Self-Defense Mechanism in Rice to Salinity: Proline

J Pub Date : 2024-03-11 DOI:10.3390/j7010006
Yunus Emre Koc, Murat Aycan, Toshiaki Mitsui
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Abstract

The increasing global population and climate change threaten food security, with the need for sustenance expected to rise by 85% by 2050. Rice, a crucial staple food for over 50% of the global population, is a major source of calories in underdeveloped and developing countries. However, by the end of the century, over 30% of rice fields will become saline due to soil salinity caused by earthquakes, tsunamis, and rising sea levels. Plants have developed strategies to deal with salt stress, such as ion homeostasis, antioxidant defense mechanisms, and morphological adaptations. Proline, an endogenous osmolyte, is the predominant endogenous osmolyte that accumulates in response to salinity, and its overexpression in rice plants has been observed to increase plant salinity tolerance. Exogenously applied proline has been shown to improve plant salt tolerance by reducing the destructive effect of salinity. Recent research has focused on ionic toxicity, nitrogen fixation, and gene expression related to salt tolerance. Exogenous proline has been shown to improve water potential and leaf content, restoring water usage efficiency. It can also ease growth inhibition in salt-sensitive plants. Exogenously applied proline increases antioxidant activities and enhances plant salinity tolerance. This review examines the role and processes of proline in rice plants under salt stress and its relationship with other tolerance mechanisms.
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水稻对盐度的自我防御机制脯氨酸
全球人口的不断增长和气候变化威胁着粮食安全,预计到 2050 年,粮食需求将增加 85%。大米是全球 50%以上人口的重要主食,也是欠发达国家和发展中国家的主要热量来源。然而,到本世纪末,由于地震、海啸和海平面上升造成的土壤盐碱化,30% 以上的稻田将变成盐碱地。植物已开发出应对盐胁迫的策略,如离子平衡、抗氧化防御机制和形态适应。脯氨酸是一种内源渗透溶质,是主要的内源渗透溶质,会在盐胁迫下积累,据观察,在水稻植株中过表达脯氨酸可提高植物的耐盐性。外源施用脯氨酸可降低盐度的破坏作用,从而提高植物的耐盐性。近期研究的重点是离子毒性、固氮作用以及与耐盐性相关的基因表达。研究表明,外源脯氨酸可改善水势和叶片含量,恢复水分利用效率。它还能缓解盐敏感植物的生长抑制。外源施用脯氨酸可提高抗氧化活性,增强植物的耐盐性。本综述探讨了盐胁迫下脯氨酸在水稻植物中的作用和过程及其与其他耐盐机制的关系。
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