Genetic variability and association of yield and yield components among bread wheat genotypes under drought-stressed conditions

Yared Semahegn, H. Shimelis, M. Laing, I. Mathew
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引用次数: 5

Abstract

Drought is one of the major constraints to wheat production and productivity globally. Developing drought-adapted wheat cultivars is paramount to increase wheat productivity under variable rainfall conditions. Understanding the genetic variability and trait association is key to the development of improved wheat cultivars. The objective of this study was to determine the extent of the genetic parameters and associations of yield and yield components of bread wheat genotypes, in order to design appropriate breeding strategies for yield improvement in wheat. One hundred and twenty genotypes were evaluated at five test sites in the 2018/19 cropping season using a 10 x 12 alpha lattice design with two replications. Different sowing dates were used to impose contrasting drought stress levels based on the onset of the main seasonal rains at each site. Data were recorded on agronomic traits such as days to heading (DH), days to maturity (DM), plant height (PH), spike length (SL), spikelet per spike (SS), kernel per spike (KS), 1000 kernel weight (TKW) and grain yield (GY). There was significant (p<0.01) genetic variation for all agronomic traits studied under both drought-stressed and non-stressed conditions. The highest estimates for genetic variance were obtained for DH (54.0%), followed by SL (38.3%). The high heritability estimated for DH (94.4%), SL (90.2%) and SS (85.2%), coupled with a high rate of genetic advance, suggest that direct selection for these traits would be effective under drought-stressed conditions. GY exhibited low genetic advance (9%) and heritability (41.5%) estimates, which were concomitant with its polygenic and complex inheritance pattern. Correlation and path analyses revealed that TKW was the most important contributing trait for improving grain yield under drought-stressed conditions
干旱胁迫条件下面包小麦基因型的遗传变异及产量和产量成分的关联
干旱是全球小麦生产和生产力的主要制约因素之一。发展适应干旱的小麦品种对提高可变降雨条件下的小麦产量至关重要。了解小麦的遗传变异和性状关联是开发小麦良种的关键。本研究的目的是确定面包小麦基因型的遗传参数及其产量和产量组成部分的关联程度,以便设计适当的育种策略以提高小麦产量。采用10 × 12 α晶格设计,2个重复,在2018/19种植季的5个试验点对120个基因型进行了评估。根据每个站点主要季节性降雨的开始,使用不同的播种日期来施加不同的干旱胁迫水平。记录了抽穗期(DH)、成熟期(DM)、株高(PH)、穗长(SL)、穗粒数(SS)、穗粒数(KS)、千粒重(TKW)和籽粒产量(GY)等农艺性状。干旱胁迫和非干旱胁迫条件下,各农艺性状遗传变异均极显著(p<0.01)。遗传变异估计最高的是DH(54.0%),其次是SL(38.3%)。DH(94.4%)、SL(90.2%)和SS(85.2%)的遗传率较高,加上遗传进阶率较高,表明这些性状的直接选择在干旱胁迫条件下是有效的。遗传超前(9%)和遗传力(41.5%)较低,这与其多基因和复杂的遗传模式有关。相关分析和通径分析表明,TKW是干旱条件下提高粮食产量最重要的贡献性状
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