35
Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville, MD

Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

  • View
    214

  • Download
    0

Embed Size (px)

Citation preview

Page 1: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Genetic Selection Tools in the Genomics Era

Curt Van Tassell, PhDBovine Functional Genomics Laboratory & Animal Improvement Programs LaboratoryBeltsville, MD

Page 2: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Outline

Background– Genetic Evaluations– Quantitative Genetics– Genomics

Integrating Genetics and Genomics Case Study: DGAT1 Tangent: Animal Identification Crystal Ball Conclusions

Page 3: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Background

Bovine Functional Genomics Laboratory (BFGL)– Structural and functional genomics of cattle– Emphasis on health and productivity– Bioinformatics (storage and use of genomic data)

Animal Improvement Programs Laboratory (AIPL)– “Traditional” genetic improvement of dairy cattle– Increasing emphasis on animal health and reproduction

Page 4: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Traditional Selection Programs

Estimate genetic merit for animals in a population

Select superior animals as parents of future generations

Page 5: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Genetic Evaluation System

Traditional selection has been very effective for many economically important traits

Example: Milk yield– Moderately heritable– ~30 million animals evaluated 4x/yr– Uses ~70 million lactation records– Includes ~300 million test-day records– Genetic improvement is near theoretical

expectation

Page 6: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Dairy Cattle Genetics Success

-6000

-4000

-2000

0

2000

1960 1970 1980 1990 2000

Year of Birth

BV

Milk

Cows Bulls

Page 7: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Dairy Cattle Genetics Industry Cooperation

Producer

DHIA/DRPC PDCA

NAAB

AIPL

Producer

DHIA/DRPC PDCA

NAAB

AIPL

Page 8: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Genomics - Introduction

Traditional dairy cattle breeding has assumed that an infinite number of genes each with very small effect control most traits of interest

Logical to expect some “major” genes with large effect; these genes are usually called quantitative trait loci (QTL)

The QTL locations are unknown! Genetic markers can provide information about

QTL

Page 9: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Genetic Markers Allow inheritance of a region

of the genome to be followed across generations

Single nucleotide polymorphisms (SNiP) are the markers of the future!

Need lots!– 3 million in the genome– 10,000 initial goal

Polymorphism“poly” = many “morph” = form

General

population 94%

6%

Single nucleotide

polymorphism

(SNP)

Page 10: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Application of Genetic Markers

1. Identify genetic markers or polymorphisms in genes that are associated with changes in genetic merit

2. Use marker assisted selection (MAS) or gene assisted selection (GAS) to make selection decisions before phenotypes are available

3. Adjust genetic merit for markers or genes in the genetic evaluation system

Page 11: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

QTL Identification

Genetic

Merit

DNA

Data

Page 12: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Compare GeneticMerit

QTL Identification and Marker Assisted Selection

3.51.7 -0.1 -2.5 -6.20.7

Page 13: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Gene Assisted Selection

Page 14: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Marker or Gene Assisted Selection

Largest benefits are for traits that:– have low heritability, i.e., traits where genetics contribute a

small fraction of observed variation (e.g., disease resistance and fertility)

– are difficult or expensive to measure (e.g., parasite resistance )

– cannot be measured selection decision needs to be made (e.g., milk yield and carcass characteristics)

Evolution in traditional selection program by improving estimation of genetic merit

Page 15: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Example: DGAT1

DGAT1: diacylglycerol acyltransferase– Enzyme involved in fat sythesis– Identified using

Genetic marker dataModel organism (mouse) gene function

information Cattle sequence verified candidate gene

Page 16: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

DGAT1

Two forms of the gene in cattle– M = high milk (low fat) form of gene– F = high fat (low milk) form gene

BFGL scientists decided to characterize the gene in North American population– Over 3300 animals genotyped for DGAT1 SNP– Approximately 2900 genotypes verified and used

in these analyses

Page 17: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

DGAT1 – Average Differencesin Daughters of Bulls

Trait MM-FF Trait MM-FFMilk lbs 361 Fat% 0.13

Fat lbs 16.5 Protein% 0.02

Protein lbs 5.0 NM$ $24

SCS 0.05 CM$ $35

PL 0.07 FM$ $4

DPR 0.21

Page 18: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

DGAT1 Genotypic Frequencies

Page 19: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Integrating Genomics Results

Genes will likely account for a fraction of the total genetic variation

Cannot select solely on gene tests!!

Page 20: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Integrating Genomic Data:An Ideal Situation!

Bull PTA

Page 21: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Integrating Genomic Data: The DGAT1 NM$ Situation!

Bull PTA NM$

MM

FF

Page 22: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Integrating Genomic Data: The DGAT1 Fat Situation!

Bull PTA Fat

MM

FF

Page 23: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Integrating Genomics Results

Combine information– Ideally would incorporate genomic data into

genetic evaluation system Adjust PTA??

– Don’t adjust well proven animals (it’s in there!!)– Adjust parent average for flush mates

– Progeny have identical parent averages– Adjusting other PTA is non-trivial!

Page 24: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Integrating Genomic Data: Another view of DGAT1 NM$!

Bull PTA NM$

MM

FF

Page 25: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

And it Really Works! Recent German study evaluated impact on adjusting

historic parent averages (PA) for DGAT1 and evaluated impact of predictability of future evaluations

Correlations of original PA with eventual PTA for milk were 45%

Correlations of adjusted PA with eventual PTA for milk were 55% (10% gain)

Incorporation of genomic data will result in increased stability of evaluations

Page 26: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Genetic Evaluations - Limitations

Slow!– Progeny testing for production traits take 3 to 4

years from insemination– A bull will be at least 5 years old before his first

evaluation is available Expensive!

– Progeny testing costs $25,000 per bull– Only 1 in 8 to 10 bulls graduate from progeny test– At least $200,000 invested in each active bull!!

Page 27: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Genetic Evaluations:Genomics Enhancements

Faster– Use of gene and marker tests allow preliminary

selection decisions beyond parent average before performance and progeny test data are available

Cheaper– Improved selection decisions should result in

higher graduation rates or enhanced genetic improvement

Page 28: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

How do we get there

Increase number of genetic markers Continue QTL discovery for MAS/GAS Better characterize the genome

– Compare genome to well characterized human and mouse genome

Page 29: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Bovine Genome Sequence

Page 30: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Bovine Genome Sequence Inbred Hereford is primary animal being

sequenced Genome size is similar to humans Sequencing about half completed First assembly released yesterday!!

– 2.3 of 2.8 billion base pairs– 84% coverage

L1 Dominette 01449

Page 31: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Bovine Genome Sequence Six breeds selected for low

level sequencing Holstein and Jersey cows

represent dairy breeds Useful for SNP marker

development Expect 3 million SNPs in the

genome Preliminary goal is to

characterize 10,000

Wa-Del RC Blckstr Martha-ET

Mason Berretta Jenetta

Page 32: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Genomic Tools for Parentage Verification

Low-cost high-throughput SNP marker tests would facilitate parentage verification and traceability

$10 to $20 per sample seems to be a common break point Progeny test herds would likely be early adopters

– Support from studs? Results in increased stability on first proofs?

– Nearly impossible to make mistake on parentage– Punished on second crop proofs?

With widespread implementation– Increase effective heritability– Decrease evaluation variability– Enhanced genetic improvement

Page 33: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Crystal Ball (Wishful Thinking?)

Large number of validated genetic tests available

Large amounts of marker and gene data publicly available

Genomic data incorporated into genetic evaluation

Management decisions facilitated by genomics data

Page 34: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Considerations in Genomic Tests

How big is the effect?– Traits of interest, economic index (NM$, TPI, PTI)– How many genetic standard deviation units?

Has this been validated by a sufficiently large independent study?

What correlated response is expected & observed? What are allele frequencies? What is the value of this test?

– not simple to answer

Page 35: Genetic Selection Tools in the Genomics Era Curt Van Tassell, PhD Bovine Functional Genomics Laboratory & Animal Improvement Programs Laboratory Beltsville,

Conclusions

Genomics is enhancing genetic improvement DGAT1 has large impacts on milk, fat,

protein, SCS Genetic tests need to be weighted

appropriately for optimal selection decisions Genomic tools will be extremely powerful for

parentage verification and traceability– Could impact genetic evaluations