ClC-2氯离子通道门控的分子解析
Molecular dissection of gating in the ClC-2 chloride channel.
作者信息
Jordt S E, Jentsch T J
机构信息
Centre for Molecular Neurobiology (ZMNH), Hamburg University, Germany.
出版信息
EMBO J. 1997 Apr 1;16(7):1582-92. doi: 10.1093/emboj/16.7.1582.
Abstract
The ClC-2 chloride channel is probably involved in the regulation of cell volume and of neuronal excitability. Site-directed mutagenesis was used to understand ClC-2 activation in response to cell swelling, hyperpolarization and acidic extracellular pH. Similar to equivalent mutations in ClC-0, neutralizing Lys566 at the end of the transmembrane domains results in outward rectification and a shift in voltage dependence, but leaves the basic gating mechanism, including swelling activation, intact. In contrast, mutations in the cytoplasmic loop between transmembrane domains D7 and D8 abolish all three modes of activation by constitutively opening the channel without changing its pore properties. These effects resemble those observed with deletions of an amino-terminal inactivation domain, and suggest that it may act as its receptor. Such a 'ball-and-chain' type mechanism may act as a final pathway in the activation of ClC-2 elicited by several stimuli.
摘要
氯离子通道ClC-2可能参与细胞体积调节和神经元兴奋性调节。采用定点诱变技术来了解ClC-2在细胞肿胀、超极化和细胞外酸性pH值作用下的激活情况。与ClC-0中的等效突变相似,跨膜结构域末端的中和性赖氨酸566突变导致外向整流和电压依赖性改变,但基本门控机制(包括肿胀激活)保持完整。相比之下,跨膜结构域D7和D8之间的胞质环突变通过持续开放通道而不改变其孔道特性,消除了所有三种激活模式。这些效应类似于氨基末端失活结构域缺失时观察到的效应,表明它可能作为其受体起作用。这种“球链”型机制可能是多种刺激引发的ClC-2激活的最终途径。
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