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Literature DB >> 23247626

Analysis of the selectivity filter of the voltage-gated sodium channel Na(v)Rh.

Xu Zhang¹, Mengdie Xia, Yang Li, Huihui Liu, Xin Jiang, Wenlin Ren, Jianping Wu, Paul DeCaen, Feng Yu, Sheng Huang, Jianhua He, David E Clapham, Nieng Yan, Haipeng Gong.

Abstract

NaChBac is a bacterial voltage-gated sodium (Nav) channel that shows sequence similarity to voltage-gated calcium channels. To understand the ion-permeation mechanism of Nav channels, we combined molecular dynamics simulation, structural biology and electrophysiological approaches to investigate the recently determined structure of NavRh, a marine bacterial NaChBac ortholog. Two Na(+) binding sites are identified in the selectivity filter (SF) in our simulations: The extracellular Na(+) ion first approaches site 1 constituted by the side groups of Ser181 and Glu183, and then spontaneously arrives at the energetically more favorable site 2 formed by the carbonyl oxygens of Leu179 and Thr178. In contrast, Ca(2+) ions are prone to being trapped by Glu183 at site 1, which then blocks the entrance of both Na(+) and Ca(2+) to the vestibule of the SF. In addition, Na(+) permeates through the selective filter in an asymmetrical manner, a feature that resembles that of the mammalian Nav orthologs. The study reported here provides insights into the mechanism of ion selectivity on Na(+) over Ca(2+) in mammalian Nav channels.

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Year: 2012 PMID： 23247626 PMCID： PMC3587708 DOI： 10.1038/cr.2012.173

Source DB: PubMed Journal: Cell Res ISSN： 1001-0602 Impact factor: 25.617

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