Analyses of African Common Bean ( L.) Germplasm Using a SNP Fingerprinting Platform: Diversity, Quality Control and Molecular Breeding

Overview

Journal Genet Resour Crop Evol

Publisher Springer

Date 2019 Apr 9

PMID 30956400

Citations 16

Authors

Bodo Raatz

Clare Mukankusi

Juan David Lobaton

Alan Male

Virginia Chisale

Berhanu Amsalu

Deidre Fourie

Floride Mukamuhirwa

Kennedy Muimui

Bruce Mutari

Susan Nchimbi-Msolla

Stanley Nkalubo

Kidane Tumsa

Rowland Chirwa

Mywish K Maredia

Chunlin He

Affiliations

Soon will be listed here.

Abstract

Common bean ( L.) is an important staple crop for smallholder farmers, particularly in Eastern and Southern Africa. To support common bean breeding and seed dissemination, a high throughput SNP genotyping platform with 1500 established SNP assays has been developed at a genotyping service provider which allows breeders without their own genotyping infrastructure to outsource such service. A set of 708 genotypes mainly composed of germplasm from African breeders and CIAT breeding program were assembled and genotyped with over 800 SNPs. Diversity analysis revealed that both Mesoamerican and Andean gene pools are in use, with an emphasis on large seeded Andean genotypes, which represents the known regional preferences. The analysis of genetic similarities among germplasm entries revealed duplicated lines with different names as well as distinct SNP patterns in identically named samples. Overall, a worrying number of inconsistencies was identified in this data set of very diverse origins. This exemplifies the necessity to develop and use a cost-effective fingerprinting platform to ensure germplasm purity for research, sharing and seed dissemination. The genetic data also allows to visualize introgressions, to identify heterozygous regions to evaluate hybridization success and to employ marker-assisted selection. This study presents a new resource for the common bean community, a SNP genotyping platform, a large SNP data set and a number of applications on how to utilize this information to improve the efficiency and quality of seed handling activities, breeding, and seed dissemination through molecular tools.

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