人类醚-à-去相关基因钾离子通道(HERG)C末端的功能特性
Functional characterization of the C-terminus of the human ether-à-go-go-related gene K(+) channel (HERG).
作者信息
Aydar E, Palmer C
机构信息
University of Wisconsin--Madison, Department of Physiology, School of Medicine, 1300 University Avenue, Room 129 S.M.I., Madison, WI 53706, USA.
出版信息
J Physiol. 2001 Jul 1;534(Pt 1):1-14. doi: 10.1111/j.1469-7793.2001.t01-3-00001.x.
Abstract
- In the present study the functional role of the C-terminus of the human ether-à-go-go-related gene K(+) channel HERG was investigated using a series of C-terminal deletion constructs expressed in Xenopus oocytes. 2. Constructs with deletions of 311 or more amino acid residues failed to form functional channels. Truncation by 215 amino acid residues or fewer had no discernable effects on channel activity. Truncation by 236 or 278 amino acid residues accelerated deactivation, and caused a faster recovery from inactivation. 3. In high extracellular K(+), channel deactivation of HERG results from the binding of the N-terminus to a site within the pore. This slows channel deactivation by a knock-off mechanism. Here, it was shown that C-terminal deletions also abolished this effect of high extracellular K(+). Mutants containing deletions in both the N- and C-termini deactivated with rates similar to those observed in individual deletion mutants. 4. In contrast, experiments with double-deletion constructs showed additive effects of the N- and C-termini on the voltage dependence of activation, and on the kinetics of inactivation and recovery from inactivation. The reduction of inactivation in these mutants contributed to an increase in peak current amplitude. 5. These results indicate that residues within the C-terminus of HERG play a role in channel expression as well as in most aspects of channel gating. The regulation of channel deactivation is likely to be mediated by an interaction with the N-terminus, but the regulation of the voltage dependence of activation, and of rate processes associated with inactivation, does not require the N-terminus.
摘要
- 在本研究中,使用在非洲爪蟾卵母细胞中表达的一系列C末端缺失构建体,研究了人类醚-à-去相关基因钾通道HERG的C末端的功能作用。2. 缺失311个或更多氨基酸残基的构建体未能形成功能性通道。截短215个或更少氨基酸残基对通道活性没有明显影响。截短236个或278个氨基酸残基会加速失活,并导致从失活状态更快恢复。3. 在高细胞外钾浓度下,HERG通道的失活是由于N末端与孔内的一个位点结合所致。这通过一种敲除机制减缓了通道失活。在此研究中表明,C末端缺失也消除了高细胞外钾的这种作用。在N末端和C末端都有缺失的突变体失活速率与在单个缺失突变体中观察到的相似。4. 相比之下,双缺失构建体的实验表明,N末端和C末端对激活的电压依赖性、失活动力学以及从失活状态恢复的动力学具有累加效应。这些突变体中失活的减少导致峰值电流幅度增加。5. 这些结果表明,HERG的C末端内的残基在通道表达以及通道门控的大多数方面都发挥作用。通道失活的调节可能是通过与N末端的相互作用介导的,但激活的电压依赖性以及与失活相关的速率过程的调节并不需要N末端。
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