Emerging strategies to improve heat stress tolerance in crops

IF 5 4区农林科学 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY aBIOTECH Pub Date : 2025-01-24 DOI:10.1007/s42994-024-00195-z

Jiawei Xiong, Hao Wang, Zhaohui Zhong, Shigui Li, Peng Qin

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Abstract

The heat stress (HS) response in plants involves complex processes at the molecular, cellular, and whole-organism levels. Sensitivity to HS differs based on the species and developmental stage of the plant, making it challenging to define HS and its impacts. Efforts to enhance HS tolerance by traditional breeding are constrained by limited genetic resources, but understanding the mechanisms that regulate HS responses can enable efforts to improve heat tolerance by precision breeding and gene editing. Here, we review recent research on the effects of HS on major cereal crops at different developmental stages and identify key genes potentially involved in the HS response, offering insight for precision molecular breeding. Additionally, we discuss the use of favorable natural variants and gene editing to improve crop tolerance to HS, emphasizing the value of alleles involved in thermomemory, combined stress tolerance, and the stress response–growth balance. This review aims to summarize recent advancements in understanding HS responses in crops, highlighting potential avenues for generating heat-tolerant crops.

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提高作物抗热胁迫能力的新策略

植物的热胁迫（HS）反应涉及分子、细胞和整个生物体水平的复杂过程。植物对HS的敏感性因物种和发育阶段的不同而不同，这使得HS的定义及其影响具有挑战性。通过传统育种提高高温耐受性的努力受到遗传资源有限的限制，但了解高温反应的调节机制可以通过精确育种和基因编辑提高耐热性。本文综述了高温胁迫对不同发育阶段主要谷物作物影响的最新研究进展，并确定了可能参与高温胁迫应答的关键基因，为精准分子育种提供参考。此外，我们讨论了利用有利的自然变异体和基因编辑来提高作物对高温胁迫的耐受性，强调了参与温度记忆、组合胁迫耐受性和胁迫响应-生长平衡的等位基因的价值。本文综述了作物对高温胁迫反应的最新研究进展，并重点介绍了培育耐热作物的潜在途径。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

aBIOTECH

CiteScore

7.70

自引率

2.80%

发文量