对参与电压门控的电鳐氯离子通道ClC-0的通透和门控的蛋白质区域的分析。
Analysis of a protein region involved in permeation and gating of the voltage-gated Torpedo chloride channel ClC-0.
作者信息
Ludewig U, Jentsch T J, Pusch M
机构信息
Centre for Molecular Neurobiology (ZMNH), Hamburg University, Germany.
出版信息
J Physiol. 1997 Feb 1;498 ( Pt 3)(Pt 3):691-702. doi: 10.1113/jphysiol.1997.sp021893.
Abstract
- The chloride channel from the Torpedo electric organ, ClC-0, is controlled by two distinct ('fast' and 'slow') voltage-dependent gates. Here we investigate the effects of mutations in a region after putative transmembrane domain D12. A mutation in this region has previously been shown to change fast gating and permeation. 2. We used a combination of site-directed mutagenesis with two-electrode voltage-clamp and patch-clamp measurements. 3. Most conservative substitutions have minor effects, while more drastic mutations change kinetics and voltage dependence of fast gating, as well as ion selectivity and rectification. 4. While ClC-0 wild-type (WT) channels deactivate fully in two-electrode voltage clamp at negative voltages, channels do not close completely in patch-clamp experiments. Open probability is increased by intracellular chloride in a concentration- but not voltage-dependent manner. 5. In several mutants, including K519R, the minimal macroscopic open probability of fast gating is larger than in WT. Mutant channels fluctuate at negative potentials between open and closed conformations. Open probability is much more effectively increased by intracellular chloride than in WT. The observations support the idea that permeating ions inside the pore stabilize the open state. 6. Besides effects on permeation and gating of single protopores, some mutations affect 'slow' gating. In summary, the region after D12 participates in fast as well as in slow gating; mutations additionally influence permeation properties.
摘要
- 电鳐电器官中的氯离子通道ClC-0由两个不同的(“快速”和“慢速”)电压依赖性门控机制控制。在此,我们研究了假定跨膜结构域D12之后区域的突变效应。此前已表明该区域的一个突变会改变快速门控和通透特性。2. 我们将定点突变与双电极电压钳和膜片钳测量相结合。3. 大多数保守性替换影响较小,而更剧烈的突变会改变快速门控的动力学和电压依赖性,以及离子选择性和整流特性。4. 虽然ClC-0野生型(WT)通道在双电极电压钳中于负电压下能完全失活,但在膜片钳实验中通道不会完全关闭。细胞内氯离子以浓度依赖性而非电压依赖性方式增加开放概率。5. 在包括K519R在内的几个突变体中,快速门控的最小宏观开放概率大于野生型。突变通道在负电位下在开放和关闭构象之间波动。细胞内氯离子增加开放概率的效果比野生型更显著。这些观察结果支持孔内通透离子稳定开放状态这一观点。6. 除了对单个原孔的通透和门控产生影响外,一些突变还影响“慢速”门控。总之,D12之后的区域参与快速和慢速门控;突变还会影响通透特性。
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