生物
等位基因
遗传学
适应(眼睛)
人口
转录因子
基因
单核苷酸多态性
过氧化氢酶
稻属
水稻
突变体
基因组
分子育种
近交系
细胞生物学
清脆的
基因型
内含子
发起人
拉伤
抄写(语言学)
表型
作者
Xuanlin Gao,Shuaizu An,Zemin Ma,Mengyuan Chen,Wenya Xie,Ming Li,Feng Yu,Shiyou Lü,Lei Zhou,Aiqing You,Pingfang Yang,Yinggen Ke
摘要
Summary High temperature is a major environmental constraint that severely limits rice ( Oryza sativa ) growth, yield potential, and geographical adaptability. The molecular mechanisms underlying rice adaptation to warm climates remain poorly understood. By integrating population genomic data with multi‐scale phenotyping, we show that a single nucleotide polymorphism (SNP‐1456) in the promoter of the defense transcription factor WRKY53 determines rice thermotolerance and grain yield. The thermotolerant allele strengthens the binding of the membrane‐tethered NAC factor OsNTL3, which represses WRKY53 expression. Low WRKY53 derepresses catalase A ( CatA ), thereby lowering hydrogen peroxide (H 2 O 2 ) levels. CRISPR knockout of WRKY53 boosts seed set and increases yield under field heat waves. Environmental‐cline analysis of 4315 accessions reveals that the thermotolerant allele of WRKY53 is predominantly distributed in low‐latitude regions with warm climates. Our findings reveal a previously uncharacterized WRKY53 ‐centered regulatory network that mediates thermotolerance and facilitates rice adaptation to warm environments, offering promising targets for molecular breeding of climate‐resilient rice varieties.
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