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钾通道电压传感器桨叶内的大规模运动——对螺旋运动的支持。

Large-scale movement within the voltage-sensor paddle of a potassium channel-support for a helical-screw motion.

作者信息

Broomand Amir, Elinder Fredrik

机构信息

Department of Clinical and Experimental Medicine, Division of Cell Biology, Linköping University, SE-58185 Linköping, Sweden.

出版信息

Neuron. 2008 Sep 11;59(5):770-7. doi: 10.1016/j.neuron.2008.07.008.

DOI:10.1016/j.neuron.2008.07.008

PMID:18786360

Abstract

The size of the movement and the molecular identity of the moving parts of the voltage sensor of a voltage-gated ion channel are debated. In the helical-screw model, the positively charged fourth transmembrane segment S4 slides and rotates along negative counter charges in S2 and S3, while in the paddle model, S4 carries the extracellular part of S3 (S3b) as a cargo. Here, we show that S4 slides 16-26 A along S3b. We introduced pairs of cysteines in S4 and S3b of the Shaker K channel to make disulfide bonds. Residue 325 in S3b makes close and state-dependent contacts with a long stretch of residues in S4. A disulfide bond between 325 and 360 was formed in the closed state, while a bond between 325 and 366 was formed in the open state. These data are not compatible with the voltage-sensor paddle model, but support the helical-screw model.

摘要

电压门控离子通道电压传感器的移动部分的运动大小和分子特性存在争议。在螺旋-螺旋模型中，带正电荷的第四跨膜片段S4沿着S2和S3中的负反电荷滑动并旋转，而在桨状模型中，S4携带S3的细胞外部分（S3b）作为货物。在这里，我们表明S4沿着S3b滑动16-26埃。我们在Shaker K通道的S4和S3b中引入了半胱氨酸对以形成二硫键。S3b中的第325位残基与S4中的一长串残基形成紧密且依赖状态的接触。在关闭状态下，325和360之间形成二硫键，而在开放状态下，325和366之间形成二硫键。这些数据与电压传感器桨状模型不兼容，但支持螺旋-螺旋模型。

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钾通道电压传感器桨叶内的大规模运动——对螺旋运动的支持。

Large-scale movement within the voltage-sensor paddle of a potassium channel-support for a helical-screw motion.

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