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二硫键将机械敏感通道MscL捕获到门控转变状态。

Disulfide trapping the mechanosensitive channel MscL into a gating-transition state.

作者信息

Iscla Irene, Levin Gal, Wray Robin, Blount Paul

机构信息

Department of Physiology, University of Texas-Southwestern Medical Center, Dallas, Texas 75390-9040, USA.

出版信息

Biophys J. 2007 Feb 15;92(4):1224-32. doi: 10.1529/biophysj.106.090316. Epub 2006 Nov 17.

DOI:10.1529/biophysj.106.090316
PMID:17114217
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1783893/
Abstract

The mechanosensitive channel of large conductance, MscL, serves as a biological emergency release valve protecting bacteria from acute osmotic downshock, and is to date the best characterized mechanosensitive channel. The N-terminal region of the protein has been shown to be critical for function by random, site-directed, and deletion mutagenesis, yet is structurally poorly understood. One model proposes that the extreme N-termini form a cluster of amphipathic helices that serves as a cytoplasmic second gate, separated from the pore-forming transmembrane domain by a "linker". Here, we have utilized cysteine trapping of single-cysteine mutated channels to determine the proximity, within the homopentameric complex, of residues within and just peripheral to this proposed linker. Our results indicate that all residues in this region can form disulfide bridges, and that the percentage of dimers increases when the channel is gated in vivo. Functional studies suggest that oxidation traps one of these mutated channels, N15C, into a gating-transition state that retains the capacity to obtain both fully open and closed states. The data are not easily explained by current models for the smooth transition from closed-to-open states, but predict that an asymmetric movement of one or more of the subunits commonly occurs upon gating.

摘要

大电导机械敏感通道(MscL)作为一种生物应急释放阀,保护细菌免受急性渗透压下降的影响,是迄今为止特征最明确的机械敏感通道。通过随机、定点和缺失诱变已表明该蛋白质的N端区域对其功能至关重要,但在结构上却知之甚少。一种模型认为,极端N端形成了一组两亲性螺旋,作为细胞质第二道门,通过一个“连接子”与形成孔的跨膜结构域隔开。在此,我们利用单半胱氨酸突变通道的半胱氨酸捕获技术,来确定在这个假定连接子内部及其周边的残基在同五聚体复合物中的接近程度。我们的结果表明,该区域内的所有残基都能形成二硫键,并且当通道在体内门控时,二聚体的比例会增加。功能研究表明,氧化将这些突变通道之一N15C捕获到一种门控转变状态,该状态保留了获得完全开放和关闭状态的能力。这些数据难以用当前关于从关闭状态到开放状态的平稳转变的模型来解释,但预测在门控时通常会发生一个或多个亚基的不对称移动。

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本文引用的文献

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