门控位于传导 Na+ 和 K+ 离子的离子通道的选择性过滤器。
Gating at the selectivity filter of ion channels that conduct Na+ and K+ ions.
机构信息
Physical and Theoretical Chemistry Laboratory, Department of Chemistry, University of Oxford, Oxford, United Kingdom.
出版信息
Biophys J. 2011 Oct 5;101(7):1623-31. doi: 10.1016/j.bpj.2011.08.035.
Abstract
The NaK channel is a cation selective channel with similar permeability for K(+) and Na(+). The available crystallographic structure of wild-type (WT) NaK is usually associated with a conductive state of the channel. Here, potential of mean force for complete conduction events of Na(+) and K(+) ions through NaK show that: i), large energy barriers prevent the passage of ions through the WT NaK structure, ii), the barriers are correlated to the presence of a hydrogen bond between Asp-66 and Asn-68, and iii), the structure of NaK mutated to mimic cyclic nucleotide-gated channels conducts Na(+) and K(+). These results support the hypothesis that the filter of cation selective channels can adopt at least two different structures: a conductive one, represented by the x-ray structures of the NaK-CNG chimeras, and a closed one, represented by the x-ray structures of the WT NaK.
摘要
钠钾通道是一种阳离子选择性通道,对钾离子 (K+) 和钠离子 (Na+) 的通透性相似。野生型 (WT) 钠钾通道的现有晶体结构通常与通道的传导状态相关。在这里,通过钠钾通道完整传导钠离子 (Na+) 和钾离子 (K+) 的平均力势表明:i),大的能量障碍阻止离子通过 WT 钠钾通道结构,ii),这些障碍与 Asp-66 和 Asn-68 之间氢键的存在相关,iii),模拟环核苷酸门控通道的钠钾通道结构可传导 Na(+) 和 K(+)。这些结果支持这样的假设,即阳离子选择性通道的过滤器可以采用至少两种不同的结构:一种是传导结构,由钠钾-CNG 嵌合体的 X 射线结构代表,另一种是关闭结构,由 WT 钠钾的 X 射线结构代表。
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