钾离子通道孔中二硫键和高亲和力金属结合位点的原子距离估计
Atomic distance estimates from disulfides and high-affinity metal-binding sites in a K+ channel pore.
作者信息
Krovetz H S, VanDongen H M, VanDongen A M
机构信息
Department of Pharmacology, Duke University Medical Center, Durham, North Carolina 27710, USA.
出版信息
Biophys J. 1997 Jan;72(1):117-26. doi: 10.1016/S0006-3495(97)78651-X.
Abstract
The pore of potassium channels is lined by four identical, highly conserved hairpin loops, symmetrically arranged around a central permeation pathway. Introduction of cysteines into the external mouth of the drk1 K channel pore resulted in the formation of disulfide bonds that were incompatible with channel function. Breaking these bonds restored function and resulted in a high-affinity Cd(2+)-binding site, indicating coordinated ligation by multiple sulfhydryls. Dimeric constructs showed that these disulfide bonds formed between subunits. These results impose narrow constraints on intersubunit atomic distances in the pore that strongly support a radial pore model. The data also suggest an important functional role for the outer mouth of the pore in gating or permeation.
摘要
钾通道的孔道由四个相同且高度保守的发夹环排列而成,这些发夹环围绕着一条中央通透路径呈对称排列。在drk1钾通道孔道的外口引入半胱氨酸会导致二硫键的形成,而这些二硫键与通道功能不兼容。打破这些二硫键可恢复通道功能,并产生一个高亲和力的Cd(2+)结合位点,这表明存在多个巯基的协同配位作用。二聚体构建体显示这些二硫键是在亚基之间形成的。这些结果对孔道中亚基间的原子距离施加了严格的限制,有力地支持了径向孔道模型。数据还表明孔道外口在门控或通透方面具有重要的功能作用。
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