线粒体导入驱动力:基质Hsp70增强的捕获作用刺激转运,并降低松散折叠前体蛋白对膜电位的依赖性。
Mitochondrial import driving forces: enhanced trapping by matrix Hsp70 stimulates translocation and reduces the membrane potential dependence of loosely folded preproteins.
作者信息
Geissler A, Rassow J, Pfanner N, Voos W
机构信息
Institut für Biochemie und Molekularbiologie, Universität Freiburg, D-79104 Freiburg, Germany.
出版信息
Mol Cell Biol. 2001 Oct;21(20):7097-104. doi: 10.1128/MCB.21.20.7097-7104.2001.
Abstract
The mitochondrial heat shock protein Hsp70 (mtHsp70) is essential for driving translocation of preproteins into the matrix. Two models, trapping and pulling by mtHsp70, are discussed, but positive evidence for either model has not been found so far. We have analyzed a mutant mtHsp70, Ssc1-2, that shows a reduced interaction with the membrane anchor Tim44, but an enhanced trapping of preproteins. Unexpectedly, at a low inner membrane potential, ssc1-2 mitochondria imported loosely folded preproteins more efficiently than wild-type mitochondria. The import of a tightly folded preprotein, however, was not increased in ssc1-2 mitochondria. Thus, enhanced trapping by mtHsp70 stimulates the import of loosely folded preproteins and reduces the dependence on the import-driving activity of the membrane potential, directly demonstrating that trapping is one of the molecular mechanisms of mtHsp70 action.
摘要
线粒体热休克蛋白Hsp70(mtHsp70)对于驱动前体蛋白转运到线粒体基质中至关重要。目前讨论了两种模型,即mtHsp70的捕获模型和牵拉模型,但迄今为止尚未找到支持任何一种模型的确凿证据。我们分析了一种突变型mtHsp70,即Ssc1-2,它与膜锚定蛋白Tim44的相互作用减弱,但对前体蛋白的捕获增强。出乎意料的是,在内膜电位较低时,携带ssc1-2的线粒体比野生型线粒体更有效地导入松散折叠的前体蛋白。然而,携带ssc1-2的线粒体中紧密折叠的前体蛋白的导入并没有增加。因此,mtHsp70增强的捕获作用刺激了松散折叠前体蛋白的导入,并降低了对膜电位导入驱动活性的依赖性,直接证明了捕获是mtHsp70作用的分子机制之一。
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