High-temperature stress in strawberry: understanding physiological, biochemical and molecular responses.

IF 3.6 3区 生物学 Q1 PLANT SCIENCES
Planta Pub Date : 2024-10-17 DOI:10.1007/s00425-024-04544-6
Izhar Ullah, Muhammad Danish Toor, Bayram Ali Yerlikaya, Heba I Mohamed, Seher Yerlikaya, Abdul Basit, Attiq Ur Rehman
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Abstract

Main conclusion: Heat stress reduces strawberry growth and fruit quality by impairing photosynthesis, disrupting hormone regulation, and altering mineral nutrition. Multi-omics studies show extensive transcriptional, post-transcriptional, proteomic and metabolomic under high temperatures. Garden strawberry is a globally cultivated, economically important fruit crop highly susceptible to episodic heat waves and chronically rising temperatures associated with climate change. Heat stress negatively affects the growth, development, and quality of strawberries. Elevated temperatures affect photosynthesis, respiration, water balance, hormone signaling, and carbohydrate metabolism in strawberries. Heat stress reduces the size and number of leaves, the number of crowns, the differentiation of flower buds, and the viability of pollen and fruit set, ultimately leading to a lower yield. On a physiological level, heat stress reduces membrane stability, increases the production of reactive oxygen species, and reduces the antioxidant capacity of strawberries. Heat-tolerant varieties have better physiological and biochemical adaptation mechanisms compared to heat-sensitive varieties. Breeding heat-tolerant strawberry cultivars involves selection for traits such as increased leaf temperature, membrane thermostability, and chlorophyll content. Multi-omics studies show extensive transcriptional, post-transcriptional, proteomic, metabolomic, and ionomic reprogramming at high temperatures. Integrative-omics approaches combine multiple omics datasets to obtain a systemic understanding of the responses to heat stress in strawberries. This article summarizes the deciphering of strawberry responses to heat stress using physiological, biochemical, and molecular approaches that will enable the development of resilient adaptation strategies that sustain strawberry production under global climate change.

草莓的高温胁迫:了解生理、生化和分子反应。
主要结论热胁迫会影响光合作用、扰乱激素调节和改变矿物质营养,从而降低草莓的生长和果实品质。多组学研究表明,在高温条件下,草莓的转录、转录后、蛋白质组和代谢组都受到广泛影响。花园草莓是一种全球栽培的、具有重要经济价值的水果作物,极易受到偶发性热浪和与气候变化相关的长期气温升高的影响。热胁迫会对草莓的生长、发育和品质产生负面影响。温度升高会影响草莓的光合作用、呼吸作用、水分平衡、激素信号转导和碳水化合物代谢。热胁迫会减少叶片的大小和数量、花冠的数量、花芽的分化、花粉的活力和坐果率,最终导致产量降低。在生理层面上,热胁迫会降低膜的稳定性,增加活性氧的产生,并降低草莓的抗氧化能力。与热敏感品种相比,耐热品种具有更好的生理和生化适应机制。培育耐热草莓品种需要对叶片温度、膜热稳定性和叶绿素含量等性状进行选择。多组学研究表明,高温条件下存在广泛的转录、转录后、蛋白质组、代谢组和离子组重构。整合组学方法结合了多种组学数据集,可系统地了解草莓对热胁迫的反应。本文总结了利用生理、生化和分子方法破译草莓对热胁迫反应的情况,这将有助于制定有弹性的适应策略,在全球气候变化的情况下维持草莓生产。
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
Planta
Planta 生物-植物科学
CiteScore
7.20
自引率
2.30%
发文量
217
审稿时长
2.3 months
期刊介绍: Planta publishes timely and substantial articles on all aspects of plant biology. We welcome original research papers on any plant species. Areas of interest include biochemistry, bioenergy, biotechnology, cell biology, development, ecological and environmental physiology, growth, metabolism, morphogenesis, molecular biology, new methods, physiology, plant-microbe interactions, structural biology, and systems biology.
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