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小电导机械敏感通道疏水孔的电压依赖性水合作用和传导特性

Voltage-dependent hydration and conduction properties of the hydrophobic pore of the mechanosensitive channel of small conductance.

作者信息

Spronk Steven A, Elmore Donald E, Dougherty Dennis A

机构信息

Division of Chemistry and Chemical Engineering, California Institute of Technology, Pasadena, USA.

出版信息

Biophys J. 2006 May 15;90(10):3555-69. doi: 10.1529/biophysj.105.080432. Epub 2006 Feb 24.

DOI:10.1529/biophysj.105.080432
PMID:16500980
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1440736/
Abstract

A detailed picture of water and ion properties in small pores is important for understanding the behavior of biological ion channels. Several recent modeling studies have shown that small, hydrophobic pores exclude water and ions even if they are physically large enough to accommodate them, a mechanism called hydrophobic gating. This mechanism has been implicated in the gating of several channels, including the mechanosensitive channel of small conductance (MscS). Although the pore in the crystal structure of MscS is wide and was initially hypothesized to be open, it is lined by hydrophobic residues and may represent a nonconducting state. Molecular dynamics simulations were performed on MscS to determine whether or not the structure can conduct ions. Unlike previous simulations of hydrophobic nanopores, electric fields were applied to this system to model the transmembrane potential, which proved to be important. Although simulations without a potential resulted in a dehydrated, occluded pore, the application of a potential increased the hydration of the pore and resulted in current flow through the channel. The calculated channel conductance was in good agreement with experiment. Therefore, it is likely that the MscS crystal structure is closer to a conducting than a nonconducting state.

摘要

了解小孔中水和离子的性质的详细情况对于理解生物离子通道的行为至关重要。最近的几项建模研究表明,即使小孔在物理尺寸上足以容纳水和离子,小的疏水性孔也会排斥水和离子,这种机制称为疏水门控。这种机制与几种通道的门控有关,包括小电导机械敏感通道(MscS)。尽管MscS晶体结构中的孔很宽,最初被假设为开放的,但它由疏水残基排列,可能代表一种非导电状态。对MscS进行了分子动力学模拟,以确定该结构是否能够传导离子。与之前对疏水纳米孔的模拟不同,该系统施加了电场来模拟跨膜电位,事实证明这很重要。尽管没有电位的模拟导致孔脱水、堵塞,但施加电位增加了孔的水合作用,并导致电流通过通道。计算得到的通道电导与实验结果吻合良好。因此,MscS晶体结构可能更接近导电状态而非非导电状态。

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