Artificial selection of mutations in two nearby genes gave rise to shattering resistance in soybean
Shuai Li, Weidong Wang, Lianjun Sun, Hong Zhu, Rui Hou, Huiying Zhang, Xuemin Tang, Chancelor B. Clark, Stephen A. Swarm, Randall L. Nelson, Jianxin Ma
Abstract
Resistance to pod shattering is a key domestication-related trait selected for seed production in many crops. Here, we show that the transition from shattering in wild soybeans to shattering resistance in cultivated soybeans resulted from selection of mutations within the coding sequences of two nearby genes - Sh1 and Pdh1. Sh1 encodes a C2H2-like zinc finger transcription factor that promotes shattering by repressing SHAT1-5 expression, thereby reducing the secondary wall thickness of fiber cap cells in the abscission layers of pod sutures, while Pdh1 encodes a dirigent protein that orchestrates asymmetric lignin distribution in inner sclerenchyma, creating torsion in pod walls that facilitates shattering. Integration analyses of quantitative trait locus mapping, genome-wide association studies, and allele distribution in representative soybean germplasm suggest that these two genes are primary modulators underlying this domestication trait. Our study thus provides comprehensive understanding regarding the genetic, molecular, and cellular bases of shattering resistance in soybeans. Resistance to pod shattering in crops is typically modulated by major loci each underpinned by a single gene. Here, the authors show that the transition from shattering in wild soybean to shattering resistance in cultivated soybean is underlain by selection of mutations within two neighboring genes.