Expression alteration analyses in the transgenic Arabidopsis carrying soybean Histidine-containing phosphotransmitter gene under salinity stress condition

Thai Chi Hung, Hoang Thi Lan Xuan, Nguyen Thien Quang, Nguyen Thi Phuong Thao
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Abstract

Productivity of many crops is highly vulnerable to extreme external conditions.  Environmental stress factors such as drought and salinity have become more and more serious due to climate change and appear in many areas worldwide with higher frequency. As both drought and salinity belong to osmotic stress, they have similar negative effects on plant growth, development, and productivity as well as trigger similar stress responses by plants. In a previous study analyzing the expression profile in two soybean (Glycine max) cultivars with contrasting drought-tolerant phenotypes, a member of two-component system (TCS) in soybean, GmHP08, was proposed to associate with the plant tolerance capacity to drought. Subsequent in planta study confirmed its action as a positive regulator under drought conditions, as the transgenic Arabidopsis plants ectopically expressing GmHP08 acquired better drought tolerance. Following this, the presented research further explored the possible function of GmHP08 in mediating plant response to salinity. The obtained data from RT-qPCR analyses suggested that GmHP08 might positively enhance the salt tolerance of the Arabidopsis transgenic plants by altering the transcriptional abundance of several stress-related genes, including RD29A, RD29B, ABI5, SAG13, and CSD1. Activities of these genes are known to be associated with osmoprotection, senescence process, and antioxidation, which contribute to salt-tolerance ability of the transgenic plants. These results provided the first line of molecular evidence regarding GmHP08 function in plant response to salinity conditions. Therefore, extensive studies should be conducted in future studies to elaborate on the mechanisms by which this TCS member could improve various types of osmotic stress tolerance in plants.
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盐胁迫条件下转大豆含组氨酸磷脂递质基因拟南芥表达变化分析
许多作物的生产力极易受到极端外部条件的影响。由于气候变化,干旱、盐渍化等环境胁迫因子日益严重,在世界范围内许多地区出现的频率越来越高。由于干旱和盐度都属于渗透胁迫,它们对植物的生长发育和生产力产生相似的负面影响,引发植物类似的胁迫反应。在对两个抗旱表型不同的大豆(Glycine max)品种的表达谱分析中,提出了大豆双组分系统(TCS)成员GmHP08与植物抗旱能力有关。随后的植物研究证实了其在干旱条件下的正向调节作用,异位表达GmHP08的转基因拟南芥植株获得了更好的抗旱性。在此基础上,本研究进一步探讨了GmHP08在介导植物盐度响应中的可能功能。RT-qPCR分析结果表明,GmHP08可能通过改变RD29A、RD29B、ABI5、SAG13和CSD1等多个胁迫相关基因的转录丰富度,正向增强转基因拟南芥植株的耐盐性。已知这些基因的活性与渗透保护、衰老过程和抗氧化有关,这有助于转基因植物的耐盐能力。这些结果为GmHP08在植物对盐度条件响应中的作用提供了第一个分子证据。因此,在未来的研究中,需要进行广泛的研究,以阐明该TCS成员提高植物各种类型渗透胁迫耐受性的机制。
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