通过分子动力学模拟深入了解钾通道的失活机制和pH敏感性。

Insight into the mechanism of inactivation and pH sensitivity in potassium channels from molecular dynamics simulations.

作者信息

Stansfeld Phillip J, Grottesi Alessandro, Sands Zara A, Sansom Mark S P, Gedeck Peter, Gosling Martin, Cox Brian, Stanfield Peter R, Mitcheson John S, Sutcliffe Michael J

机构信息

Department of Cell Physiology and Pharmacology, University of Leicester, UK.

出版信息

Biochemistry. 2008 Jul 15;47(28):7414-22. doi: 10.1021/bi800475j. Epub 2008 Jun 18.

DOI:10.1021/bi800475j

PMID:18558719

Abstract

Potassium (K (+)) channels can regulate ionic conduction through their pore by a mechanism, involving the selectivity filter, known as C-type inactivation. This process is rapid in the hERG K (+) channel and is fundamental to its physiological role. Although mutations within hERG are known to remove this process, a structural basis for the inactivation mechanism has yet to be characterized. Using MD simulations based on homology modeling, we observe that the carbonyl of the filter aromatic, Phe627, forming the S 0 K (+) binding site, swiftly rotates away from the conduction axis in the wild-type channel. In contrast, in well-characterized non-inactivating mutant channels, this conformational change occurs less frequently. In the non-inactivating channels, interactions with a water molecule located behind the selectivity filter are critical to the enhanced stability of the conducting state. We observe comparable conformational changes in the acid sensitive TASK-1 channel and propose a common mechanism in these channels for regulating efflux of K (+) ions through the selectivity filter.

摘要

钾离子（K(+)）通道可通过一种涉及选择性过滤器的机制调节其孔道中的离子传导，这种机制称为C型失活。该过程在hERG K(+)通道中很快，并且对其生理作用至关重要。尽管已知hERG内的突变会消除此过程，但失活机制的结构基础尚未得到表征。使用基于同源建模的分子动力学模拟，我们观察到形成S0 K(+)结合位点的过滤器芳香族残基Phe627的羰基在野生型通道中迅速从传导轴旋转离开。相比之下，在特征明确的非失活突变通道中，这种构象变化发生的频率较低。在非失活通道中，与位于选择性过滤器后面的水分子的相互作用对于传导状态增强的稳定性至关重要。我们在酸敏感的TASK-1通道中观察到了类似的构象变化，并提出了这些通道中通过选择性过滤器调节K(+)离子外流的共同机制。

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通过分子动力学模拟深入了解钾通道的失活机制和pH敏感性。

Insight into the mechanism of inactivation and pH sensitivity in potassium channels from molecular dynamics simulations.

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