TT2 通过 SCT1 依赖途径调控蜡质生物合成从而控制水稻的耐热性。

TT2 controls rice thermotolerance through SCT1-dependent alteration of wax biosynthesis.

机构信息

National Key Laboratory of Plant Molecular Genetics, CAS Centre for Excellence in Molecular Plant Sciences and Collaborative Innovation Center of Genetics and Development, Shanghai Institute of Plant Physiology and Ecology, Chinese Academy of Sciences, Shanghai, China.

University of the Chinese Academy of Sciences, Beijing, China.

出版信息

Nat Plants. 2022 Jan;8(1):53-67. doi: 10.1038/s41477-021-01039-0. Epub 2021 Dec 30.

DOI:10.1038/s41477-021-01039-0

PMID:34992240

Abstract

Global warming threatens crop production. G proteins mediate plant responses to multiple abiotic stresses. Here we identified a natural quantitative trait locus, TT2 (THEROMOTOLERANCE 2), encoding a Gγ subunit, that confers thermotolerance in rice during both vegetative and reproductive growth without a yield penalty. A natural allele with loss of TT2 function was associated with greater retention of wax at high temperatures and increased thermotolerance. Mechanistically, we found that a transcription factor, SCT1 (Sensing Ca Transcription factor 1), functions to decode Ca through Ca-enhanced interaction with calmodulin and acts as a negative regulator of its target genes (for example, Wax Synthesis Regulatory 2 (OsWR2)). The calmodulin-SCT1 interaction was attenuated by reduced heat-triggered Ca caused by disrupted TT2, thus explaining the observed heat-induced changes in wax content. Beyond establishing a bridge linking G protein, Ca sensing and wax metabolism, our study illustrates innovative approaches for developing potentially yield-penalty-free thermotolerant crop varieties.

摘要

全球变暖威胁作物生产。G 蛋白介导植物对多种非生物胁迫的反应。在这里，我们鉴定了一个自然数量性状位点 TT2（耐热性 2），它编码一个 Gγ亚基，在营养生长和生殖生长过程中赋予水稻耐热性，而不会降低产量。具有 TT2 功能丧失的天然等位基因与高温下蜡质的保留增加和耐热性的提高有关。从机制上讲，我们发现转录因子 SCT1（感受 Ca 转录因子 1）通过 Ca 增强与钙调蛋白的相互作用来解码 Ca，并作为其靶基因（例如 Wax Synthesis Regulatory 2（OsWR2）的负调节剂。钙调蛋白-SCT1 相互作用被破坏 TT2 引起的减少的热触发 Ca 减弱，从而解释了观察到的蜡质含量的热诱导变化。除了建立连接 G 蛋白、Ca 感应和蜡质代谢的桥梁外，我们的研究还说明了开发潜在无产量损失耐热作物品种的创新方法。

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TT2 通过 SCT1 依赖途径调控蜡质生物合成从而控制水稻的耐热性。

TT2 controls rice thermotolerance through SCT1-dependent alteration of wax biosynthesis.

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