Resequencing of Sweetpotato Germplasm Resources Reveals Key Loci Associated with Multiple Agronomic Traits

Overview

Journal Hortic Res

Publisher Oxford University Press

Date 2023 Jan 16

PMID 36643760

Authors

Shizhuo Xiao

Xibin Dai

Lingxiao Zhao

Zhilin Zhou

Lukuan Zhao

Pan Xu

Bingqian Gao

An Zhang

Donglan Zhao

Rui Yuan

Yao Wang

Jie Wang

Qinglian Li

Qinghe Cao

Affiliations

Soon will be listed here.

Abstract

Sweetpotato is an important crop that exhibits hexaploidy and high heterozygosity, which limits gene mining for important agronomic traits. Here, 314 sweetpotato germplasm resources were deeply resequenced, and 4 599 509 SNPs and 846 654 InDels were generated, among which 196 124 SNPs were nonsynonymous and 9690 InDels were frameshifted. Based on the Indels, genome-wide marker primers were designed, and 3219 of 40 366 primer pairs were selected to construct the core InDel marker set. The molecular ID of 104 sweetpotato samples verified the availability of these primers. The sweetpotato population structures were then assessed through multiple approaches using SNPs, and diverse approaches demonstrated that population stratification was not obvious for most Chinese germplasm resources. As many as 20 important agronomic traits were evaluated, and a genome-wide association study was conducted on these traits. A total of 19 high-confidence loci were detected in both models. These loci included several candidate genes, such as , and , which might be involved in anthocyanin metabolism, carotenoid metabolism, and leaf morphogenesis, respectively. Among them, and were first reported in sweetpotato. The variants in the promoter and the expression levels of were significantly correlated with flesh color (orange or not orange) in sweetpotato. The expression levels of were also correlated with leaf shape. These results will assist in genetic and breeding studies in sweetpotato.

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