Binding kinetics of quaternary ammonium ions in Kcv potassium channels.

Channels (Austin, Tex.) Pub Date : 2024-12-01 Epub Date: 2024-10-09 DOI:10.1080/19336950.2024.2402749
Tobias Korn, Ulf-Peter Hansen, Tobias Sebastian Gabriel, Oliver Rauh, Nils Drexler, Indra Schroeder
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Abstract

Kcv channels from plant viruses represent the autonomous pore module of potassium channels, devoid of any regulatory domains. These small proteins show very reproducible single-channel behavior in planar lipid bilayers. Thus, they are an optimum system for the study of the biophysics of ion transport and gating. Structural models based on homology modeling have been used successfully, but experimental structural data are currently not available. Here we determine the size of the cytosolic pore entrance by studying the blocker kinetics. Blocker binding and dissociation rate constants ranging from 0.01 to 1000 ms-1 were determined for different quaternary ammonium ions. We found that the cytosolic pore entrance of KcvNTS must be at least 11 Å wide. The results further indicate that the residues controlling a cytosolic gate in one of the Kcv isoforms influence blocker binding/dissociation as well as a second gate even when the cytosolic gate is in the open state. The voltage dependence of the rate constant of blocker release is used to test, which blockers bind to the same binding site.

季铵盐离子在 Kcv 钾通道中的结合动力学。
来自植物病毒的 Kcv 通道代表了钾通道的自主孔模块,没有任何调节结构域。这些小蛋白在平面脂质双分子层中显示出非常可重现的单通道行为。因此,它们是研究离子转运和门控生物物理学的最佳系统。基于同源建模的结构模型已被成功应用,但目前还没有实验结构数据。在这里,我们通过研究阻断剂动力学来确定细胞膜孔入口的大小。我们测定了不同季铵盐离子的阻断剂结合和解离速率常数,范围从 0.01 到 1000 ms-1。我们发现,KcvNTS 的胞浆孔入口必须至少有 11 Å 宽。结果进一步表明,在 Kcv 的一种异构体中,控制胞吐门的残基会影响阻断剂的结合/解离以及第二个门,即使胞吐门处于打开状态。阻滞剂释放速率常数的电压依赖性被用来测试哪些阻滞剂与相同的结合位点结合。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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