Interspecific Common Bean Population Derived from Using a Bridging Genotype Demonstrate Useful Adaptation to Heat Tolerance

Overview

Journal Front Plant Sci

Date 2023 Jun 9

PMID 37293677

Authors

Sergio Cruz

Juan Lobaton

Milan O Urban

Daniel Ariza-Suarez

Bodo Raatz

Johan Aparicio

Gloria Mosquera

Stephen Beebe

Affiliations

Soon will be listed here.

Abstract

Common bean ( L.) is an important legume crop worldwide and is a major nutrient source in the tropics. Common bean reproductive development is strongly affected by heat stress, particularly overnight temperatures above 20°C. The desert Tepary bean ( A. Gray) offers a promising source of adaptative genes due to its natural acclimation to arid conditions. Hybridization between both species is challenging, requiring embryo rescue and multiple backcrossing cycles to restore fertility. This labor-intensive process constrains developing mapping populations necessary for studying heat tolerance. Here we show the development of an interspecific mapping population using a novel technique based on a bridging genotype derived from , and named VAP1 and is compatible with both common and tepary bean. The population was based on two wild accessions, repeatedly crossed with Mesoamerican elite common bush bean breeding lines. The population was genotyped through genotyping-by-sequencing and evaluated for heat tolerance by genome-wide association studies. We found that the population harbored 59.8% introgressions from wild tepary, but also genetic regions from , a relative represented in some early bridging crosses. We found 27 significative quantitative trait loci, nine located inside tepary introgressed segments exhibiting allelic effects that reduced seed weight, and increased the number of empty pods, seeds per pod, stem production and yield under high temperature conditions. Our results demonstrate that the bridging genotype VAP1 can intercross common bean with tepary bean and positively influence the physiology of derived interspecific lines, which displayed useful variance for heat tolerance.

Citing Articles

Genetic differentiation of a southern Africa tepary bean (Phaseolus acutifolius A Gray) germplasm collection using high-density DArTseq SNP markers.

Mwale S, Shimelis H, Abincha W, Nkhata W, Sefasi A, Mashilo J PLoS One. 2023; 18(12):e0295773.

PMID: 38096255 PMC: 10721083. DOI: 10.1371/journal.pone.0295773.

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