (5cm from the midline over the 12th
rib). Gardner
et al. (2015) demonstrated an increase in pre slaughter live weight with a reduction in
PFAT and no association with PEMD. Therefore selection for leanness via a reduced
sire PFAT may result in heavier progeny while selection for increased muscling via an
increased sire PEMD may have no impact on live weight.
91
As a component of the Information Nucleus Flock (van der Werf et al., 2010) run by the
Australian Cooperative Research Centre for Sheep Industry Innovation numerous
measurements, including live weight, were taken on the progeny of sires with divergent
ASBV values enabling the effects of genotype and production factors to be determined.
As the effect of sire PWWT varies with nutrition we hypothesised that the magnitude of
the PWWT effect would vary between sites. We also hypothesised that lambs born and
raised as multiples or born to Merino dams would have a reduced response to increased
sire PWWT. Furthermore, lambs from low PFAT sires will be heavier while selection
for increased muscling via an increased sire PEMD will not impact lamb weight.
4.2 Materials and Methods
4.2.1 Experimental Design
The design of the Sheep CRC’s Information Nucleus Flock was presented in detail by
Fogarty et al. (2007) and van der Werf et al. (2010). Each year for 5 years a total of
approximately 3,500 lambs were produced at eight research sites across Australia,
which represent a broad range of production systems (Kirby NSW, Trangie NSW,
Cowra NSW, Rutherglen VIC, Hamilton VIC, Struan SA, Turretfield SA, and
Katanning WA). The lambs were progeny of 435 sires selected to represent the key
breeds used in Australia, and of different production traits. The sire types included
Merino sires (Merino, Poll Merino), Maternal sires (Border Leicester, Booroola,
Coopworth, Corriedale, Dohne Merino, East Friesian, Prime SAMM), and Terminal
sires (Hampshire Down, Ile De France, Poll Dorset, Southdown, Suffolk, Texel, White
Suffolk). Lambs were reared under extensive pasture grazing conditions and fed grain,
hay or feedlot pellets when feed supply was limited (Ponnampalam et al., 2014a).
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4.2.2 Lamb weights
Lambs were weighed at birth, at weaning (90 days of age) and approximately every two
weeks thereafter.
4.2.3 Data available
A total of 18,185 lambs with 142,572 weight recordings were available. Of these, a total
of 17,525 lambs with 141,206 weight recordings had data available for the fixed
production effects in the model, which included site, year of birth and sire type. Actual
birth weight was available for 17,480 animals. Actual birth weight and estimated weight
and estimated growth rate ranges are presented in Table 4-1.
Table 4-1 Actual birth weight (kg) ranges and estimated weight (kg) and growth rate (g/day) ranges at
100, 150 and 240 days.
Mean Minimum Maximum Range SD
Birth Weight (kg) 4.91 1.40 10.10 8.70 1.06
Weight 100 days (kg) 28.70 3.38 60.76 57.38 8.17
Weight 150 days (kg) 34.38 10.81 68.78 57.97 7.84
Weight 240 days (kg) 43.42 21.24 74.94 53.70 8.90
Growth Rate 100 days (g/day) 136.96 -184.43 547.70 732.13 80.52
Growth Rate 150 days (g/day) 97.17 -170.23 393.49 563.72 67.23
Growth Rate 240 days (g/day) 125.11 -559.42 897.38 1456.80 167.58
SD: Standard deviation
Of the 435 sires used, 84 Maternal, 167 Merino and 184 Terminal had ASBVs for birth
weight (BWT), PWWT, PFAT and PEMD. The PFAT and PEMD breeding values were
based on live ultrasound measurements while the BWT and PWWT breeding values
were based on live weight. All ASBVs were sourced from Sheep Genetics, Australia’s
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national genetic evaluation database for sheep (Brown et al., 2007). A correlation
matrix is presented in
Table 4-2. The ASBVs were estimated in April 2012 and were generated within
individual databases for Terminal, Maternal and Merino sires. Progeny from the
Information Nucleus Flock were excluded from the calculation of sire ASBVs.
Table 4-2 Phenotypic correlations (standard errors) of post weaning sire breeding values for weight, fat
depth and eye muscle depth among Maternal, Merino and Terminal sires.
PWWT PFAT PEMD
Maternal
PWWT 1.00 -0.18 (0.09) -0.06 (0.62)
PFAT -0.18 (0.09) 1.00 0.47 (0.00)
PEMD -0.06 (0.62) 0.47 (0.00) 1.00
Merino
PWWT 1.00 0.23 (0.00) 0.29 (0.00)
PFAT 0.23 (0.00) 1.00 0.76 (0.00)
PEMD 0.29 (0.00) 0.76 (0.00) 1.00
Terminal
PWWT 1.00 -0.03 (0.69) -0.26 (0.00)
PFAT -0.03 (0.69) 1.00 0.39 (0.00)
PEMD -0.26 (0.00) 0.39 (0.00) 1.00
4.2.4 Statistical analysis
A mixed effects regression was used in the study due to its ability to accommodate the
correlation of data due to repeated measures for the growth curve, and its ability to
handle unbalanced data. This allowed the estimation of live weight gain, allowing
weights and growth rates to be determined at the key ages in the growth cycle. Markov
chain Monte Carlo (MCMC) stochastic simulation, developed for estimation and
inference, was used within a generalised linear mixed model in the statistical package R
94
to fit a growth curve to the entire population and the growth curve of each individual
lamb deviated from this population curve. The number of iterations was 100,000 with a
burn in period of 5,000 and thinning was set at 100. The priors used were g priors.
Initially base models were developed to describe live weight, which included fixed
production effects for site (representing research station site; Kirby, Trangie, Cowra,
Rutherglen, Hamilton, Struan, Turretfield, Katanning), year of birth (2007, 2008, 2009,
2010, 2011), sex (male, female), birth type – rear type (11, 21, 22, 31, 32, 33), age of
dam (2, 3, 4, 5, 6, 7 years), sire type (Merino, Maternal, Terminal) and dam breed
within sire type (Merino x Merino, Merino x Maternal, Merino x Terminal, Border
Leicester-Merino x Terminal). The production effects and their interactions with animal
age was modelled using linear, quadratic and cubic terms for time, in days, since birth.
Individual identification, sire identification and dam identification by year were
included as random terms and were tested for linear, quadratic and cubic interactions
with time. All relevant first order interactions between fixed effects were tested and
removed if non-significant (P > 0.05).
From this model weights and growth rates, the first derivative from the random effects
model, were estimated for each animal at 100, 150 and 240 days with day 100
representing weaning age, day 150 representing the post weaning time point and day
240 representing near the average age at which the post weaning weight ASBV is
calculated in the Sheep Genetics data base (Brown et al., 2007). All appropriate results
for the individual, including curves for sire, dam, dam by year and animal, were
combined to calculate the estimated individual growth curve and derivative.
The estimated weights and growth rates were then analysed in SAS using a linear mixed
effects model (SAS Version 9.1, SAS Institute, Cary, NC, USA) where fixed and
random effects were tested using likelihood ratios. The model contained the same
95
production effects as described in the base random effects model above however the
effect of the production factors did not vary with time, nor was time included as a
random variable. The models contained relevant first order interactions between the
production effects and these were removed in a stepwise manner, by a process of
backward elimination, if non-significant (P > 0.05). The impact of production effects on
lamb weight at 100, 150 and 240 days could be estimated from R however it was not
possible to determine the impact on growth rate directly from R. As the impact of
production effects on weight as estimated from R and SAS were similar a decision was
made to determine the impact of production effects on both weight and growth rate in
SAS.
To assess the impact of sire birth weight (BWT) ASBV on weight at birth BWT was
included as a covariate in the base model. The model also contained relevant first order
interactions between the fixed effects and covariates, including a quadratic effect of the
covariate, and were removed if non-significant (P > 0.05).
To assess the impact of sire weaning weight (WWT) ASBV on weight and growth rate
at 100 days WWT was included as a covariate in the base model. The model also
contained relevant first order interactions between the fixed effects and covariates,
including a quadratic effect of the covariate, and were removed if non-significant (P >
0.05).
To assess the impact of sire PWWT, PEMD and PFAT on weight and growth rate at
150 and 240 days these were included in the base model. The model also contained
relevant first order interactions between the fixed effects and covariates, including a
quadratic effect of the covariate, and were removed if non-significant (P > 0.05).
96
4.3 Results
4.3.1 Actual birth weights
The phenotypic linear mixed effects model is presented in Table 4-3. The model did not
change when animals with birth weights greater than 3 standard deviations from the
mean were excluded so these animals were retained.
97
97
Table 4-3 Numerator and denominator degrees of freedom and F-values for the base models for birth weight and estimated weights and growth rates at 100, 150 and 240 days.
Birth Weight Day 100 Day 150 Day 240
Wt Gr Wt Gr Wt Gr
NDF;DDF F-value NDF;DDF F-value F-value NDF;DDF F-value F-value NDF;DDF F-value F-value
Site 7;5085 473.89** 7;5099 778.80** 306.43** 7;5099 1836.24** 69.08** 7;5099 19950.40** 42.38**
Year 4;12,000 4.64** 4;12,000 22.19** 5.56** 4;12,000 46.66** 6.49** 4;12,000 275.18** 20.92**
Sex 1;5085 853.25** 1;5099 480.52** 32.55** 1;5099 954.89** 5.06* 1;5099 33221.30** 409.77**
Birth type-rear type 2;5085 3326.84** 5;5099 724.59** 6.36** 5;5099 1009.60** 10.87** 5;5099 4108.29** -
Dam age 6;5085 29.83** 6;5099 27.64** 48.07** 6;5099 25.46** 32.02** 6;5099 300.10** 17.62**
Sire type 2;5085 268.01** 2;5099 1140.22** 32.16** 2;5099 2409.76** 56.59** 2;5099 4686.92** 49.80**
Dam breed (sire type) 1;5085 344.23** 1;5099 719.81** 67.02** 1;5099 1363.61** - 1;5099 8350.83** -
Site by Year 27;5085 42.53** 27;5099 167.95** 193.97** 27;5099 128.92** 53.17** 27;5099 80.71** 100.77**
Site by Sire type - - 14;5099 27.16** 39.86** 14;5099 15.67** - 14;5099 11.70** 13.56**
Year by Sire type - - 8;5099 - 51.75** - - - - - 36.57**
NDF, DDF; Numerator and denominator degrees of freedom; Wt; Weight; Gr; Growth rate; *P < 0.05, **P < 0.01
98
4.3.1.1 Production effects on actual birth weight
The average actual birth weight was 4.91 kg and ranged from 1.40 to 10.10 kg. Birth
weight was greatest at the Turretfield site and least at the Kirby site with average birth
weights of 5.09 kg and 3.90 kg respectively (P < 0.01). Lambs born in 2011 were
heaviest on average weighing 4.77 kg and lambs born in 2010 were the lightest
weighing 4.65 kg (P < 0.01). Within a site birth weight varied between years by as
much as 0.86 kg at Katanning and as little as 0.37 kg at Cowra (P < 0.01).
Predicted means for the impact of the production effects on birth weight are presented in
Table 4-4. Ram lambs were on average 0.32 kg heavier than ewe lambs (P < 0.01)
(Table 4-5). Single born lambs were on average 1.02 kg heavier than twin lambs and
1.74 kg heavier than triplets (P < 0.01). Lambs born to 2 year old dams were the lightest
and were on average 0.50 kg lighter than lambs born to 8 year old dams which were the
heaviest (P < 0.01). Lambs were 0.22 kg heavier on average for each year that dam age
increased up until 4 years of age (P < 0.01) then there was no significant difference in
lamb weight with each year that dam age increased. Terminal sired lambs were on
average 0.43 kg heavier than Maternal sired lambs and 0.53 kg heavier than Merino
sired lambs (P < 0.01). Within the Terminal sired lambs, those from Border Leicester-
Merino dams were on average 0.46 kg heavier than lambs from Merino dams (P <
0.01).
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Table 4-4 Predicted means for birth weight (kg) and estimated weight at 100, 150 and 240 days for different sexes, birth type-rear types, dam ages, sire types and dam breed within
sire type combinations.
Birth Weight Weight Day 100 Weight Day 150 Weight Day 240
(kg) (kg) (kg) (kg)
Level Mean s.e. Coefficient s.e. Coefficient s.e. Coefficient s.e.
Sex F 4.54 0.02 26.54 0.13 32.38 0.11 40.58 0.07
M 4.86 0.02 28.10 0.13 34.14 0.11 43.76 0.07
Birth type-rear type 11 5.62 0.02 31.87 0.12 37.47 0.10 45.47 0.07
21 4.60 0.02 29.41 0.16 35.27 0.13 43.68 0.07
22 - - 26.75 0.12 32.61 0.10 41.76 0.07
31 3.88 0.03 28.33 0.37 34.33 0.30 42.83 0.12
32 - - 25.12 0.23 31.21 0.19 40.61 0.09
33 - - 22.45 0.26 28.66 0.22 38.70 0.10
Dam age 2 4.34 0.05 27.59 0.32 31.78 0.26 38.90 0.11
3 4.57 0.02 27.40 0.16 33.33 0.13 42.52 0.07
4 4.77 0.02 27.68 0.14 33.98 0.12 42.97 0.07
5 4.78 0.02 27.98 0.14 33.76 0.12 42.63 0.07
6 4.80 0.02 28.64 0.16 33.69 0.13 42.43 0.07
7 4.79 0.03 26.81 0.22 33.39 0.18 42.75 0.09
8 4.84 0.06 25.14 0.36 32.89 0.29 43.01 0.12
Dam breed-Sire type Maternal-Merino 4.59 0.03 27.01 0.22 33.43 0.18 42.52 0.14
Merino-Merino 4.49 0.02 22.87 0.16 27.95 0.13 34.57 0.10
Terminal-Merino 4.79 0.02 29.82 0.18 36.02 0.15 47.07 0.10
Terminal-BLM 5.25 0.02 34.34 0.17 40.76 0.14 51.79 0.09
s.e.: Standard Error; BLM: Border Leicester-Merino
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Table 4-5 Magnitude of effect (difference between the highest and lowest values) for production or for genetic effects on weight and growth rate.
Birth Weight Weight Weight Weight Growth Rate Growth Rate Growth Rate
Day 100 Day 150 Day 240 Day 100 Day 150 Day 240
Site 1.19 10.26 13.20 17.90 79.85 88.63 74.52
Year 0.12 2.72 2.79 1.95 12.16 14.28 88.72
Sex 0.32 1.56 1.76 3.18 4.10 3.90 30.56
Birth type-rear type 1.74 9.42 8.81 6.77 10.30 23.77 NS
Dam age 0.50 3.50 2.20 4.11 44.30 98.12 66.47
Sire type 0.53 9.21 10.44 14.86 25.10 30.81 82.41
Dam breed-Sire type 0.46 4.52 4.74 4.72 11.00 NS NS
BWT 0.95 - - - - - -
WWT - 5.98 - - NS - -
PWWT - - 6.62 8.24 - NS NS
PFAT - - 1.41 NS - NS NS
PEMD - - NS NS - NS NS
NS: Not significant; -: Not modelled; Australian Sheep Breeding Values; BWT: Birth weight; WWT: Weaning weight; PWWT: Post weaning weight; PFAT: Post weaning fat depth;
PEMD: Post weaning eye muscle depth
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4.3.1.2 ASBV effects
In the base model sire as a random term was significant (P < 0.01) with 95% confidence
intervals of sire estimates presented in Table 4-6.
Table 4-6 95% Confidence intervals of sire estimates for birth weight (kg) and estimated weights (kg) and
growth rates (g/day) at 100, 150 and 240 days.
Maternal Merino Terminal
Birth Weight (kg) 4.55 - 4.61 4.46 - 4.51 4.99 - 5.02
Weight 100 days (kg) 26.69 - 27.31 22.72 - 23.10 31.89 - 32.18
Weight 150 days (kg) 33.18 - 33.64 27.83 - 28.15 38.20 - 38.46
Weight 240 days (kg) 42.34 - 42.74 34.40 - 34.74 49.28 - 49.60
Growth Rate 100 days (g/day) 142.16 - 150.03 119.10 - 125.20 142.71 - 151.54
Growth Rate 150 days (g/day) 111.73 - 118.28 82.00 - 85.99 109.57 - 113.56
Growth Rate 240 days (g/day) 92.37 - 109.50 70.11 - 80.94 154.36 - 170.21
BWT had an association with actual weight at birth increasing it by 0.53 kg for each kg
of BWT (P < 0.05) (Table 4-7). Across the 1.8 kg range, increasing BWT was
associated with an increase of 0.95 kg in weight at birth (Table 4-5). The association
varied with year of birth and birth type. The variation between years was as much as
0.75 kg per kg of BWT in 2011 and as little as 0.43 kg in 2010 while the variation
between birth types was as much as 0.70 kg per kg of BWT in single born lambs and as
little as 0.37 kg in triplet born lambs.
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Table 4-7 Regression coefficients for the relationship between sire ASBVs for growth and actual birth weight (kg) or estimated weight and growth rate at 100, 150 and 240 days.
Birth Weight Weight Day 100 Growth Rate Day 100 Weight Day 150 Growth Rate Day 150 Weight Day 240 Growth Rate Day 240 (kg) (kg) (g/d) (kg) (g/d) (kg) (g/d)
Level Coeff. s.e. Coeff. s.e. Coeff. s.e. Coeff. s.e. Coeff. s.e. Coeff. s.e. Coeff. s.e.
BWT ASBV WWT ASBV PWWT ASBV PWWT ASBV
ASBV 0.59 0.09 0.19 0.12 NS - 0.17 0.05 NS - 0.45 0.03 3.99 1.83
ASBV*Site Kirby - - -0.35 0.08 - - -0.13 0.04 - - - - - -
Trangie - - 0.07 0.12 - - 0.10 0.06 - - - - - -
Cowra - - 0.05 0.10 - - 0.09 0.05 - - - - - -
Rutherglen - - -0.16 0.09 - - -0.03 0.04 - - - - - -
Hamilton - - -0.26 0.09 - - -0.13 0.05 - - - - - -
Struan - - -0.22 0.10 - - -0.09 0.05 - - - - - - Turretfield - - -0.09 0.10 - - -0.03 0.04 - - - - - -
Katanning - - 0.00 . 0.00 . - - - -
ASBV*Year 2007 -0.27 0.07 - - - - - - - - -0.21 0.02 - -
2008 -0.22 0.07 - - - - - - - - -0.05 0.02 - -
2009 -0.30 0.08 - - - - - - - - -0.05 0.02 - - 2010 -0.33 0.07 - - - - - - - - -0.03 0.02 - -
2011 0.00 . - - - - - - - - 0.00 . - -
ASBV*Birth type-rear type 11 0.33 0.09 0.46 0.08 - - 0.28 0.04 - - - - -6.13 1.46
21 0.15 0.09 0.39 0.09 - - 0.21 0.04 - - - - -4.35 1.55
22 0.23 0.08 - - 0.15 0.04 - - - - -3.15 1.46 31 0.00 . 0.16 0.14 - - 0.11 0.07 - - - - -4.67 2.19
32 0.12 0.11 - - 0.10 0.05 - - - - -3.52 1.79
33 0.00 . - - 0.00 . - - - - 0.00 .
ASBV*Dam age 2 - - - - - - - - - - -0.07 0.02 - -
3 - - - - - - - - - - -0.02 0.02 - - 4 - - - - - - - - - - -0.01 0.02 - -
5 - - - - - - - - - - -0.01 0.02 - -
6 - - - - - - - - - - -0.05 0.02 - - 7 - - - - - - - - - - -0.03 0.02 - -
8 - - - - - - - - - - 0.00 . - -
ASBV*Dam breed-Sire type Maternal-Merino - - -0.01 0.13 - - -0.06 0.05 - - - - - -
Merino-Merino - - 0.26 0.09 - - 0.06 0.04 - - - - - -
Terminal-Merino - - 0.00 . - - 0.00 . - - - - - - Terminal-BLM - - 0.00 . - - 0.00 . - - - - - -
s.e.: Standard Error; Coeff.: Coefficient; BLM: Border Leicester-Merino; NS: Non significant
103
4.3.2 Estimated live weights and growth rates at 100, 150 and 240 days
The phenotypic linear mixed effects models are presented in Table 4-3
4.3.2.1 Production effects
The average weights at 100, 150 and 240 days were 28.70 ± 8.17, 34.38 ± 7.84 and
43.42 kg ± 8.90 kg. Lambs at Trangie were the heaviest on average at 100, 150 and 240
days weighing 31.87, 40.38 and 53.61 kg, while lambs at Kirby were lightest at 100 and
150 days weighing 21.61 and 27.18 kg (P < 0.01) (Table 4-5). At 240 days the lambs
from Hamilton were lightest on average at 35.71 kg while lambs at Kirby were second
lightest at 35.87 kg. Lambs born in 2011 were heaviest on average at 100 and 150 days
weighing 29.16 and 35.18 kg and at these ages lambs born in 2009 were the lightest
weighing 26.44 and 32.39 kg (P < 0.01). At 240 days, lambs born in 2007 were heaviest
on average weighing 43.08 kg and lambs born in 2008 were lightest weighing 41.13 kg.
At 100 days the difference between years varied across sites by as much as 11.17 kg at
Katanning and as little as 3.89 kg at Cowra. At 150 days the difference between years
varied across sites by as much as 10.72 kg at Trangie and as little as 2.71 kg at Cowra.
At 240 days the difference between years varied across sites by as much as 4.44 kg at
Turretfield and as little as 3.33 kg at Rutherglen (P < 0.01).
Predicted means for the impact of the production effects on weight are presented in
Table 4-4 and predicted means for the impact of the production effects on growth rate
are presented in Table 4-8. Wethers were 1.56 kg heavier than ewe lambs at 100 days,
1.76 kg heaver at 150 days and 3.18 kg heaver at 240 days (P < 0.01). Wethers also
grew faster by 4.10 g/day at 100 days, 3.90 g/day at 150 days and by 30.56 g/day at 240
days (P < 0.01).
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Table 4-8 Predicted means for estimated growth rate at 100, 150 and 240 days for different sexes, birth type-rear types, dam ages, sire types and dam breed within sire type
combinations.
Growth Rate Day 100
Growth Rate Day 150
Growth Rate Day 240
(g/day)
(g/day)
(g/day)
Level
Coefficient s.e.
Coefficient s.e.
Coefficient s.e.
Sex F
136.90 1.84
101.50 2.67
96.44 3.34
M
141.00 1.84
105.40 2.67
127.00 3.34
Birth type-rear type 11
140.20 1.69
90.53 2.26
- -
21
143.70 2.06
97.83 3.48
- -
22
135.70 1.72
104.00 2.17
- -
31
143.10 4.00
104.20 8.49
- -
32
137.60 2.86
110.01 4.84
- -
33
133.40 3.29
114.30 5.22
- -
Dam age 2
118.20 3.71
58.48 6.39
137.50 8.07
3
136.70 2.05
100.90 3.12
116.50 3.93
4
148.10 1.92
109.50 2.84
107.90 3.64
5
138.10 1.93
99.68 2.83
118.40 3.65
6
124.50 2.12
78.51 3.35
137.00 4.24
7
144.60 2.63
120.80 4.59
93.84 5.65
8
162.50 4.09
156.60 8.04
71.03 9.35
Dam breed-Sire type Maternal-Merino
146.50 3.45
114.90 3.68
99.01 6.60
Merino-Merino
122.60 2.42
84.09 3.01
76.89 4.51
Terminal-Merino
142.20 2.50
111.50 2.85
159.30 4.28
Terminal-BLM
153.20 2.47
111.50 2.85
159.30 4.28
s.e.: Standard Error; BLM: Border Leicester-Merino
105
Lambs born and raised as singles were the heaviest, being 2.46 kg heavier at 100 days,
2.20 kg heavier at 150 days and 1.79 kg heavier at 240 days than the next heaviest
lambs, twins raised as singles (P < 0.01) (Table 4-4). This was generally reflected in the
growth rates at 100 days with lambs raised as singles growing faster than lambs raised
as multiples (Table 4-8). At 150 days, lambs born and raised as triplets were growing
between 10 and 24 g/day faster than lambs born as twin or singles. At 240 days growth
rate did not vary between birth and rear types.
At 100 and 150 days the progeny of 4-6 year old dams were heavier (P < 0.01) however
by 240 days this pattern was no longer evident (Table 4-4). At 100 and 150 days the
lambs of 8 year old dams were growing the fastest and by 240 days were also the
heaviest (P < 0.01) (Table 4-8).
The progeny of Terminal sires were 5.07, 4.96 and 6.91 kg heavier than the progeny of
Maternal sires and 9.21, 10.44 and 14.86 kg heavier than the progeny of Merino sires at
100, 150 and 240 days respectively (P < 0.01) (Table 4-4). The progeny of Terminal
sires also grew 25.10, 27.41 and 82.41 g/day faster than the progeny of Merino sires at
100, 150 and 240 days (P < 0.01) (Table 4-8).
Within the Terminal sired lambs, those from Border Leicester-Merino dams were 4.52,
4.74 and 4.72 kg heavier than those from Merino dams at 100, 150 and 240 days (P <
0.01) (Table 4-4) and grew faster by 11.00 g/day at 100 days (Table 4-8).
4.3.2.2 ASBV effects
In the base models for weight and growth rate at 100, 150 and 240 days sire as a random
term was significant (P < 0.01) with 95% confidence intervals of sire estimates
presented in Table 4-6.
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4.3.2.2.1 WWT and PWWT on weight at 100, 150 and 240 days
WWT demonstrated an association with weight at 100 days (P < 0.01). Across the 16 kg
range, increasing WWT was associated with an increase in weight of 5.98 kg (Table
4-5). This effect varied between sites, birth type-rear type combinations and sire types
(P < 0.01) (Table 4-7). There was no effect at the Kirby, Hamilton or Struan sites
however within the Trangie, Cowra, Katanning, Turretfield and Rutherglen sites weight
increased by 9.00, 8.75, 7.90, 6.47 and 5.34 kg across the 16 kg range in WWT. The
was no effect in triplet born lambs however the weight of single born lambs increased
by 9.63 kg across the 16kg range in WWT while the weight of 21 and 22 lambs
increased by 8.53 and 6.09 kg respectively. Progeny of Merino sires had the largest
weight response of 0.55 kg per kg of WWT increase while progeny of Terminal sires
increased by 0.29 and progeny of Maternal sires increased by 0.28. This equated to
increases of 6.66, 2.91 and 2.31 kg across the 12.11, 10.04 and 8.26 kg WWT ranges for
Merino, Terminal and Maternal sire types.
PWWT demonstrated an association with weight at 150 days (P < 0.01) (Figure 4-1).
Across the 23 kg range, increasing PWWT was associated with an increase in weight of
6.62 kg. This effect varied between sites, birth type-rear type combinations and sire
types (P < 0.05) (Table 4-7). There was no effect at the Kirby or Hamilton sites
however within Trangie, Cowra, Katanning, Rutherglen, Turretfield, Rutherglen and
Struan sites weight increased by 9.60, 9.28, 7.29, 6.54, 6.49 and 5.09 kg across the 23
kg range in PWWT. There was no effect in triplet born lambs however the weight of
single born lambs increased by 9.83 kg across the 23 kg range in PWWT while the
weight of 21 and 22 lambs increased by 8.29 and 6.81 kg respectively. Progeny of
Merino sires had the largest weight response of 0.35 kg per kg of PWWT while progeny
of Terminal sires increased by 0.29 and progeny of Maternal sires increased by 0.22.
107
This equated to increases of 5.54, 4.98 and 3.11 kg across the 15.83, 17.16 and 14.14 kg
PWWT ranges for Merino, Terminal and Maternal sire types (Figure 4-1).
Figure 4-1 Comparison of sire estimates for post weaning weight (PWWT) Australian Sheep Breeding
Values for Maternal, Merino and Terminal sires with predicted means for weight at 150 days. Lines
represent predicted means for weight (± s.e.) for each sire type. Symbols (∆,+,o) represent individual sire
estimates.
20
25
30
35
40
45
-5 0 5 10 15 20
Lam
b W
eigh
t 150 d
ays
(kg)
Sire PWWT Breeding Value
Maternal Merino Terminal
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108
PWWT demonstrated an association with weight at 240 days (P < 0.01) (Table 4-7).
Across the 23 kg range, increasing PWWT was associated with an increase in weight of
8.24 kg. This effect varied between years and dam ages (P < 0.01) (Table 4-7). In 2011,
2010, 2008, 2009 and 2010 weight increased by 9.81, 9.11, 8.66, 8.63 and 4.97 kg
across the 23 kg range in PWWT. Lambs from dams aged 8, 5, 4, 3, 7, 6 and 2 increased
in weight by 8.85, 8.64, 8.60, 8.46, 8.20, 7.74 and 7.17 kg across the 23kg range in
PWWT.
4.3.2.2.2 WWT and PWWT on growth rate at 100, 150 and 240 days
There was no impact of WWT on growth rate at 100 days and no impact of PWWT on
growth rate at 150 days (Table 4-7). PWWT demonstrated an association with growth
rate at 240 days however this effect was only present in some birth type-rear type
combinations (Table 4-7). The variation was as much as 3.99 g/day in triplet born and
raised lambs and as little as -2.14 in single born lambs. This equated to an increased
growth rate in triplet born and raised lambs of 92.89 g/day and a reduced growth rate in
single born lambs of 49.82 g/day across the 23 kg range in PWWT.
4.3.2.2.3 PEMD on weight and growth rate at 150 and 240 days
PEMD had no effect on weight or growth rate at 150 days (Table 4-9). There was an
effect of PEMD on weight at 240 days however this was only present at the Katanning
site where weight reduced by 0.12 kg per kg of PEMD equating to a reduction of 0.96
kg across the 8 kg PEMD range. There was no effect of PEMD on growth rate at 240
days.
109
Table 4-9 Regression coefficients for the relationship between sire ASBVs for muscling and leanness and
estimated weight and growth rate at 100, 150 and 240 days.
Weight Day 240 Weight Day 150
(kg) (kg)
Coefficient s.e. Coefficient s.e.
PEMD ASBV PFAT ASBV
ASBV -0.12 0.05 -0.28 0.06
ASBV*Site Kirby -0.01 0.04 - -
Trangie 0.01 0.05 - -
Cowra 0.13 0.05 - -
Rutherglen 0.10 0.05 - -
Hamilton 0.06 0.05 - -
Struan 0.15 0.05 - -
Turretfield 0.05 0.05 - -
Katanning 0.00 . - -
ASBV: Australian Sheep Breeding Value; PEMD: Post weaning eye muscle depth; PFAT: Post weaning
fat depth; s.e.: Standard Error
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110
4.3.2.2.4 PFAT on weight and growth rate at 150 and 240 days
PFAT demonstrated an association with weight at 150 days, increasing weight by 1.41
kg across the decreasing 5 kg PFAT range (P < 0.01) (Figure 4-2). PFAT had no effect
on weight at 240 days or growth rate at 150 or 240 days.
Figure 4-2 Comparison of sire estimates for post weaning fat depth (PFAT) Australian Sheep Breeding
Values for Maternal, Merino and Terminal sires with predicted means for weight at 150 days. Lines
represent predicted means for weight (± s.e.) for each sire type. Symbols (∆,+,o) represent individual sire
estimates.
20
25
30
35
40
45
-3 -2 -1 0 1 2 3
Lam
b W
eigh
t 150 d
ays
(kg)
Sire PFAT Breeding Value
Maternal Merino Terminal
111
4.4 Discussion
4.4.1 Association between carcass breeding values and lamb weight
and growth rate
As expected, the progeny of sires with increased BWT were heavier at birth, WWT
were heavier at 100 days and PWWT were heavier at 150 and 240 days. As lamb
survival increases with increased birth weight in Merinos (Holst et al., 2002) increased
sire BWT may increase lamb survival rates. However, the relationship is non-linear
with increased lamb mortality beyond birth weights of 6.5kg, primarily due to dystocia
(Brown et al., 2014; Fogarty et al., 1992; Fogarty et al., 2000; Oldham et al., 2011;
Smith, 1977). Therefore at the highest extreme of BWT lamb mortality will be
increased.
As hypothesised, the magnitude of the responses to WWT and PWWT varied between
sites. This is likely to be due, in part, to differences in nutrition at different sites which
is known to impact on the magnitude of the PWWT effect (Hegarty et al., 2006c). The
largest response to WWT and PWWT were seen at Trangie and Cowra, the two sites at
which lambs were also the heaviest, consistent with improved nutrition. Alternatively,
the smallest response to WWT and PWWT was seen at Kirby where lambs were also
the lightest, consistent with inferior nutrition. These site differences were present
despite the implementation of management strategies such as supplementary feeding
when feed supply was limited or of poor quality (Ponnampalam et al., 2014a).
Nonetheless, as the dams used at each site were of different genetic lines, we cannot
discount the possibility that the varying WWT and PWWT effects have been impacted
by dam genetics. Other factors that vary between sites, and may contribute to the
variation in effect between sites, include weather and worm or other disease burden. At
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112
240 days the response to increased sire PWWT did not differ between sites so it is
possible that at this time point the extremes for the sites with the poorest nutrition were
not enough to depress to response to the PWWT ASBV. There was also no variation
between sites in response to the BWT ASBV. This may indicate a buffering of the
lambs by maternal nutrition with dams mobilising more of their own energy reserves.
Alternatively, the variation may have been present but obscured by the fact that the
error represents a larger proportion of the difference between weights at birth than later
in life. This is more likely to be the case as the difference in magnitude of response
between sites in response the BWT ASBV were similar to that for WWT and PWWT
being high at Trangie and Cowra and lowest at Kirby when the site by BWT interaction
was retained despite being insignificant.
Lamb birth type and rear type also moderated the response to increased BWT, WWT
and PWWT with the magnitude of the weight response at birth, 100 and 150 days
depressed with multiple births. This depressive effect due to in-utero restriction was
partially alleviated when the nutritional restriction between birth and weaning was lifted
through loss of a sibling for multiple birth lambs. The effect on growth rate was also
moderated at 240 days where the response to increased sire PWWT was positive in
lambs born and raised as triplets and by contrast was negative in lambs born as singles.
This would imply that increased PWWT accelerated early life growth such that mature
size is reached sooner in single born lambs thus growth rate slows down by 240 days.
As triplet born and raised lambs are proportionately less of their mature size by 240
days the full PWWT effect is still present.
Sire type moderated the response to increased WWT and PWWT with progeny of
Merino sires having the greatest response at 100 and 150 days. As Merino sired progeny
weighed less and had lower growth rates in general they are likely to be proportionately
113
less of their mature size at weaning and post weaning and therefore have an increased
response to sire growth ASBVs. As sire breeding values represent twice the expected
progeny difference, lamb weight is expected to increase by 0.5kg for each 1kg increase
in sire growth ASBV. Increases in lamb weight with sire growth ASBVs were as
expected for the progeny of Merino sires and reduced to 60% of the expected increase
in progeny of Maternal and Terminal sires. Maternal sires had a reduced accuracy of
sire ASBVs compared to Merino sires which may account for some of the variation in
sire type performances.
Although lambs from Border Leicester-Merino dams were larger and grew faster than
lambs from Merino dams, there was no difference in weight response to WWT or
PWWT in these lambs. This is despite evidence suggesting restricted nutrition to
progeny of Merino dams due to their restricted milk output (Kleemann et al., 1984) and
supporting evidence that pre weaning growth rates are reduced in progeny of Merino
dams compared to progeny of Border Leicester-Merino dams (Atkins and Thompson,
1979). As expected, a weight and growth rate differential was seen in response to dam
breed as a production effect. It is not clear why there was no breeding value differential
however the nutritional restriction due to dam breed may not be enough to reach a
threshold beyond which there is an impact on the expression of breeding values. The
magnitude of the production effects of site, birth type-rear type combination and sire
type was between 1.5 and 3.5 times the magnitude of the effect of dam breed on weight
at 100, 150 and 240 days (Table 4-5). The production effects which vary with WWT
and PWWT follow a similar pattern. As dam breed only had a small impact on lamb
weight the variation in the expression of the breeding value was too small to detect.
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As hypothesised, selection for increased muscle via an increased sire PEMD did not
impact on progeny weight. As the breeding values are calculated corrected to a constant
live weight (Brown et al., 2007) their impact on the phenotypic expression of growth
may be limited.
As hypothesised, selection for leanness via a reduced PFAT increased lamb weight
however this effect was only present at 150 days. The effect across the PFAT range was
small, representing an increase of just 4% above the average lamb weight at 150 days.
The phenotypic correlation between c-site ultrasound fat depth and weight was
relatively small in the Huisman and Brown (2008) study which may reflect the lack of a
consistent effect on weight in this study.
4.4.2 Production effects
The site at which lambs were reared impacted on weight throughout life. The
differences between sites are likely to be partly explained by nutrition and dam genetics.
Trangie had consistently high lamb weights and Kirby consistently low lamb weights,
possibly indicating increased and reduced planes of nutrition respectively. However, the
Information Nucleus Flock was not designed to control nutrition and thus conclusions
regarding the nutritional impact on birth weight are difficult to assess. As dam genetics
vary at each site they may also contribute to the variation in weights between sites. If
dam genetics at each site were entirely responsible for differences in lamb weight there
would be minimal differences in lamb weights at each site across different years
however lamb weight at a single site varied between years by nearly 40% of the average
lamb weight. Thus while dam genetics varies between sites and contributes to lamb
weight differences they are not solely responsible for these differences.
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The year in which lambs were born had no impact at birth and was relatively consistent
between 100 and 240 days. The effect was small being as little as 10% of the magnitude
of the site of rearing, which had the largest effect. While the effect was small it may be
due to post weaning nutritional availability within a year which would explain why the
impact is not present at birth. However, the sites at which lambs were raised were
spread across different regions of Australia where pasture availability varied
dramatically. Therefore it is likely that there are also non nutritional factors which
contributed to the impact of lamb weight within a year.
Male lambs were heavier and grew faster at all times measured and this has been
demonstrated in previous studies (Afolayan et al., 2007; Thatcher et al., 1991;
Thompson et al., 1985b). Despite male lambs being castrated in this study this effect is
consistent with the impact of testosterone, a potent muscle growth stimulant (Lawrence
and Fowler, 2002). The study by Thatcher et al. (1991) compared growth rates in rams,
wethers and ewes and found that rams grew significantly faster than wethers which in
turn grew significantly faster than ewes (P < 0.05). Thus while the wethers in this
experiment grew faster than the ewes it can be surmised that growth rate would have
been further increased if the male lambs were left entire.
Single born lambs were 22% heavier than twin born lambs and 45% heavier than triplet
born lambs at birth which is consistent with findings of Afolayan et al. (2007). The
weight differences due to birth type were present throughout life, although they were
proportionately less with age. Within a birth type, weight also varied with rearing type
with twins raised as singles heavier than twins raised as twins. Triplets raised as singles
were also heavier than triplets raised as twins which were heavier than triplets raised as
triplets. These weight differences were also present throughout life and reducing
throughout age although the weight differences were at most 19%. Thus while both
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birth type and rearing type impact on weight, birth type has the greatest effect. The
weight differences at birth were likely to be due to the effects of in-utero nutritional
restriction. As birth type represents a prenatal restriction and rear type represents a
postnatal to weaning restriction it can be concluded that prenatal restriction has a greater
impact on lamb weight. At 100 days the triplet born and raised lambs had the slowest
growth rate however by 150 days their growth rate was the fastest suggesting that
multiple born lambs experience a period of compensatory growth once nutritional
restriction is lifted at weaning. Compensatory growth in immature sheep whose
nutrition has been restricted has been previously demonstrated by Thornton et al.
(1979). In this experiment the 7 month old sheep (approximately 210 days old) had their
nutrition restricted and lost an average of 85g/day over a two month period. When feed
was reintroduced ad libitum these sheep then gained 500 g/day in the first 3 days and
300 g/day on average over 33 days to achieve similar live weights to the non-restricted
sheep. These growth rates exceed the 114.30 g/day seen in the 150 day old triplet born
and raised lambs in this experiment, however the lambs in this experiment were not
severely nutritionally restricted post weaning as in the Thornton et al. (1979)
experiment which demonstrates the difference between restriction in-utero versus just
that imposed during the postnatal period. Interestingly the initial live weight of these
Dorset Horn x Merino wethers at 7 months of age was 22.5 kg in the Thornton et al.
(1979) experiment, more than 50% lighter than current weight estimations.
Dam age influenced lamb birth weight with lambs born to 2 year old dams being the
lightest. This may be due to the utilisation of energy by the 2 year old dam for its own
growth and development at the expense of the lamb, causing in-utero nutritional
restriction. Ali et al. (2006) demonstrated an increase in birth weight of 25 grams for
each one year increase in dam age. As in our study this effect was present until dams
reached 4 years of age however the magnitude was smaller than the 230 – 430 g
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increase between years seen in our study. This may be a reflection of the variation of the
dam age effect between dam breeds as only Rambouilet ewes were used by Ali et al.
(2006) whereas Afolayan et al. (2007) used crossbred ewes and the increase in lamb
weight at birth between dam years was as much as 630g. While there was no dam age
by dam breed effect in this study Rambouilet ewes were not used and the dam breeds
which were used may not have been divergent enough to drive an effect. Dam age also
influenced weaning and post weaning lamb weights with lambs from 4-6 year old dams
tending to be heavier at 100 and 150 days. Increases in lamb weight at birth, weaning
and post weaning (200 days) with increasing dam age were also found in the Afolayan
et al. (2007), study, although only 1-4 year old dams were included so the effect beyond
this age is unknown. At 240 days, when lambs were close to adult weight, this pattern
was no longer evident. It is possible that the early influence on lamb weight is due to
dam factors such as mothering ability, milk production and colostrum composition, the
effects of which diminish post weaning, however these effects were not measured
during this experiment.
The progeny of Terminal sires were heavier between birth and 240 days while the
progeny of Merino sires were lighter at and had the slowest growth rates which is
consistent with the findings of Fogarty et al. (2000). Furthermore, progeny of elite
Terminal sires grew in excess of 250 g /day at 100, 150 and 240 days. As many
nutritional requirement tables used for ration formulation only accommodate lamb
growth rates up to 250 g / day (ARC, 1980) the nutrient requirements in the progeny of
contemporary elite growth sires need to be updated.
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Within the progeny of Terminal sires, those from Border Leicester-Merino dams were
heavier and had higher growth rates than those from Merino dams which is a reflection
of the increased mothering ability (Alexander et al., 1983) and milk yield of Border
Leicester-Merino dams (Kleemann et al., 1984).
Lamb weight was influenced by both production and genotypic factors and the
magnitude of the effects varied (Table 4-5). Site, birth type-rear type and sire type had
the greatest impact on lamb weight. Birth type had the largest effect on weight at birth
and this was 1.8 times the magnitude of the effect across 1.8 units of the BWT breeding
value. The difference in weight between sites had the second largest effect and was 1.3
times the magnitude of the BWT effect on birth weight. At 100, 150 and 240 days site
had the largest effect on weight. At 100 days the differences between sites was 1.7 times
the magnitude of the effect across 16 units of the WWT breeding value and between 1.1
and 6.6 times the magnitude of the other production effects. At 150 and 240 days the
differences between sites was twice the magnitude of the effect across 23 units of the
PWWT breeding value and between 1.2 and 9.2 times the magnitude of the other
production effects.
Lamb growth rate was also influenced by both production and genotypic factors (Table
4-5). At 100 and 150 days site had the largest effect on growth rate whereas at 240 days
year of birth had the largest effect. At 100 days there was no effect of WWT on growth
rate however the difference in growth rate between sites was between 1.8 and 19.5 times
the magnitude of the other production effects. At 150 days there was no effect of
PWWT on growth rate however the difference in growth rate between sites and dam
ages was similar and between 2.8 and 25.2 times the magnitude of the other production
factors. At 240 days there was no main effect of PWWT and the difference in growth
rates between years and sire types was similar and between 1.1 and 2.9 times the
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magnitude of other production effects. Therefore, while sire ASBVs do impact on
weight and growth rate in their progeny the effect is smaller than the impact of the
environment, year of birth or birth type.
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4.5 Conclusion
This study demonstrated that both genotypic and production factors had significant
effects on lamb growth. Selection for growth by selection of sires with an increased
BWT, WWT and PWWT resulted in lambs that were heavier at birth, weaning and post
weaning. The magnitude of these responses was moderated by nutrition hence varied
between sites and with birth type-rear type combinations. Lambs born as multiples, with
nutritional restriction from conception to weaning, had a reduced response to sire
PWWT. Selection for leanness and muscling by selection of sires with a reduced PFAT
and increased PEMD resulted had little impact on weight with increasing PEMD having
no effect at all. Reducing PFAT increased lamb weight, however this effect was only
present at the post weaning time point and was relatively small. As expected, single
born lambs, male lambs and lambs born to Terminal sires were heavier and grew faster.
Weight and growth rate were heavily influenced by environmental effects at each site
and the effects were stable with minimal re-ranking of sites based on lamb weight over
time. In conclusion, while selection for growth impacts on lamb growth, these effects
and those of production factors such as sex and sire type are generally small compared
to the impact of the environment.
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Chapter 5. Selection for lean meat yield in lambs
reduces indicators of oxidative metabolism in the
longissimus muscle
This chapter has been published in Meat Science:
Kelman, K.R., Pannier, L., Pethick, D.W. and Gardner, G.E. (2014) Selection for lean
meat yield in lambs reduces indicators of oxidative metabolism in the longissimus
muscle. Meat Science. 96 (2, Part B): 1058-1067.
5.1 Introduction
Lamb is marketed in Australia as a nutritious red meat and a ‘good source’ of iron and
zinc (Pannier et al., 2014b). The qualities of redness and mineral content of meat are
highly linked to muscle fibre type and thus oxidative capacity of muscles, with reduced
oxidative capacity being associated with reduced levels of iron and zinc (Pannier et al.,
2014b) and a less red appearance. For this reason oxidative capacity is an important
determinant of consumer appeal impacting both the colour and nutritional content of the
product.
Muscle oxidative capacity is intrinsically linked to fibre type (Brandstetter et al., 1998a;
Staron and Johnson, 1993) with type I muscle fibres having greater expression of
oxidative enzymes in cattle, guinea pigs and rabbits (Brandstetter et al., 1998a; Peter et
al., 1972) and higher levels of myoglobin in sheep (Pethick et al., 2005c), in contrast to
type II muscle fibres which express higher levels of glycolytic enzymes (Brandstetter et
al., 1998a). Therefore the activity of oxidative enzymes such as isocitrate
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dehydrogenase (ICDH; EC 1.1.1.42) and myoglobin concentration can be used as
indicators of oxidative metabolism, an approach previously taken to study the muscle of
lamb (Gardner et al., 2006b).
Production factors such as lamb nutrition and age have been shown to influence
oxidative metabolism. A study by Gardner et al. (2006b) demonstrated the impact of
plane of nutrition in lambs, with nutritional restriction reducing muscle ICDH activity
and myoglobin concentration. In comparison the genotypic effects on these traits were
smaller, having only half (for ICDH activity) or a quarter (for myoglobin concentration)
the impact of the nutritional effects (Gardner et al., 2006b).
Animal age is also a strong driver of muscle oxidative capacity with older more mature
lambs having decreased proportions of type IIX glycolytic muscle fibres and increased
proportions of type I and type IIA fibres (Greenwood et al., 2007; Suzuki and Cassens,
1983; White et al., 1978) leading to an increased ICDH activity (Brandstetter et al.,
1998a) and myoglobin concentration (Gardner et al., 2007; Pethick et al., 2005c).
Fibre type and thus oxidative capacity can also be influenced by genetics. The
Australian sheep industry uses Australian Sheep Breeding Values (ASBVs) to select for
increased growth, muscularity and leanness, which are all likely to impact on oxidative
capacity. Selection for increased growth via an increased post weaning weight (PWWT)
has been shown to correlate with an increased mature size (Huisman and Brown, 2008).
Thus at the same weight lambs from high PWWT sires will be less mature resulting in
reduced oxidative capacity. Increased muscularity in double muscled cattle and
increased muscling in lamb, achieved by selection for an increased post weaning eye
muscle depth (PEMD), have been shown to result in a greater proportion of type IIX
glycolytic fibres (Greenwood et al., 2006c; Wegner et al., 2000). Likewise, selection for
leanness via a reduced post weaning c-site fat depth (PFAT) has been shown to increase
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eye muscle depth and increase the proportion of type IIX fibres (Greenwood et al.,
2006c), reducing ICDH activity and myoglobin concentration (Gardner et al., 2006b).
Thus current selection for increased PWWT and PEMD and reduced PFAT are all likely
to reduce the oxidative capacity of muscle.
As a component of the Information Nucleus Flock (van der Werf et al., 2010) run by the
Australian Cooperative Research Centre for Sheep Industry Innovation numerous
measurements, including muscle ICDH activity and myoglobin concentration, were
taken on the progeny of sires with divergent ASBVs enabling the effects of genotype
and production factors to be determined. We hypothesised that increasing sire PWWT
and PEMD ASBVs and reducing sire PFAT ASBVs would all reduce the oxidative
capacity of muscle in their progeny. As production factors varied between sites, we also
hypothesised that this would cause differences in muscle oxidative capacity and that the
magnitude of these effects would be larger than the magnitude of the genotypic effects.
5.2 Materials and Methods
5.2.1 Experimental Design
The design of the Sheep CRC's Information Nucleus Flock was presented in detail by
(Fogarty et al., 2007). Each year a total of approximately 2,000 lambs were produced at
eight research sites across Australia, which represent a broad range of production
systems (Kirby NSW, Trangie NSW, Cowra NSW, Rutherglen VIC, Hamilton VIC,
Struan SA, Turretfield SA, and Katanning WA). The lambs were progeny of 267 key
industry sires, including Merino sires (Merino, Poll Merino), Maternal sires (Border
Leicester, Bond, Booroola, Coopworth, Corriedale, Dohne Merino, East Friesian, Prime
SAMM, White Dorper), and Terminal sires (Hampshire Down, Ile De France, Poll
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Dorset, Southdown, Suffolk, Texel, White Suffolk). Lambs were reared under extensive
pasture grazing conditions and fed grain, hay or feedlot pellets when feed supply was
limited (Ponnampalam et al., 2014a) to enable them to reach an average carcass weight
of approximately 21.5 kg. The time taken to reach this weight varied between 134 and
504 days. Lambs were yarded for 6 h on the day before slaughter then transported to
one of five commercial abattoirs where they were held in lairage overnight. After
slaughter, all carcasses were subjected to medium voltage electrical stimulation (Pearce
et al., 2010) and dressed according to AUS-MEAT specifications (Anonymous, 2005).
Carcasses were chilled overnight (3-4 °C) before a wide range of carcass and meat traits
were sampled.
5.2.2 Collection of phenotypic measurements
Hot carcass weight (HCWT) was measured at slaughter, and within 5 h post-mortem a 1
g sample of m. longissimus lumborum (short loin muscle) was excised from the carcass
(over the 12th rib) for every animal. Subcutaneous fat was removed and the samples
were snap-frozen in liquid nitrogen and stored at−80 °C until subsequent ICDH
determination. The ICDH activity was determined by the method of Briand (1981),
which was adapted to run on an Olympus AU400 auto analyser. At 24 h post-mortem
the entire short loin muscle was removed and weighed (short loin muscle weight), and
additional samples for myoglobin, intramuscular fat and protein determination were
collected. Subcutaneous short loin fat was also dissected and weighed (short loin fat).
For myoglobin, a 1 g sample of short loin muscle was excised and stored at −20 °C until
myoglobin concentration determination by the method of Trout (1991). For lambs born
in 2007 only, extractable protein was measured for the ICDH and myoglobin samples
by the method of (Bradford, 1976). For intramuscular fat, a 40 g sample of loin muscle
was excised and stored at −20 °C until subsequent freeze drying using a Cuddon FD
1015 freeze dryer (Cuddon Freeze Dry, NZ). The intramuscular fat content was
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determined using a near infrared (NIR) procedure in a Technicon Infralyser 450 (19
wavelengths) using the method described by Perry et al. (2001).
5.2.3 Data available
For the ICDH analysis muscle samples for a total of 3,178 lambs, which were the
progeny of 178 sires across 2 years were available, while for the myoglobin analysis
muscle samples for a total of 5,580 lambs, which were the progeny of 267 sires across 3
years were available.
5.2.4 Statistical analysis
ICDH activity and myoglobin concentration were analysed using linear mixed effects
models (SAS Version 9.1, SAS Institute, Cary, NC, USA). Initially, base models for
ICDH activity and myoglobin concentration were developed, which included fixed
production effects for site (representing research station site; Kirby, Trangie, Cowra,
Rutherglen, Hamilton, Struan, Turretfield, Katanning), year of birth (2007 and 2008 for
ICDH and 2007, 2008 and 2009 for myoglobin), sex (male, female), birth type–rear
type (11, 21, 22, 31, 32, 33), age of dam (2, 3, 4, 5, 6, 7 years), sire type (Merino,
Maternal, Terminal), dam breed within sire type (Merino ×Merino, Merino × Maternal,
Merino × Terminal, Border Leicester– Merino × Terminal) and kill group within site by
year. Sire identification and dam identification by year were included as random terms.
All relevant first order interactions between fixed effects were tested and removed in a
stepwise manner, by a process of backward elimination, if non-significant (P > 0.05).
To assess the relationship of ICDH activity and myoglobin concentration with aspects
of carcass phenotype traits, HCWT, short loin fat weight, short loin muscle weight and
intramuscular fat were included as covariates in the above base models. Initially HCWT
was included, and then either short loin muscle or fat weight was also included. All
models contained all relevant first order interactions between the fixed effects and
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covariates, including a quadratic effect of the covariate, and were removed in a stepwise
manner if non-significant (P > 0.05).
To assess the impact of sire PWWT, PFAT and PEMD ASBVs on ICDH activity and
myoglobin concentration, the three ASBVs were analysed concurrently as covariates in
the base model. Additionally the carcass traits of HCWT, short loin fat weight, short
loin muscle weight and intramuscular fat were analysed one at a time within this ASBV
model. Each ASBV was also analysed as an individual covariate within the base model.
All models contained relevant first order interactions between the fixed effects and
covariates, including a quadratic effect of the covariate, and were removed in a stepwise
manner if non-significant (P > 0.05).
To assess the impact of age at slaughter on ICDH activity and myoglobin concentration,
age at slaughter was included as a covariate in the base model. The model contained all
relevant first order interactions between the fixed effects and the age at slaughter
covariate, including a quadratic effect of age, and these were removed in a stepwise
manner if non-significant (P > 0.05). The kill group within site by year term was not
included as a fixed effect in this model as within each site by year the age at slaughter
was confounded by kill group. This is because the variation in age within each kill
group was less than 10 days. Removing the kill group term as a fixed effect allowed the
effect of age at slaughter to be estimated. As kill group accounts for factors the age at
slaughter term does not two versions of the model were used to estimate the impact of
age, the first with kill group as a random term and the second without kill group as a
random term, for comparison.
For lambs born in 2007 only, protein was determined and tested as a covariate within
this subset of the data. For both ICDH activity and myoglobin concentration, protein
had a large effect, increasing ICDH activity by 1.92 μmol/min/g tissue across the 35 g
protein range (Figure 5-1) and myoglobin concentration by 3.98 mg/g tissue across the
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60 g protein range. However, in both cases the magnitude of the other genotype and
environmental effects described within these models did not change whether the models
were corrected for protein or not. As the protein correction did not alter the magnitude
of the effects, a pragmatic decision was made to reduce assay workload by
discontinuing protein determination. Therefore protein was not measured in subsequent
years, and the analyses presented are expressed on a per gramme of tissue basis, with no
protein correction.
Figure 5-1 Linear relationship between muscle sample protein concentration (mg/g tissue) and isocitrate
dehydrogenase activity (± s.e.) in μmol/min/g tissue per gramme of protein. Each icon (o) represents an
individual lamb.
4
4.5
5
5.5
6
6.5
7
7.5
8
8.5
9
20 30 40 50 60 70 80 90
ICD
H A
ctiv
ity
(µ
mo
l/m
in/g
tis
sue)
Protein Concentration (mg/g tissue)
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5.3 Results
5.3.1 Isocitrate Dehydrogenase
5.3.1.1 Production effects
The phenotypic linear mixed effects model utilised ICDH activity for 3,178 animals and
described 68% of the total variance. The model is presented in Table 5-1.
Table 5-1 Numerator degrees of freedom, denominator degrees of freedom and F-values for the base
models for isocitrate dehydrogenase activity (μmol/min/g tissue) and myoglobin concentration (mg/g
tissue).
Isocitrate dehydrogenase Myoglobin concentration
(μmol/min/g tissue) (mg/g tissue)
NDF, DDF F-value NDF, DDF F-value
Site 7, 532 43.32** 7, 972 228.59**
Year of birth 1, 2409 1593.09** 2, 4242 16.76**
Sex 1, 532 8.75** 1, 972 34.81**
Sire type 2, 532 3.17* 2, 972 7.10**
Dam breed (sire type) 1, 532 10.60** NA NA
Kill group (site by year) 38, 532 18.57** 64, 972 40.21**
Site by year 6, 532 4.22** 13, 972 58.95**
NDF, DDF: Numerator and denominator degrees of freedom; * P < 0.05; ** P < 0.01; NA: Not
applicable (non-significant term)
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The number of progeny analysed in the base model is presented in Table 5-2.
Table 5-2 Number of progeny at each site for year of birth, sex, sire type and dam breed within sire type from the base ICDH activity model.
Year of birth Sex Sire type Dam breed within sire type
2007 2008 Female Male Maternal Merino Terminal MATM MM TM TBLM
Kirby 168 298 121 345 105 143 212 102 142 124 85
Trangie * 218 68 150 43 43 133 43 43 69 63
Cowra 290 157 143 304 65 65 317 64 64 213 101
Rutherglen 298 203 179 322 54 71 376 54 71 0 376
Hamilton 203 194 143 250 61 63 270 61 63 266 0
Struan 89 131 77 143 42 51 128 41 51 38 88
Turretfield 66 184 47 203 64 84 102 64 84 102 0
Katanning 392 409 239 560 184 161 446 184 161 442 0
*No animals were produced; MATM: Maternal x Merino; MM: Merino x Merino; TM: Terminal x Merino; TBLM: Terminal x Border Leicester-Merino
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The raw mean and ranges for ICDH activity and phenotypic covariates are presented in
Table 5-3.
Table 5-3 Raw mean ± standard deviation, and minimum to maximum value, for isocitrate dehydrogenase
activity and the phenotypic covariates tested within the base model.
Isocitrate Hot carcass Intramuscular Short loin Short loin Slaughter
Dehydrogenase weight fat muscle weight fat weight age
(µmol/min/g tissue) (kg) (%) (g) (g) (days)
Site
Kirby 4.75 ± 1.62 26.2 ± 5.3 4.8 ± 1.0 404.8 ± 84.7 289.2 ± 166.3 365.4 ± 49.4
(1.02 - 9.01) (16.0 - 40.0) (2.8 - 9.1) (140 - 670) (30 - 865) (270 - 420)
Trangie 3.78 ± 1.10 24.6 ± 3.0 4.4 ± 0.9 373.3 ± 62.9 147.8 ± 53.0 226.7 ± 53.3
(1.67 - 7.05) (18.5 - 34.7) (2.9 - 7.8) (245 - 583) (40 - 330) (193 - 333)
Cowra 6.07 ± 1.42 23.4 ± 3.2 4.0 ± 0.8 360.1 ± 63.1 159.2 ± 63.1 193.4 ± 57.2
(2.67 - 10.29) (16.3 - 35.3) (2.3 - 7.1) (215 - 565) (28 - 385) (138 - 325)
Rutherglen 4.72 ± 1.47 21.9 ± 2.5 3.9 ± 1.0 326.4 ± 53.5 175.6 ± 56.5 266.6 ± 54.6
(1.43 - 8.71) (14.4 - 31.8) (1.9 - 7.2) (157 - 558) (47 - 429) (215 - 392)
Hamilton 5.48 ± 1.63 21.1 ± 2.6 4.3 ± 1.0 341.3 ± 55.1 167.4 ± 53.0 313.2 ± 62.3
(2.42 - 11.29) (14.2 - 32.2) (2.1 - 7.7) (189 - 525) (11 - 354) (270 - 456)
Struan 4.73 ± 1.58 20.9 ± 3.2 4.3 ± 0.9 317.4 ± 71.7 206.2 ± 84.5 280.6 ± 63.7
(2.16 - 10.46) (12.8 - 29.0) (2.2 - 8.0) (165 - 549) (59 - 531) (219 - 426)
Turretfield 5.03 ± 1.53 20.5 ± 2.8 4.2 ± 1.2 332.6 ± 59.2 252.6 ± 78.2 262.7 ± 73.2
(2.90 - 11.27) (14.6 - 29.8) (2.6 - 10.5) (211 - 496) (0 - 555) (188 - 361)
Katanning 5.58 ± 1.72 21.5 ± 3.3 4.7 ± 1.1 343.8 ± 66.6 194.9 ± 87.3 280.4 ± 96.8
(2.25 -11.40) (13.6 - 31.3) (1.5 - 9.6) (173 - 598) (15 - 560) (178 - 499)
Year of birth
2007 6.44 ± 1.35 21.8 ± 2.8 4.2 ± 1.0 339.6 ± 57.7 182.4 ± 73.2 262.9 ± 71.3
(2.81 - 11.40) (12.8 – 32.2) (1.5 - 9.1) (140 - 580) (0 - 531) (157 - 456)
2008 4.10 ± 1.06 23.2 ± 4.4 4.5 ± 1.0 359.8 ± 77.5 211.2 ± 115.9 290.0 ± 93.5
(1.02 - 9.54) (13.6 – 40.0) (1.8 - 10.5) (173 - 670) (15 - 865) (138 - 499)
Sex
Female 5.00 ± 1.67 22.7 ± 3.7 4.3 ± 0.9 357.2 ± 65.7 213.4 ± 99.6 250.2 ± 61.0
(1.02 - 11.33) (12.8 – 39.6) (1.9 - 8.4) (165 - 625) (53 - 865) (138 - 420)
Male 5.24 ± 1.66 22.5 ± 3.9 4.4 ± 1.1 348.4 ± 72.2 192.3 ± 100.7 289.9 ± 91.4
(1.36 - 11.40) (13.6 – 40.0) (1.5 - 10.5) (140 - 670) (0 - 740) (138 - 499)
Sire type
Maternal 5.15 ± 1.63 21.6 ± 3.5 4.4 ± 1.0 319.8 ± 59.1 206.1 ± 96.1 250.5 ± 64.2
(1.70 - 10.72) (14.3 - 36.6) (2.2 - 9.6) (186 - 565) (63 - 585) (138 - 420)
Merino 5.62 ± 1.64 21.3 ± 3.8 4.6 ± 1.3 330.4 ± 65.8 164.6 ± 110.7 394.4 ± 57.0
(2.42 - 11.29) (12.8 - 33.8) (1.8 - 10.5) (140 - 580) (0 - 610) (178 - 499)
Terminal 5.02 ± 1.67 23.3 ± 3.8 4.2 ± 0.9 367.5 ± 69.8 207.8 ± 94.4 245.7 ± 60.4
(1.02 - 11.40) (14.8 – 40.0) (1.5 - 8.8) (193 - 670) (53 - 865) (138 - 420)
Dam breed within sire type
MATM 5.15 ± 1.63 21.7 ± 3.5 4.4 ± 1.0 319.9 ± 59.0 206.3 ± 96.3 250.2 ± 63.9
(1.70 - 10.72) (14.3 - 36.6) (2.2 - 9.6) (186 - 565) (63 - 585) (138 - 420)
MM 5.61 ± 1.64 21.3 ± 3.8 4.6 ± 1.3 330.6 ± 65.8 164.9 ± 110.6 393.9 ± 58.2
(2.42 - 11.29) (12.8 - 33.8) (1.8 - 10.5) (140 - 580) (0 - 610) (178 - 499)
TM 5.21 ± 1.64 22.6 ± 3.6 4.3 ± 0.9 367.1 ± 66.9 204.9 ± 94.1 244.5 ± 61.5
(1.90 - 11.40) (14.8 - 38.8) (1.5 - 8.8) (195 - 598) (53 - 695) (138 - 420)
TBLM 4.65 ± 1.66 24.4 ± 3.9 4.1 ± 0.9 368.6 ± 74.5 213.7 ± 95.1 247.6 ± 58.4
(1.02 - 9.41) (16.0 – 40.0) (1.9 - 7.0) (193 - 670) (61 - 865) (138 - 420)
MATM: Maternal x Merino; MM: Merino x Merino; TM: Terminal x Merino; TBLM: Terminal x Border
Leicester - Merino
131
The average activity level of ICDH was 5.17 ± 0.06 μmol/min/g tissue and ranged from
1.02 to 11.40 μmol/min/g tissue. Wethers (5.27 ± 0.03) had on average 0.13 μmol/min/g
tissue higher ICDH activity than ewe lambs (5.14 ± 0.05) (P < 0.01). Maternal (5.27 ±
0.08) and Merino (5.27 ± 0.12) sired lambs had 0.19 μmol/min/g tissue higher ICDH
activity than Terminal (5.08 ± 0.06) sired lambs (P < 0.05). Within the Terminal sired
lambs, those from Merino dams (5.19 ± 0.07) had 0.23 μmol/min/g tissue higher ICDH
activity than lambs from Border Leicester–Merino dams (4.96 ± 0.08) (P < 0.01).
ICDH activity was greatest at the Cowra site and least at the Trangie site with activities
of 5.76 and 3.99 μmol/min/g tissue (P < 0.01). It was also greater in lambs born in 2007
compared to lambs born in 2008 with activities of 6.45 and 4.12 μmol/min/g tissue (P <
0.01). However the difference between years varied across sites by as much as 2.69
μmol/min/g tissue at Hamilton to as little as 2.11 μmol/min/g tissue at Kirby (P < 0.01)
(Figure 5-2).
Figure 5-2 The effect of site by year of birth on isocitrate dehydrogenase activity (μmol/min/g tissue) (±
s.e.) from the base model.
0
1
2
3
4
5
6
7
8
ICD
H A
ctiv
ity
(µ
mo
l/m
in/g
tis
sue)
9
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132
Within each site and year there were marked differences between kill groups which
varied in ICDH activity by as little as 0.29 μmol/min/g tissue in Hamilton in 2008 to as
much a 2.36 μmol/min/g tissue in Katanning in 2007 (P < 0.01). ICDH activity
generally increased with older kill groups although this trend was not always consistent
across all sites. Age at slaughter was associated with an increase in ICDH activity of
0.26 μmol/min/g tissue across the 370 day age range (Figure 5-3). When kill group
within site by year was included as a random term the magnitude of the effect increased
to 1.23 μmol/min/g tissue.
Figure 5-3 Linear relationship between isocitrate dehydrogenase activity (μmol/min/g tissue) (± s.e.) and
slaughter age in days. Symbols represent predicted means for kill groups. Lines represent predicted means
for age at slaughter (± s.e.) from base model with no kill group term.
2
3
4
5
6
7
8
9
120 170 220 270 320 370 420 470
ICD
H A
ctiv
ity
(µ
mo
l/m
in/g
tis
sue)
Age at slaughter (days)
Kirby Trangie Cowra Rutherglen
Hamilton Struan Turretfield Katanning
133
When phenotypic (i.e. short loin muscle weight, short loin fat weight, intramuscular fat,
HCWT) or genotypic (PWWT, PFAT, PEMD) covariates were included in this model,
the production effects remained unchanged. The only exception to this was for sire type
which rarely impacted on ICDH activity in the presence of phenotypic or genotypic
covariates.
5.3.1.2 Association between ICDH activity and carcass phenotypic indicators
HCWT varied between 15 and 35 kg and demonstrated an association with ICDH
activity, but this was only present at the Turretfield and Kirby sites (P < 0.05). At the
Turretfield site ICDH activity increased by 1 μmol/min/g tissue across the 20 kg HCWT
range while at the Kirby site it decreased by 0.7 μmol/min/g tissue. Short loin muscle
weight varied between 200 and 550 g and demonstrated an association with ICDH
activity, but only at some sites. At the Turretfield site, ICDH activity increased by 0.88
μmol/min/g tissue across the 350 g short loin muscle weight range while at the Cowra
and Katanning sites it decreased by 0.52 and 0.59 μmol/min/g tissue (P < 0.05). This
association did not change when HCWT was included in the model. Short loin fat
demonstrated no association with ICDH activity. Intramuscular fat demonstrated a
curvilinear association with ICDH activity (P < 0.01), which increased by 0.72
μmol/min/g tissue between 2 and 6 intramuscular fat percent (Figure 5-4). The
relationship appeared to plateau beyond 6 intramuscular fat percent. The magnitude of
this effect was not changed by the inclusion of the phenotypic covariates short loin fat,
short loin muscle weight or HCWT.
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134
Figure 5-4 Curvilinear relationship between intramuscular fat percentage and isocitrate dehydrogenase
activity (± s.e.) in μmol/min/g tissue. Symbols (o) represent individual lamb residuals from the
intramuscular fat model.
5.3.1.3 Effect of sire and sire breeding values
In the base model sire as a random term was significant with individual sire estimates
for ICDH activity varying between 5.04 and 5.54 μmol/min/g tissue for Merino, 4.89
and 5.60 for Maternal and 4.59 and 5.78 for Terminal sires (P < 0.01) (Figure 5-5).
When PWWT, PFAT and PEMD were included simultaneously as covariates in the
base model each had an association with ICDH activity (P < 0.01). Across the 21 kg
range, increasing PWWT was associated with an increase in ICDH activity of 0.43
μmol/min/g tissue. This effect was no longer significant when the model was corrected
for short loin muscle weight, HCWT or intramuscular fat.
0
1
2
3
4
5
6
7
8
9
10
0 2 4 6 8 10 12
ICD
H A
cti
vit
y (
µm
ol/m
in/g
ti
ssu
e)
Intramuscular Fat (%)
135
Figure 5-5 Relationship between sire estimates for isocitrate dehydrogenase activity (μmol/min/g tissue)
and subcutaneous post weaning c-site fat depth (PFAT) for Maternal, Merino and Terminal sires. Lines
represent predicted means for isocitrate dehydrogenase activity (± s.e.) for all sire types combined.
Symbols represent individual sire estimates.
Across the 5 mm range, reducing PFAT was associated with a reduction in ICDH
activity of 0.46 μmol/min/g tissue (Fig. 5). This effect was no longer significant when
the model was corrected for short loin muscle weight.
Across the 7 mm range, increasing PEMD was associated with a reduction in ICDH
activity of 0.50 μmol/min/g tissue. This effect was no longer significant when the model
was corrected for short loin muscle weight.
The magnitudes of the PWWT and PEMD responses were similar when analysed as
single covariates in the base model, however the PFAT effect was no longer significant.
4.5
4.7
4.9
5.1
5.3
5.5
5.7
5.9
-2.5 -1.5 -0.5 0.5 1.5 2.5
ICD
H A
ctiv
ity
(µ
mo
l/m
in/g
tis
sue)
Post-weaning fat depth (mm)
Maternal Merino Terminal
136
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The mean and ranges for PWWT, PFAT and PEMD are presented in Table 5-4.
Table 5-4 Number of sires and Australian Sheep Breeding Values mean (min, max) for each sire type from the isocitrate dehydrogenase (ICDH) activity and myoglobin
concentration data.
Sire type No. of sires PFAT (mm) PEMD (mm) PWWT (kg)
ICDH Activity Maternal 37 -0.05 (-1.06, 2.56) 0.05 (-1.28, 1.82) 4.79 (-3.66, 10.49)
Merino 70 -0.25 (-1.89, 1.42) -0.18 (-2.02, 2.27) 1.45 (-5.00, 7.29)
Terminal 71 -0.82 (-2.41, 2.27) 1.12 (-1.33, 4.92) 11.92 (1.13, 16.05)
Myoglobin Concentration Maternal 61 -0.07 (-1.61, 2.56) 0.06 (-1.44, 1.82) 5.19 (-3.66, 10.49)
Merino 101 -0.22 (-1.89, 1.50) -0.10 (-2.02, 2.32) 1.81 (-5.00, 8.39)
Terminal 105 -0.85 (-2.44, 2.27) 1.07 (-1.33, 4.92) 12.06 (1.13, 18.08)
ICDH: Isocitrate dehydrogenase; PFAT: Post weaning c-site fat depth, PEMD: Post weaning eye muscle depth, PWWT: Post weaning weight
137
5.3.2 Myoglobin Concentration
5.3.2.1 Production effects
The phenotypic linear mixed effects model utilised myoglobin concentration for 5,580
animals and described 62% of the variance. The model is presented in Table 5-1. The
number of progeny analysed in the base model is presented in Table 5-5.
.
138
97
Table 5-5 Number of progeny at each site for year of birth, sex and sire type from the base myoglobin concentration model.
Year of Birth
Sex
Sire type
2007 2008 2009 Female Male Maternal Merino Terminal
Kirby
247 399 393
324 708
197 203 628
Trangie
* 216 199
145 270
76 77 262
Cowra
291 154 199
208 436
105 90 449
Rutherglen
298 213 172
325 358
88 103 492
Hamilton
198 194 175
196 368
90 80 395
Struan
296 123 177
207 389
108 67 420
Turretfield
269 185 214
207 461
136 119 411
Katanning 399 409 359 364 801 269 199 684
*No animals were produced
139
The raw mean and ranges for myoglobin concentration and phenotypic covariates are
presented in Table 5-6.
Table 5-6 Raw mean ± standard deviation and minimum to maximum values for myoglobin concentration
and the phenotypic covariates tested within the base model.
Myoglobin Hot carcass Intramuscular Short loin Short loin Slaughter
Concentration weight fat muscle weight fat weight age
(mg/g tissue) (kg) (%) (g) (g) (days)
Site
Kirby 8.18 ± 2.03 25.6 ± 5.1 4.7 ± 1.0 388.9 ± 78.6 270.6 ± 160.4 327.3 ± 56.5
(3.09 - 13.65) (15.4 - 40.0) (2.4 - 9.1) (140 - 670) (30 - 880) (235 - 420)
Trangie 6.18 ± 1.65 23.3 ± 3.3 3.8 ± 1.0 359.4 ± 62.6 122.6 ± 55.3 208.0 ± 65.3
(2.99 - 12.66) (16.2 - 34.7) (1.6 - 7.8) (228 - 583) (30 - 330) (154 - 342)
Cowra 6.13 ± 1.48 23.4 ± 3.4 3.9 ± 0.8 362.3 ± 65.2 147.7 ± 63.8 195.2 ± 54.8
(3.17 - 13.80) (14.0 - 35.3) (1.7 - 7.1) (160 - 585) (20 - 385) (138 - 325)
Rutherglen 6.69 ± 1.43 22.3 ± 2.9 3.8 ± 0.9 335.0 ± 58.6 190.2 ± 70.3 270.0 ± 50.9
(3.12 - 13.09) (14.2 - 31.8) (1.9 - 7.2) (157 - 558) (46 - 590) (215 - 392)
Hamilton 6.25 ± 1.69 21.8 ± 3.1 4.2 ± 0.9 341.5 ± 59.1 176.3 ± 73.0 295.6 ± 57.5
(2.15 - 11.33) (13.4 - 32.2) (2.1 - 7.7) (160 - 525) (10 - 412) (229 - 456)
Struan 5.81 ± 1.50 22.0 ± 3.3 4.1 ± 1.0 336.7 ± 71.8 195.6 ± 112.7 260.4 ± 49.7
(2.48 - 10.75) (12.8 - 31.4) (1.6 - 8.2) (155 - 590) (21 - 543) (210 - 426)
Turretfield 5.83 ± 1.58 21.6 ± 2.7 4.1 ± 1.0 335.6 ± 58.3 193.9 ± 107.4 259.9 ± 51.2
(2.24 - 11.57) (14.6 - 29.8) (1.9 - 10.5) (190 - 558) (0 - 555) (188 - 361)
Katanning 6.81 ± 1.66 22.3 ± 3.6 4.6 ± 1.1 364.3 ± 72.4 212.6 ± 88.1 274.6 ± 84.4
(2.95 -15.62) (13.6 - 35.8) (1.5 - 9.8) (173 - 661) (15 - 560) (178 - 499)
Year of birth
2007 6.50 ± 1.97 22.4 ± 3.1 4.3 ± 1.0 349.0 ± 62.3 203.2 ± 87.3 257.7 ± 63.3
(2.15 - 15.62) (12.8 – 35.8) (1.5 - 9.1) (140 - 661) (0 - 543) (157 - 456)
2008 6.76 ± 1.85 23.0 ± 4.4 4.5 ± 1.0 359.1 ± 76.5 205.7 ± 115.4 288.9 ± 91.0
(2.48 - 13.66) (13.6 – 40.0) (1.8 - 10.5) (173 - 670) (15 - 865) (138 - 499)
2009 6.70 ± 1.70 23.4 ± 4.0 4.0 ± 1.1 360.7 ± 71.3 187.6 ± 126.0 260.3 ± 58.6
(2.99 - 13.80) (13.4 – 40.0) (1.6 - 9.8) (155 - 620) (10 - 880) (154 - 359)
Sex
Female 6.45 ± 1.61 23.1 ± 3.7 4.2 ± 1.0 361.6 ± 64.5 212.5 ± 113.1 250.5 ± 57.2
(2.47 - 12.88) (12.8 – 40.0) (1.9 - 9.8) (165 - 625) (31 - 880) (138 - 420)
Male 6.74 ± 1.95 22.8 ± 3.9 4.3 ± 1.1 353.3 ± 72.8 192.2 ± 109.1 277.6 ± 78.9
(2.15 - 15.62) (13.4 – 40.0) (1.5 - 10.5) (140 - 670) (0 - 740) (138 - 499)
Sire type
Maternal 6.55 ± 1.76 21.9 ± 3.5 4.4 ± 1.1 324.1 ± 60.5 194.9 ± 105.9 252.7 ± 60.4
(2.24 - 14.41) (14.0 - 36.6) (1.6 - 9.7) (155 - 565) (20 - 585) (138 - 420)
Merino 8.22 ± 2.08 21.1 ± 3.6 4.5 ± 1.2 324.6 ± 66.0 157.1 ± 107.2 373.2 ± 59.7
(2.83 - 15.62) (12.8 - 33.8) (1.8 - 10.5) (140 - 580) (0 - 610) (178 - 499)
Terminal 6.27 ± 1.58 23.7 ± 3.8 4.1 ± 1.0 373.0 ± 68.1 210.2 ± 110.0 246.8 ± 55.3
(2.15 - 12.88) (14.8 – 40.0) (1.5 - 9.8) (193 - 670) (28 - 880) (138 - 420)
9
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140
The average myoglobin concentration was 6.65 ± 0.02 mg/g tissue and ranged from
2.15 to 15.62. Ewe lambs (6.89 ± 0.04) had on average 0.23 mg/g tissue higher
myoglobin concentration than wethers (6.66 ± 0.03) (P < 0.01). Maternal (6.87 ± 0.06)
and Merino (6.84 ± 0.09) sired lambs had higher myoglobin concentrations than
Terminal (6.61 ± 0.04) sired lambs (P < 0.01).
Myoglobin concentration was greatest at the Kirby site and least at the Struan site with
8.19 and 6.07 mg/g tissue (P < 0.01). It was also greater in lambs born in 2008 or 2009
than lambs born in 2007 with values of 6.93, 6.79 and 6.58 mg/g tissue (P < 0.01).
However these year differences varied across sites by as much as 2.09 mg/g tissue at
Hamilton to as little as 0.18 at Trangie (P < 0.01) (Figure 5-6).
Figure 5-6 The effect of site by year of birth on myoglobin concentration (mg/g tissue) (± s.e.) from the
base model.
0
1
2
3
4
5
6
7
8
9
My
og
lob
in C
on
cen
tra
tion
(m
g/g
tis
sue)
141
Within each site and year there were marked differences between kill groups which
varied by as little as 0.40 mg/g tissue in Struan in 2008 to as much as 4.77 in Kirby in
2008 (P < 0.01). Myoglobin concentration generally increased with later kill groups and
this result aligned well with the age at slaughter effect which was associated with an
increase in myoglobin concentration of 5.01 mg/g tissue across the 370 day age range
(Figure 5-7). When kill group within site by year was included as a random term the
magnitude of the effect increased to 5.73 mg/g tissue.
Figure 5-7 Linear relationship between myoglobin concentration (mg/g tissue) and slaughter age in days.
Symbols represent predicted means for kill groups. Lines represent predicted means for age at slaughter
(± s.e.) from base model with no kill group term.
When phenotypic (i.e. short loin muscle weight, short loin fat weight, intramuscular fat,
HCWT) or genotypic (PWWT, PFAT, PEMD) covariates were included in this model,
the production effects remained unchanged.
3
4
5
6
7
8
9
10
11
100 150 200 250 300 350 400 450 500 550
My
og
lob
in C
on
cen
tra
tio
n (
mg
/g t
issu
e)
Age at slaughter (days)
Kirby Trangie Cowra Rutherglen
Hamilton Struan Turretfield Katanning
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5.3.2.2 Association between myoglobin concentration and carcass phenotypic
indicators
HCWT demonstrated an association with myoglobin concentration increasing by 1.56
mg/g tissue across the 20 kg HCWT range (P < 0.01). This effect varied between sites
and sire types (P < 0.01). At the Kirby, Cowra, Turretfield, Hamilton, Katanning,
Rutherglen, Struan and Trangie sites myoglobin concentration increased by 0.66, 1.23,
1.28, 1.46, 1.72, 1.87, 2.08 and 2.22 mg/g tissue across the 20 kg range in HCWT.
Progeny with Merino sires had the largest increase in myoglobin concentration across
the HCWT range of 1.90 mg/g tissue, while progeny with Maternal and Terminal sires
increased by 1.82 mg/g tissue and 0.97 mg/g tissue across the HCWT range.
Short loin muscle weight did not demonstrate an association with myoglobin
concentration.
Short loin fat weight varied between 50 and 400 g and demonstrated an association with
myoglobin concentration, increasing by 0.83 mg/g tissue across the 350 g short loin fat
weight range (P < 0.01). This effect varied between sire types with progeny of Merino
sires increasing by 1.29 mg/g, progeny of Terminal sires increasing by 0.64 mg/g tissue
and progeny of Maternal sires increasing by 0.57 mg/g tissue across the short loin fat
weight range.
Intramuscular fat demonstrated a curvilinear association with myoglobin concentration
(P < 0.01). Between 2 and 6 intramuscular fat percent myoglobin concentration
increased by 0.61 mg/g tissue (Figure 5-8). The relationship appeared to plateau beyond
6% intramuscular fat. The association varied between sire types with increases of 0.35,
0.66 and 0.84 mg/g tissue in the progeny of Terminal, Maternal and Merino sires
respectively (P < 0.05).
143
Figure 5-8 Curvilinear relationship between intramuscular fat percentage and myoglobin concentration (±
s.e.) in mg/g tissue. Symbols (o) represent individual lamb residuals from the intramuscular fat model.
When ICDH activity was included as a covariate in the base model it was a significant
predictor of myoglobin concentration, which increased by 0.64 mg/g tissue across the
10.05 μmol/min/g tissue ICDH activity range (P < 0.01).
0
2
4
6
8
10
12
14
0 2 4 6 8 10 12
Myo
glo
bin
Co
ncen
tra
tio
n (
mg
/g t
issu
e)
Intramuscular Fat (%)
9
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144
5.3.2.3 Effect of sire and sire breeding values
In the base model sire as a random term was significant with individual sire estimates
for myoglobin concentration varying between 6.44 and 7.24 mg/g tissue for Maternal,
6.26 and 7.56 for Merino and 6.03 and 7.49 for Terminal sires (P < 0.01) (Figure 5-9).
When PWWT, PFAT and PEMD were included simultaneously as covariates in the
base model each had an association with myoglobin concentration (P < 0.05). Across
the 23 kg range, increasing PWWT was associated with an increase in myoglobin
concentration of 0.50 mg/g tissue. This effect varied between sites being greatest at the
Hamilton and Struan sites where myoglobin concentration increased by 0.89 and 1.00
mg/g tissue across the PWWT range (P < 0.05). These effects were no longer
significant when the model was corrected for short loin muscle weight, short loin fat
weight or intramuscular fat.
Across the 6 mm range, reducing PFAT was associated with a reduction in myoglobin
concentration of 0.67 mg/g tissue and this effect varied between sexes with a reduction
of 0.26 mg/g tissue in wethers and a reduction of 1.07 mg/g tissue in ewe lambs. There
was no impact to the magnitude of the PFAT effect when short loin muscle weight and
short loin fat weight were included separately as covariates. The magnitude of the
PFAT effect reduced to 0.58 mg/g tissue when intramuscular fat was included as a
covariate.
There was also an association between PEMD and myoglobin concentration however
this was only present within the Merino and Terminal sire types (P < 0.01). Across the
6 mm range, increasing PEMD was associated with a reduction in myoglobin
concentration of 0.49 mg/g tissue in the progeny of Terminal sires and an increase of
1.36 in the progeny of Merino sires (Figure 5-9). When short loin muscle weight, short
145
loin fat weight and intramuscular fat were included separately as covariates in the
ASBV model there was a reduction of the PEMD effect in progeny of Merino sires to
1.22 mg/g tissue and increase to 0.57 mg/g tissue in the progeny of Terminal sires.
When these ASBVs were analysed as single covariates in the base model the magnitude
of the PWWT response increased to 0.74 mg/g tissue and the PFAT response reduced to
0.57 mg/g tissue. The magnitude of the PEMD response remained unchanged.
The mean and ranges for PWWT, PFAT and PEMD are presented in Table 5-4.
146
97
Figure 5-9 Relationship between sire estimates for myoglobin concentration (mg/g tissue) and post weaning eye muscle depth (PEMD) for Maternal, Merino and Terminal sires.
Lines represent predicted means for myoglobin concentration (± s.e.) for each sire type. Symbols (o) represent individual sire estimates.
1
147
5.4 Discussion
5.4.1 Association between carcass breeding values and oxidative
capacity
Aligning with our hypothesis, the progeny of sires with an increased PEMD had a
reduced oxidative capacity, as indicated by reduced ICDH activity across all sire types
and reduced myoglobin concentration within Terminal sired lambs. This aligns well
with previous studies, with Gardner et al. (2006a) demonstrating reduced myoglobin
concentration in response to PEMD with in Poll Dorset x Merino lambs, and Gardner et
al. (2007) demonstrating reduced ICDH activity within Poll Dorset x Merino and
Border Leicester x Merino lambs. A further study by Gardner et al. (2006b) also
showed a reduced myoglobin concentration within the progeny of all sire types with
increased PEMD but failed to show this effect on ICDH activity. This is likely to be due
to the limited number of sires used, 9 compared to 267 in this study, where the PEMD
range of 5 mm compared to 7 mm in this study may not have been divergent enough to
elicit a response.
The association between PEMD and reduced oxidative capacity may be due to a shift in
muscle fibre type with increased PEMD leading to a greater proportion of type IIX
fibres (Greenwood et al., 2006c) which have been associated with increased glycolytic
(Gardner et al., 2006b) and reduced oxidative enzyme activities (Brandstetter et al.,
1998a).
The use of the PEMD breeding value within the Australian sheep industry has been
shown to increase loin muscle weight (Gardner et al., 2010). As there is an association
between increased phenotypic muscle weight and reduced muscle oxidative capacity it
could be concluded that the PEMD effect on muscle oxidative capacity is merely a
148
correlate of its impact on short loin muscle weight. However, in this study there was no
phenotypic association between short loin muscle weight and myoglobin concentration,
and a variable association with ICDH activity.
Furthermore, correcting the models for short loin muscle weight had no impact on the
association between PEMD and myoglobin concentration. This inconsistent overall
phenotypic association between short loin muscle weight and muscle oxidative capacity
is unusual and appears to suggest that PEMD is affecting myoglobin concentration
through a mechanism other than the phenotype that it directly delivers.
As hypothesised, progeny of sires with a reduced PFAT had a reduced oxidative
capacity, as indicated by reduced ICDH activity and myoglobin concentration. Previous
studies have demonstrated similar results with Gardner et al. (2006b) and (Gardner et
al., 2007) both demonstrating reduced ICDH activity in lambs with low PFAT sires, and
Greenwood et al. (2006c) showing higher levels of glycolytic type IIX fibres. Although
the Gardner et al. (2006b) study showed a reduction in ICDH activity there was no
impact on myoglobin concentration. The study was performed on wether lambs which
in our study had a smaller response to a reduction in PFAT than ewe lambs. As the
Gardner et al. (2006b) study included only 56 wethers this may not have been enough to
show an effect.
Intramuscular fat is reduced in the progeny of sires with a reduced PFAT in the animals
in this study (Pannier et al., 2014c) however inclusion of intramuscular fat in the ASBV
model did not diminish the impact of PFAT on ICDH activity or myoglobin
concentration, indicating that the impact of PFAT is not delivered through its correlated
impact on intramuscular fat.
149
Contrary to our initial hypothesis, isocitrate dehydrogenase activity and myoglobin
concentration were both increased in the progeny of sires with an increased PWWT.
Our hypothesis was based on the assumption that the progeny of high PWWT sires
would be less mature and therefore have a lower oxidative capacity at a given slaughter
age due to their larger mature size (Huisman and Brown, 2008). However, this effect
has clearly been over-ridden by other factors. The samples for ICDH activity and
myoglobin concentration were taken from the short loin, and the inclusion of short loin
muscle weight as a phenotypic covariate nullified the impact of the PWWT ASBV on
both ICDH activity and myoglobin concentration. Evidence from computed tomography
scanning of a subset of these same animals suggests an altered tissue distribution within
high PWWT lambs. In particular, the weight of muscle within the saddle region of the
carcass was 7% higher at any given carcass weight (Gardner et al., 2012). As such the
increased growth potential of these tissues would have required greater energy
producing capacity, of which the TCA cycle is a vital component. As such it is possible
that the impact of PWWT on muscle oxidative capacity is limited to the saddle region.
5.4.2 Associations with carcass phenotypic measurements
Heavier carcasses were associated with increased myoglobin concentration, although
there was no effect of HCWT on ICDH activity except at the Turretfield and Kirby
sites. In this study HCWT at a constant slaughter age (i.e. kill group corrected for age as
per Figure 5-3 and Figure 5-7) reflects growth rate, which is most likely delivered
through variation in environment and nutrition. As such the faster growing lambs are
likely to be closer to their mature size, aligning well with the myoglobin results which
have previously been shown to increase as lambs approach maturity (Gardner et al.,
2007). Yet this increase in myoglobin concentration may have occurred without a
150
corresponding increase in muscle oxidative capacity, as there was no increase in ICDH
activity. Alternatively the higher growth rate may have been due to a larger mature size,
in which case faster growing animals slaughtered at the same age would be less mature
(Butterfield, 1988), but this seems unlikely as it would have resulted in proportionately
less oxidative muscle tissue (Brandstetter et al., 1998a), the opposite of what was found
here.
The relationship between muscle oxidative capacity and phenotypic carcass muscularity
(short loin muscle weight) and adiposity (short loin fat weight) was also assessed.
Computed tomography was used to determine whole carcass muscle and fat weights on
a subset of the animals used in this study, and these measurements demonstrated that
short loin muscle weight was strongly correlated with whole carcass muscle weight
(0.84), and short loin fat weight was strongly correlated with whole carcass fat weight
(0.83) (Anderson, unpublished data). As such these measurements are good indicators
of whole carcass muscularity and adiposity. As mentioned, the muscularity indicator,
short loin muscle weight, demonstrated no association with myoglobin and an
inconsistent relationship with ICDH. Alternatively the carcass adiposity indicator, short
loin fat weight, demonstrated a consistently positive association with myoglobin,
although no association with ICDH. Thus phenotypic carcass composition demonstrates
some alignment with the oxidative capacity of muscle, albeit an inconsistent
association. The phenotypic correlation between ICDH activity and myoglobin
concentration in this experiment was 0.14 (Mortimer et al., 2014) which may explain
some of the variation in response of the oxidative indicators.
In contrast, a far more consistent association was evident for the relationship between
muscle oxidative capacity and intramuscular fat. ICDH activity and myoglobin
concentration both increased with higher levels of intramuscular fat. Similar effects
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have been demonstrated in cattle, where the genotypes which expressed higher levels of
intramuscular fat also had a more oxidative muscle type, characterised by increased
ICDH activity (Hocquette et al., 2003; Jurie et al., 2007; Pethick et al., 2005c).
Likewise, this has also been demonstrated in pigs (Essén-Gustavsson et al., 1994) and
rabbits (Gondret et al., 1998) in which slow twitch oxidative muscles had higher levels
of intramuscular fat. More recently, Pannier et al. (2014b) demonstrated a positive
association between intramuscular fat and iron and zinc levels.
The association between intramuscular fat and oxidative capacity appears to be
independent of maturity, or whole carcass adiposity and muscularity. This was
demonstrated by also correcting the ICDH activity and myoglobin models for HCWT,
short loin muscle weight and short loin fat weight. In all cases the intramuscular fat
association with ICDH activity or myoglobin concentration remained unchanged. As
such the association between intramuscular fat and muscle oxidative capacity appears to
be more than just a correlate of whole carcass fatness or muscularity. It seems unlikely
that intramuscular fat would directly mediate the oxidative capacity of adjacent muscle
cells, however this result may highlight the presence of some localised control that
ensures that more oxidative muscle cells have greater amounts of stored oxidative fuel
(fat) in the near vicinity (i.e. intramuscular adipocytes).
5.4.3 Production effects
As hypothesised, the site at which lambs were reared impacted on oxidative capacity
and the magnitude of the effect of site was larger than most other genotypic and
production effects. Between sites, the average age at slaughter varied which may
explain part of the differences between sites. This was particularly evident in the
myoglobin analysis where the Kirby site had the oldest average age at slaughter as well
as the highest myoglobin concentration, and of the four sites with the oldest average
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age, three sites also had higher than average myoglobin concentrations. In line with
these findings, a previous study showed a significant increase in Chromameter a* values
indicating an increase in the relative redness of meat as lambs age (Hopkins et al.,
2007). In the ICDH analysis the site differences appeared to be less age dependant,
however this was not entirely unexpected as ICDH activity demonstrated a weaker
association with age than myoglobin concentration (Figure 5-3 and Figure 5-7). In
addition the effect of age at slaughter on ICDH activity was small compared to the
magnitude of the production or breeding value effects while the effect on myoglobin
concentration was large compared to all other effects indicating that age was a critical
factor in determining myoglobin concentration but not ICDH activity. When kill group
was included as a random term the effect of age on ICDH activity was larger. As age
and kill group are strongly confounded within the Information Nucleus Flock the true
magnitude of the impact of age is likely to lie somewhere between the two results.
The differences between sites are also likely to be partly explained by nutrition.
Nutritional variation has been shown to impact on muscle fibre type (Greenwood et al.,
2006b; Moody et al., 1980) and subsequently may alter oxidative capacity. Oxidative
capacity was highest at the Kirby and Cowra sites after correcting for age and weight
(maturity), perhaps indicating an increased plane of nutrition at these sites. However,
the Information Nucleus Flock was not designed to control nutrition and thus
conclusions regarding the nutritional impact on oxidative capacity are difficult to assess.
There was a difference in oxidative capacity between wether and ewe lambs although
ICDH activity was greater in wethers and myoglobin concentration was greater in ewe
lambs. Gardner et al. (2007) demonstrated an increased ICDH activity in wether lambs
when compared to ewe lambs. Consistent with these results, Greenwood et al. (2007)
sampled the same lambs as used in the Gardner et al. (2007) study and demonstrated
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that wether lambs had reduced proportions of type IIX myofibres. While higher
myoglobin levels in ewe lambs were unexpected, a previous study by Ledward and
Shorthose (1971) found a similar result, with ewe lambs having a 10% higher
myoglobin concentration than wethers. The reason for myoglobin concentration to be
increased in ewe lambs is unclear, thus gender demonstrates some alignment with the
oxidative capacity of muscle however the association is inconsistent.
The progeny of Terminal sires had reduced oxidative capacity compared Maternal or
Merino sired lambs. This is due to the selection pressure on muscling in these sires
(Hall et al., 2002) which has also been shown in this study to reduce oxidative capacity.
Muscle oxidative capacity was influenced by both production and genotypic factors,
with site having the largest effect overall. The difference between sites was about three
and a half times the magnitude of the effect of PWWT, PFAT or PEMD, and about 10
times the magnitude of the other production effects on ICDH activity and myoglobin
concentration. The only exception to this was for year of birth which had a larger effect
than site on ICDH activity. Therefore, while sire ASBVs do impact on oxidative
capacity in their progeny, the effect is small compared to the impact of the environment.
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5.5 Conclusion
This study demonstrated that both genotypic and production factors had significant
effects on oxidative capacity. Selection for leanness and muscling by selection of sires
with a reduced PFAT and increased PEMD resulted in a reduction in oxidative capacity
in muscle of the progeny. This effect was also seen in the progeny of Terminal sires,
which have received greater selection pressure for lean growth and muscling. Selection
for lambs with a larger mature size using sires with an increased PWWT resulted in
increased oxidative capacity however this may be an effect which is localised to the loin
region. An increase in intramuscular fat is linked to an increase in oxidative capacity
that is independent of its association with PFAT or whole body adiposity or
muscularity. Oxidative capacity also increased with age however the effect was more
evident on myoglobin concentration than ICDH activity. Increased growth rate, which is
heavily influenced by environmental effects at each site, was associated with an
increase in oxidative capacity however the effect of growth rate was smaller than the
effect of site itself. In conclusion, while selection for leanness, muscling or mature size
using ASBVs impacts on oxidative capacity, these effects and those of production
factors such as sex and sire type are small compared to the impact of the environment.
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Chapter 6. Lamb growth increases intramuscular
fat levels and reduces shear force in the longissimus
muscle
6.1 Introduction
Lamb eating quality is becoming increasingly important to consumers (Pethick et al.,
2006a). It is strongly influenced by intramuscular fat due to its associations with
consumer sensory scores. As intramuscular fat increases the sensory scores for
tenderness in lamb increase (Pannier et al., 2014a), which is supported by a negative
phenotypic correlation between intramuscular fat and shear force (Mortimer et al.,
2014). There is also an increase in consumer overall liking, a score out of 100 based on
the Meat Standards Australia sensory system, with an increase in intramuscular fat
(Pannier et al., 2014a) and a reduction with a reduced intramuscular fat (Hopkins et al.,
2006). Therefore changes in intramuscular fat will impact eating quality through
changes in shear force and consumer sensory scores.
Lamb growth may impact intramuscular fat although this has not been thoroughly
investigated in sheep. In cattle, pre finishing growth restrictions result in reduced levels
of intramuscular fat at the end of finishing, with the development of intramuscular fat
linked to carcass fatness (Pethick et al., 2004). Pannier et al. (2014c) used hot carcass
weight as a proxy for whole of life growth in sheep to suggest that intramuscular fat is
increased with lamb growth. However, the accuracy of the hot carcass weight effect as
an estimate of the impact of growth is untested against actual growth rates. As hot
carcass weight is dependent on age at slaughter it is less representative of growth and
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more representative of environmental influences as animals get older and is likely to be
a poor proxy for whole of life growth. Furthermore, hot carcass weight is unable to
differentiate the effect during different phases of growth.
As intramuscular fat increases with hot carcass weight (Pannier et al., 2014c) and shear
force and consumer sensory scores are influenced by intramuscular fat (Pannier et al.,
2014a) quantification of the true impact of lamb growth is important to highlight any
potential effects on meat quality. We hypothesise that intramuscular fat and overall
liking will increase with growth and shear force will reduce.
6.2 Materials and Methods
6.2.1 Experimental Design
The design of the Sheep Cooperative Resource Centre (CRC) Information Nucleus
Flock was presented in detail by Fogarty et al. (2007) and van der Werf et al. (2010).
Each year, for 5 years between 2007 and 2011, a total of approximately 3,500 lambs
were produced at eight research sites across Australia, which represent a broad range of
production systems (Kirby NSW, Trangie NSW, Cowra NSW, Rutherglen VIC,
Hamilton VIC, Struan SA, Turretfield SA, and Katanning WA). The lambs were the
progeny of sires selected to represent the key breeds used in Australia. These included
Merino sires (Merino, Poll Merino), Maternal sires (Bond, Border Leicester, Booroola,
Coopworth, Corriedale, Dohne Merino, East Friesian, Prime SAMM, White Dorper),
and Terminal sires (Hampshire Down, Ile De France, Poll Dorset, Southdown, Suffolk,
Texel, White Suffolk). Lambs were reared under extensive pasture grazing conditions
and fed grain, hay or feedlot pellets when feed supply was limited (Ponnampalam et al.,
2014a).
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6.2.2 Collection of phenotypic measurements
Lambs were weighed at birth, at weaning (90 days of age) and approximately every two
weeks thereafter. Hot carcass weight was measured at slaughter. After slaughter all
carcasses were subjected to medium voltage electrical stimulation (Pearce et al., 2010)
and dressed according to AUS-MEAT specifications (Anonymous, 2005). Carcasses
were chilled overnight (3-4°C). Twenty four hours post slaughter the entire short loin
muscle was removed from the carcass saddle region (cut between the 12th and 13th
ribs) and the m. longissimus lumborum muscle dissected. The subcutaneous short loin
fat was weighed (short loin fat weight). The topside muscle (semimembranosus) was
also excised from the carcass. The two muscles were vacuum packed and stored at 2°C
to age for 5 days. Five steaks from each muscle of 15 mm thick were cut, vacuum
packed and frozen at −20°C for subsequent sensory testing. The contralateral loin and
topside of the carcass were also excised and used for subsequent objective meat quality
measurements of intramuscular fat and shear force.
For intramuscular fat, a 40 g sample of loin muscle was excised and stored at -20ºC
until subsequent freeze drying using a Cuddon FD 1015 freeze dryer (Cuddon Freeze
Dry, NZ). Intramuscular fat content, expressed as a percentage, was determined using a
near infrared procedure (NIR) in a Technicon Infralyser 450 (19 wavelengths) using the
method described by Perry et al. (2001). NIR readings were validated with chemical fat
determinations using solvent extraction.
For shear force, a 65 g sample of loin muscle was excised and vacuum packed. After 5
days of aging the samples were stored at -20ºC until subsequent shear force testing.
Samples were cooked at 71ºC in plastic bags in water baths for 35 minutes before being
cooled in running water for 30 minutes. Shear force was measured on six cores from
each loin sample using a Lloyd texture analyser (Model LRX, Lloyd Instruments,
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Hampshire UK) with a Warner-Bratzler shear blade fitted as described by Hopkins et al.
(2010).
Consumer overall likability was determined using a score scale out of 100 was based on
the Meat Standards Australia sensory system using untrained consumers and has been
explained in detail by Pannier et al. (2014a). Loin and topside steaks were also assessed
for tenderness, juiciness, liking of flavour and liking of odour. Each steak (5 steaks per
muscle) was halved to form ten test samples which were uniformly grilled using a Silex
griller to a medium degree of doneness (internal temperature of 65°C). Samples were
rested for 2 min before being served. Each consumer tested an initial sample of average
quality with an overall liking score of 72 (Pethick et al., 2006b) followed by 6 test
samples (3 loin and 3 topside). Samples were allocated using a Latin square design to
balance position and carry over effects (Thompson et al., 2005). In total 60 consumers
were recruited in each consumer group to taste 36 samples to obtain 10 responses per
sample. The sensory testing protocol is described in detail by Thompson et al. (2005)
and Watson et al. (2008).
6.2.3 Data available
The range for weights and growth rates, derived in Chapter 4, are presented in Table 6-1
and the number of samples analysed, years of data and number of sires with post
weaning weight (PWWT), post weaning c-site fat depth (PFAT) and post weaning eye
muscle depth (PEMD) Australian sheep breeding values (ASBVs) for each trait are
presented in Table 6-2. The PFAT and PEMD breeding values were based on live
ultrasound measurements while the PWWT breeding values were based on live weight.
All ASBVs were sourced from Sheep Genetics, Australia’s national genetic evaluation
database for sheep (Brown et al., 2007) and a correlation matrix is presented in Table
6-3. Sire ASBVs ranged by as much as 23 kg, 5 mm and 8 mm for PWWT, PFAT and
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PEMD respectively. The number of kill groups within a site and year varied between 2
and 5, and ages varied from 5 weeks to 40 weeks apart.
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97
Table 6-1 Weight and growth rate ranges for intramuscular fat, shear force and overall liking.
Variable Minimum Maximum Range Mean Standard Deviation
Intramuscular Fat (n = 8,254) Birth Weight (kg) 1.70 9.80 8.10 5.05 1.05
Weight 100 days (kg) 3.38 60.76 57.38 31.58 8.01
Weight 150 days (kg) 11.33 68.78 57.45 37.26 7.52
Growth Rate 100 days (g/day) -170.09 547.70 717.79 134.61 80.92
Growth Rate 150 days (g/day) -170.23 393.49 563.72 99.77 67.12
Weight Change 100 to 150 days (kg) -7.25 20.01 27.26 5.68 3.26
Shear Force (n = 8,433) Hot Carcass Weight (kg) 13.20 40.00 26.80 23.13 3.75
Birth Weight (kg) 1.70 10.10 8.40 5.08 1.06
Weight 100 days (kg) 3.38 60.76 57.38 31.67 7.93
Weight 150 days (kg) 11.33 68.78 57.45 37.39 7.45
Growth Rate 100 days (g/day) -170.09 496.22 666.31 135.20 81.21
Growth Rate 150 days (g/day) -107.37 393.49 500.86 100.53 65.86
Weight Change 100 to 150 days (kg) -5.01 20.01 25.02 5.72 3.22
Overall Liking (n = 1,411) Hot Carcass Weight (kg) 15.00 40.00 25.00 23.70 3.86
Birth Weight (kg) 1.98 9.50 7.52 4.83 1.15
Weight 100 days (kg) 3.71 57.97 54.26 29.14 7.60
Weight 150 days (kg) 11.33 59.36 48.03 34.76 6.90
Growth Rate 100 days (g/day) -89.03 416.19 505.22 127.34 89.04
Growth Rate 150 days (g/day) -107.37 366.30 473.67 103.46 77.56
Weight Change 100 to 150 days (kg) -5.01 18.79 23.80 5.63 4.04
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Table 6-2 Number of animals, years of data and number of sires available for intramuscular fat, shear
force and overall liking.
Number
of animals
Years
of data
Number
of sires
Maternal
sires
Merino
sires
Terminal
sires
Intramuscular Fat 8,254 5 428 83 163 182
Shear Force 8,433 5 425 83 159 183
Overall Liking 1,411 2 156 39 52 65
Table 6-3 Phenotypic correlations (standard errors) of post weaning sire breeding values for weight, fat
depth and eye muscle depth among Maternal, Merino and Terminal sires.
PWWT PFAT PEMD
Maternal
PWWT 1.00 -0.18 (0.09) -0.06 (0.62)
PFAT -0.18 (0.09) 1.00 0.47 (0.00)
PEMD -0.06 (0.62) 0.47 (0.00) 1.00
Merino
PWWT 1.00 0.23 (0.00) 0.29 (0.00)
PFAT 0.23 (0.00) 1.00 0.76 (0.00)
PEMD 0.29 (0.00) 0.76 (0.00) 1.00
Terminal
PWWT 1.00 -0.03 (0.69) -0.26 (0.00)
PFAT -0.03 (0.69) 1.00 0.39 (0.00)
PEMD -0.26 (0.00) 0.39 (0.00) 1.00
6.2.4 Statistical analysis
Intramuscular fat, shear force and overall liking were analysed using linear mixed
effects models (SAS Version 9.1, SAS Institute, Cary, NC, USA). Overall liking in the
loin and topside were analysed separately. For intramuscular fat and overall liking base
statistical models were developed and then compared to the base models previously
published, based on less data (Pannier et al., 2014a; Pannier et al., 2014c). In the case of
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shear force a base statistical model was developed for this paper (data not shown). The
base models included fixed production effects for site (representing research station site;
Kirby, Trangie, Cowra, Rutherglen, Hamilton, Struan, Turretfield, Katanning), year of
birth (2007, 2008, 2009, 2010, 2011), birth type – rear type (11, 21, 22, 31, 32, 33), age
of dam (2, 3, 4, 5, 6, 7, 8 years), sire type (Merino, Maternal, Terminal), sex-dam breed
within sire type (Female x Merino x Terminal, Male x Merino x Terminal, Female x
Border Leicester-Merino x Terminal, Male x Border Leicester-Merino x Terminal) and
kill group within site by year. Two base models for overall liking were developed using
the average value of the 10 consumer responses, one for loin and one for the topside cut.
Sire identification and dam identification by year were included as random terms.
Consumer group was included as a random term in the overall liking analyses. All
relevant first order interactions between fixed effects were tested and removed in a
stepwise manner, by a process of backward elimination, if non-significant (P > 0.05).
To assess the impact of growth on intramuscular fat, shear force and consumer overall
liking measures of weight and growth rate were included separately as covariates in the
above base models. For weight these included weight at birth and estimates of weight at
100 and 150 days. The effect of weight on the trait being analysed reflected the
cumulative impact of weight from conception to its point of measurement. For growth
rate, we examined the impact of weight change between 100 and 150 days (weaning and
post weaning) as well as instantaneous growth rate, estimated as the first derivative of
the growth curve, at 100 or 150 days. The advantage of also including the instantaneous
growth rate measures was that the simple weight change between 100 and 150 days
provides no ability to determine where growth rate was having the greater effect, closer
to weaning or post weaning time points. Furthermore, given the smoothed nature of a
growth curve the tangent, or growth rate, will be similar on days that are close to the
day being examined. Therefore, the impact of instantaneous growth rate on the trait in
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question can be extrapolated to a limited degree either side of its point of estimation,
providing information on the likely change in association between live weight and the
trait in question closer to these time points. Lamb weights and growth rates were
obtained in Chapter 4, on the same animals which had intramuscular fat, shear force and
overall liking measured.
To determine the accuracy of hot carcass weight as a proxy for growth the impact of hot
carcass weight on intramuscular fat, as previously assessed by (Pannier et al., 2014c),
was compared to the impact weight at 100 and 150 days. For shear force and overall
liking, hot carcass weight was included as a covariate in both the shear force base model
and the overall liking base model to determine its impact. To determine whether the
impact of growth on the meat traits was due to adiposity at the site of sampling or whole
carcass adiposity rather than growth, intramuscular fat and short loin fat weight were
included separately as covariates in the base models for each trait. All models contained
all relevant first order interactions between the fixed effects and covariates, including a
quadratic effect of the covariate, and were removed in a stepwise manner if non-
significant (P > 0.05).
The impact of PWWT, PFAT and PEMD ASBVs on intramuscular fat and overall
liking has previously been assessed (Pannier et al., 2014a; Pannier et al., 2014c). To
determine the impact of PWWT, PFAT and PEMD ASBVs on shear force all three
ASBVs were analysed concurrently as covariates in the base model. Subsequently,
weight at 150 days or growth rate at 150 days were included separately in the base
models for each trait, along with the three ASBVs. The aim of this analysis was to
determine whether the impact of these ASBVs on intramuscular fat, shear force and
overall liking were delivered via their impact on growth. The impact of the ASBV for
birth weight (BWT) and weaning weight (WWT) on intramuscular fat were determined
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by including the ASBVs separately in the intramuscular fat base model. Subsequently
weight at birth was included in the base model, along with BWT and weight at 100 days
was included in the base model, along with WWT. The aim of this analysis was to
determine whether the impact of BWT or WWT on intramuscular fat, were delivered
via their impact on growth. All ASBV models contained relevant first order interactions
between the fixed effects and covariates, including a quadratic effect of the covariate,
and were removed in a stepwise manner if non-significant (P > 0.05).
Partial correlations of weight and growth rate with intramuscular fat, shear force and
overall liking were determined using a multivariate analysis (Version 9.1, SAS Institute,
Cary, NC, USA). The analysis included the fixed effects and their interactions described
for the base models.
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6.3 Results
6.3.1 Intramuscular fat
6.3.1.1 Base model
The base model for this study (not shown) utilised intramuscular fat for 8,254 animals,
and has previously been published by Pannier et al. (2014c) who analysed a subset of
this data (n = 5,642). There were minor variations to the Pannier et al. (2014c) model
with the inclusion of small effects for dam age, a site by sire type interaction, and the
absence of a site by sex effect.
6.3.1.2 Birth weight
Birth weight demonstrated an association with intramuscular fat reducing by 0.85%
across the 8.1 kg weight range (P < 0.05) (Table 6-4). This association varied in twin
born lambs and between sire types. Intramuscular fat reduced by 0.14% units for each
kg of birth weight in twin born lambs. The variation between sire types is detailed in
Table 6-5.
.
Table 6-4 The magnitude of effect (difference between the highest and lowest values) of lamb weight and
growth rate on intramuscular fat or on shear force across the entire weight or growth rate range.
Trait Intramuscular Fat (%) Shear Force (N)
Birth Weight (kg) -0.85 -
Weight 100 days (kg) 1.09 -10.43
Weight 150 days (kg) 0.49 -6.32
Growth Rate 100 days (g/day) -0.95 7.01
Growth Rate 150 days (g/day) -1.24 12.89
Weight Change 100 to 150 days (kg) -1.17 12.90
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Table 6-5 Variation in slopes between sire types for the impact of birth weight, weight at 100 days and
weight at 150 days on intramuscular fat.
Intramuscular Fat
Trait Sire type Slope Trait -Min. Trait - Max. Magnitude
Birth weight Maternal -0.13 1.90 9.50 -0.97
Merino -0.12 2.20 8.60 -0.80
Terminal -0.06 1.70 9.80 -0.51
Weight 150 Maternal 0.001 15.46 55.81 0.04
Merino 0.008 13.93 51.20 0.31
Terminal 0.016 11.33 68.78 0.94
Min: Minimum value for the variable; Max: Maximum value for the variable; Magnitude: The total
magnitude of the effect of the trait on intramuscular fat.
6.3.1.3 Effect of weight at 100 and 150 days
Weight at 100 days was associated with an increase in intramuscular fat of 0.02% units
for each kg of weight, which was equivalent to 1.09% across the 57 kg weight range (P
< 0.01). For weight at 150 days, intramuscular fat increased by 0.01% units for each kg
of weight, which was equivalent to 0.49% across the 57 kg weight range. This
association varied between sire types and is detailed in Table 6-5.
6.3.1.4 Effect of change in weight between 100 and 150 days and growth rate at
100 and 150 days
Growth rate measured at 100 and 150 days or the change in weight measured between
these time points were all associated with reducing intramuscular fat (P < 0.01). Change
in weight between 100 and 150 days varied between -7.25 and 20.01 kg, growth rate at
100 days varied between -170.09 and 547.70 g/day, and growth rate at 150 days varied
between -170.23 and 393.49 g/day and across these ranges intramuscular fat diminished
by 1.17%, 0.95% and 1.24%. The association between change in weight between 100
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and 150 days and intramuscular fat varied between sites and years. The variation
between sites reduced intramuscular fat by as much as 0.09% units and as little as
0.04% units per kg of weight change. The variation between years reduced
intramuscular fat by as much as 0.07% units and as little as 0.05% units per kg of
weight change.
6.3.1.5 Effect of adiposity
When correcting the growth models for short loin fat weight (P < 0.01) the magnitude
of the growth covariates diminished by a third to a half.
6.3.1.6 Effect of ASBVs
When BWT, or WWT were included separately as covariates in the base model, neither
had an association with intramuscular fat. When the BWT and WWT models were
corrected for weight at birth and weight at 100 days respectively, there was no change to
the lack of association of the breeding values with intramuscular fat.
When the PWWT, PFAT and PEMD ASBV model was corrected for weight at 150
days or growth rate at 150 days the magnitude of the effect of the breeding values
reported by (Pannier et al., 2014c) did not change.
6.3.2 Shear force
6.3.2.1 Base model
The base model utilised shear force for 8,433 animals. When phenotypic (i.e. weight,
growth rate, hot carcass weight) or genotypic (PWWT, PFAT, PEMD) covariates were
included in this model, the production effects generally remained unchanged. The
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exceptions were sire type which was not significant when the base model was corrected
for hot carcass weight, and dam age which became significant when the base model was
corrected for birth weight, weight at 100 days and growth rate at 150 days.
6.3.2.2 Hot carcass weight
When hot carcass weight was included as a covariate in the base model it demonstrated
a curvilinear association with shear force reducing it by 0.34 N for each kg of hot
carcass weight, which was equivalent to a 9.06 N across the 27 kg hot carcass weight
range (P < 0.01). This association varied between sex-dam breed within sire type
combinations. Within the Terminal sired lambs, shear force varied between males and
female lambs with Border Leicester-Merino compared to Merino dams. The reduction
in shear force was 0.05 N less in male compared to female lambs from Merino dams
while it was 0.25 N greater in male compared to female lambs from Border Leicester-
Merino dams (P < 0.05).
6.3.2.3 Birth weight
Birth weight demonstrated an association with shear force however this was only
present in progeny of 4 year old dams where there was a small increase of 0.15 N for
each kg of birth weight (P < 0.05).
6.3.2.4 Effect of weight at 100 and 150 days
Weight at 100 days was associated with a reduction in shear force of 0.18 N for each kg
of weight, which was equivalent to 10.43 N across the 57 kg weight range. The
association was reduced by about 35% with a reduction in shear force of 0.11 N for
each kg of weight at 150 days, which was equivalent to 6.32 N across the 57 kg weight
range.
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6.3.2.5 Effect of change in weight between 100 and 150 days and growth rate at 100
and 150 days
Growth rate measured at 100 and 150 days or the change in weight measured between
these time points were all associated with increasing shear force (P < 0.01). Change in
weight between 100 and 150 days varied between -5.01 and 20.01 kg, growth rate at
100 days varied between -170.09 and 496.22 g/day, and growth rate at 150 days varied
between -107.37and 393.49 g/day and across these ranges shear force increased by
12.90 N, 7.01 N and 12.89 N. The association between growth rate at 100 days and
shear force varied between years increasing shear force by as much as 0.02 N and as
little as 0.01 N per g of increase growth rate.
6.3.2.6 Effect of adiposity
When correcting the growth models for short loin fat weight (P < 0.01) or intramuscular
fat (P < 0.01) the magnitude of the growth covariates diminished by a third to a half,
except for weight at 150 days which was no longer had a significant association with
shear force when correcting for short loin fat weight.
6.3.2.7 Effect of ASBVs
When PWWT, PFAT and PEMD were included simultaneously as covariates in the
base model, only PFAT had an association with shear force (P < 0.01). Shear force was
increased by 0.60 N for each mm reduction in PFAT, which equated to an increase in
shear force of 3.02 N across the 5 mm PFAT range.
When the PWWT, PFAT and PEMD ASBV model was corrected for weight at 150
days the magnitude of the breeding value effects did not change. When the ASBV
model was corrected for growth rate at 150 days PFAT was no longer significant.
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6.3.3 Overall liking
6.3.3.1 Base model
The base model for this study utilised overall liking for 1,411 animals, and has
previously been published by Pannier et al. (2014a).
6.3.3.2 Effect of weight
When hot carcass weight was included as a covariate in the base model it demonstrated
no association with overall liking in the loin or topside. Birth weight, weight at 100 days
and weight at 150 days also demonstrated no association with overall liking.
6.3.3.3 Effect of growth rate
Weight change between 100 and 150 days and growth rate at 100 and 150 days
demonstrated no association with overall liking in the loin or topside.
6.3.3.4 Effect of ASBVs
When the PWWT, PFAT and PEMD ASBV model reported by Pannier et al. (2014a)
was corrected for weight at 150 days or growth rate at 150 days there was no variation
in the magnitude of the breeding values on overall liking in the loin or topside.
6.3.4 Phenotypic correlations
The phenotypic correlations of the meat traits with weight and growth rate are presented
in Table 6-6. Intramuscular fat had a negative correlation with all measures of growth
except weigh at 150 days. Shear force was negatively correlated with weight from
weaning onwards and positively correlated with growth rate. There were no significant
correlations between overall liking and growth.
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Table 6-6 Phenotypic correlations of intramuscular fat, shear force and overall liking with lamb weight and growth rate. Standard error values in brackets. Significant correlations are
in bold.
Birth weight Weight 100 days Weight 150 days Growth rate 100 days Growth rate 150 days
Intramuscular Fat -0.06 (0.00) 0.10 (0.00) -0.06 (0.00) -0.07 (0.00) -0.11 (0.00)
Shear Force 0.01 (0.47) -0.09 (0.00) -0.04 (0.00) 0.06 (0.00) 0.12 (0.00)
Overall liking (Loin) 0.01 (0.64) 0.01 (0.81) -0.02 (0.44) 0.01 (0.68) -0.06 (0.04)
Overall liking (Topside) 0.02 (0.50) -0.01 (0.77) -0.03 (0.22) 0.01 (0.69) -0.06 (0.03)
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6.4 Discussion
6.4.1 Intramuscular fat
Intramuscular fat had a negative association with birth weight after which the
association inverted and intramuscular fat had a strong positive association with weight
at 100 days (Table 6-4). The association between intramuscular fat and growth rate was
similar in magnitude to the association between intramuscular fat and weight at 100
days however it was negative and strengthened from 100 to 150 days. This resulted in a
diminished association between weight and intramuscular fat at 150 days, which was
less than half that observed at 100 days. In general, these phenotypic associations
aligned well with the phenotypic correlations between intramuscular fat and weight and
growth rate (Table 6-6).
To determine whether the change in intramuscular fat with growth was simply a
reflection of its association with whole carcass adiposity the growth models were
corrected for short loin fat weight. In general, this reduced the association between
intramuscular fat and growth by half and in the case of weight at 100 days completely
accounted for this association. This suggests that the impact of growth on intramuscular
fat is largely delivered through the associated increase in whole body fatness as animals
get older. Alternatively, there was still significant variation that was not associated with
whole body fatness.
The positive association between weight at 100 and 150 days and intramuscular fat
aligned well with our hypothesis, and provides more conclusive evidence to confirm the
earlier suggestions of Pannier et al. (2014c) that intramuscular fat is linked to growth.
This suggestion was based on the observed positive association between intramuscular
fat and carcass weight at slaughter in lambs of a similar age, although was proposed
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with some uncertainty given that carcass weight at slaughter is potentially influenced by
factors other than just whole of life growth. What is less clear is why the phenotypic
association between intramuscular fat and hot carcass with weight in the Pannier et al.
(2014c) study was greater than the magnitude seen for weight at 100 or 150 days in this
study, particularly when the association with weight was diminishing over time. In part
this may be because weight early in life also reflects changes in non-carcass tissues,
which are not represented by hot carcass weight. There is no significant phenotypic
correlation between intramuscular fat and hot carcass weight (Mortimer et al., 2014)
which makes the increased phenotypic association with hot carcass weight is difficult to
explain.
Although contrasting with the positive association between intramuscular fat and post
weaning weight, the negative association with birth weight was not entirely unexpected.
A similar phenomenon has been described in pigs (Beaulieu et al., 2010; Gondret et al.,
2006; Rehfeldt et al., 2008), and is hypothesised to be due to the slow and inefficient
growth of the pigs resulting in reduced lean percentages at slaughter. However, the
apparent inversion of this association between birth and weaning highlights this phase
of growth as a key period in which growth rate may modulate intramuscular fat
development, with the magnitude of the association between intramuscular fat and
growth increasing during this period by as much as 1.98 intramuscular fat percentage
units. This aligns with research indicating that adipocyte development is fixed relatively
early in life (Kirkland and Dobson, 1997), as has been demonstrated in sheep (McPhee
et al., 2008), pigs (Beaulieu et al., 2010) and cattle (Pethick et al., 2004), with greater
adipogenic and lipogenic gene expression in young cattle with increased intramuscular
fat (Wang et al., 2009). Alternatively the inversion of the association between birth and
weaning may reflect a poor association between birth weight and intramuscular fat due
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to weight close to birth being controlled by a number of factors that are not linked to
maturity, such as dam milk production.
Increased growth rate in lambs at 100 and 150 days was associated with reduced levels
of intramuscular fat. Post weaning weight and adult weight are positively correlated
(Huisman and Brown, 2008) so lambs growing faster at 100 and 150 days are likely to
be growing to an increased mature size. Therefore, they are proportionately less of their
mature size at 150 days resulting in reduced levels of intramuscular fat.
The impact of weight at birth and 150 days on intramuscular fat varied between sire
types (Table 6-5). At birth, the effect of weight on intramuscular fat was strongest in
progeny of Maternal sires. When the model was corrected for short loin fat weight the
variation between sire types was no longer present. This suggests that the variation
between sire types was simply a reflection of whole body fatness. At 150 days, the
effect of weight on intramuscular fat was strongest in the progeny of Terminal sires.
When the model was corrected for short loin fat weigh the variation between sire types
was still present, and the magnitude of effect was again largest in Maternal sires. This
may indicate these animals have higher levels of intramuscular fat at maturity,
independent of whole body adiposity.
6.4.2 Shear force
Shear force was reduced in lambs that were heavier at 100 and 150 days, yet at birth
there was no association. The lack of relationship between lamb birth weight and shear
force is consistent with findings in pigs (Bérard et al., 2010) and cattle (Greenwood et
al., 2006a). This transition from no main effect of weight at birth to a large negative
effect of weight at 100 days highlights early life pre weaning growth as an important
developmental period impacting on shear force. Similarly, early life pre weaning growth
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is also a key developmental period for intramuscular fat deposition. Given the strong
association between shear force and intramuscular fat (Mortimer et al., 2014; Pannier et
al., 2014a) it is not surprising that these traits are impacted during the same period of
growth.
In contrast to the association with weight, the impact of growth rate at 100 and 150 days
was opposite, with lambs of higher growth rates having increased shear force. This also
explains why the magnitude of the effect of weight on shear force diminished by 35%
between 100 and 150 days (Table 6-4). Although the mechanism for this growth rate
association is unclear, the changing associations across the life of the animal align well
with the phenotypic correlations (Table 6-6) evident in these same animals.
Shear force is reduced with increased intramuscular fat in lamb (Pannier et al., 2014a)
and pigs (van Laack et al., 2001). As intramuscular fat increases with weight, a
concurrent reduction in shear force with weight at 100 and 150 days was expected.
When the growth models were corrected separately for intramuscular fat and short loin
fat weight both measures of fatness generally reduced the association between shear
force and growth by a third to a half. This suggests that the impact of growth on shear
force is largely delivered through the associated increase in local or whole body fatness,
although there was still significant variation that was not associated with whole body
fatness.
Published associations between animal growth and shear force vary. In sheep, several
studies have demonstrated an increased shear force with weight, the opposite to what
was found in this study, however none of these studies were controlled for age (Beriain
et al., 2000; Sañudo et al., 1996; Teixeira et al., 2005). In cattle, neither weight at
slaughter (Lucero-Borja et al., 2014) or average daily gain (Calkins et al., 1987;
Moloney et al., 2000), both representing growth rate of a given period, have an
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association with shear force. Perry and Thompson (2005) showed no overall impact of
growth path on shear force in beef cattle which aligns with the findings of Greenwood
et al. (2006a).
Although not a live weight measure itself hot carcass weight, and its association with
shear force, was taken into account due to its strong phenotypic correlation with live
weight at slaughter. Therefore, what is less clear is why the phenotypic association
between shear force and slaughter weight, as indicated by the association between shear
force and hot carcass weight in this study, was greater than the magnitude seen for
weight at 100 or 150 days, particularly when the association with weight was
diminishing over time. Furthermore, there was no significant phenotypic correlation
between shear force and hot carcass weight (Mortimer et al., 2014) so the increased
phenotypic association with hot carcass weight is difficult to explain. Shear force is
influenced by intramuscular fat so, as expected, these findings parallel the findings
between intramuscular fat and growth.
6.4.3 Overall liking
Contrary to our hypothesis, overall liking showed no association with lamb growth,
contrasting with the findings of Fisher et al. (2000) who demonstrated that lambs from
heavier breeds had improved overall liking scores. This lack of effect is all the more
surprising given that growth impacted on intramuscular fat and shear force, both of
which have been shown to influence overall liking scores (Hopkins and Mortimer,
2014; Pannier et al., 2014a). In the Pannier et al. (2014a) study, which used the same
lambs as used in the present study, the magnitude of the impact of shear force and
intramuscular fat on overall liking represented around 12 - 14% of the average overall
liking score. Thus other factors must play a role in determining overall liking, beyond
just intramuscular fat and shear force.
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While the associations of intramuscular fat and shear force with overall liking did not
amount to an effect on overall liking it is possible, based on the phenotypic associations,
that this will change over time. Furthermore, changes in overall liking with lamb growth
may not have been captured due to the highly variable nature of consumer data.
There was no phenotypic association between overall liking and slaughter weight, as
indicated by the lack of association between overall liking and hot carcass weight, in
this study. This is in contrast to the positive correlation between hot carcass weight and
overall liking in the Lambe et al. (2009) study. In the Lambe et al. (2009) study on two
lamb breeds, the correlation was only significant in the loin, and not in the leg. Hence
there was inconsistency between cuts and the lack of correlation in the leg aligns with
the lack of effect in in the topside in the present study. The lack of a relationship
between overall liking and lamb growth was reflected in the phenotypic correlations
between overall liking and growth, which were generally not significant (Table 6-6).
The published impact of PWWT, PFAT and PEMD on intramuscular fat (Pannier et al.,
2014c), shear force and overall liking (Pannier et al., 2014a) did not change when
corrected for weight at 150 days or growth rate at 150 days. The effects of PFAT and
PEMD did not change with correction for weight or growth rate at 150 days indicating
that they are not mechanistically driven through the impact of growth, as evidenced by
the lack of a PWWT effect. The impact of birth weight and weight at 100 days on
intramuscular fat did not vary with the inclusion of ASBVs for birth and weaning
weights indicating that the impact of weight at birth and 100 days on intramuscular fat
is not due to genotype.
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6.5 Conclusion
This study demonstrated that lamb growth impacts on both intramuscular fat and shear
force, and had no impact on consumer overall liking. The key period for modulation of
intramuscular fat and shear force by growth was in the pre weaning period with the
magnitude of the responses of both traits to weight reducing after weaning.
Intramuscular fat may also be influenced by in-utero growth as the association with
weight inverts between birth and weaning. Lambs heavier at birth had the lowest
intramuscular fat and lambs heavier at weaning had the highest intramuscular fat. A
third to a half of the association between lamb growth and either intramuscular fat or
shear force was delivered through an associated increase in whole carcass adiposity.
This indicated that a large portion of the impact of growth on these two traits is
delivered through the associated increase in whole body fatness as animals get older.
However, there was still significant variation that was not associated with whole body
fatness, indicating that growth was still having an impact on intramuscular fat and shear
force which was independent of whole carcass adiposity. Currently, lamb growth is not
impacting overall liking. However the associations between overall liking and both
intramuscular fat and shear force are such that growth can be expected to impact overall
liking as a result of continual selection for growth. Hot carcass weight, as a proxy for
whole of life growth, overestimated the impact of growth on intramuscular fat and shear
force and was unable to describe the impact of growth during different phases of
growth. Hot carcass weight varies with age at slaughter, while growth at weaning and
post weaning do not, contributing to the poor alignment of hot carcass weight and
growth effects.
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Chapter 7. Lamb growth increases oxidative
capacity and mineral content in the longissimus muscle
7.1 Introduction
The nutritional value of meat is a key driver of the consumer decision making process
(Pethick et al., 2006a). Currently, the level of minerals such as iron and zinc are
sufficient to claim lamb meat as a good source for the majority of the population
(Pannier et al., 2014b; Pannier et al., 2010). These mineral levels are influenced by
muscle fibre type with reduced iron and zinc in muscles exhibiting low oxidative fibre
types and therefore having a low oxidative capacity (Kondo et al., 1991; Pearce et al.,
2009). Oxidative capacity is indicated by levels of the oxidative enzyme isocitrate
dehydrogenase (ICDH; EC 1.1.1.42) and by myoglobin concentration which are both
elevated in oxidative type I and type IIA muscle fibres (Brandstetter et al., 1998a;
Pethick et al., 2005c). Therefore, changes in fibre type with lamb growth may impact
muscle oxidative capacity as well as iron and zinc concentrations.
The impact of lamb growth on muscle fibre type with subsequent changes in oxidative
capacity and mineral content has not been thoroughly investigated. Kelman et al. (2014)
used hot carcass weight at a given age as a proxy for whole of life growth to suggest
that oxidative capacity is increased with lamb growth rate. Given the association
between oxidative capacity and iron and zinc concentrations (Pannier et al., 2014b), it
seems reasonable that iron and zinc will also increase with increased growth. Aligning
with this suggestion, Pannier et al. (2014b) demonstrated in these same lambs an
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association between increasing iron and zinc concentration and heavier hot carcass
weight.
The use of hot carcass weight as a proxy for whole of life growth is based on the
assumption that lamb growth is linear. However, lamb growth is sigmoidal with rapid
exponential growth during early life followed by a deceleration and then a late tapering
of growth close to adult weight (Hendrick et al., 1989). Thus hot carcass weight
measured at a fixed time point only is a crude representation of growth. Therefore a
more detailed analysis of growth path is required to understand the impact of this on
oxidative capacity and mineral content and thus consumer acceptability.
The surface browning of meat at retail display slowly increases as red myoglobin
oxidises forming “brown” metmyoglobin. Browning is accelerated when type I muscle
fibres (O'keeffe and Hood, 1982; Renerre and Labas, 1987) and thus oxidative capacity
(Calnan et al., 2014) increase. Therefore, any changes to muscle fibre type with growth
may also impact meat browning. Furthermore meat browning is increased with
increasing intramuscular fat due to the auto-oxidation of the lipid accelerating the
oxidisation of myoglobin and the formation of brown pigment (Faustman et al., 2010).
As oxidative capacity and intramuscular fat increase with hot carcass weight (Kelman et
al., 2014; Pannier et al., 2014c) meat browning is likely to increase with increased
growth.
Lambs from the Information Nucleus Flock (van der Werf et al., 2010) (van der Werf et
al., 2010) run by the Australian Cooperative Research Centre (CRC) for Sheep Industry
Innovation were measured for live weight, markers of oxidative capacity, mineral
content and retail meat browning. Live weights of these lambs were used to model
growth (Chapter 4) allowing growth at different phases of lamb development and the
association with the muscle measurements to be assessed. Given the associations with
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hot carcass weight we hypothesised that increased growth would be associated with
higher myoglobin concentration, iron concentration and zinc concentration, increased
activity of ICDH and accelerated meat browning.
7.2 Materials and Methods
7.2.1 Experimental Design
The design of the Sheep CRC’s Information Nucleus Flock was presented in detail by
Fogarty et al. (2007) and van der Werf et al. (2010). Each year, for 5 years between
2007 and 2011, a total of approximately 3,500 lambs were produced at eight research
sites across Australia, which represent a broad range of production systems (Kirby
NSW, Trangie NSW, Cowra NSW, Rutherglen VIC, Hamilton VIC, Struan SA,
Turretfield SA, and Katanning WA). The lambs were the progeny of sires selected to
represent the key breeds used in Australia. These included Merino sires (Merino, Poll
Merino), Maternal sires (Bond, Border Leicester, Booroola, Coopworth, Corriedale,
Dohne Merino, East Friesian, Prime SAMM, White Dorper), and Terminal sires
(Hampshire Down, Ile De France, Poll Dorset, Southdown, Suffolk, Texel, White
Suffolk). Lambs were reared under extensive pasture grazing conditions and fed grain,
hay or feedlot pellets when feed supply was limited (Ponnampalam et al., 2014a).
7.2.2 Collection of phenotypic measurements
Lambs were weighed at birth, at weaning (90 days of age) and approximately every two
weeks thereafter. Hot carcass weight was measured at slaughter. After slaughter all
carcasses were subjected to medium voltage electrical stimulation(Pearce et al., 2010)
and dressed according to AUS-MEAT specifications (Anonymous, 2005). Carcasses
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were chilled overnight (3-4°C). After slaughter and within 5 h post–mortem, a 1 g
sample of m. longissimus lumborum (short loin muscle) was excised from the carcass
(over the 12th
rib) of every animal. Subcutaneous fat was removed and the samples were
snap-frozen in liquid nitrogen and stored at -80C until subsequent ICDH
determination. The ICDH activity was determined by the method of (Briand, 1981),
which was adapted to run on an Olympus AU400 auto analyser. At 24 h post-mortem
the entire short loin muscle was removed from the carcass and the subcutaneous short
loin fat was dissected and weighed (short loin fat weight). A 40 g sample of short loin
muscle was excised and stored at -20ºC until subsequent freeze drying using a Cuddon
FD 1015 freeze dryer (Cuddon Freeze Dry, NZ). Approximately 0.2 g of dry matter was
collected for iron and zinc concentration analysis.
These were prepared according to the USEPA method 200.3 (USEPA, 1991) and iron
and zinc concentrations were determined using a Vista AX CCD simultaneous ICP-AES
(Varian Australia Pty Ltd). Intramuscular fat content, expressed as a percentage, was
measured on the 40 g sample of loin muscle. Intramuscular fat was determined using a
near infrared procedure (NIR) in a Technicon Infralyser 450 (19 wavelengths) using the
method described by Perry et al. (2001). NIR readings were validated with chemical fat
determinations using solvent extraction.
For myoglobin, a 1 g sample of short loin muscle was excised and stored at -20C until
myoglobin concentration determination by the method of Trout (1991). To determine
meat browning a 50 mm long by 30 mm deep section was excised from the loin,
vacuum packed in clear gas impermeable plastic and aged in a chiller at 3-4°C for 5
days. The loin samples were then incised perpendicular to the long axis to expose a
fresh surface and wrapped with oxygen-permeable polyvinyl chloride film. The samples
were then placed under simulated retail display conditions of temperature and light as
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described by Calnan et al. (2014). After 3 days of display light reflectance colour
measures were taken of each loin sample through the film within the chiller using a
Hunterlab spectrophotometer XE Plus (Cat. No. 6352, model No. 45/0-L, aperture of
3.18 cm). A ratio of red oxymyoglobin pigment to brown metmyoglobin pigment was
calculated as (% reflectance at 630 nm) / (% reflectance at 580 nm) or R630/R580.
Higher ratios indicate increased redness with lower values representing increased
surface browning. Two spectrophotometric readings of each sample were taken at 90
degrees on the horizontal plane and the ratios were then averaged.
7.2.3 Data available
The ranges for weights and growth rates, derived in Chapter 4, are presented in Table
7-1 and the number of samples analysed, years of data and number of sires with post
weaning weight (PWWT), post weaning c-site fat depth (PFAT) and post weaning eye
muscle depth (PEMD) Australian sheep breeding values (ASBVs) for each trait are
presented in Table 7-2. The PFAT and PEMD breeding values were based on live
ultrasound measurements while the PWWT breeding values were based on live weight.
All ASBVs were sourced from Sheep Genetics, Australia’s national genetic evaluation
database for sheep (Brown et al., 2007) and a correlation matrix is presented in Table
7-3. Sire ASBVs ranged by as much as 23 kg, 5 mm and 8 mm for PWWT, PFAT and
PEMD respectively. The number of kill groups within a site and year varied between 2
and 5, and ages varied from 5 weeks to 40 weeks apart.
.
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Table 7-1 Weight and growth rate ranges for isocitrate dehydrogenase (ICDH) activity, myoglobin concentration, iron concentration, zinc concentration and meat browning.
Variable Minimum Maximum Range Mean Standard Deviation
ICDH Activity (n = 4,571) Birth Weight (kg) 1.70 9.80 8.10 5.04 1.01
Weight 100 days (kg) 3.38 57.97 54.59 31.37 8.19
Weight 150 days (kg) 13.93 60.20 46.27 36.94 7.46
Growth Rate 100 days (g/day) -170.09 547.70 717.79 132.16 74.06
Growth Rate 150 days (g/day) -170.23 393.49 563.72 97.93 66.29
Weight Change 100 to 150 days (kg) -7.25 16.95 24.20 5.57 3.05
Myoglobin Concentration (n = 8,987) Birth Weight (kg) 1.90 10.10 8.20 5.08 1.08
Weight 100 days (kg) 3.38 60.76 57.38 31.67 7.93
Weight 150 days (kg) 11.33 68.78 57.45 37.39 7.48
Growth Rate 100 days (g/day) -170.09 547.70 717.79 137.33 81.17
Growth Rate 150 days (g/day) -170.23 393.49 563.72 99.39 65.80
Weight Change 100 to 150 days (kg) -7.25 20.01 27.26 5.73 3.20
Iron Concentration (n = 8,434) Birth Weight (kg) 1.90 9.80 7.90 5.05 1.04
Weight 100 days (kg) 3.38 60.76 57.38 31.54 7.97
Weight 150 days (kg) 11.33 68.78 57.45 37.25 7.48
Growth Rate 100 days (g/day) -170.09 547.70 717.79 135.60 81.23
Growth Rate 150 days (g/day) -143.78 393.49 537.27 99.82 66.49
Weight Change 100 to 150 days (kg) -5.01 20.01 25.02 5.70 3.24
Zinc Concentration (n = 7,236) Birth Weight (kg) 1.90 9.80 7.90 5.03 1.05
Weight 100 days (kg) 3.38 57.97 54.59 31.32 8.00
Weight 150 days (kg) 11.33 60.79 49.46 36.94 7.36
Growth Rate 100 days (g/day) -170.09 547.70 717.79 131.27 78.05
Growth Rate 150 days (g/day) -170.23 393.49 563.72 100.41 67.92
Weight Change 100 to 150 days (kg) -7.25 20.01 27.26 5.62 3.28
Meat Browning (n = 5,033) Birth Weight (kg) 1.70 10.10 8.40 5.18 1.07
Weight 100 days (kg) 7.33 60.76 53.43 33.12 7.81
Weight 150 days (kg) 13.93 68.78 54.85 39.35 7.33
Growth Rate 100 days (g/day) -170.09 496.22 666.31 149.71 80.23
Growth Rate 150 days (g/day) -170.23 393.49 563.72 106.66 66.78
Weight Change 100 to 150 days (kg) -7.25 19.31 26.56 6.23 3.25
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97
Table 7-2 Number of animals, years of data and number of sires available for isocitrate dehydrogenase (ICDH) activity, myoglobin concentration, iron concentration, zinc
concentration and meat browning.
Number of animals Years of data Number of sires Maternal sires Merino sires Terminal sires
ICDH Activity 4, 571 3 258 60 93 105
Myoglobin Concentration 8, 987 5 429 83 163 183
Iron Concentration 8, 434 5 428 83 163 182
Zinc Concentration 7, 236 4 336 75 126 135
Meat Browning 5, 933 5 416 82 151 183
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Table 7-3 Phenotypic correlations (standard errors) of post weaning sire breeding values for weight, fat
depth and eye muscle depth among Maternal, Merino and Terminal sires.
PWWT PFAT PEMD
Maternal
PWWT 1.00 -0.18 (0.09) -0.06 (0.62)
PFAT -0.18 (0.09) 1.00 0.47 (0.00)
PEMD -0.06 (0.62) 0.47 (0.00) 1.00
Merino
PWWT 1.00 0.23 (0.00) 0.29 (0.00)
PFAT 0.23 (0.00) 1.00 0.76 (0.00)
PEMD 0.29 (0.00) 0.76 (0.00) 1.00
Terminal
PWWT 1.00 -0.03 (0.69) -0.26 (0.00)
PFAT -0.03 (0.69) 1.00 0.39 (0.00)
PEMD -0.26 (0.00) 0.39 (0.00) 1.00
7.2.4 Statistical analysis
ICDH activity and myoglobin, iron and zinc concentrations were analysed using linear
mixed effects models (SAS Version 9.1, SAS Institute, Cary, NC, USA). Initially, base
statistical models were developed and then compared to the base models previously
published, based on less data, for ICDH activity, myoglobin concentration (Kelman et
al., 2014), iron and zinc concentrations (Pannier et al., 2014b) and meat browning
(Calnan et al., 2014). The base models included fixed production effects for site
(representing research station site; Kirby, Trangie, Cowra, Rutherglen, Hamilton,
Struan, Turretfield, Katanning), year of birth (2007, 2008, 2009, 2010, 2011), birth type
– rear type (11, 21, 22, 31, 32, 33), age of dam (2, 3, 4, 5, 6, 7, 8 years), sire type
(Merino, Maternal, Terminal), sex-dam breed within sire type (Female x Merino x
Terminal, Male x Merino x Terminal, Female x Border Leicester-Merino x Terminal,
Male x Border Leicester-Merino x Terminal) and kill group within site by year. Sire
identification and dam identification by year were included as random terms. All
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relevant first order interactions between fixed effects were tested and removed in a
stepwise manner, by a process of backward elimination, if non-significant (P > 0.05).
To assess the impact of growth on intramuscular fat, shear force and consumer overall
liking measures of weight and growth rate were included separately as covariates in the
above base models. For weight these included weight at birth and estimates of weight at
100 and 150 days. The effect of weight on the trait being analysed reflected the
cumulative impact of weight from conception to its point of measurement. For growth
rate, we examined the impact of weight change between 100 and 150 days (weaning and
post weaning) as well as instantaneous growth rate, estimated as the first derivative of
the growth curve, at 100 or 150 days. The advantage of also including the instantaneous
growth rate measures was that the simple weight change between 100 and 150 days
provides no ability to determine where growth rate was having the greater effect, closer
to weaning or post weaning time points. Furthermore, given the smoothed nature of a
growth curve the tangent, or growth rate, will be similar on days that are close to the
day being examined. Therefore, the impact of instantaneous growth rate on the trait in
question can be extrapolated to a limited degree either side of its point of estimation,
providing information on the likely change in association between live weight and the
trait in question closer to these time points. Lamb weights and growth rates were
obtained in Chapter 4, on the same animals which had these traits measured.
To determine the accuracy of hot carcass weight as a proxy for growth the impact of hot
carcass weight on isocitrate dehydrogenase activity and myoglobin concentration, as
previously assessed by Kelman et al. (2014), iron concentration and zinc concentration,
as previously assessed by Pannier et al. (2014b) and meat browning, as previously
assessed by Calnan et al. (2014) was compared to the impact of weight at 100 and 150
days. To determine whether the impact of growth on the meat traits was due to adiposity
188
at the site of sampling or whole carcass adiposity rather than growth, intramuscular fat
and short loin fat weight were included separately as covariates in the base models for
each trait. All models contained all relevant first order interactions between the fixed
effects and covariates, including a quadratic effect of the covariate, and were removed
in a stepwise manner if non-significant (P > 0.05).
The impact of PWWT, PFAT and PEMD ASBVs on ICDH activity, myoglobin, iron
and zinc concentration and meat browning has previously been assessed (Calnan et al.,
2014; Kelman et al., 2014; Pannier et al., 2014b). This analysis aimed to determine
whether the impact of these ASBVs was delivered via their impact on growth. Thus
weight at 150 days or growth rate at 150 days were included separately in the base
model for each trait, along with the three ASBVs. All models contained relevant first
order interactions between the fixed effects and covariates, including a quadratic effect
of the covariate, and were removed in a stepwise manner if non-significant (P > 0.05).
Partial correlations of weight and growth rate with ICDH activity, myoglobin, iron and
zinc concentration and meat browning were determined using a multivariate analysis
(Version 9.1, SAS Institute, Cary, NC, USA). The analysis included the fixed effects
and their interactions described for the base models.
7.3 Results
7.3.1 Isocitrate Dehydrogenase
7.3.1.1 Base model
The base model for this study (not shown) utilised ICDH activity for 4,571 animals, and
has previously been published by Kelman et al. (2014) who analysed a subset of this
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data (n = 3, 178). There were no significant variations to the Kelman et al. (2014) model
with the additional data, and the magnitude of the effects were similar.
7.3.1.2 Birth weight
Birth weight varied between 1.70 and 9.80 kg and across this range was associated with
a reduction in ICDH activity of 0.57 µmol/min/g tissue (P < 0.01) (Table 7-4).
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Table 7-4 The magnitude of effect (difference between the highest and lowest values) of lamb weight and growth rate on isocitrate dehydrogenase activity, myoglobin concentration,
iron concentration, zinc concentration and meat browning.
ICDH Activity Myoglobin Concentration Iron Concentration Zinc Concentration Meat Browning
Birth Weight (kg) -0.57 -1.22 -0.25 - -0.14
Weight 100 days (kg) -0.38 2.22 0.26 0.13 -0.86
Weight 150 days (kg) -0.78 1.81 0.23 - -0.88
Growth Rate 100 days (g/day) -0.78 -0.91 -0.17 -0.35 -
Growth Rate 150 days (g/day) -0.60 -0.72 -0.22 -0.32 0.67
Weight Change 100 to 150 days (kg) -0.83 -1.47 -0.26 -0.35 0.60
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7.3.1.3 Effect of weight at 100 and 150 days
Weight at 100 days was associated with a reduction in ICDH activity of 0.01
µmol/min/g tissue for each kg of weight, which was equivalent to 0.38 µmol/min/g
tissue across the 55 kg weight range. For weight at 150 days the association was twice
as strong with a reduction in ICDH activity of 0.78 µmol/min/g tissue across the 46 kg
weight range.
7.3.1.4 Effect of change in weight between 100 and 150 days and growth rate at 100
and 150 days
Growth rate measured at 100 and 150 days or the change in weight measured between
these time points were all associated with reducing ICDH activity (P < 0.01). Change in
weight between 100 and 150 days varied between -7.25 and 16.95 kg, growth rate at
100 days varied between -170.09 and 547.70 g/day, and growth rate at 150 days varied
between -170.23 and 393.49 g/day and across these ranges ICDH activity reduced by
0.83, 0.78 and 0.60 µmol/min/g tissue.
7.3.1.5 Effect of adiposity
When correcting the growth models for short loin fat weight, short loin fat weight did
not impact on ICDH activity, nor did it diminish the association between growth and
ICDH activity. When correcting the growth models for intramuscular fat (P < 0.01) the
magnitude of the growth covariates was not diminished for weight, and diminished by
less than a third for growth rate.
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7.3.1.6 Effect of ASBVs
When the ASBV model was corrected for weight at 150 days or for growth rate at 150
days the magnitude of the breeding value effects reported by Kelman et al. (2014) did
not change.
7.3.2 Myoglobin Concentration
7.3.2.1 Base model
The base model for this study (not shown) utilised myoglobin concentration for 8,987
animals, and has previously been published by Kelman et al. (2014) who analysed a
subset of this data (n = 5,580). There was a minor variation to the Kelman et al. (2014)
model with the inclusion of a small effect for birth type-rear type combination.
7.3.2.2 Birth weight
Birth weight demonstrated an association with myoglobin concentration reducing it by
0.15 mg/g tissue for each kg of weight, which was equivalent to 1.22 mg/g tissue across
the 8.2 kg weight range (P < 0.01) (Table 7-4). This association varied between sites
and sire types. Between sites, myoglobin concentration reduced by as much as 0.28
mg/g tissue and as little as 0.11 mg/g tissue for each kg of weight. The variation with
sire type is detailed in Table 7-5.
.
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Table 7-5 Variation in slopes between sire types for the impact of birth weight, weight at 100 and 150 days, weight change between 100 and 150 days and growth rate at 100 and 150
days on myoglobin concentration, iron concentration and zinc concentration.
Myoglobin Concentration Iron Concentration Zinc Concentration
Trait Sire type Slope Trait - Min. Trait - Max. Magnitude Slope Trait - Min. Trait - Max. Magnitude Slope Trait - Min. Trait - Max. Magnitude
Birth weight Maternal -0.12 1.90 9.70 -0.91 -0.03 1.90 9.50 -0.24 - - - -
Merino -0.26 2.20 9.10 -1.77 -0.05 2.28 8.60 -0.33 - - - -
Terminal -0.08 1.98 10.10 -0.61 -0.02 1.98 9.80 -0.18 - - - -
Weight 100 Maternal ND 0.006 6.87 51.06 0.28 ND
Merino ND 0.001 8.65 51.60 0.06 ND
Terminal ND 0.006 3.38 60.76 0.36 ND
Weight 150 Maternal 0.04 15.46 53.06 1.55 0.006 15.46 55.81 0.25 - - - -
Merino 0.01 13.93 51.20 0.35 -0.002 13.93 51.20 -0.07 - - - -
Terminal 0.04 11.33 68.78 2.54 0.008 11.33 68.78 0.44 - - - -
Weight Change Maternal -0.02 -4.18 15.27 -0.46 -0.007 -4.19 15.27 -0.13 ND
100 to 150 Merino -0.12 -7.25 15.88 -2.78 -0.022 -4.45 15.88 -0.45 ND
Terminal -0.02 -5.01 20.01 -0.45 -0.003 -5.01 20.12 -0.07 ND
Growth Rate 100 Maternal -0.15* -89.23 348.68 -0.07 -0.09* -89.23 348.68 -0.04 -0.47* -89.23 348.68 -0.21
Merino -3.79* -168.78 359.54 -2.00 -0.75* -168.78 359.54 -0.40 -0.81* -89.03 359.54 -0.37
Terminal 0.17* -170.09 547.70 0.12 0.14* -170.09 547.70 0.10 -0.19* -170.09 547.70 -0.13
Growth Rate 150 Maternal -2.27* -85.69 297.86 -0.87 ND ND
Merino -5.35* -170.23 277.49 -2.39 ND ND
Terminal -2.22* -107.37 393.49 -1.11 ND ND
Min: Minimum value for the variable; Max: Maximum value for the variable; Magnitude: The total magnitude of the effect the variable has on myoglobin concentration, iron
concentration and zinc concentration; *(slope) x10-3
; ND: No difference in slope between sire types; -: No significant association
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7.3.2.3 Effect of weight at 100 and 150 days
Weight at 100 days demonstrated a curvilinear association with myoglobin
concentration increasing it by 0.04 mg/g tissue for each kg of weight, which was
equivalent to 2.22 mg/g tissue across the 57 kg weight range (P < 0.01). For weight at
150 days, the association increased myoglobin concentration by 1.81 mg/g tissue across
the 57.45 kg range (P < 0.01). This association varied between sites and sire types.
Between sites, myoglobin concentration increased by as much as 0.05 mg/g tissue and
as little as 0.05x10-2
mg/g tissue for each kg of weight. The variation with sire type is
detailed in Table 7-5.
7.3.2.4 Effect of change in weight between 100 and 150 days and growth rate at 100
and 150 days
Growth rate measured at 100 and 150 days or the change in weight measured between
these time points all demonstrated a relationship with myoglobin concentration (P <
0.01). Change in weight between 100 and 150 days varied between -7.25 and 20.01 kg,
growth rate at 100 days varied between -170.09 and 547.70 g/day, and growth rate at
150 days varied between -170.23 and 393.49 g/day and across these ranges myoglobin
concentration reduced by 1.47, 0.91 and 0.72 mg/g tissue. These associations varied
between sire types and are presented in Table 7-5.
7.3.2.5 Effect of adiposity
When correcting the growth models for short loin fat weight (P < 0.01) the magnitude
of the growth covariates diminished by a third to a half. When correcting the growth
models for intramuscular fat (P < 0.01) the magnitude of the growth covariates was
diminished by less than a tenth.
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7.3.2.6 Effect of ASBVs
When the ASBV model was corrected for weight at 150 days or for growth rate at 150
days the magnitude of the breeding value effects reported by Kelman et al. (2014) did
not change, with the exception of PWWT which was no longer significant in either
model.
7.3.3 Iron Concentration
7.3.3.1 Base model
The base model for this study (not shown) utilised iron concentration for 8,434 animals,
and has previously been published by Pannier et al. (2014b) who analysed a subset of
this data (n = 5,625). There were minor variations to the Pannier et al. (2014b) model
with the inclusion of an effect for dam breed within sire type and the absence of a birth
type-rear type or birth type-rear type by sire type effect.
7.3.3.2 Birth weight
Birth weight demonstrated an association with iron concentration reducing it by 0.03
mg/100g for each kg of weight, which was equivalent to 0.25 mg/100g across the 7.9 kg
weight range (P < 0.01) (Table 7-4). This association varied between sites and sire
types. Between sites, iron concentration increased by as much as 0.06x10-2
mg/100g and
reduced by as much as 0.05 mg/100g for each kg of weight. The variation with sire type
is detailed in Table 7-5.
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7.3.3.3 Effect of weight at 100 and 150 days
Weight at 100 days was associated with an increase in iron concentration of 0.45x10-2
mg/100g for each kg of weight, which was equivalent to 0.26 mg/100g across the 57 kg
weight range (P < 0.01). This association varied between sire types. Weight at 150 days
demonstrated an association with iron concentration, increasing it by 0.23 mg/100g
across the 57.45 kg weight range (P < 0.01). This association varied between sire types.
The variation with sire type at 100 and 150 days is detailed in Table 7-5.
7.3.3.4 Effect of change in weight between 100 and 150 days and growth rate at 100
and 150 days
Growth rate measured at 100 and 150 days or the change in weight measured between
these time points were all associated with reducing iron concentration (P < 0.01).
Change in weight between 100 and 150 days varied between -5.01 and 20.01 kg, growth
rate at 100 days varied between -170.09 and 547.70 g/day, and growth rate at 150 days
varied between -143.78 and 393.49 g/day and across these ranges iron concentration
reduced by 0.26, 0.17 and 0.22 mg/100g. The association between change in weight
between 100 and 150 days or growth rate and iron concentration varied at some sites
and between sire types. The variation at one site reduced iron concentration by 0.65x10-
2 mg/100g for each kg of weight change between 100 and 150 days. For growth rate at
100 days iron concentration reduced by as much as 0.06x10-2
mg/100g and as little as
0.01x10-2
mg/100g between sites for each g of growth rate. The variation with sire type
with change in weight between 100 and 150 days and growth rate at 100 days is detailed
in Table 7-5.
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7.3.3.5 Effect of adiposity
When correcting the growth models for short loin fat weight (P < 0.05) the magnitude
of the growth covariates diminished by a third to a half. When correcting the growth
models for intramuscular fat (P < 0.01) the magnitude of the growth covariates did not
diminish.
7.3.3.6 Effect of ASBVs
When the ASBV model was corrected for weight at 150 days or growth rate at 150 days
the magnitude of the effect of the breeding values reported by Pannier et al. (2014b) did
not change, with the exception of PWWT which became significant with the inclusion
of weight at 150 days.
7.3.4 Zinc Concentration
7.3.4.1 Base model
The base model for this study (not shown) utilised zinc concentration for 7,236 animals,
and has previously been published by Pannier et al. (2014b) who analysed a subset of
this data (n = 5,625). There were no variations to the Pannier et al. (2014b) base model.
7.3.4.2 Birth weight
Birth weight demonstrated no association with zinc concentration.
7.3.4.3 Effect of weight at 100 and 150 days
Weight at 100 days was associated with an increase in zinc concentration of 0.23x10-2
mg/100g for each kg of weight, which was equivalent to 0.13 mg/100g across the 55 kg
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weight range (P < 0.05) (Table 7-4). Weight at 150 days demonstrated no association
with zinc concentration.
7.3.4.4 Effect of change in weight between 100 and 150 days and growth rate at 100
and 150 days
Growth rate measured at 100 and 150 days or the change in weight measured between
these time points were all associated with reducing zinc concentration. Change in
weight between 100 and 150 days varied between -7.25 and 20.01 kg, growth rate at
100 days varied between -170.09 and 547.70 g/day, and growth rate at 150 days varied
between -170.23 and 393.49 g/day and across these ranges zinc concentration reduced
by 0.35, 0.35 and 0.32 mg/100g. The association between growth rate at 100 days and
zinc concentration varied between sire types and the magnitude of the variations are
detailed in Table 7-5.
7.3.4.5 Effect of adiposity
When correcting the growth models for short loin fat weight (P < 0.05) the magnitude
of the effect of growth rate at 100 days did not diminish, short loin fat weight was no
longer significant with weight change between 100 and 150 days or growth rate at 150
days and did not diminish the association between growth rate and zinc concentration,
and the association between weight at 100 days and zinc concentration was no longer
significant. When correcting the growth models for intramuscular fat (P < 0.01) the
magnitude of the growth covariates did not diminish except for weight at 100 days
which no longer had a significant association with zinc concentration.
7.3.4.6 Effect of ASBVs
When the ASBV model was corrected for weight at 150 days the magnitude of the
effect of the breeding values reported by Pannier et al. (2014b) did not change. When
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the ASBV model was corrected for growth rate at 150 days PWWT became significant,
increasing zinc concentration by 0.16 mg/100g across the 23 kg PWWT range.
7.3.5 Meat Browning
7.3.5.1 Base model
The base model for this study (not shown) utilised meat colour for 5,033 animals, and
has previously been published by Calnan et al. (2014) who analysed a subset of this
data (n = 4,238). There were minor variations to the Calnan et al. (2014) model with the
inclusion of a site by year effect.
7.3.5.2 Birth weight
Birth weight varied between 1.70 and 10.10 kg and across this range was associated
with a reduction in meat browning of 0.14 units (P < 0.05) (Table 7-4).
7.3.5.3 Effect of weight at 100 and 150 days
Weight at 100 days demonstrated a curvilinear association with meat browning reducing
it by 0.02 units for each kg of weight, which was equivalent to 0.86 units across the 53
kg weight range (P < 0.05). Weight at 150 days was associated with a reduction in meat
browning of 0.02 units for each kg of weight, which was equivalent to 0.88 units across
the 55 kg weight range (P < 0.01).
7.3.5.4 Effect of change in weight between 100 and 150 days and growth rate at 100
and 150 days
Growth rate measured at 150 days and the change in weight between 100 and 150 days
were both associated with an increase in meat browning (P < 0.01), while there was no
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association with growth rate at 100 days. Change in weight between 100 and 150 days
varied between -7.25 and 19.31 kg and growth rate at 150 days varied between -170.23
and 393.49 g/day and across these ranges meat browning increased by 0.60 and 0.67
units. The effect of growth rate at 150 days varied between sites and years. Between
sites, meat browning increased by as much as 0.23x10-2
and as little as 0.10x10-2
units
for each g of growth rate at 150 days. Between years, meat browning increased by as
much as 0.24x10-2
and as little as 0.11x10-2
units for each g of growth rate at 150 days.
7.3.5.5 Effect of adiposity
When correcting the growth models for short loin fat weight (P < 0.05) the
magnitude of the growth covariates diminished by around a third. When correcting the
growth models for intramuscular fat (P < 0.01) the magnitude of the growth covariates
did not diminish.
7.3.5.6 Effect of ASBVs
When the ASBV model was corrected for weight at 150 days or growth rate at 150 days
the magnitude of the breeding value effects reported by (Calnan et al., 2014) did not
change.
7.3.6 Phenotypic correlations
The phenotypic correlations of the meat traits with weight and growth rate are presented
in Table 7-6. For most traits there is a negative correlation with birth weight followed
by a positive correlation with weight at 100 days. The phenotypic correlations generally
aligned well with the phenotypic associations.
.
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Table 7-6 Phenotypic correlations of isocitrate dehydrogenase (ICDH) activity, myoglobin concentration, iron concentration, zinc concentration and meat browning with lamb weight
and growth rate. Standard error values in brackets. Significant correlations are in bold.
Birth weight Weight 100 days Weight 150 days Growth rate 100 days Growth rate 150 days
ICDH Activity -0.05 (0.00) 0.00 (0.97) -0.04 (0.01) -0.05 (0.00) -0.05 (0.00)
Myoglobin Concentration -0.08 (0.00) 0.11 (0.00) 0.11 (0.00) 0.02 (0.09) -0.07 (0.00)
Iron Concentration -0.07 (0.00) 0.06 (0.00) 0.07 (0.00) 0.03 (0.01) -0.04 (0.00)
Zinc Concentration -0.03 (0.03) 0.03 (0.04) 0.00 (0.98) -0.04 (0.00) -0.05 (0.00)
Meat Browning -0.02 (0.12) -0.12 (0.00) -0.10 (0.00) 0.03 (0.04) 0.09 (0.00)
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7.4 Discussion
7.4.1 Isocitrate dehydrogenase activity
Contrary to our hypothesis, the oxidative indicator enzyme ICDH showed a negative
association with lamb growth. This association was consistent with both weight and
growth rate measures including weight at birth, 100 and 150 days, weight change
between 100 to 150 days, and instantaneous growth rate at 100 and 150 days. The
negative association between lamb growth and ICDH activity is supported by the
negative phenotypic correlations between ICDH activity and both weight and growth
rate (Table 7-6).
The strength of the association between weight and ICDH activity increased between
100 and 150 days as indicated by the magnitude of change in ICDH activity across the
range of weights, with this magnitude doubling from 0.39 µmol/min/g tissue at 100
days to 0.78 µmol/min/g tissue at 150 days (Table 7-4). Supporting this change was the
strong association between growth rate at 100 days and ICDH activity (i.e. 0.78) which
would have gradually increased the strength of the association between ICDH activity
and live weight. Therefore the window for growth rate to elicit the greatest change to
oxidative capacity lies in the period between 100 and 150 days from the weaning to post
weaning phase.
ICDH activity has a strong positive association with intramuscular fat (Kelman et al.,
2014) which is similar in magnitude to the association between ICDH activity and
weight at 150 days. Given that intramuscular fat increases with live weight (Chapter 6)
the change in ICDH activity with growth may be associated with intramuscular fat or
whole carcass adiposity. However, the correction of the growth models for
intramuscular fat or short loin fat weight (indicating whole carcass fatness) had little
203
impact on the association between growth and ICDH, suggesting that the effect of
growth on ICDH activity is independent of intramuscular fat. Bernard et al. (2009)
showed a similar disassociation between muscle metabolism with growth and fat
deposition in cattle. When short loin fat weight was included in the growth models it
was not significant, and therefore did not diminish the association between growth and
ICDH activity. This is not surprising given that short loin fat weight alone had no
impact on ICDH activity (Kelman et al., 2014). Thus, it is can be concluded that growth
drives reduced oxidative capacity and this is not simply a reflection of associated
changes in fatness.
Although the hypothesis for an increase in ICDH activity with lamb growth was based
on a positive association between oxidative capacity and hot carcass weight there is
evidence suggesting the reverse can occur. Selection for increased growth rate has been
shown to shift muscle metabolism toward a more glycolytic and less oxidative type
(Rahelic and Puac, 1981). This shift may occur as animals selected for growth tend
toward a larger mature size (Huisman and Brown, 2008) having heavier carcass weights
(Sharaby and Suleiman, 1988) but being proportionately less of their mature size at a
given age. Thus they have more glycolytic fibres and lower levels of ICDH activity.
Likewise, the impact of selection for leanness in lambs has also been shown to increase
weight at 150 days (Chapter 4) and reduce ICDH activity (Gardner et al., 2007; Gardner
et al., 2006b). Hence there is some basis for our results in the literature.
What is less clear is why there was no phenotypic association (Kelman et al., 2014) or
phenotypic correlation (Mortimer et al., 2014) between hot carcass weight at slaughter
and ICDH activity. While Kelman et al. (2014) indicated increased oxidative capacity
with heavier hot carcass weights, this was largely based on myoglobin concentration not
ICDH activity. ICDH activity varied with hot carcass weight at two of the eight sites in
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the study, increasing at one site and reducing at the other so the effect was quite
inconsistent. With weight change increasingly dominated by fat deposition as animals
approach slaughter, we speculate that there may a gradual uncoupling of the association
between early life growth and muscle oxidative type, resulting in no hot carcass weight
association at slaughter. Given the lack of consistent phenotypic association with ICDH
activity, hot carcass weight alone should not be used as a proxy for growth at all stages
of development when assessing its impact on muscle metabolic type.
7.4.2 Myoglobin concentration
The association between lamb growth and myoglobin concentration varied throughout
the different phases of lamb growth. Myoglobin concentration had a negative
association with weight at birth, suggesting an impact of in-utero growth rate, after
which the association inverted and myoglobin concentration had a strong positive
association with weight at 100 days (Table 7-4). These results align well with the
phenotypic correlations between growth indicators and myoglobin concentration during
this period (Table 7-6).
While the association with weight from weaning onwards aligned with our hypothesis,
and has been demonstrated previously (Beriain et al., 2000), the inversion between birth
and weaning was unexpected. It did however highlight that the window for the greatest
change to myoglobin concentration was between birth and weaning, with the magnitude
of the increase in myoglobin concentration during this period being as large as 3.52
mg/g tissue.
The association between myoglobin concentration and growth rate was negative and
strengthened between 100 and 150 days. This may explain the diminishing association
between myoglobin concentration and live weight which decreased by about 20% at
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150 days compared to 100 days. Nonetheless, the magnitude of the association between
myoglobin concentration and slaughter weight, as indicated by the association with hot
carcass weight in the Kelman et al. (2014) study, was a similar magnitude to that seen
for weight at 150 days. This suggests that the negative association between myoglobin
concentration and growth rate following weaning was not enough to uncouple the
overall positive association with weight. During this same time period there is a shift in
muscle fibre type with increasing hot carcass weight from a glycolytic to an oxidative
metabolism (Greenwood et al., 2007). As myoglobin concentration is increased with
oxidative capacity the association between myoglobin concentration and weight may
stabilise post weaning due to a shift in muscle fibre type.
As with ICDH activity, myoglobin concentration has a positive association with
intramuscular fat (Kelman et al., 2014). To determine whether the change in myoglobin
concentration with growth was simply a reflection of its association with adipose tissue
the growth models were corrected separately for intramuscular fat and short loin fat
weight. The inclusion of intramuscular fat had little impact on the magnitude of the
association between myoglobin concentration and growth while the inclusion of short
loin fat weight reduced the association by a third to a half. These results suggest that the
impact of growth on myoglobin concentration is independent of intramuscular fat
although not completely independent from whole carcass adiposity. Nonetheless growth
still describes a significant amount beyond just that which is correlated with whole
carcass adiposity.
Myoglobin concentration is an indirect indicator of oxidative muscle type however the
association with growth does not perfectly align with the results of the more direct
indicator of oxidative metabolism in ICDH activity. This was also true in the Kelman et
al. (2014) study where hot carcass weight impacted myoglobin concentration however
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had no overall impact on ICDH activity, so the association between hot carcass weight
and oxidative capacity was inconsistent. The lack of alignment between the two
indicators is also evident in the window of growth during which both can be influenced,
being during early pre weaning growth for myoglobin concentration and post weaning
for ICDH activity.
7.4.3 Iron and zinc concentration
In general, the association between growth and iron and zinc concentration largely
reflected the results of myoglobin concentration. This was particularly true for iron
concentration, which had a negative association with weight at birth followed by a
strong positive association with weight at 100 days that diminished slightly by 150 days
in response to an strengthening negative association with growth rate between 100 and
at 150 days (Table 7-4). Again, these associations align well with the phenotypic
correlations for iron which were negative with birth weight and positive with weight at
100 and 150 days (Table 7-6). The phenotypic correlations between zinc concentration
and growth were generally weaker, reflecting a lack of association with birth weight and
weight at 150 days, a weak positive association with weight at 100 days and negative
associations with growth rate at 100 and 150 days. Based on the phenotypic associations
and correlations the window for greatest change to iron concentration is between birth
and weaning, as was the case for the myoglobin concentration, with the magnitude of
the increase in iron concentration during this period being as large as 0.51 mg/100g.
The alignment in responses of myoglobin and iron concentrations to growth is not
unexpected given myoglobin is an iron rich protein resulting in a high phenotypic
correlation of 0.97 (Mortimer et al., 2014) between these two measurements. In Chapter
6, the response of intramuscular fat to growth paralleled the responses of myoglobin and
iron concentrations, including a window for greatest change during early life pre
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weaning growth. This is likely to be due to the close association of these traits, each
being linked to muscle fibre type and oxidative capacity (Hocquette et al., 2003; Jurie et
al., 2007; Kelman et al., 2014). Given lambs are reliant on ewes for nutrition prior to
weaning, and that the greatest window for change for these traits is pre weaning, there
may be scope to influence intramuscular fat, myoglobin concentration and iron
concentration in lambs by manipulating feed to ewes.
Iron and zinc concentration are linked to oxidative capacity (Pannier et al., 2014b) and
are therefore linked to oxidative fibre types (Gardner et al., 2007) so an increase in
mineral content with increased weight was expected, however iron concentration was
found to be more sensitive to changes in weight than zinc concentration. This aligns
with the findings of Pannier et al. (2014b) of a larger increase in iron concentration with
increasing hot carcass weight. In the current study, the total magnitude of change in zinc
concentration due to weight at 100 days was equivalent to approximately 5% of the
average zinc concentration, indicating a relatively small impact of weight on zinc
concentration.
Despite a negative phenotypic correlation for iron concentration and no significant
correlation for zinc concentration (Mortimer et al., 2014) the impact of hot carcass
weight on both iron and zinc concentration was positive, as reported by Pannier et al.
(2014b). The magnitude of the association between iron concentration and slaughter
weight, as indicated by the association with hot carcass weight in Pannier et al. (2014b)
was a similar magnitude to that seen for weight at 150 days so the negative association
between iron concentration and growth rate was not enough to uncouple the positive
association with weight. Similarly for zinc concentration, where the association with hot
carcass weight was about 50% less (Pannier et al., 2014b) than with weight at 100 days,
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the negative association between zinc concentration and growth rate did not completely
uncouple the positive association with weight.
Iron and zinc concentrations increase with intramuscular fat (Pannier et al., 2014b) and
intramuscular fat increases with weight (Chapter 6) so the growth models were
corrected separately for intramuscular fat and short loin weight to determine if the
impact of growth was a reflection of increased adiposity. The results largely reflected
those seen for myoglobin concentration, in that the inclusion of intramuscular fat
generally had no impact on the magnitude of the association between growth and iron or
zinc concentration while the inclusion of short loin fat weight reduced the associations
by around a third to a half. The only exception was weight at 100 days, where both
measures completely accounted for the association with zinc concentration. These
results suggest that the impact of growth on iron and zinc concentration describes a
significant amount beyond just that which is correlated with whole carcass adiposity.
The impact of growth on myoglobin concentration, iron concentration and zinc
concentration varied between sire types (Table 7-5). The effect on myoglobin
concentration was strongest in Merinos at most times measured and did not change with
correction of the model for short loin fat weight. This indicates a higher level of
myoglobin in progeny of Merino sires at maturity, independent of whole body
adiposity. Similarly, correction of the iron and zinc models for whole carcass adiposity
did not change the variation of the impact of growth between sire types.
7.4.4 Meat browning
The reduction in meat browning with increasing weight was contrary to expectation but
aligns well with the association between ICDH activity and weight. As oxidative
metabolism is a key driver of meat browning (Calnan et al., 2014) it makes sense that a
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reduction in oxidative metabolism, as indicated by ICDH activity, with increasing
weight will result in a reduction in meat browning. Furthermore, these results align well
with the negative phenotypic correlations between meat browning and weight (Table
7-6). The lack of association between meat browning and growth rate at 100 days
explains why there is no change in the magnitude of the association between meat
browning and weight at 100 and 150 days (Table 7-4). The difference in association
between meat browning and weight is greatest between birth and weaning indicating the
period where the greatest change can be made.
Meat browning is reduced with increased hot carcass weight at slaughter (Calnan et al.,
2014). The magnitude of the association is about two thirds the magnitude of the
association with weight at 100 or 150 days in this study. This reduction in magnitude is
due to the positive association between meat browning and growth rate starting to
uncouple the negative association with weight.
Meat browning has a positive association (Calnan et al., 2014) and phenotypic
correlation (Mortimer et al., 2014) with intramuscular fat. Therefore, increases in
intramuscular fat with increased live weight (Chapter 6) may increase browning. When
the growth models were corrected for intramuscular fat the association with meat
browning did not diminish. This suggests that growth impacts meat browning
independently of associated changes in intramuscular fat, which aligns with the findings
for ICDH activity. Alternatively, correction of the growth models for short loin fat
weight reduced the association with meat browning by about one third. This indicates
that the impact of growth on meat browning is not completely independent of whole
carcass adiposity, although growth still describes a significant amount beyond its
correlation with whole carcass adiposity.
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The published impact of PWWT, PFAT and PEMD on ICDH activity and myoglobin
concentration (Kelman et al., 2014), iron and zinc concentration (Pannier et al., 2014b)
and meat browning (Calnan et al., 2014) did not change when corrected for weight at
150 days or growth rate at 150 days. The effects of PFAT and PEMD did not change
with correction for weight or growth rate at 150 days indicating that they are not
mechanistically driven through the impact of growth, as evidenced by the lack of a
PWWT effect on mineral content and meat browning.
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7.5 Conclusion
This study demonstrated that lamb growth impacts on muscle oxidative capacity,
mineral content and meat browning. The key period for modulation of myoglobin and
iron concentration was between birth and weaning with the magnitude of the responses
reducing after weaning. As iron is a key component of myoglobin the alignment of the
response was as expected. Birth to weaning was also the key period for modulation of
meat browning, although the magnitude of the response does not diminish after
weaning. They key period for modulation of the oxidative capacity indicator enzyme
isocitrate dehydrogenase is later than for other traits reported, being between weaning
and post weaning as the strength of the association between isocitrate dehydrogenase
and live weight increases. Zinc was less sensitive to changes in growth although the
responses which were present aligned with iron concentration. As for intramuscular fat
in Section 6.3.1.5, the response of myoglobin concentration, iron concentrations and
meat browning to lamb weight inverted between birth and weaning indicating they may
also be influenced by in-utero growth. In general, the impact of growth on oxidative
capacity, mineral content and meat browning were not due to local adiposity while up to
half the magnitude of the associations were due to a correlated increase in whole carcass
adiposity. However, there was still a significant variation that was not associated with
whole body fatness. Hot carcass weight, as a proxy for whole of life growth, provided a
poor estimate of the impact of growth frequently underestimating the impact of growth
on oxidative capacity, mineral content and meat browning. Hot carcass weight varies
with age at slaughter, while growth at weaning and post weaning do not, contributing to
the poor alignment of hot carcass weight and growth effects. Furthermore, hot carcass
weight was unable to describe the impact of growth during different phases of growth.
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Chapter 8. General Discussion
8.1 Benefits of lamb growth to industry
The growth of lambs from birth to slaughter is of vital importance to producers in the
Australian sheep industry, while meat quality is of increasing interest to consumers
(Pethick et al., 2006a; Pethick et al., 2006b). Currently, producers use Australian Sheep
Breeding Values (ASBVs) to select for increased growth at birth, weaning and post
weaning time points (Hall et al., 2002). However, the impact of growth at these time
points on meat quality has not been well characterised.
Lamb growth can be tracked throughout life by measuring live weight at various
intervals as they grow. However, lamb weight at individual time points varies greatly
due to gut fill, time of day, length of curfew and other production factors. Furthermore,
when dealing with large populations, not all animals are weighed at the same time.
Hence there is a need to assign an accurate growth function through the available live
weight data so that growth at equivalent time points of interest can be estimated.
Three growth functions were fitted to the available live weight data collected on 18,185
lambs to determine the function with the best fitting characteristics (Chapter 3). These
functions were chosen to represent a difference in curve shape, linear or nonlinear, and a
difference in fitting type, individual or population based.
Subsequent to growth being estimated at weaning and post weaning time points
(Chapter 4), the impact of growth at these times on meat quality was examined
(Chapters 6 and 7). The indicators of meat quality examined were chosen due to their
importance in consumer acceptability of meat and their links to muscle fibre type.
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Muscle fibre type is of particular interest because it is linked to important traits of
consumer acceptability such as fresh and retail meat colour, mineral content, ultimate
pH and rate of pH decline, intramuscular fat and ageing rate. Therefore, growth may
impact meat traits, and thus consumer acceptability, through its impact on fibre type.
Oxidative fibre type can be indicated by activity of the oxidative enzyme isocitrate
dehydrogenase (ICDH) and by myoglobin concentration so the impact of growth on
these markers was examined. The impact of growth on traits linked to eating quality,
retail shelf life and nutritional qualities were examined. These included:
Indicators of eating quality: intramuscular fat, shear force and consumer overall liking;
and
Indicators of meat nutrition: iron and zinc concentration; and
Indicators of retail shelf life: rate of meat browning.
8.2 Brody function
The Brody function is a nonlinear function which is fitted individually to each animal’s
weight records. It is commonly used due to its ease of estimation, with an ease of
computation and a limited number of curves which do not converge (Kaps et al., 1999;
Topal et al., 2004). Furthermore, the parameters have biological significance and are
simple to interpret, representing mature body weight and maximum growth rate
(Fitzhugh, 1976). However, the Brody function had the poorest fitting characteristics of
all three curves examined including the highest mean squared error indicating the
greatest deviation of the estimated weights from the recorded weights. A contributing
factor to this is the overestimation of weights during early life growth, a recognised
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limitation of the Brody function (Beltrán et al., 1992). To rectify this, a two function
approach could be used, with a separate function fitted during early life growth and a
Brody function fitted after the point of inflection of the growth curve. However, this
unnecessarily increases the complexity of the curve fitting process and would also
require the collection of more data points during this early growth period pre weaning.
This was not done with this study due to the risk of mis-mothering of lambs, a practical
challenge likely to limit the application of this approach.
The scope to include further nonlinear growth functions in the comparison is virtually
unlimited. The Brody function was used due to its ease of computation, however other
nonlinear functions such as the Von Bertalanffy, Richards, Logistic and Gompertz
functions have each been used to model lamb growth and may have been acceptable
substitutes.
8.3 Cubic polynomial function
The cubic polynomial is a linear function fitting weight as a function of time only. As
for the Brody function, it is fitted on an individual basis. Polynomial functions are
attractive when modelling weight change due to the flexible nature of the curves
increasing as the degree of polynomial increases from linear to quadratic to cubic to
quartic and so on. While this appears advantageous there are limitations.
It is difficult to know when to stop increasing the polynomial since with every increase
in polynomial the curve will conform to the live weight data with greater accuracy. This
results in smaller residual weights and a lower mean square error than for other curves,
as seen in the first experiment. However this could result in the modelling of small
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changes in weight including gut fill on a given day, which may not necessarily increase
the understanding of how weight changes with time on a macroscopic level. The shape
of the curve would fluctuate increasingly with the degree of polynomial and the
trajectory, from which instantaneous growth rates are calculated, would be influenced
by factors such as gut fill rather than whole of life trajectory.
Increasing the degree of polynomial also increases by one the number of weight
recordings needed for each animal. Thus, for a cubic polynomial to be fitted, an animal
needs to have at least four data points. Therefore as the degree of polynomial increases
the number of animals with sufficient weight recordings reduces, potentially limiting
the application of this technique. In comparison, a Brody function can be fitted to
animals with as little as three weight recordings.
Polynomial functions are frequently asymptotic. This can result in extreme estimates for
birth and adult weights. Brody curves may also have asymptotes however they are
closer to horizontal so the estimated adult weight is relatively stable.
Lastly, unlike the parameters of a Brody function, the parameters of polynomial
functions do not have a direct biological interpretation. Therefore it is difficult to
compare the results across studies or understand how they influence the fit of the
growth curve.
8.4 Random effects model
A random effects model function fits a growth curve to the entire population of animals,
with the growth curve of individual animals varying directly from the population
growth curve. As it is based on a polynomial function it has similar limitations to fitting
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a cubic polynomial. However this method is not as subject to bias as an individual
Brody or cubic polynomial fit. This is because random effects models can accommodate
different durations of data recording. Where weight data is missing in some animals, it
is informed by other animals with similar production or genetic information. Based on
these properties, a random effects model can be fitted for an animal with as little as one
live weight recording.
The random effects model was hypothesised to have better curve fitting characteristics
than an individual animal function fitted on an individual animal basis. While this did
prove to be the case when compared to the Brody function, the fit was actually worse
than for the individually fitted cubic polynomial function. The specific reason for this is
unknown however the inclusion of animals with less than three or four weight
recordings, which was not possible with a Brody or cubic polynomial function, did not
significantly compromise the fit, increasing the MSE by around only 5%.
An alternative population based fit not examined in this thesis is the use of spline
functions, which do not require the growth function to follow a strict cubic polynomial
form (McPhee et al., 2012). Rather, spline functions can force the growth curve through
actual weight recordings. While this reduces the variance it also increases bias as the
value of the smoothing parameter lambda increases to facilitate the curvature. Due to
the large number of growth functions that exist, it was not possible to utilise each
method. The limitations of potential functions were considered and splines were not
used due to the bias they introduce. However, splines are not uncommonly used when
modelling animal growth data so the method cannot be entirely discounted.
From a pragmatic standpoint, each of the growth functions assessed gave a reasonable
estimation of growth. Ultimately the random effects model offers a more powerful and
flexible means of evaluating repeated live weight measures, particularly with respect to
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accommodating animals with few live weight recordings, which is common with
industry data. Random effects models are also subject to less bias than the Brody
function, which is influenced when estimating weights near the edge of the available
data. Therefore, the random effects model was used to estimate growth at weaning and
post weaning time points, which were used to determine the impact of growth on meat
quality.
Based on the random effects model, weights and growth rates were estimated at key
points in production. These were 100 days, 150 days and 240 days which represent the
ages at weaning, post weaning and the average age at which post weaning ASBVs were
calculated.
8.5 Impact of environment on growth
Growth is a function of environment. Environmental and production factors within this
study included site of birth, year of birth, age, sex, birth type-rear type combination,
dam age, dam breed and sire type (Chapter 4).
Numerous studies have reported the impact of environmental factors on lamb growth
hence the impacts on growth were generally as expected (Afolayan et al., 2007;
Thatcher et al., 1991). However, this analysis represents a benchmarking study allowing
comparison of magnitudes of effect for each of these factors based on large numbers of
animals.
The site at which lambs were reared had the largest effect on growth while the effect
varied very little between years. The differences in growth between sites was partly due
to differences in nutrition. However nutrition was confounded by environmental factors
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such as rainfall, pasture types and fertiliser application, and no single factor explains all
the variation in growth between sites. For example, annual rainfall at the Kirby site is
50% greater than at the Trangie site yet lamb growth at Kirby was consistently low and
at Trangie was consistently high.
The effect of birth type on lamb growth was almost as large in magnitude as the impact
of environmental factors at the site of rearing with multiple birth lambs having lower
weights and growth rates. However, from a practical standpoint it is difficult to select
against multiple births to ensure maximum lamb growth. Furthermore, the number of
lambs weaned and is also a profit driver in lamb production which may be an acceptable
trade-off for reduced growth.
Production effects which producers can target include dam breed, dam age and sire type
with lambs from dams less than four years of age and Terminal sires with Border
Leicester x Merino dams increasing lamb growth. Of these, the magnitude of the sire
type effect is greatest, and it represents as much as 80% of the magnitude of the effect
of site.
Production systems which are targeting accelerated lamb growth will increase success
by ensuring adequate nutrition, in male lambs born to Terminal sires and Border
Leicester x Merino which are less than 4 years of age.
Nutrition is a key driver of lamb growth however there are production factors which can
impact nutrition that were not directly captured by this experiment. For example, milk
volume is reduced in Merino dams leading to reduced growth in lambs compared to
Border Leicester-Merino dams. However the impact of colostrum volume and
composition is unknown. Colostrum volume and composition could be investigated,
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particularly from single compared to multiple pregnancy ewes, to determine if
colostrum quality was a source of nutritional restriction in addition to milk volume.
While most of the results of this study are not new, the key outcome of this analysis was
to provide a good basis for the comparative magnitude of these effects, based on large
numbers of animals.
8.6 Impact of genetics on growth
The impact of selection for growth using ASBVs was quantified (Chapter 4). The
magnitude of the effect increased with time, being larger at 240 days than at birth.
However, as a proportion of the average live weight the effect diminished with time,
being strongest at birth. There was no effect of the breeding values on instantaneous
growth rate measured at 100, 150 and 240 days. The magnitude of the ASBV effects
compared to production effects also diminished with time. For example, at birth the site
of rearing (i.e. environmental effect) and the ASBV for birth weight had a similar
magnitude of effect however by 240 days the ASBV effect was half the effect of site.
While producers cannot control the environmental/site effects they are able to control
ASBVs and genotype. Therefore, the magnitude of these effects is a more fair
comparison. For example, the magnitude of the effect of the ASBV for birth weight is
twice that for dam breed or sire type, so if birth weight is critical, ASBVs will have a
larger effect. This effect is reversed at weaning and post weaning with the magnitude of
difference between sire types close to double the magnitude of the growth ASBV effect.
Therefore producers interested in higher growth at weaning and post weaning will have
more of an impact by choosing a Terminal sire, although use of a Terminal sire in
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combination with growth ASBVs will have the greatest impact on lamb growth. That is
not to say that progeny of Terminal sires will always be heaviest as progeny from high
PWWT Maternal sires are on average heavier than progeny from low PWWT Terminal
sires. Thus expectations of weight must be tempered with knowledge of the interaction
between production factors, such as sire type, and potential weights based on PWWT.
The expression of growth breeding values, particularly sire PWWT, is limited by poor
nutrition (Hegarty et al., 2006b). Following on from these findings, our study
investigated different forms of nutritional restriction in dams or lambs due to siblings,
dam breed, dam age etc. on the expression of growth breeding values. Nutritional
restriction was found to moderate the full expression of growth breeding values.
The cause of reduced expression of growth breeding values is important for producers
to understand. It identified breeding objectives which may be in conflict. For example,
producers selecting for multiple birth and increased lamb growth can now expect less
genetic growth in multiples compared to singles.
These findings are extremely important from an industry perspective. Firstly, they
highlight nutrition as an important and powerful production tool for the manipulation of
lamb growth. Secondly, these results highlight that production factors which limit the
available nutrition, such as birth type, will depress the full expression of growth
breeding values. Quantification of the magnitude of these effects are provided at birth,
weaning and post weaning.
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8.7 Fibre type and oxidative capacity
Muscle oxidative capacity was a specific focus of this thesis as it reflects fibre type
which is of central importance as it influences a number of meat traits of commercial
importance, including meat eating quality, mineral content, and meat browning (Calnan
et al., 2014; Pannier et al., 2014b; Pannier et al., 2014c). Therefore, factors that impact
on muscle oxidative capacity may lead to correlated changes in these meat traits.
Furthermore, a number of these factors are likely to be a reflection of the effect of
growth rate on muscle oxidative capacity and fibre type. Thus characterising them in
detail and then assessing their magnitude, after correcting for growth, enables us to
asses which are simply a reflection of growth.
Muscle oxidative capacity was indicated by isocitrate dehydrogenase activity and
myoglobin concentration in this thesis (Chapter 5). Due to the large number of animals
sampled in this experiment, and the costs and time associated with measurement, a
pragmatic decision was made to include only two indicators of muscle oxidative
capacity. This approach to assessing oxidative capacity has been taken previously in
lamb. There are a number of other indicator enzymes that could have been measured to
reflect oxidative (citrate synthase) or glycolytic (lactate dehydrogenase) capacity, as
well as other histochemical and immunohistochemical fibre typing techniques.
However, isocitrate dehydrogenase was chosen as it is a relatively consistent indicator
of muscle fibre type (Gardner et al., 2006b). Myoglobin concentration was also used,
not only for its links to aerobicity, but due to its phenotypic and genetic correlation with
other important meat traits investigated in this thesis. These include a high correlation
with iron concentration and meat browning (Mortimer et al., 2014).
Despite the links of ICDH activity and myoglobin concentration with muscle fibre type
and aerobicity their response to environmental and growth factors was not always
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consistent. ICDH activity, which is linked to metabolic efficiency, was demonstrated to
be more responsive to the environment than myoglobin concentration with a greater
variation across sites and years. Conversely myoglobin concentration was less
responsive to environmental factors and heavily driven by age.
8.8 Impact of genetics on oxidative capacity
Oxidative capacity increased with selection for increased PWWT ASBV. Although this
was unexpected the shift in fibre type with growth could impact meat quality traits
linked to fibre type. The impact of PWWT on isocitrate dehydrogenase activity negated
through its association with whole body adiposity so the main impact of PWWT was on
myoglobin concentration. Therefore, the traits linked to myoglobin concentration,
namely zinc concentration and meat browning were likely to have similar responses to
growth. This was particularly evident for iron concentration, which is intrinsically
linked to myoglobin concentration (Hazell, 1982).
The environment in which the lamb was raised had the largest influence on both
indicators of oxidative capacity, being triple the magnitude of the effect of PWWT. The
impact of growth ASBVs on oxidative capacity was only assessed at the post weaning
time point. As myoglobin concentration changes significantly between birth and
weaning it would be interesting to see if growth ASBVs at birth and weaning were
impacted by weight at these times as they could be used by producers to manipulate
oxidative capacity and meat colour.
While there are currently no market price signals for eating quality that flow back to
producers this is likely to change in the future. The impact of selection for growth on
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meat quality can be predicted and then tracked using gene markers and altered using
quantitative breeding values if necessary.
8.9 Impact of growth on oxidative capacity
Myoglobin concentration changed markedly with weight between birth and weaning
however the change in the negative association with weight at birth to a positive
association with weight at weaning is not well characterised as few weights were
recorded during this period (Chapter 7).
As fibre type is linked to meat quality traits it is relevant to know the impact that
selection for leanness and growth will have, and to know whether phenotypic growth
will have an impact in addition to genetic selection for growth. The impact of selection
using PEMD and PFAT ASBVs on oxidative capacity was generally unchanged with
correction for phenotypic growth, indicating that these breeding values impact oxidative
capacity through mechanisms not correlated with growth rate. This is not surprising,
particularly given the growth breeding value itself (i.e. PWWT) also had minimal
impact on oxidative capacity.
While intramuscular fat was linked to an increase in oxidative capacity (Chapter 5) it
was shown to be independent of its association with PFAT or whole body adiposity or
muscularity (Chapter 5). An increase in growth reduced isocitrate dehydrogenase
activity however this was independent of a correlated increase in adiposity with growth
(Chapter 6 and Chapter 7). Thus growth impacts oxidative capacity independently of
adiposity.
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8.10 Impact of growth on objective and subjective measures of
eating quality
Intramuscular fat and shear force are important objective measures of eating quality
which influence the subjective measure of eating quality, consumer overall liking
(Chapter 6). Intramuscular fat in particular influences the organoleptic properties of
meat (Hocquette et al., 2010) and is clearly visible to consumers.
As for myoglobin concentration, intramuscular fat changed markedly with weight
between birth and weaning. The change was less dramatic for shear force, with no
impact of birth weight followed by a negative association at weaning. For both traits the
association had weakened by the post weaning time point (150 days) due to an
increasing positive association with growth rate. The magnitude of the effect at weaning
represented as much as a quarter the average total amount of intramuscular fat present at
slaughter, while for shear force it was two fifths, indicating the size of the impact
delivered through increased growth.
The magnitude of the effect of growth on intramuscular fat or shear force was in part
delivered through an associated increase in carcass adiposity. Within this study
adiposity accounted for about a third to a half of the magnitude of the growth effect.
Alternatively this still means that growth independent of its associated increase in
adiposity still accounted for the remaining half of the effect.
While there is currently no price premium for objective measures of eating quality in
lambs, this may change in the future. This could occur with the development of an
ASBV for intramuscular fat, which will allow intramuscular fat and carcass leanness to
be controlled independently thus uncoupling the biological association. While it is not
currently detectable, the impact of phenotypic growth could eventually impact overall
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liking through its associations with intramuscular fat. Therefore it is relevant to know
whether phenotypic growth will have an impact on these traits in addition to genetic
selection for growth.
The impact of selection using PEMD and PFAT ASBVs on intramuscular fat, shear
force and overall liking was generally unchanged when corrected for phenotypic
growth, indicating that these breeding values impact these traits through mechanisms
not correlated with growth rate. This is not surprising, particularly given the growth
breeding value itself (i.e. PWWT) also had no impact on intramuscular fat, shear force
and overall liking.
A key hypothesis was based on hot carcass weight, which is used as a proxy for whole
of life growth rate (Pannier et al., 2014b; Pannier et al., 2014c) based on its high
correlation with pre slaughter live weight. This study demonstrated that the effect of hot
carcass weight on traits is a poor proxy for the effect of growth, overestimating the
effect for intramuscular fat and shear force. Obviously this measure cannot describe the
impact of growth during different phases of growth therefore the window for
intramuscular fat and shear force manipulation during pre weaning growth had not
previously been demonstrated.
8.11 Impact of growth on mineral content of meat
Iron and zinc concentration are important consumer health traits. As for myoglobin
concentration, intramuscular fat and shear force, iron concentration changed markedly
with weight between birth and weaning (Chapter 7). This is not surprising given that
iron is a key component of myoglobin (Hazell, 1982). The change was less dramatic for
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zinc concentration which was less sensitive to lamb weight, as indicated by a reduced
association with hot carcass weight compared to zinc concentration. Arguably however,
the profile of iron in human health is more prominent than zinc so the stronger
association of lamb weight is of more commercial significance.
As for measures of oxidative capacity as well as subjective and objective measures of
meat quality, the magnitude of the effect of growth on iron and zinc concentration was
in part delivered through an associated increase in carcass adiposity. Within this study
adiposity accounted for about a third to a half of the magnitude of the growth effect on
iron and zinc concentration. This suggests that growth, independent of the associated
increase in adiposity, accounts for at least half the effect.
As for other traits, it is relevant to know what portion of the impact of PFAT and PEMD
ASBVs were delivered through their correlated effects on growth. The impact of
selection using PEMD and PFAT ASBVs on mineral content was unchanged with
correction for phenotypic growth, indicating that these breeding values impact iron and
zinc concentration through mechanisms not correlated with growth rate. This is not
surprising, particularly given the growth breeding value itself (i.e. PWWT) also had no
impact on mineral content.
As for other oxidative capacity as well as objective and subjective measures of eating
quality, the impact of hot carcass weight on iron and zinc concentration (Pannier et al.,
2014b) was shown to be a poor proxy for growth, underestimating the effect.
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8.12 Impact of growth on meat browning
Meat browning is costly to retailers due to discounting of otherwise safe and saleable
meat. The rate of meat browning is slower in heavier lambs, with the magnitude of the
effect increasing in the birth to weaning period then reaching a plateau (Chapter 7). This
was contrary to expectations as increased growth is associated with increased
intramuscular fat, which accelerates the rate of browning due to the auto oxidation of
lipid. Alternatively, the results align well with the associated reduction in oxidative
capacity with weight during the same period.
When the growth models were corrected for intramuscular fat there was no change in
the effect of growth on intramuscular fat, further emphasising that intramuscular fat
isn’t driving more rapid browning. When the growth models were corrected for whole
body adiposity, the magnitude of the impact on meat browning reduced by one third.
Thus the impact of growth on browning is only partially explained by its correlation
with adiposity.
As for the traits mentioned previously, the impacts of PFAT and PEMD on meat
browning were not delivered through mechanisms correlated with growth rate since
they did not change with correction for phenotypic growth. This was as expected given
the lack of association between PWWT and meat browning.
The effect of hot carcass weight (Calnan et al., 2014) was found to be a poor proxy for
the effect of growth, underestimating the effect on meat browning.
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8.13 Impact of growth on meat traits
Several meat traits had a similar period in which they were influenced by growth and a
similar pattern of change with growth. These are likely to be linked to fibre type.
Birth to weaning: Intramuscular fat, myoglobin concentration, iron concentration and
meat browning are impacted by lamb growth during this period. Although growth
between birth and weaning is now known to be a key driver for the manipulation of
these traits, it is still a three month window. Greater precision would allow for targeted
manipulation of ewe nutrition to impact the traits. These traits may also be influenced
by in-utero growth as the association with weight inverts between birth and weaning.
Pre weaning: Zinc concentration and shear force are impacted by lamb growth during
this period.
Post weaning: ICDH activity is impacted by lamb growth during this period.
Arguably increased pre weaning growth leading to heavier lamb weights has a positive
impact on traits impacted in this period resulting in higher levels of intramuscular fat,
myoglobin and iron concentration, a reduction in shear force and meat browning. While
increased intramuscular fat with growth may become a consumer health issue in the
future its uncoupling from whole carcass adiposity using an ASBV would avoid large
visible layers of subcutaneous fat in lambs with increased intramuscular fat, minimising
the impact on visual appeal.
Associations between meat traits and lamb growth beyond 150 days were not
investigated in this study as the window for greatest changed was in the pre weaning
period for most traits. Other traits related to meat quality which are likely to be
influenced later in life, such as muscle glycogen concentration, would benefit for
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investigation of associations later in life. Due to a lack of bias, random effects models
can be used to estimate growth later in life, despite a reducing proportion of animals
having weights recorded after the post weaning time point.
Environment had the largest effect on most traits and in general this was the same or
larger than the impact of growth on traits. Therefore, growth impacted most traits
however was not a large driver of the traits relative to the magnitude of environment,
although it had a larger effect than some production factors such as sex or sire type.
This warrants further investigation.
Further investigation may also include the change in magnitude of the impact of
production factors on traits, e.g. birth type, after correction for growth.
8.14 Adjustments to experimental design
Information Nucleus Flock Design
This thesis is based on information collected as part of the Information Nucleus Flock
experiment. The comprehensive design allows the assessment of production, phenotypic
and genetic effects (Fogarty et al., 2007; van der Werf et al., 2010) however there are
areas of the design that could be addressed differently. Ewe lambs from Maternal and
Merino progeny were retained so no slaughter information is available for these
animals. As a result sire type comparisons are only possible in wether progeny of
Merino dams where Terminal, Maternal and Merino sire types were represented
equally. Similarly it was only possible to compare dam breed effects within the
Terminal sired lambs as Border-Leicester x Merino dams were not used in the Merino
and Maternal sire type groups.
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Many analyses highlighted the large effect of site or rearing, reflecting environment, on
traits. Within the design of the Information Nucleus Flock it was not possible to
measure all factors contributing to the effect of environment however these could
include pasture availability and feed type, worm burden and weather conditions. If these
factors were known in detail the impacts of nutrition, disease and climate could be
teased apart from the generic environmental effect. Measures were taken to reduce bias
caused by these factors by balancing the sites for key factors of sire type and breeding
value impacts by ensuring a representation of sires across all sites.
Frequency of weight recording between birth and weaning
In this experiment live weight was infrequently measured between birth and weaning at
approximately 100 days. The lack of data available in this time reduced confidence in
the ability to make a good estimation of growth between these times so it was difficult
to characterise how the relationship between growth and traits such as intramuscular fat
and myoglobin concentration changed between birth and weaning. Therefore, a
mechanistic experiment where lambs on divergent growth paths were weighed
frequently, every 7-10 days, would help to characterise the associations between growth
and meat quality traits at slaughter.
Accounting for wool growth
When growth functions were fitted to lamb live weight data no adjustment was made
for the approximate wool weight at the time of measuring live weight. Likewise no
adjustment was made for the reduction in live weight at shearing due to the loss of
wood. The impact of wool weight on the fit of the growth function was expected to be
small, as wool weight is a small proportion of live weight, particularly when wool
length is short. Furthermore, the effect of wool weight would be captured, within small
232
groups, by the kill group effect. Therefore no adjustment was made in this study.
However, since it is possible to estimate the weight of wool during lamb growth, and
accounting for this may make a small improvement in the precision of the growth
function fit, this would be a consideration in future experiments.
8.15 Future studies
Curve fitting methodology
Random effects models offer significant advantages in terms of flexibility in the
estimation of lamb weights however it is based on linear functions. An improved
scenario would be a random effects model which utilises a nonlinear function so that the
curve parameters would have a simple biological interpretation. The usefulness of a
curve with this methodology has been expressed by various authors and to this end a
random effects model based on a nonlinear Brody function is being developed
subsequent to this thesis.
Estimated or recorded weights
In this thesis growth curves were used to estimate lamb weights rather than using the
measurements routinely collected in industry at weaning and post weaning. This was
undertaken as estimated weights are less influenced (within each animal) by factors that
cause large day to day fluctuations in weight, such as gut fill. However it would be
useful to compare the outcome of using estimated weights with routinely collected
measurements in industry. If the magnitude of the effect of growth on traits was similar
using routinely collected measurements then the additional effort required to derive
growth curves may be unnecessary.
233
Growth rates between birth and weaning
Growth had the greatest impact on several traits between birth and weaning. Isolating
the specific window during which growth most heavily impacts these traits will allow
producers to have more control over manipulation of these traits. For example, traits
which are heavily influenced by growth in early life could be manipulated through dam
nutrition or the use of the ASBV for birth weight, which has a magnitude of effect as
large, or larger, than most production effects. To achieve this it would be necessary to
perform more frequent weighing of lambs during the birth to weaning period.
234
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