生物
苗木
连锁不平衡
耐寒性
遗传学
人口
基因
遗传关联
全基因组关联研究
候选基因
数量性状位点
遗传变异
遗传连锁
植物育种
植物
植物遗传学
关联映射
园艺
表型
染色体
单核苷酸多态性
遗传分析
遗传变异
标记辅助选择
基因定位
冷应激
生物技术
农学
基因座(遗传学)
分子标记
遗传标记
拟南芥
棉属
作者
Aamir Ali Abro,Mubashir Abbas,Qiankun Liu,Jie Zheng,Yanchao Xu,Yuqing Hou,Zhongli Zhou,Rashid Iqbal,Fang Liu,Xiaoyan Cai
标识
DOI:10.1016/j.indcrop.2025.122164
摘要
Cold stress during the seedling emergence stage severely affects the growth and development of cotton ( Gossypium hirsutum ), leading to reduced yield and plant health. Despite its importance, the molecular mechanisms underlying cold tolerance in cotton remain poorly understood. In this study, we analyzed 302 cotton accessions from the Cotton Research Institute in Anyang, China, to assess phenotypic and genetic responses to cold stress. Statistical analysis revealed significant reductions in primary root length (PRL) under cold stress. Genome-wide association studies (GWAS) identified key genetic loci associated with cold tolerance, particularly on chromosome A11. Linkage disequilibrium (LD) analysis revealed high LD in this region, which was significantly associated with primary root length (PRL) under cold stress. Within this locus, we identified 137 candidate genes. Among these, Gh_A11G315100 ( GhPRL ) emerged as a key candidate for cold tolerance, exhibiting significantly higher expression under cold stress in cold-tolerant varieties compared to susceptible varieties. Virus-Induced Gene Silencing (VIGS) of GhPRL confirmed its essential role in maintaining plant health under cold stress, with GhPRL -silenced plants showing greater phenotypic damage, increased ion leakage, and reduced antioxidant activity. This study provides valuable insights into the genetic basis of cold tolerance in cotton and identifies GhPRL as a critical target for future breeding efforts aimed at enhancing cold resilience. • Phenotyping of 302 cotton accessions revealed substantial variation in primary root length under cold stress. • GWAS identified significant loci on chromosome A11, with SNPs linked to cold tolerance and PRL variation. • Population genetic analysis revealed evolutionary selection of GhPRL . • Functional validation confirmed the role of GhPRL in cold adaptation, making it a promising breeding target.
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