Abstract
Dissecting the genetic basis of physiological and yield traits against tolerance to heat stress is an essential in wheat breeding programs to boost up the wheat yield for sustainable food security. Herein, a genome-wide association study (GWAS) was performed to reveal the genetic basis of heat tolerance using high-density Illumina 90K Infinium SNPs array through physiological and yield indices. These indices were phenotyped on a diverse panel of foreign and domestic genotypes of Pakistan, grown in normal and heat-stressed environments. Based on STRUCTURE analysis, the studied germplasm clustered into four sub-population. Highly significant variations with a range of moderate (58.3%) to high (77.8%) heritability was observed under both conditions. Strong positive correlation existed among physiological and yield related attributes. A total of 320 significant (-log10 P ≥ 3) marker-trait associations (MTAs) were identified for the observed characters. Out of them 169 and 151 MTAs were recorded in normal and heat stress environments, respectively. Among the MTA loci, three (RAC875_c103017_302, Tdurum_contig42087_1199, and Tdurum_contig46877_488 on chromosomes 4B, 6B, and 7B respectively), two (BobWhite_c836_422 and BS00010616_51) and three (Kukri_rep_c87210_361, D_GA8KES401BNLTU_253 and Tdurum_contig1015_131) on chromosomes 5A, 1B, and 3D at the positions 243.59cM, 77.82cM and 292.51cM) showed pleiotropic effects in studied traits under normal, heat-stressed and both conditions respectively. The present study not only authenticated the numerous previously reported MTAs for examined attributes but also revealed novel MTAs under heat-stressed conditions. Identified SNPs will be beneficial in determining the novel genes in wheat to develop the heat tolerant and best yielded genotypes to fulfill the wheat requirement for the growing population.
Highlights
Wheat is one of the staple crop in the world, high and stable yield in this crop is an essential goal for growing wheat
The 72.2% and 59.6% heritability values were noted for Days to heading (DH) and Days to maturity (DM) respectively under non-stressed conditions, while 70.1% and H2 = 61.6% respectively under heat stressed conditions
The canopy temperature at vegetative stage (CTV) was significantly associated with flag leaf area (FLA), Cell membrane thermo-stability (CMT), TGW and grain yield/plant (GYP) in both environments
Summary
Wheat is one of the staple crop in the world, high and stable yield in this crop is an essential goal for growing wheat. Wheat has an optimum day-time growing temperature due to cool season crop during reproductive development of 15 ̊C and for each degree Celsius more than optimal temperature a yield decrease of 3–4% were recorded [1]. The global average temperature is recorded, would increase at a rate of 0.18 ̊C every ten years [2]. Climate change is causing an increase in global average temperatures, and the more frequent occurrence of extreme weather events [3]. To develop the heat tolerant wheat genotype, it is necessary to explore desired alleles to use in breeding programs
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