期刊
MOLECULAR BREEDING
卷 41, 期 4, 页码 -出版社
SPRINGER
DOI: 10.1007/s11032-021-01222-3
关键词
GWAS; Heat tolerance; Emmer wheat; Genetic variation
资金
- Grains Research and Development Corporation [US00057, US00059, US00080, US00081]
- Generation Challenge Program, heat
Research on heat stress tolerance in wheat has shown that there is a complex interplay of multiple genes of minor effects influenced by the environment. By crossbreeding emmer wheat with hexaploid wheat, a diverse set of genotypes with heat tolerance traits have been identified. These genotypes showed significant phenotypic and genotypic variations, with some marker-trait associations (MTAs) having pleiotropic effects across different environments, including some new MTAs linked to the emmer genome. Genomic regions on specific chromosomes were identified as having a positive impact on grain yield and thousand kernel weight under heat stress, indicating potential for marker-assisted selection to improve heat tolerance in wheat.
Heat stress tolerance in plants is a complex trait controlled by multiple genes of minor effect which are influenced by the environment and this makes breeding and selection complicated. Emmer wheat (Triticum dicoccon Schrank) carries valuable diversity that can be used to improve the heat tolerance of modern bread wheat. A diverse set of emmer-based genotypes was developed by crossing emmer wheat with hexaploid wheat. These materials, along with their hexaploid recurrent parents and commercial cultivars, were evaluated at optimum (E1) and heat stressed (E2) sowing times in the field for three consecutive years (2014-2016). The material was genotyped using the Infinium iSelect SNP 90K SNP Assay. The phenotypic data were combined across years within each sowing time and best linear unbiased estimators calculated for each genotype in each environment. These estimates were used for GWAS analysis. Significant phenotypic and genotypic variation was observed for all traits. A total of 125 and 142 marker-trait associations (MTAs) were identified in E1 and E2, respectively. The highest number of MTAs were observed on the A genome (106), followed by the B (105) and D (56) genomes. MTAs with pleiotropic effects within and across the environments were observed. Many of the MTAs found were reported previously for various traits, and a few significant MTAs under heat stress were new and linked to emmer genome. Genomic regions identified on chromosomes 2B and 3A had a significant positive impact on grain yield under stress with a 7% allelic effect. Genomic regions on chromosomes 1A and 4B contributed 11% and 9% of the variation for thousand kernel weight (TKW) under heat stress respectively. Following fine mapping, these regions could be used for marker-assisted selection to improve heat tolerance in wheat.
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