Browsing by Author "Juan C. Motamayor"

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    A computer simulation study on the number of loci and trees required to estimate genetic variability in cacao (Theobroma cacao L.)
    (2006) Cuauhtemoc Cervantes-Martinez; J. Steven Brown; Raymond Schnell; Juan C. Motamayor; Alan W. Meerow; Dapeng Zhang
    Current methods for measures of genetic diversity of populations and germplasm collections are often based on statistics calculated from molecular markers. The objective of this study was to investigate the precision and accuracy of the most common estimators of genetic variability and population structure, as calculated from simple sequence repeat (SSR) marker data from cacao (Theobroma cacao L.). Computer simulated genomes of replicate populations were generated from initial allele frequencies estimated using SSR data from cacao accessions in a collection. The simulated genomes consisted of ten linkage groups of 100 cM in length each. Heterozygosity, gene diversity and the F statistics were studied as a function of number of loci and trees sampled. The results showed that relatively small random samples of trees were needed to achieve consistency in the observed estimations. In contrast, very large random samples of loci per linkage group were required to enable reliable inferences on the whole genome. Precision of estimates was increased by more than 50% with an increase in sample size from one to five loci per linkage group or 50 per genome, and up to 70% with ten loci per linkage group, or equivalently, 100 loci per genome. The use of fewer, highly polymorphic loci to analyze genetic variability led to estimates with substantially smaller variance but with an upward bias. Nevertheless, the relative differences of estimates among populations were generally consistent for the different levels of polymorphism considered.
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    Genetic diversity and structure of farm and GenBank accessions of cacao (Theobroma cacao L.) in Cameroon revealed by microsatellite markers
    (2008) Ives Bruno M. Efombagn; Juan C. Motamayor; Olivier Sounigo; Albertus B. Eskes; Salomon Nyasse; Christian Cilas; Ray Schnell; Maria J. Manzanares-Dauleux; Maria Kolesnikova-Allen
    The genetic diversity of 400 accessions collected in cacao farms, 95 GenBank, and 31 reference accessions was analyzed using the 12 microsatellite markers. The GenBank and reference accessions were subdivided into 12 accession groups (AG) that belong to the traditional cacao genetic groups (GG) Lower Amazon Forastero (LA), Upper Amazon Forastero (UA), Trinitario, and Criollo (Cr). The 12-microsatellite loci revealed a total of 125 alleles, 113 of which were present in the farm accession group (FA). The within and between group variation for all AGs accounted respectively for 81% and 19% of the total molecular variation. The average Fis for the FAwas 0.15 suggesting a moderate level of inbreeding. Significant differences for the level of gene diversity were found between the farm (0.50), GenBank (0.42 to 0.62), and reference (0.10 to 0.60) AGs. Genetic differentiation among AGs was variable with Fst values varying between 0.14 and 0.57 for the different AGs. Analysis using a Bayesian model-based method showed the existence of a high level of admixture for the farm accessions group. The LA genes were most represented in the FA (54%), followed by UA (33%) and Cr (7%). The genes of LAwere also the most represented in the GenBank (48%), followed by UA (24%) and Cr (14%). Only 14% and 6% of the genes of the GenBank and farm accessions, respectively, could not be attributed to any of the reference GGs. The results suggest the predominating presence of LA genes in the Cameroon farm accessions and a high level of admixture, with apparent presence of genes of more than three GGs in most accessions. The traditional Trinitario types appear to have almost disappeared from farmers fields. The admixture must be the result of hybridization and recombination of these genes from the different GGs in seed gardens and in farmers’ fields. The use of selected farm accessions will depend on the GG that it belongs to and also on their level of heterozygosity. Further implications of the results for breeding and for introduction of new germplasm into the Cameroon GenBank are discussed.