Genome-wide association study of grain micronutrient concentrations in bread wheat

Abstract

Bread wheat (Triticum aestivum) is a staple food crop worldwide. The genetic dissection of important nutrient traits is essential for the biofortification of wheat to meet the nutritional needs of the world’s growing population. Here, 45,298 single-nucleotide polymorphisms (SNPs) from 55K chip arrays were used to genotype a panel of 768 wheat cultivars, and a total of 154 quantitative trait loci (QTLs) were detected for eight traits under three environments by genome-wide association study (GWAS). Three QTLs (qMn-3B.1, qFe-3B.4, and qSe-3B.1/qFe-3B.6) detected repetedly under different environments or traits were subjected to subsequent analyses based on linkage disequilibrium decay and the P-values of significant SNPs. Significant SNPs in the three QTL regions formed six haplotypes for qMn-3B.1, three haplotypes for qFe-3B.4, and three haplotypes for qSe-3B.1/qFe-3B.6. Phenotypic analysis revealed significant differences among haplotypes. These results indicated that the concentrations of several nutrient elements have been modified during the domestication of landraces to modern wheat. Based on the QTL regions, we identified 15 high-confidence genes, eight of which were stably expressed in different tissues and/or developmental stages. TraesCS3B02G046100 in qMn-3B.1 and TraesCS3B02G199500 in qSe-3B.1/qFe-3B.6 were both inferred to interact with metal ions according to the Gene Ontology (GO) analysis. TraesCS3B02G199000, which belongs to qSe-3B.1/qFe-3B.6, was determined to be a member of the WRKY gene family. Overall, this study provides several reliable QTLs that may significantly affect the concentrations of nutrient elements in wheat grain, and this information will facilitate the breeding of wheat cultivars with improved grain properties.