A review of approaches to enhance salt stress tolerance in cotton by genetic engineering

IF 0.7 Q4 PLANT SCIENCES
S Ayubov Mirzakamol, M Asrorov Akmal, M. Darmanov Mukhtor, E. Narmatov Sardor, Mamajanov Akramjon, E Bozorov Ilhomjon, N Khusenov Naim, Matusikova Ildiko, T Buriev Zabardast, Y Abdurakhmonov Ibrokhim
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引用次数: 0

Abstract

Due to climate change, deserts are expanding, water reservoirs are drying, soil erosion is becoming more serious, and salinity areas are expanding worldwide. Among these disasters, soil salinization is one of the serious issues that affect agricultural production, with significant effects on plant development. Although plants have a solid adaptation to severe environmental conditions, their vulnerability to some abiotic stresses is still preserved in the plant genome. Cotton is a salt stress-tolerant crop among other main cash crops. However, its tolerance is limited in overwatered soil conditions or water-deficient soil. Several research investigations have been carried out to date to better understand salinity stress responses in various cotton species. The accumulation of salt due to irrigation-dependent practices exerts an adverse impact on crop productivity. However, this deleterious effect can be mitigated through a comprehensive understanding of the mechanisms by which certain plants flourish under saline conditions. Over the past few decades, there has been a notable augmentation in mechanistic comprehension, leading to the initiation of discovery-oriented methodologies aimed at discerning the genetic determinants of salt tolerance. Recent studies are showing the results of the manipulation of some important genes and proteins for salt tolerance using modern approaches. The identification of salt-resistance genes from salt-tolerant germplasm resources plays an essential role in improving the yield of cotton in saline soils. In this paper, we reviewed what has been achieved in cotton in terms of the development of its salt tolerance using genetic engineering.
利用基因工程提高棉花耐盐性的途径综述
由于气候变化,沙漠正在扩大,水库正在干涸,水土流失日益严重,全球范围内的盐碱区正在扩大。在这些灾害中,土壤盐渍化是影响农业生产的严重问题之一,对植物的生长发育有重大影响。尽管植物对恶劣的环境条件具有很强的适应性,但它们对一些非生物胁迫的脆弱性仍然保留在植物基因组中。棉花是主要经济作物中的耐盐作物。然而,它的耐受性是有限的,在水分过多的土壤条件或缺水的土壤。为了更好地了解不同棉花品种对盐胁迫的反应,迄今为止已经进行了几项研究调查。由于依赖灌溉的做法而积累的盐分对作物生产力产生不利影响。然而,通过对某些植物在盐水条件下繁茂生长的机制的全面了解,可以减轻这种有害影响。在过去的几十年里,机械理解有了显著的增强,导致了以发现为导向的方法的开始,旨在识别耐盐性的遗传决定因素。最近的研究显示了使用现代方法操纵一些重要的耐盐基因和蛋白质的结果。从耐盐种质资源中鉴定耐盐基因对提高盐碱地棉花产量具有重要意义。本文综述了利用基因工程技术开发棉花耐盐性状的研究进展。
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
Plant Science Today
Plant Science Today PLANT SCIENCES-
CiteScore
1.50
自引率
11.10%
发文量
177
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