酵母的热休克和乙醇应激反应表现出广泛的相似性和功能重叠。

The heat shock and ethanol stress responses of yeast exhibit extensive similarity and functional overlap.

作者信息

Piper P W

机构信息

Department of Biochemistry and Molecular Biology, University College London, UK.

出版信息

FEMS Microbiol Lett. 1995 Dec 15;134(2-3):121-7. doi: 10.1111/j.1574-6968.1995.tb07925.x.

DOI:10.1111/j.1574-6968.1995.tb07925.x

PMID:8586257

Abstract

Sublethal heat and ethanol exposure induce essentially identical stress responses in yeast. These responses are characterized by the induction of heat shock proteins, proteins requiring a temperature above about 35 degrees C or ethanol levels above a threshold level of 4-6% (v/v) for strong induction. One induced protein, Hsp104, contributes to both thermotolerance and ethanol tolerance, while others are anti-oxidant enzymes. Heat and ethanol stress cause similar changes to plasma membrane protein composition, reducing the levels of plasma membrane H(+)-ATPase protein and inducing the plasma membrane-associated Hsp30. Both stresses also stimulate the activity of the fraction of H(+)-ATPase remaining in the plasma membrane. The resulting enhancement to catalysed proton efflux from the cell represents a considerable energy demand, yet may help to counteract the adverse effects for homeostasis of the increased membrane permeability that results from stress.

摘要

亚致死热暴露和乙醇暴露在酵母中诱导出基本相同的应激反应。这些反应的特征是诱导热休克蛋白，即需要高于约35摄氏度的温度或高于4-6%（v/v）阈值水平的乙醇浓度才能强烈诱导的蛋白质。一种诱导蛋白Hsp104有助于耐热性和耐乙醇性，而其他的则是抗氧化酶。热应激和乙醇应激会导致质膜蛋白质组成发生类似变化，降低质膜H(+)-ATP酶蛋白水平，并诱导与质膜相关的Hsp30。两种应激还会刺激质膜中剩余的H(+)-ATP酶部分的活性。由此导致的细胞催化质子外流增强代表了相当大的能量需求，但可能有助于抵消应激导致的膜通透性增加对体内平衡的不利影响。

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酵母的热休克和乙醇应激反应表现出广泛的相似性和功能重叠。

The heat shock and ethanol stress responses of yeast exhibit extensive similarity and functional overlap.

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