Abscisic acid, and abscisic acid-induced water stress tolerance in mycorrhizal herbaceous and olive (Olea europaea) plants

Q4 Agricultural and Biological Sciences

Lilloa Pub Date : 2023-07-31 DOI:10.30550/j.lil/1689

M. A. Busso

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Abstract

The worldwide expansion of drought-affected areas has a negative effect on crop yield and production, making water stress the most significant abiotic stress, limiting plant growth and development. The use of arbuscular mycorrhizal fungi (AMF) is a strategy that mitigates the effects of this kind of stress in a sustainable way, which occurs due to the increased tolerance to water stress in plants inoculated with these fungi. Modern agriculture is facing the challenge of ensuring global food demand. However, climate change is causing an increase in temperature that leads to severe droughts in some areas. Numerous biotechnological techniques are being used to overcome this drought stress. Among them, the use of AMF is considered an efficient approach to mitigate such stress. AMF provide water stress tolerance through biochemical and physiological mechanisms. Some of the well-known mechanisms include modification of hormonal balances comprising strigolactones, abscisic acid, gibberellic acid, salicylic acid, and jasmonic acid. The symbiosis of AMF changes the expression of the aquaporins (water transporting channels) present in the plasma membrane and tonoplast, improving plant water status.

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脱落酸和脱落酸诱导的菌根草本和橄榄（Olea europaea）植物的水分胁迫耐受性

受干旱影响地区的全球扩张对作物产量和生产产生了负面影响，使水分胁迫成为最重要的非生物胁迫，限制了植物的生长和发育。丛枝菌根真菌（AMF）的使用是一种以可持续的方式减轻这种胁迫影响的策略，这是由于接种这些真菌的植物对水分胁迫的耐受性增强。现代农业面临着确保全球粮食需求的挑战。然而，气候变化导致气温上升，导致一些地区出现严重干旱。许多生物技术正在被用来克服这种干旱压力。其中，使用AMF被认为是缓解这种压力的有效方法。AMF通过生物化学和生理机制提供水分胁迫耐受性。一些众所周知的机制包括改变激素平衡，包括三羟内酯、脱落酸、赤霉酸、水杨酸和茉莉酸。AMF的共生改变了质膜和液泡膜中水通道蛋白（水传输通道）的表达，改善了植物的水分状况。

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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