Department of Plant Molecular Biology and Biotechnology, Indira Gandhi Krishi Vidyalaya, Raipur, 492012, India.
PG Department of Botany, Seva Sadan's R. K. Talreja College of Arts, Science and Commerce, Ulhasnagar, 421003, India.
Plant Cell Rep. 2022 Mar;41(3):799-813. doi: 10.1007/s00299-021-02793-3. Epub 2021 Oct 21.
Climate-change-mediated increase in temperature extremes has become a threat to plant productivity. Heat stress-induced changes in growth pattern, sensitivity to pests, plant phonologies, flowering, shrinkage of maturity period, grain filling, and increased senescence result in significant yield losses. Heat stress triggers multitude of cellular, physiological and molecular responses in plants beginning from the early sensing followed by signal transduction, osmolyte synthesis, antioxidant defense, and heat stress-associated gene expression. Several genes and metabolites involved in heat perception and in the adaptation response have been isolated and characterized in plants. Heat stress responses are also regulated by the heat stress transcription factors (HSFs), miRNAs and transcriptional factors which together form another layer of regulatory circuit. With the availability of functionally validated candidate genes, transgenic approaches have been applied for developing heat-tolerant transgenic maize, tobacco and sweet potato. In this review, we present an account of molecular mechanisms of heat tolerance and discuss the current developments in genetic manipulation for heat tolerant crops for future sustainable agriculture.
气候变化引起的温度极端升高已成为植物生产力的威胁。热应激引起的生长模式变化、对害虫的敏感性、植物物候学、开花、成熟期缩短、籽粒灌浆和衰老加速,导致产量显著损失。热应激在植物中引发多种细胞、生理和分子反应,从早期感知开始,随后是信号转导、渗透调节物质合成、抗氧化防御和与热应激相关的基因表达。已经在植物中分离和鉴定了参与热感知和适应反应的几个基因和代谢物。热应激反应还受到热应激转录因子(HSFs)、miRNA 和转录因子的调控,它们共同构成了另一个调控回路。随着具有功能验证的候选基因的出现,已经应用转基因方法来开发耐热性转基因玉米、烟草和甘薯。在这篇综述中,我们介绍了耐热性的分子机制,并讨论了遗传操纵耐热作物的最新进展,以实现未来可持续农业。
