增加拟南芥<i>HSP101组成型表达对氟化钠细胞培养抗性的影响

IF 0.2 Q4 CHEMISTRY, MULTIDISCIPLINARY Izvestiya Vuzov-Prikladnaya Khimiya i Biotekhnologiya Pub Date : 2023-09-30 DOI:10.21285/2227-2925-2023-13-3-434-441
E. L. Gorbyleva, M. A. Safonova, A. V. Stepanov, E. G. Rikhvanov
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引用次数: 0

摘要

氟是工业排放物的有毒元素成分之一。大气、土壤或水中氟化物含量的增加会对植物的生长发育产生负面影响,并降低对各种环境压力源的抵抗力。环境温度的升高在所有生物体中引起保护性反应,以热休克蛋白合成的形式出现。特殊蛋白HSP101具有保护植物细胞免受热损伤的功能,也负责诱导耐热性,代表生物体承受严重热休克影响的能力,之前暴露于轻度热应激,因此热休克蛋白被诱导。热休克蛋白不仅参与抵抗高温,还参与抵抗各种其他应激因素。本研究研究了氟化钠处理对拟南芥细胞培养活力、热休克蛋白表达和合成的影响,以及热休克蛋白HSP101在抗氟性中的作用。氟化钠已被证明通过抑制HSP101基因表达的激活,随着温度的升高,显著降低拟南芥细胞的活力。与此同时,具有HSP101基因组成表达的拟南芥系对氟化钠的毒性作用具有更强的抵抗力。
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Increased <i>Arabidopsis thaliana</i> cell culture resistance to sodium fluoride by constitutive expression of HSP101
Fluorine is one of the toxic elemental components of industrial emissions. Increased fluoride content in the atmosphere, soil or water negatively affects the growth and development of plants, as well as reducing resistance to various environmental stressors. An increase in ambient temperature causes a protective response in all organisms taking the form heat shock protein synthesis. The specific protein HSP101, which performs the function of protecting plant cells from heat damage, is also responsible for inducible thermotolerance, representing the ability of organisms to withstand the effects of severe heat shock that were previously exposed to mild heat stress, as a result of which heat shock proteins are induced. Heat shock proteins are involved in protecting not only against elevated temperatures, but also various other stress factors. In this work, the effect of sodium fluoride treatment on the viability of Arabidopsis thaliana cell culture, expression and synthesis of heat shock proteins was studied along with the role of heat shock protein HSP101 in providing resistance to fluoride. Sodium fluoride has been shown to significantly reduce the viability of A. thaliana cells by suppressing the activation of HSP101 gene expression with an increase in temperature. At the same time, the A. thaliana line, which has constitutive expression of the HSP101 gene, proved to be more resistant to the toxic effects of sodium fluoride.
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来源期刊
自引率
50.00%
发文量
63
审稿时长
12 weeks
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