Abstract
Successful seedling establishment depends on the optimum depth of seed placement especially in drought-prone conditions, providing an opportunity to exploit subsoil water and increase winter survival in winter wheat. Coleoptile length is a key determinant for the appropriate depth at which seed can be sown. Thus, understanding the genetic basis of coleoptile length is necessary and important for wheat breeding. We conducted a genome-wide association study (GWAS) using a diverse panel of 298 winter wheat genotypes to dissect the genetic architecture of coleoptile length. We identified nine genomic regions associated with the coleoptile length on seven different chromosomes. Of the nine genomic regions, five have been previously reported in various studies, including one mapped to previously known Rht-B1 region. Three novel quantitative trait loci (QTLs), QCL.sdsu-2AS, QCL.sdsu-4BL, and QCL.sdsu-5BL were identified in our study. QCL.sdsu-5BL has a large substitution effect which is comparable to Rht-B1's effect and could be used to compensate for the negative effect of Rht-B1 on coleoptile length. In total, the nine QTLs explained 59% of the total phenotypic variation. Cultivars ‘Agate’ and ‘MT06103’ have the longest coleoptile length and interestingly, have favorable alleles at nine and eight coleoptile loci, respectively. These lines could be a valuable germplasm for longer coleoptile breeding. Gene annotations in the candidate regions revealed several putative proteins of specific interest including cytochrome P450-like, expansins, and phytochrome A. The QTLs for coleoptile length linked to single-nucleotide polymorphism (SNP) markers reported in this study could be employed in marker-assisted breeding for longer coleoptile in wheat. Thus, our study provides valuable insights into the genetic and molecular regulation of the coleoptile length in winter wheat.
Highlights
Successful crop stand establishment is the first critical step for achieving a high yield potential (Rebetzke et al, 2007b; Rebetzke et al, 2014)
The objectives of this study were; (i) mapping QTLs that control the length of coleoptile by conducting genome-wide association analysis in a hard winter wheat panel of 298 winter wheat accessions; (ii) identifying single-nucleotide polymorphism (SNP) markers linked to QTLs for marker-assisted selection; (iii) identifying candidate genes located in the QTL regions
We evaluated if the seed source may have an impact on the coleoptile length by comparing the coleoptile length of two varieties from four different locations
Summary
Successful crop stand establishment is the first critical step for achieving a high yield potential (Rebetzke et al, 2007b; Rebetzke et al, 2014). In regions with dry soils and higher temperatures, deep seed placement ensures optimum temperature and moisture (Mahdi et al, 1998). Whereas genotypes having shorter coleoptiles may fail to emerge if sown too deep and result in a poor stand and eventually leading to production losses (Mahdi et al, 1998; Rebetzke et al, 2005; Rebetzke et al, 2007b). An increase in temperature affects coleoptile length negatively Such genotype*environmental interactions can be devastating on crop yield (Jame and Cutforth, 2004; Rebetzke et al, 2016). Extreme fluctuations in weather with changing climate necessitate an adjustment in the breeding programs towards developing crop varieties having longer coleoptiles to ensure better plant stands and establishment
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