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KcsA孔道内Na(+)和Li(+)结合位点揭示钾通道选择性机制。

Mechanism of potassium-channel selectivity revealed by Na(+) and Li(+) binding sites within the KcsA pore.

作者信息

Thompson Ameer N, Kim Ilsoo, Panosian Timothy D, Iverson Tina M, Allen Toby W, Nimigean Crina M

机构信息

Department of Anesthesiology, Weill Cornell Medical College, New York, New York, USA.

出版信息

Nat Struct Mol Biol. 2009 Dec;16(12):1317-24. doi: 10.1038/nsmb.1703. Epub 2009 Nov 29.

DOI:10.1038/nsmb.1703
PMID:19946269
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2825899/
Abstract

Potassium channels allow K(+) ions to diffuse through their pores while preventing smaller Na(+) ions from permeating. Discrimination between these similar, abundant ions enables these proteins to control electrical and chemical activity in all organisms. Selection occurs at the narrow selectivity filter containing structurally identified K(+) binding sites. Selectivity is thought to arise because smaller ions such as Na(+) do not bind to these K(+) sites in a thermodynamically favorable way. Using the model K(+) channel KcsA, we examined how intracellular Na(+) and Li(+) interact with the pore and the permeant ions using electrophysiology, molecular dynamics simulations and X-ray crystallography. Our results suggest that these small cations have a separate binding site within the K(+) selectivity filter. We propose that selective permeation from the intracellular side primarily results from a large energy barrier blocking filter entry for Na(+) and Li(+) in the presence of K(+), not from a difference of binding affinity between ions.

摘要

钾通道允许K⁺离子通过其孔隙扩散,同时阻止较小的Na⁺离子渗透。区分这些相似且丰富的离子使这些蛋白质能够控制所有生物体中的电活动和化学活动。选择发生在含有结构已确定的K⁺结合位点的狭窄选择性过滤器处。人们认为选择性的产生是因为较小的离子如Na⁺不会以热力学有利的方式结合到这些K⁺位点上。我们使用模型钾通道KcsA,通过电生理学、分子动力学模拟和X射线晶体学研究了细胞内的Na⁺和Li⁺如何与孔隙及渗透离子相互作用。我们的结果表明,这些小阳离子在K⁺选择性过滤器内有一个单独的结合位点。我们提出,从细胞内侧的选择性渗透主要是由于在存在K⁺的情况下,一个大的能量屏障阻止了Na⁺和Li⁺进入过滤器,而不是由于离子之间结合亲和力的差异。

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