Dissecting the Genetic Basis of Local Adaptation in Soybean

Overview

Journal Sci Rep

Specialty Science

Date 2017 Dec 10

PMID 29222468

Citations 21

Authors

Nonoy B Bandillo

Justin E Anderson

Michael B Kantar

Robert M Stupar

James E Specht

George L Graef

Aaron J Lorenz

Affiliations

Soon will be listed here.

Abstract

Soybean (Glycine max) is the most widely grown oilseed in the world and is an important source of protein for both humans and livestock. Soybean is widely adapted to both temperate and tropical regions, but a changing climate demands a better understanding of adaptation to specific environmental conditions. Here, we explore genetic variation in a collection of 3,012 georeferenced, locally adapted landraces from a broad geographical range to help elucidate the genetic basis of local adaptation. We used geographic origin, environmental data and dense genome-wide SNP data to perform an environmental association analysis and discover loci displaying steep gradients in allele frequency across geographical distance and between landrace and modern cultivars. Our combined application of methods in environmental association mapping and detection of selection targets provide a better understanding of how geography and selection may have shaped genetic variation among soybean landraces. Moreover, we identified several important candidate genes related to drought and heat stress, and revealed important genomic regions possibly involved in the geographic divergence of soybean.

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