细菌Tat前体蛋白前SufI的脂质结合形式与转位体结合形式之间的相互转换性

Interconvertibility of lipid- and translocon-bound forms of the bacterial Tat precursor pre-SufI.

作者信息

Bageshwar Umesh K, Whitaker Neal, Liang Fu-Cheng, Musser Siegfried M

机构信息

Department of Molecular and Cellular Medicine, College of Medicine, Texas A&M Health Science Center, College Station, TX 77843, USA.

出版信息

Mol Microbiol. 2009 Oct;74(1):209-226. doi: 10.1111/j.1365-2958.2009.06862.x. Epub 2009 Sep 2.

DOI:10.1111/j.1365-2958.2009.06862.x

PMID:19732346

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2770089/

Abstract

Signal peptides target protein cargos for secretion from the bacterial cytoplasm. These signal peptides contain a tri-partite structure consisting of a central hydrophobic domain (h-domain), and two flanking polar domains. Using a recently developed in vitro transport assay, we report here that a central h-domain position (C17) of the twin arginine translocation (Tat) substrate pre-SufI is especially sensitive to amino acid hydrophobicity. The C17I mutant is transported more efficiently than wild type, whereas charged substitutions completely block transport. Transport efficiency is well-correlated with Tat translocon binding efficiency. The precursor protein also binds to non-Tat components of the membrane, presumably to the lipids. This lipid-bound precursor can be chased through the Tat translocons under conditions of high proton motive force. Thus, the non-Tat bound form of the precursor is a functional intermediate in the transport cycle. This intermediate appears to directly equilibrate with the translocon-bound form of the precursor.

摘要

信号肽将蛋白质货物靶向从细菌细胞质中分泌出来。这些信号肽包含一个由中央疏水结构域（h结构域）和两个侧翼极性结构域组成的三部分结构。利用最近开发的体外转运测定法，我们在此报告，双精氨酸转运（Tat）底物前体SufI的中央h结构域位置（C17）对氨基酸疏水性特别敏感。C17I突变体比野生型更有效地被转运，而带电取代则完全阻断转运。转运效率与Tat转运体结合效率高度相关。前体蛋白也与膜的非Tat成分结合，推测是与脂质结合。在高质子动力势条件下，这种脂质结合的前体可以通过Tat转运体进行追踪。因此，前体的非Tat结合形式是转运循环中的一种功能中间体。这种中间体似乎直接与前体的转运体结合形式达到平衡。

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本文引用的文献

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Twin-arginine-dependent translocation of SufI in the absence of cytosolic helper proteins.在没有胞质辅助蛋白的情况下，SufI的双精氨酸依赖性转运

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Polar or apolar--the role of polarity for urea-induced protein denaturation.极性或非极性——极性在尿素诱导蛋白质变性中的作用

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Urea denaturation by stronger dispersion interactions with proteins than water implies a 2-stage unfolding.与蛋白质的分散相互作用比与水的更强，尿素变性意味着两阶段展开。

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