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离子通道温度依赖性门控的分子框架。

A molecular framework for temperature-dependent gating of ion channels.

作者信息

Chowdhury Sandipan, Jarecki Brian W, Chanda Baron

机构信息

Graduate Program in Biophysics, 1111 Highland Ave, School of Medicine and Public Health, University of Wisconsin, Madison, Madison, WI 53705, USA; Department of Neuroscience, 1111 Highland Ave, School of Medicine and Public Health, University of Wisconsin, Madison, Madison, WI 53705, USA.

Department of Neuroscience, 1111 Highland Ave, School of Medicine and Public Health, University of Wisconsin, Madison, Madison, WI 53705, USA.

出版信息

Cell. 2014 Aug 28;158(5):1148-1158. doi: 10.1016/j.cell.2014.07.026. Epub 2014 Aug 21.

DOI:10.1016/j.cell.2014.07.026
PMID:25156949
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4405168/
Abstract

Perception of heat or cold in higher organisms is mediated by specialized ion channels whose gating is exquisitely sensitive to temperature. The physicochemical underpinnings of this temperature-sensitive gating have proven difficult to parse. Here, we took a bottom-up protein design approach and rationally engineered ion channels to activate in response to thermal stimuli. By varying amino acid polarities at sites undergoing state-dependent changes in solvation, we were able to systematically confer temperature sensitivity to a canonical voltage-gated ion channel. Our results imply that the specific heat capacity change during channel gating is a major determinant of thermosensitive gating. We also show that reduction of gating charges amplifies temperature sensitivity of designer channels, which accounts for low-voltage sensitivity in all known temperature-gated ion channels. These emerging principles suggest a plausible molecular mechanism for temperature-dependent gating that reconcile how ion channels with an overall conserved transmembrane architecture may exhibit a wide range of temperature-sensing phenotypes. :

摘要

高等生物对热或冷的感知是由专门的离子通道介导的,这些离子通道的门控对温度极为敏感。这种温度敏感门控的物理化学基础已被证明难以解析。在这里,我们采用了自下而上的蛋白质设计方法,合理地设计离子通道,使其对热刺激做出反应而激活。通过改变在溶剂化过程中经历状态依赖性变化的位点的氨基酸极性,我们能够系统地赋予一个典型的电压门控离子通道温度敏感性。我们的结果表明,通道门控过程中的比热容量变化是热敏门控的主要决定因素。我们还表明,门控电荷的减少会放大设计通道的温度敏感性,这解释了所有已知的温度门控离子通道中的低电压敏感性。这些新出现的原理为温度依赖性门控提出了一种合理的分子机制,解释了具有整体保守跨膜结构的离子通道如何可能表现出广泛的温度传感表型。

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