AFLP Analysis of Gene Pools of a Wild Bean Core Collection

Tohmé, Joe; Gonzalez, Dolorez; Beebe, Steve; Duque, Myriam C.

doi:10.2135/cropsci1996.0011183x003600050048x

Cited by 241 publications

(192 citation statements)

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“…Typically, during domestication, important agronomic characters are selected which result in a genome-wide reduction of genetic diversity in the domesticates (Tanksley and McCouch 1997;Eyre-Walker et al 1998;Buckler et al 2001;Diamond 2002;Clark et al 2004;Papa et al 2007, Pozzi et al 2004Otero-Arnaiz et al 2005;Vasemagi et al 2005;Doebley et al 2006;Kilian et al 2007;Zhu et al 2007). Earlier studies in bean using DNA marker, protein and morphological variation, determined that domesticated landraces indeed contain a subset of the variability found in wild beans Debouck et al 1993;Kami et al 1995;Tohme et al 1996;Beebe et al 2001;Chacón et al 2005). Here we observed that the amount of variability/polymorphisms retained is similar to the diversity estimates found in wild types.…”

Section: A Model For Domestication In Common Beanmentioning

confidence: 99%

“…Two large gene pools of wild types were identified based on phaseolin seed protein variation Gepts 1990), DNA marker diversity (Becerra Velasquez and Gepts 1994;Sonnante et al 1994;Freyre et al 1996;Tohme et al 1996), morphology (Evans 1976;Gepts and Debouck 1991), isozymes (Koenig and Gepts 1989), mitochondrial DNA variation (Khairallah et al 1992) and amplified fragment length polymorphism (AFLP) (Rossi et al 2009) and short sequence repeats (SSR) ) marker data.…”

Section: Introductionmentioning

confidence: 99%

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Investigation of the domestication of common bean (Phaseolus vulgaris) using multilocus sequence data

Mamidi

Rossi

Annam

et al. 2011

Functional Plant Biol.

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Abstract. Multilocus sequence data collected from domesticated and related wild relatives provides a rich source of information on the effect of human selection on the diversity and adaptability of a species to complex environments. To evaluate the domestication history of common bean (Phaseolus vulgaris L.), multilocus sequence data from landraces representing the various races within the Middle American (MA) and Andean gene pools was evaluated. Across 13 loci, nucleotide diversity was similar between landraces and wild germplasm in both gene pools. The diversity data were evaluated using the approximate Bayesian computation approach to test multiple domestication models and estimate population demographic parameters. A model with a single domestication event coupled with bidirectional migration between wild and domesticated genotypes fitted the data better than models consisting of two or three domestication events in each genepool. The effective bottleneck population size was~50% of the base population in each genepool. The bottleneck began~8200 and 8500 years before present and ended at~6300 and~7000 years before present in MA and Andean gene pools respectively. Linkage disequilibrium decayed to a greater extent in the MA genepool. Given the (1) geographical adaptation bottleneck in each wild gene pool, (2) a subsequent domestication bottleneck within each gene pool, (3) differentiation into gene-pool specific races and (4) variable extents of linkage disequilibrium, association mapping experiments for common bean would more appropriately be performed within each genepool.

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Section: A Model For Domestication In Common Beanmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Investigation of the domestication of common bean (Phaseolus vulgaris) using multilocus sequence data

Mamidi

Rossi

Annam

et al. 2011

Functional Plant Biol.

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“…Common beans have exceptionally wide genetic variation among four gene pools and many races (Tohme et al 1996;Beebe et al 2001) two of which form the focus of sequencing work performed by Mamidi et al (2011). Reflecting this diversity, the CIAT maintains a primary gene bank with more than 36 000 accessions providing raw material for improving the crop using traditional breeding and molecular marker approaches.…”

Section: The Workhopmentioning

confidence: 99%

Why not beans?

Cavalieri

Merchant

Volkenburgh

2011

Functional Plant Biol.

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Abstract. Changes in climate and urbanisation rapidly affecting human livelihood are particularly threatening to developing nations in tropical regions. Food production crises have focused the global development agenda on agricultural research, a proven approach for increasing crop yield. A few crops benefit from private investment, but improvement of most crops will rely on limited public funding that must be deployed strategically, pushing forward both proven approaches and new ideas. Why not invest in beans? More than 300 million people rely on this crop, considered to be the most important grain legume for human consumption. Yet the yield of beans, especially in poor regions or marginal soils, is reduced by abiotic stresses such as phosphorus deficiency, aluminum toxicity and especially drought. Is it possible to assemble resources, including genetic diversity in beans, breeding expertise, genomic information and tools, and physiological insight to generate rapid progress in developing new lines of beans more tolerant to abiotic stress? A workshop to address this question was held in November 2010 at the International Center for Tropical Agriculture (CIAT) in Colombia. The resulting 'call to action' is presented in this issue which also includes research papers focused on tolerance of beans to stress.

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“…Polimorfismos de DNA amplificado ao acaso (RAPD), assim como outros marcadores de DNA, como RFLP (polimorfismos de comprimento de fragmentos de restrição) e AFLP (polimorfismos de comprimento de fragmentos amplificados) têm sido utilizados para medir a diversidade genética entre e dentro de espécies de microrganismos e plantas, incluindo o feijoeiro (Berkum et al, 1996;Tohme et al, 1996;Vasconcelos et al, 1996). Marcadores RAPD, pela sua simplicidade técnica e capacidade em detectar diferenças entre genótipos relacionados, são mais utilizados.…”

Section: Characterization Of the Genetic Diversity Of Common Beans Byunclassified

Caracterização da diversidade genética em feijão por meio de marcadores RAPD

Franco¹,

Cassini

Oliveira

et al. 2001

Pesq. agropec. bras.

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Resumo -Marcadores RAPD (Random Amplified Polymorphic DNA) foram usados para avaliar a diversidade genética entre 19 cultivares de feijão (Phaseolus vulgaris L.). Dos cento e oito locos de RAPD obtidos de 15 primers decâmeros, 70 foram polimórficos. Para estimar a distância genética foi usado o coeficiente de similaridade de Jaccard e as análises de agrupamento foram feitas pelos métodos UPGMA e Tocher. As análises de agrupamento confirmaram a ampla diversidade genética existente entre germoplasmas tropicais de feijão, separando as cultivares em dois grupos principais, correspondendo aos centros de domesticação Andino (genótipos de sementes médias e grandes) e Mesoamericano (genótipos de sementes pequenas). No grupo Andino, a diversidade genética relativa foi maior do que no Mesoamericano.Termos para indexação: Phaseolus vulgaris, marcadores genéticos, distância genética. Characterization of the genetic diversity of common beans by RAPD markersAbstract -RAPD (Random Amplified Polymorphic DNA) markers were used to evaluate the genetic diversity among 19 common bean (Phaseolus vulgaris L.) cultivars. Amplifications using 15 decamers primers revealed 108 RAPD loci, 70 of which were polymorphic. The relative genetic distance was estimated using the complement of Jaccard´s coefficient and grouping analyses were derived from UPGMA and Tocher. These two grouping analyses confirmed the broad genetic diversity among the common bean tropical germplasm, which was divided into two main groups. These groups correspond to the Andean (genotypes with medium and large size seeds) and Mesoamerican (genotypes with small seeds) domestication centers. The relative genetic diversity was greater among the Andean cultivars than that of the Mesoamerican cultivars.

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AFLP Analysis of Gene Pools of a Wild Bean Core Collection

Cited by 241 publications

References 0 publications

Investigation of the domestication of common bean (Phaseolus vulgaris) using multilocus sequence data

Investigation of the domestication of common bean (Phaseolus vulgaris) using multilocus sequence data

Why not beans?

Caracterização da diversidade genética em feijão por meio de marcadores RAPD

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