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AcrA 抑制剂的改变通过诱导 TolC 孔道开放,逆转 TolC 突变体的药物过敏表型。

AcrA suppressor alterations reverse the drug hypersensitivity phenotype of a TolC mutant by inducing TolC aperture opening.

机构信息

Faculty of Cellular and Molecular Biosciences, School of Life Sciences, Arizona State University, Tempe, AZ, USA.

出版信息

Mol Microbiol. 2010 Mar;75(6):1468-83. doi: 10.1111/j.1365-2958.2010.07068.x. Epub 2010 Feb 1.

DOI:10.1111/j.1365-2958.2010.07068.x
PMID:20132445
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2875072/
Abstract

In Escherichia coli, the TolC-AcrAB complex forms a major antibiotic efflux system with broad substrate specificity. During the complex assembly, the periplasmic helices and bottom turns of TolC are thought to interact with a hairpin helix of AcrA and hairpin loops of AcrB respectively. In the present study we show that a four-residue substitution in TolC's turn 1, which connects outer helices 3 and 4 proximal to TolC's periplasmic aperture, confers antibiotic hypersensitivity, without affecting TolC-mediated phage or colicin infection. However, despite the null-like drug sensitivity phenotype, chemical cross-linking analysis revealed no apparent defects in the ability of the mutant TolC protein to physically interact with AcrA and AcrB. A role for TolC turn 1 residues in the functional assembly of the tripartite efflux pump complex was uncovered through isolating suppressor mutations of the mutant TolC protein that mapped within acrA and by utilizing a labile AcrA protein. The data showed that AcrA-mediated suppression of antibiotic sensitivity was achieved by dilating the TolC aperture/channel in an AcrB-dependent manner. The results underscore the importance of the periplasmic turn 1 of TolC in the functional assembly of the tripartite efflux complex and AcrA in transitioning TolC from its closed to open state.

摘要

在大肠杆菌中,TolC-AcrAB 复合物形成了具有广泛底物特异性的主要抗生素外排系统。在复合物组装过程中,TolC 的周质螺旋和底部转弯被认为分别与 AcrA 的发夹螺旋和 AcrB 的发夹环相互作用。在本研究中,我们表明 TolC 转角 1 中的四个残基取代,该取代连接靠近 TolC 周质腔的外螺旋 3 和 4,赋予抗生素超敏性,而不影响 TolC 介导的噬菌体或 colicin 感染。然而,尽管药物敏感性表型类似于缺失,但化学交联分析显示突变 TolC 蛋白与 AcrA 和 AcrB 物理相互作用的能力没有明显缺陷。通过分离突变 TolC 蛋白的抑制突变,这些突变位于 acrA 内,并利用不稳定的 AcrA 蛋白,揭示了 TolC 转角 1 残基在三组分外排泵复合物的功能组装中的作用。数据表明,AcrA 介导的抗生素敏感性抑制是通过以 AcrB 依赖的方式扩张 TolC 孔径/通道来实现的。结果强调了 TolC 周质转角 1 在三组分外排复合物的功能组装以及 AcrA 在将 TolC 从关闭状态转变为开放状态中的重要性。

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