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Hindawi Publishing CorporationInternational Journal of Forestry ResearchVolume 2010, Article ID 658396, 10 pagesdoi:10.1155/2010/658396
Research Article
Morphological Variation and Ecological Structure ofIroko (Milicia excelsa Welw. C.C. Berg) Populations acrossDifferent Biogeographical Zones in Benin
Christine Ouinsavi and Nestor Sokpon
Laboratoire d’Etudes et de Recherches Forestieres, Faculte d’Agronomie, Universite de Parakou, 123 Parakou, Benin
Correspondence should be addressed to Christine Ouinsavi, [email protected]
Received 17 March 2010; Revised 7 June 2010; Accepted 9 June 2010
Academic Editor: Marc D. Abrams
Copyright © 2010 C. Ouinsavi and N. Sokpon. This is an open access article distributed under the Creative Commons AttributionLicense, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properlycited.
Iroko (Milicia excelsa) is a commercially important timber tree species formerly known by local people in Benin. Because of thehighly attractive technological properties of its wood and its multipurpose uses, the species was subjected to intensive humanpressure. Apart from strong climate oscillation during the Pleistocene, human caused habitat fragmentation through continuousland clearing for agriculture, extensive forests exploitation and urbanization induced the occurrence of many isolated forest plotsand trees species among which Milicia excelsa trees. As fragmentation was proved to have deleterious effects on genetic diversitywithin a species and its morphological structure, it was of interest to investigate the current demographic, morphological andgenetic structure of M. excelsa before coming up with conservation strategies. In the current study, morphological variation andecological structure of M. excelsa populations were assessed in Benin using transect sampling method and multivariate analysesincluding principal component, cluster and canonical discriminant analyses. On the basis of morphological parameters, M. excelsaindividuals and populations were clustered into four and discrimination of groups indicated that most of variations were highlyrelated to edaphic factors and annual rainfall. Erratic diameter distribution was found for many populations although most ofthem showed bell shaped diameter distribution.
1. Introduction
Since habitat destruction and fragmentation are the majorcauses of species extinction [1]; this is the greatest con-servation crisis. Indeed, increasing human populations andattendant land-use intensification (e.g., cultivation, grazing,and urban development) resulted in the loss and subdivi-sion of native habitats, increasing species extinction rates,and lowered species diversity within managed ecosystems.Previous to that or concomitantly, several strong climateoscillations which occurred during the Pliocene affectedvegetation shape and species distribution all over the world.Indeed, the forest-savannah mosaic vegetation type observedin the Dahomey gap was reported by several authors as theresult of mid-Holocene marine transgression, followed bydrier and wetter climatic conditions successively [2–4]. Thisphenomenon could be referred to as natural habitat loss
in terms of changes in landscape composition that mighthave caused a proportional loss of individuals from thelandscape and to natural habitat fragmentation in terms ofadditional effects resulting from the configuration of habitat(reduction of habitat patch size and isolation of patches [5,6]). Adaptation of a species to these variations may producedifferent morphological and physiological characteristics,resulting in the development of ecotypes. In addition,such fragmentation of natural plant communities can havedeleterious effects on the genetic diversity within a speciesbecause there will be a decreasing in levels of gene flow,particularly over longer distances. The subsequent effects ofgenetic drift in small, isolated populations will lead to loss ofdiversity, leaving plants less able to adapt to changes in theirenvironment and ultimately increasing the risk of extinction[7]. Indeed, many species faced extinction given the currentrate of habitat loss and degradation [1, 8, 9].
2 International Journal of Forestry Research
Milicia excelsa (formerly Chlorophora excelsa) Welw C.C.Berg. commercially known as iroko, is from Moraceaefamily, Urticaceae order, Tracheophyta phylum, and planteaekingdom. It is a large deciduous tree up to 30–50 m height,with a diameter of 1.70–2 m, with high crown, umbrella-likeand growing from a few thick branches.
Iroko is a hardwood tree of great socioeconomical andcultural importance in Sub-Saharan Africa. It is a dioeciousspecies which occurs in a wide range of climatic and edaphicenvironment and adapts to various ecological conditions. InBenin, its natural range extends from the south to 10◦30′ Nand from east to west of the country. The species hasbeen submitted to its habitat destruction and fragmentationand human pressure through intensive logging and land-use practices. A recent study carried out on timber woodexploitation in Benin [10] revealed the almost nonexistencelumber of iroko in sawmills and wood markets. The remnantiroko trees are sparsely distributed across the landscape,either on farms and public places [11], or in sacred groves[12–15], owing their existence to traditional ethnobotanicpractices of conservation. Such a situation might haveaffected morphological structure of the populations.
This paper aims to assess ecological structure andmorphological variation in Milicia excelsa populations inBenin.
2. Methods
2.1. Population Samples. Milicia excelsa tree inventory wascarried out using a transect methods [16] modified fromthe Buckland et al.’s [17] plotless distance sampling methodfor estimating abundance of biological populations. Giventhat the remnant iroko trees are sparsely distributed acrossthe landscape and relict forest patches, ten transects wereused in order to cover as much as possible the species rangein Benin. Then, 500 m width transects with variable length,the minimum length being 50 km were laid across differentbiogeographical zones within the species natural distributionarea. Along those transects, all iroko trees were inventoriedand registered with the GPS (Global Positioning System). Atotal of 1,028 iroko trees were measured.
The recorded geographical coordinates were plotted ontoBenin map and twelve Milicia excelsa populations wereinferred from geographical distribution of iroko trees on themap (Figure 1 and Table 1).
2.2. Assessing Structural Characteristics of Iroko Populations.For each of the censured iroko tree, the diameter at thebreast height (DBH), the total height (TH), bole height (BH),and crown diameter (CD) were systematically measured. Thecrown diameter is an average diameter measured from thecrown projection circle on the ground when sun is at zenith.
DBH data were used to draw the diameter class distribu-tion of the species for each population. Stand basal area (G)were calculated using the formula: G = ∑
(πD2i )/4, where
Di is the DBH. In addition, trees number per hectare wasestimated using the simplified Buckland et al.’s [17] estimatorof density (D) expressed as D = n/2Lw, where n is the
number of recorded tree, L the total length of transect, and wis the strip width.
2.3. Morphometric Analysis. Eight morphometric param-eters were analyzed including bearing and architecturalparameters (diameter at the breast height, total height, boleheight, and crown diameter) and descriptive parameters ofthe tree’s organ (length and width of the leaf blade, thefruit, and the petiole [18]). The bearing and architecturalparameters were measured on all of the censured treeswhile organ descriptive parameters were measured on 10leaves and 10 flowers randomly collected from adult trees.A total of 1,880 leaves, 1,340 male flowers and 1,360 femaleflowers were measured (Table 1). Different ratios such asDBH/TH, DBH/BH, and DBH/CD were used to minimizethe effect of the unevenness age of trees. For leaves andflowers measurements, data were averaged over individualtree before undertaking the series of multivariate analysesusing appropriate procedures.
Principal component analysis (PCA) was performed onthe untransformed morphometric data using the correlationmatrix. Two populations were clearly separated, and thethird group composed of individuals from the remainingpopulations was subjected to a partial PCA using the samevariables.
2.4. Assessing Morphological Variation of Iroko Populationsand its Relationship with Environmental Factors. To evaluatethe importance of environmental factors in the morpho-logical variation of iroko population, rainfall data werecollected from ASECNA (Agence pour la Securite de laNavigation Aerienne) for the last thirty years and soilphysical and chemical characteristics were collected fromLSSE (Laboratoire des Sciences de Sol et de l’Eau) forcomment. PCA was performed on environmental dataincluding average rainfall (mm) and edaphic variablessuch as percentage of clay, silt, sand, Carbon, Nitrogen,C/N ratio, organic matter (MO), Ca, Mg, K, Na, totalexchangeable bases (TEB), and caption exchange capacity(CEC). Cluster analysis (CA) was performed to examinethe morphological similarity, at individual level, betweenthe twelve sampled populations. A total of 134 individuals,which were measured all at once for DBH, total height,leaf dimensions, and flower size, were clustered using PASTsoftware version 1.43 [19]. The measure of dissimilarity wasEuclidian distance and clustering methods was UnweightedPair-Group Method using Arithmetic Average (UPGMA).For all of the morphometric variables, Multivariate Analysisof Variance (MANOVA) was used to test for significance ofvariation among populations and among groups of popu-lations. Multiple regressions were carried out to correlatepatterns of populations’ differentiation to environmentalvariables. A Canonical Correspondence Analysis (CCA)was performed on the two sets of variables, the first setcontaining morphometric variables weighed in the principalcomponents (PC), and the second set composed of the mostPC weighed environmental variables. This is a direct gradientanalysis which incorporates both ordination and multiple
International Journal of Forestry Research 3
Table 1: Sample-size geographical locations and ecological characteristics of iroko populations sites.
PopulationsGeographical coordinates
Soil type Average rainfall (mm)Number of samples collected
Longitude (◦E) Latitude (◦N) MF FF Leaves Trees (DBH, H, CD)
Aplahoue 001◦50′42.6′′ 07◦05′06.4′′ S1 1,200–1,300 160 140 300 143
Bante 001◦58′06.6′′ 08◦13′49.2′′ S2 1,100–1,200 120 90 110 175
Basssila 001◦39′16.9′′ 09◦02′36.1′′ S2 1,200–1,300 90 120 120 131
Biro 002◦56′28.8′′ 09◦56′11.2′′ S2 900–1,100 130 110 120 60
Bohicon 002◦04′49.6′′ 07◦18′16.1′′ S1 1,200–1,300 80 130 130 21
Djougou 001◦26′04.8′′ 10◦07′27.4′′ S2 900–1,100 180 130 140 153
Ketou 002◦35′45.2′′ 07◦20′59.2′′ S1 and S3 1,200–1,300 90 80 90 23
Lokossa 001◦40′16.4′′ 06◦45′26.1′′ S1 and S3 1,200–1,300 140 150 270 144
Niaouli 002◦08′08.1′′ 06◦44′16.1′′ S1 and S3 1,200–1,300 80 90 130 23
Sakete 002◦35′34.8′′ 06◦37′05.2′′ S1 1,200–1,300 120 110 220 122
Save 002◦31′16.1′′ 08◦04′27.9′′ S2 1,100–1,200 60 90 90 16
Tamarou 002◦39′38.4′′ 09◦38′17.7′′ S2 900–1,100 90 120 160 19
Total 1,340 1,360 1,880 1,028
Male flowers (MF), female flowers (FF), diameter at breast height (DBH), Height (H) crown diameter (CD), ferralitic soil (S1), tropical ferruginous (S2),and vertisols (S3).
Table 2: Results from principal component analysis (PCA) ofmorphometric traits.
Axis1 Axis2
Coefficient Loading Coefficient Loading
DBH/TH −0.0047 0.2704 −0.0043 −0.1628
DBH/BH −0.0015 0.2206 0.0015 0.1508
DBH/CD −0.0002 −0.0579 0.0001 0.0203
LL 0.8943 0.9900 0.1142 0.0828
LW 0.4346 0.8927 −0.0250 −0.0337
MFL 0.0006 0.0163 −0.0090 −0.1700
MFW 0.0776 0.1209 0.9683 0.9882
FFL 0.0709 0.2380 0.2165 0.4759
FFW 0.0196 0.1849 −0.0422 0.2608
eigenvalue 9.551 27.387
%variance 63.841 4.097
Diameter at breast height (DBH), total height (TH), bole height (BH),crown diameter (CD), leaf length (LL), leaf width (LW), male flowers length(MFL), male flower width (MFW), female flowers length (FFL), and femaleflower width (FFW).
regression techniques to reveal the relationship betweentables of multivariate data [20, 21].
CCA ordination was done on standardized environ-mental variables. MANOVA and multiple regressions werecarried out using SPSS software. PCAs were performed usingPAST software version 1.43 [19] while CCA was performedusing CANOCO for Windows 4.0 [20].
3. Results
3.1. Principal Component Analysis and Morphological Vari-ation among Individuals. In principal component analysis,91.23% of morphological variation was explained by the firsttwo principal axes (Table 2). The first axis, with eigenvalue of9.55, explained 63.84% of total variation, and the second axis
explained 27.8% of variation with eigenvalue of 4.09. Mor-phological trait coefficient (i.e., eigenvectors) indicated thatleaf dimensions (length and width) and the ratio DBH/THwere the loading variables in the first axis while male flowerswidth and female flowers size (length and width) were theloaded variables onto the second principal axis. Along theprincipal component axis 1, most of individuals from Niaoulipopulation occupied the right side whereas the mixed groupdrew aside to the centre and the left side (Figure 2(a)). Thisfirst axis differentiated populations on the basis of treesheight and leaves width. Along the principal axis 2, mostof individuals from Save population occupied the middlelower part while the mixed populations were in the middlearound the central point. Partial PCA dispatched the mixedpopulations into two groups (Figure 2(b)).
3.2. Patterns of Morphological Variation among Iroko Popula-tions. Cluster analysis of iroko individuals revealed four clus-ters (Figure 3). The first cluster contained most of individualsfrom Niaouli population. The three others cluster were rathermixed with cluster 2 grouping most of individuals fromSave Aplahoue and Lokossa populations, cluster 3 mainlycomposed of individuals from populations Bohicon Banteand Sakete, and cluster 4 encompassing individuals fromDjougou, Bassila, Tamarou, Ketou, and Biro populations.Analysis of variance indicated significant morphologicalvariation among groups of populations (F = 12.28, df =133, P < .001). Population Niaouli which composed cluster1 has the highest leaves size (mean LL = 18.93, meanLW = 11.84) and showed highest height growth (averageDBH/TH = 0.022). Cluster 2 showed medium leaf size andheight growth (mean LL ranged from 15.69 to 16.69, meanLW ranged from 9.64 to 10.41, and Average DBH/TH =0.03). Cluster 3 has the smallest leaf size and lowest heightgrowth (mean LL varied from 12 to 13.16, mean LW from8.02 to 8.68, and mean DBH/TH varied from 0.064 to 0.085).Medium leaf size and low height growth were observed for
4 International Journal of Forestry Research
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Oueme
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People of Iroko
Iroko’s inventory
Figure 1: Milicia excelsa populations and their geographical location in Benin. Aplahoue (1), Lokossa (2), Niaouli (3), Sakete (4), Bohicon(5), Save (6), Ketou (7), Tamarou (8), Biro (9), Bassila (10), Djougou (11), and Bante (12).
populations in cluster 4 (Mean LL ranged from 13.04 to 14.9,average LW ranged from 7.35 to 7.50, and mean DBH/THvaried from 0.032 to 0.039) except Tamarou populationwhich has small leaf size (LL = 10.37, LW = 6.76). Almostall group of iroko populations produced similar femaleflowers in terms of flower size except populations Djougou,Tamarou, and Bassila from cluster 4 which showed shortestfemale flowers (Table 4).
3.3. Influence of Environmental Factors on MorphologicalVariation in Milicia excelsa. Principal component analysisbased on environmental variables revealed that the firsttwo principal components accounted for 80.36% of totalvariation (Table 3). The order of importance of the variousparameters in the first principal component was high (CEC,0.97; Mg and Ca, 0.96; Sand, −0.95; Na, 0.85; Clay, 0.80,and N, 0.59). This principal component, with eigenvalue of6.05 explained 65.11% of variation. Rainfall (−0.88) and Silt(0.59) were the variables loaded into the second component
which explained 15.25% of variation with eigenvalue of 1.41(Table 3).
Multiple linear regressions of morphological traits onenvironmental factors indicated that height growth in Miliciaexcelsa was moderately related to silt content in the soil andrainfall (Table 5) and highly but negatively related to Nacontent in the soil. Soil texture as clay, silt, and sand amountin soil appeared to be important factors for explainingleaf-size variation among iroko populations. Leaf-lengthvariation was dependent on soil chemical properties suchas N, Ca, Mg, Na, Mo, and CEC. Rainfall has moderate butsignificant influence on flowers-size variation.
CCA combining ordination and multiples regression ofmorphological traits on environmental variables confirmedthat rainfall and edaphic factors significantly affect morpho-logical variation in iroko populations (r = 0.92 and r =0.87, Table 6). Directions and influences of environmentalfactors (Figure 4) clearly indicate that variation in the irokoCluster 1 was explained by soil content of Na and rainfall,
International Journal of Forestry Research 5
Lok1
Lok2
Lok3 Lok4
Lok5 Lok6 Lok7 Lok8
Lok9 Lok10
Apl1 Apl2
Apl3
Apl4 Apl5 Apl6
Apl7
Apl8
Apl9
Apl10
Boh1
Boh2 Boh3
Boh4
Boh5
Boh6 Boh7
Boh8 Boh9
Boh10 Tam1
Tam2
Tam3
Tam4 Tam5
Tam6
Tam7
Tam8
Tam9 Tam10
Bir1 Bir2 Bir3 Bir4
Bir5
Bir6
Bir7 Bir8 Bir9
Bir10 Sak1
Sak2
Sak3
Sak4 Sak5
Sak6
Sak7
Sak8
Sak9
Sak10 bass1
bass2 bass3
bass4 bass5
bass6
bass7
bass8
bass9
bass10 djou1
djou2 djou3
djou4
djou5
djou6
djou7 djou8 djou9
djou10
Ban1
Ban2 Ban3
Ban4 Ban5
Ban6 Ban7
Ban8
Ban9
Ban10 ket1 ket2
ket3 ket4
ket5 ket6 ket7
ket8 ket9
ket10
save1
save2 save3
save4
save5 save6
save7
save8 save9
Niao1
Niao2
Niao3
Niao4
Niao5
Niao6 Niao7
Niao8
Niao9
Niao10
−0.1 0 0.1 0.2 0.3
−0.1
0
0.1
Axis 1
Axi
s2
(a)
Lok1
Lok2
Lok3
Lok4
Lok5
Lok6 Lok7
Lok8 Lok9
Lok10
Apl1
Apl2
Apl3
Apl4
Apl5
Apl6 Apl7
Apl8
Apl9
Apl10
Boh1
Boh2
Boh3
Boh4
Boh5
Boh6 Boh7
Boh8
Boh9 Boh10
Tam1
Tam2
Tam3
Tam4
Tam5
Tam6
Tam7
Tam8
Tam9
Tam10
Bir1
Bir2
Bir3
Bir4
Bir5
Bir6
Bir7
Bir8
Bir9 Bir10
Sak1
Sak2
Sak3
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Sak5 Sak6
Sak7
Sak8
Sak9
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bass1 bass2
bass3
bass4
bass5
bass6
bass7
bass8
bass9
bass10
djou1
djou2
djou3
djou4
djou5
djou6 djou7
djou8
djou9
djou10
Ban1 Ban2
Ban3
Ban4
Ban5
Ban6
Ban7
Ban8
Ban9 Ban10
ket1 ket2
ket3 ket4
ket5
ket6
ket7
ket8 ket9 ket10
−0.1 0 0.1 0.2
−0.1
0
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Axis 1
Axi
s2
0.2
(b)
Figure 2: Projection of individuals of Milicia excelsa in the space of the first and second principal components. Sak = Sakete; Ket = Ketou;Tam = Tamarou; Bir = Biro; Djo = Djougou; Bas = Bassila; Ban = Bante; Boh = Bohicon; Nia = Niaouli; Apl = Aplahoue; Lok = Lokossa; andSav = Save. A = first PCA and B = partial PCA.
67 70 71 69 72 68 73 74 66 42 22 23 24 25 26 27 28 4 12 13 40 36 14 15 18 16 17 20 19 41 5 8 6 7 9 3 21 56 58 57 59 60 61 64 62 63 29 31 30 32 33 34 35 127
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43 10 11 37 38 39 84 86 87 85 88 89 91 90
Cluster 1 Cluster 2 Cluster 3 Cluster 4
Figure 3: UPGMA cluster of Milicia excelsa individuals from twelve populations. 1–11 (Aplahoue), 12–20 (Lokossa), 21–28 (Save), 29–37(Sakete), 38–49 (Ketou), 50–62 (Bohicon), 63–80 (Niaouli), 81–92 (Tamarou), 93–102 (Biro), 103–118 (Bassila), 119–126 (Bante), and 127–134 (Djougou).
and to a lesser extend by the amount of clay, silt, and Nin soil. Morphological variation in cluster 2 (populationsof Save, Aplahoue, and Lokossa) and cluster 3 (populationsof Bohicon, Bante, and Sakete) was related to amount ofCa, Mg, and clay in the soil and to rainfall and soil’scaption exchangeable capacity. Sandy texture and amount oforganic matter in soil are the main factors which explainedmorphological variation in iroko cluster 4 (Figure 4).
3.4. Structural Characteristics of Milicia excelsa Populations.Milicia excelsa populations density varied from 1 stem/ha2
to 9 stems/ha (see Table 4). The highest average DBH valueswere recorded for Biro, Bohicon, Niaouli, Tamarou, andSave populations. Stand basal area ranged from 0.19 m2/hato 2.05 m2/ha. All of the iroko populations showed bell-shaped diameter class distribution except Bassila population(see Figure 5). They typically have fewer number of stem
6 International Journal of Forestry Research
Table 3: Results from principal component analysis (PCA) ofenvironmental data.
PC1 PC2
Coefficient Loading Coefficient Loading
Clay 0.327 0.805 −.400 0.476
Silt 0.195 0.483 0.498 0.599
Sand 0.388 0.954 0.051 0.060
N 0.013 0.592 −0.015 −0.336
M.O 0.192 0.481 0.105 0.127
Ca 0.392 0.964 0.121 0.144
Mg 0.389 0.960 0.063 0.075
Na −0.203 −0.847 −0.032 −0.064
Cat. 0.397 0.975 0.101 0.120
CEC 0.397 0.976 −0.028 −0.033
Rainfall −0.082 −0.201 −0.740 0.881
Eigenvalue 6.048 1.417
Variance (%) 65.112 15.252
Bohicon
Aplaho
SaveLokossa
SaketeBante
Djougou
Bassila
Biro
Tamarou
Ketou
Niaouli
−1
1
−1 1
N
CaClay
Rain fall
Na
M.O
MgCEC
Silt
Sand
Figure 4: CCA ordination diagram indicating the influence ofrainfall and edaphic factors on the morphological distribution ofiroko populations
in the smaller and larger diameter classes and more in theintermediate classes as observed for a well-thinned tree pop-ulation structure. Among these populations four (Tamarou,Save, Ketou, and Bohicon) showed an erratic structure withlarge gap in their class distribution. Population of Bassilafollows an inverted J shape curve with large number of smalltrees and small number of large trees.
4. Discussion
4.1. Morphological Variation in Milicia excelsa. Our resultsrevealed that height growth and leaf size showed morpholog-ical variation in the Milicia excelsa populations. These trends
were strongly influenced by environmental factors. Severalstudies have indicated that morphological variation is appar-ently the result of an adaptive response to the environment;for example, variation in growth traits and phonologicaltraits is associated with a latitudinal and altitudinal range[22, 23] or by contrasting climatic conditions [24]. Ourresults suggested that some characters were variable amongpopulations without showing any geographic trend. Theobserved trend of morphological variation made mentionof adaptation to the contrasting microedaphic conditionsprevailing for these groups and this was supported by thesignificant correlation with soil physicochemical characteris-tics. The greater discrimination power of adaptation microedaphic conditions compared to the geographical regionsof origin of accession in this study clearly indicated thegreater importance of environmental factors (soil texture,soil chemical characteristics, and annual rainfall) thangeographical location, in discriminating populations. Thiscorroborated the results of Carter et al. [25] who reportedthat water stress, together with soil nutritional deficiencies,have led to the development of adaptation aptitudes andhence morphological variation in trees populations. Similarresults were found on other plant families (e.g., Casas et al.[26] on Stenocereus stellatus in Central Mexico, Bruschi et al.[24] on Italian populations of Quercus petraea).
The variation observed in Milicia excelsa morphologicalstructure could indirectly reveal the consequences of naturalhabitat fragmentation and human pressure on ecosystemsand tree populations. Indeed, most of the individuals fromcluster 1 in this study (Niaouli population) which showedthe highest height growth and wider leaf size came froma region which harbors a typical humid semideciduousforest as a proof of its soil nutritional richness. In addition,majority of those sampled trees were from the protectedsite of a research centre, which has probably experiencedvarious soil fertilizations. Similarly, populations from cluster2 and 4 have most of their sampled trees being either theoldest one whose growth might have not been submitted torecent human pressure on ecosystems (Save population), ordwelling sites that benefited from positive consequences ofnatural fragmentations such as (i) humid forest vegetationtype and consequently soil type in Bassila and Djougouregion due to Atacora mountain and the phenomenon ofdense forest species eradiation, and (ii) eastern and westernextension of Lama depression which maintained edaphicmicro conditions in the surrounded areas in Aplahoueand Lokossa zones in the west and Ketou zone in theeast. This explanation is congruent with our CCA resultswhich indicated the amount of clay and silt, MO and CECas the main explanatory variables of variation in theseclusters. In this category, the inclusion of Tamarou and Biropopulations harbouring trees with moderate height growthand leaf size, could be explained by the extensive land useand intensive chemical fertilization of soils due to cottonculture in that region. To the contrary, the smallest leaf sizeand lowest height growth revealed by cluster 3 (Bohicon,Sakete, and Bante populations) could result from intensiveland use, lack of soil fertilization and absence of fallow.The flower-size variation observed among populations with
International Journal of Forestry Research 7
0
0.5
1
1.5
2
2.5
3
45 65 85 105 125 145
Diameter class (cm)
Nu
mbe
rof
indi
vidu
als
(Ni)
Tamarouy = −0.0458x2 + 0.6105xR2 = −0.7243
3.5
(a)
0
1
2
3
4
5
6
7
8
25 45 65 85 105 125 145
Diameter class (cm)N
um
ber
ofin
divi
dual
s(N
i)
Biroy = −0.0724x2 + 1.1125xR2 = 0.3567
(b)
0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
25 45 65 85 105
Diameter class (cm)
Nu
mbe
rof
indi
vidu
als
(Ni)
Djougouy = −0.1046x2 + 1.1725xR2 = 0.6388
(c)
0
2
4
6
8
12
15 35 55 75 95 115 135
Diameter class (cm)
Nu
mbe
rof
indi
vidu
als
(Ni)
Bassila10
y = 0.0426x2 − 1.3464x + 10.725R2 = 0.6978
(d)
0
2
4
6
8
10
12
15 35 55 75 95 115 135
Diameter class (cm)
Nu
mbe
rof
indi
vidu
als
(Ni) Bante y = −0.1557x2 + 1.8892x + 2
R2 = 0.4038
(e)
−40
−20
0
20
40
60
80
15 35 55 75 95 115 135
Diameter class (cm)N
um
ber
ofin
divi
dual
s(N
i)
Lokossa
y = −0.9935x2 + 10.856x + 20R2 = 0.5974
(f)
0
2
4
6
8
10
12
14
16
25 45 65 85 105 125
Diameter class (cm)
Nu
mbe
rof
indi
vidu
als
(Ni) Saketey = −0.3108x2 + 3.4882x
R2 = 0.5952
(g)
0
0.5
1
1.5
2
2.5
3
3.5
35 55 75 95 115
Diameter class (cm)
Nu
mbe
rof
indi
vidu
als
(Ni) Savey = −0.0219x2 + 0.476x
R2 = 0.2873
(h)
−10
−5
0
5
10
15
20
25
30
15 35 55 75 95 115 135
Diameter class (cm)
Nu
mbe
rof
indi
vidu
als
(Ni)
Aplahoue
y = −0.5779x2 + 7.536x − 5.7273R2 = 0.6095
(i)
0
2
4
6
8
10
12
35 55 75 95 115 135
Diameter class (cm)
Nu
mbe
rof
indi
vidu
als
(Ni)
Niaouli
y = −0.2389x2 + 2.657xR2 = 0.5392
(j)
0
1
2
3
4
5
6
15 35 55 75Diameter class (cm)
Nu
mbe
rof
indi
vidu
als
(Ni) Ketouy = −0.2132x2 + 1.727x
R2 = 0.1397
(k)
0
0.5
1
1.5
2
2.5
3
3.5
4
4.5
35 55 75 95 115 135
Diameter class (cm)
Nu
mbe
rof
indi
vidu
als
(Ni)
Bohicon
y = −0.0397x2 + 0.5829x
R2 = 0.0352
(l)
Figure 5: Diameter distribution of Milicia excelsa populations.
8 International Journal of Forestry Research
Table 4: Morphological variation of the twelve studied Milicia excelsa populations.
Populations DBH/TH DBH/BH DBH/CD LL LW MFL MFW FFL FFW D (Ni/ha) G (m2/ha)
Aplahoue 0.0296 b 0.0138 d 0.0677 f 15.943 d 9.755 d 8.844 a 0.5 a 4.555 b 1.8556 b 6.00 2.05
Bante 0.0636 d 0.0163 c 0.0476 c 13.16 b 8.68 c 9.511 a 0.5 a 4.733 b 2 b 1.00 0.19
Basssila 0.0399 c 0.0848 a 0.0323 a 14.46 c 7.44 b 11.5 c 0.65 c 6 c 2.36 c 1.00 0.70
Biro 0.0346 c 0.0892 a 0.0458 c 14.9 c 7.767 b 12.833 c 0.6 b 5.217 b 2.217 b 1.00 0.68
Bohicon 0.0661 d 0.0205 c 0.0667 f 12.377 b 8.022 c 9.6 b 0.7 c 4.789 b 1.933 b 2.00 0.35
Djougou 0.0348 c 0.0825 a 0.0406 b 14.043 c 7.957 b 8.886 a 0.533 b 3.057 b 1.686 a 1.00 0.46
Ketou 0.0320 c 0.0797 b 0.0512 d 13.043 c 7.357 b 9.071 a 0.514 b 4.871 b 2.071 b 1.00 0.24
Lokossa 0.0305 b 0.0147 d 0.0578 e 15.69 d 9.64 d 10.76 b 0.54 b 4.02 b 1.73 b 9.00 2.0
Niaouli 0.0222 a 0.0102 e 0.0516 d 18.933 e 11.844 e 14.2 d 0.66 b 5.98 b 1.8 b 2.00 1.25
Sakete 0.0854 e 0.0191 c 0.0635 e 12 b 8.2 c 12.5 c 0.56 b 5.357 b 2 b 2.00 0.89
Save 0.0292 b 0.0128 d 0.0457 c 16.867 d 10.417 d 12.667 c 0.578 b 3.833 b 2 b 1.00 0.57
Tamarou 0.0390 c 0.0902 a 0.0430 b 10.371 a 6.757 a 10.328 b 0.586 b 3.5 a 1.814 b 1.00 0.61
Diameter at breast height (DBH), total height (TH), bole height (BH), crown diameter (CD), leaf length (LL), leaf width (LW), male flowers length (MFL),male flower width (MFW), female flowers length (FFL), female flower width (FFW), and stand basal area (G).
Table 5: Coefficient of determination (R2) of the linear regressions of morphometric traits on environmental variables.
Clay Silt Sand N M.O Ca Mg Na CEC Rainfall
DBH/TH 0, 285 0, 532∗∗ 0, 053 0, 244 0, 250∗ 0, 235 0, 050 0, 620∗∗∗ 0, 159 0, 350∗
DBH/BH 0, 219 0, 092 0, 148 0, 379∗ 0, 058 0, 016 0, 027 0, 121 0, 027 0, 157
DBH/CD 0, 209 0, 369∗∗ 0, 169 0, 272∗ 0, 188 0, 033 0, 002 0, 426∗∗∗ 0, 017 0, 057
LL 0, 494∗∗ 0, 025 0, 488∗∗ 0, 579∗∗∗ 0, 376∗ 0, 545∗∗∗ 0, 626∗∗∗ 0, 386∗∗ 0, 637∗∗∗ 0, 089
LW 0, 037 0, 525∗∗ 0, 080 0, 287 0, 053 0, 036 0, 099 0,005 0, 068 0, 062
MFL 0, 137 0, 190 0, 252∗ 0, 002 0, 107 0, 285∗ 0, 201 0,192 0, 263∗ 0, 062
MFW 0, 013 0, 178 0, 086 0, 083 0, 034 0, 211∗ 0, 188∗ 0,148 0, 205∗ 0, 262∗∗
FFL 0, 259∗ 0, 030 0, 131 0, 028 0, 193 0, 004 0, 036 0,065 0, 015 0, 473∗∗∗
FFW 0, 080 0, 060 0, 073 0, 038 0, 197 0, 016 0, 038 0,063 0, 006 0, 220∗
Diameter at breast height (DBH), total height (TH), bole height (BH), crown diameter (CD), leaf length (LL), leaf width (LW), male flowers length (MFL),male flower width (MFW), and female flowers length (FFL), and female flower width (FFW). Significant level of the correlations are indicated by ∗(P < .05),∗∗(P < .01), and ∗∗∗(P < .001).
Table 6: Relationship among morphological variation in iroko populations and environmental factors, derived from CCA.
Axis EigenvaluePopulation-environment
correlations
Cumulative % varianceof
population-environmentrelations
Cumulative % varianceof population data
1 0.059 0.92 78.9 62.6
2 0.015 0.87 99.1 78.7
relation to annual rainfall made mention of development ofadaptation abilities to climatic conditions, although it couldbe related to genetic variation in Milicia excelsa populations.Indeed, Camussi et al. [27] have stated that human actionsand natural selection factors, by affecting morphologicaltraits related to adaptation of a population, could allowinterference with adaptation due to genetic distances fromquantitative traits.
4.2. Milicia excelsa Populations’ Structure and Temperamentof the Species. The stand density calculated for Miliciaexcelsa populations was low but in the range with thatreported by Peres and Baider [16] on Bertholletia excelsa
from line-transect censuses. The bell-shaped stem classdistribution exhibited by iroko populations supported thespecies temperament as light demanding species are knownto show such distribution. They are gap demanding fortheir regeneration and mortality is higher in earlier stageunder closed forest canopy [28–30]. Combining the speciestemperament and seeds dispersal pattern of iroko whichis a barochore (mature fruits are heavy and drop underthe mature trees [31]) and widely disseminated by bat(Eidolon helvum [32]), iroko is expected to show largenumber of seedling under parent tree but it did not, althoughinventoried trees are mostly in open areas (in fallow lands,on farm, etc.) and seedling are protected by traditional
International Journal of Forestry Research 9
ethnobotanic practices in Benin [11]. This adequate lightlevel and abundant Milicia fruits, but lower than predictedregeneration under and around iroko trees suggest thatsome factor or combination of factors limits successfulregeneration. Indeed, iroko female trees produce abundantfruit but the germination rate is low and decreases veryquickly. In addition, the bulk part of fruit found beneathiroko tree is rejecta pellets. According to Taylor et al. [32]the rejecta seeds have a very low percent germination becauseEidolon feeds on Milicia fruit by sucking to select the moreviable seeds, while immature, deformed or aborted seedsremain in the rejecta pellet. Thomas [33] examining Eidolonexcreta, found that its diet during migration was 88.8%Milicia fruits. Nichols et al. [34] reported that fruit fall washeavy beneath female Milicia, but seedlings are found insmall clumps, 150 m distanced away from supposed parenttrees, which represent sites at which birds or especially batsdefecated seeds.
The inverted J shaped curve show in Bassila populationclass distribution can be explained by the heavily selectivelogging activity in that region which creamed valuablespecies in term of tree size.
Combining the ecological structure of the remnantiroko populations and the abovementioned morphologicalvariation, it could be inferred that the current trend of thosepopulations mirrored back the adaptation of Milicia excelsato environmental changes due to its habitat destruction andfragmentation. However fragmentation might not induceonly occurrence of microvegetational and edaphic conditionsto which species has to adapt but also isolation of individualpopulations may have been causing decreasing of geneticvariability and genetic drift progressively moving towards adiscrete extinction of the species. Although morphologicaltraits and ecological structure are known to represent onlya small proportion of plants genome because there areinfluenced by environmental factors [35], morphologicalvariation, and spatial structure may have some genetic basiswhich could be useful for studies of the developmental mech-anisms of plant populations [26, 36]. Therefore, the resultsof this study raised urgent needs of genetic variation andpopulation structure assessment in Milicia excelsa species.
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