钠离子通道域 III 电压传感器与孔之间偶联的分子决定因素。
Molecular determinants of coupling between the domain III voltage sensor and pore of a sodium channel.
机构信息
Department of Physiology, School of Medicine and Public Health, University of Wisconsin, Madison, Wisconsin, USA.
出版信息
Nat Struct Mol Biol. 2010 Feb;17(2):230-7. doi: 10.1038/nsmb.1749. Epub 2010 Jan 31.
Abstract
In a voltage-dependent sodium channel, the activation of voltage sensors upon depolarization leads to the opening of the pore gates. To elucidate the principles underlying this conformational coupling, we investigated a putative gating interface in domain III of the sodium channel using voltage-clamp fluorimetry and tryptophan-scanning mutagenesis. Most mutations have similar energetic effects on voltage-sensor activation and pore opening. However, several mutations stabilized the activated voltage sensor while concurrently destabilizing the open pore. When mapped onto a homology model of the sodium channel, most localized to hinge regions of the gating interface. Our analysis shows that these residues are involved in energetic coupling of the voltage sensor to the pore when both are in resting and when both are in activated conformations, supporting the notion that electromechanical coupling in a voltage-dependent ion channel involves the movement of rigid segments connected by elastic hinges.
摘要
在电压门控钠离子通道中,去极化时电压感受器的激活导致孔道门的打开。为了阐明这种构象偶联的原理,我们使用电压钳荧光法和色氨酸扫描突变技术研究了钠离子通道 III 域中的一个假定门控界面。大多数突变对电压感受器的激活和孔道的打开有相似的能量效应。然而,一些突变稳定了激活的电压感受器,同时使开放的孔道不稳定。当映射到钠离子通道的同源模型上时,大多数突变定位在门控界面的铰链区域。我们的分析表明,当电压感受器和孔道都处于静息状态和激活状态时,这些残基参与了电压感受器与孔道之间的能量偶联,支持这样一种观点,即在电压依赖型离子通道中,机电偶联涉及由弹性铰链连接的刚性片段的运动。
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