人类心脏钠通道中的缓慢失活

Slow inactivation in human cardiac sodium channels.

作者信息

Richmond J E, Featherstone D E, Hartmann H A, Ruben P C

机构信息

Department of Biology, Utah State University, Logan 84322-5305, USA.

出版信息

Biophys J. 1998 Jun;74(6):2945-52. doi: 10.1016/S0006-3495(98)78001-4.

DOI:10.1016/S0006-3495(98)78001-4

PMID:9635748

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1299635/

Abstract

The available pool of sodium channels, and thus cell excitability, is regulated by both fast and slow inactivation. In cardiac tissue, the requirement for sustained firing of long-duration action potentials suggests that slow inactivation in cardiac sodium channels may differ from slow inactivation in skeletal muscle sodium channels. To test this hypothesis, we used the macropatch technique to characterize slow inactivation in human cardiac sodium channels heterologously expressed in Xenopus oocytes. Slow inactivation was isolated from fast inactivation kinetically (by selectively recovering channels from fast inactivation before measurement of slow inactivation) and structurally (by modification of fast inactivation by mutation of IFM1488QQQ). Time constants of slow inactivation in cardiac sodium channels were larger than previously reported for skeletal muscle sodium channels. In addition, steady-state slow inactivation was only 40% complete in cardiac sodium channels, compared to 80% in skeletal muscle channels. These results suggest that cardiac sodium channel slow inactivation is adapted for the sustained depolarizations found in normally functioning cardiac tissue. Complete slow inactivation in the fast inactivation modified IFM1488QQQ cardiac channel mutant suggests that this impairment of slow inactivation may result from an interaction between fast and slow inactivation.

摘要

钠通道的可用储备以及细胞兴奋性受快速失活和缓慢失活的双重调控。在心脏组织中，持续发放长时程动作电位的需求表明，心脏钠通道的缓慢失活可能不同于骨骼肌钠通道的缓慢失活。为验证这一假说，我们采用巨膜片钳技术对非洲爪蟾卵母细胞中异源表达的人心脏钠通道的缓慢失活特性进行了表征。通过动力学方法（在测量缓慢失活之前，先选择性地从快速失活状态恢复通道）和结构方法（通过IFM1488QQQ突变改变快速失活）将缓慢失活与快速失活区分开来。心脏钠通道缓慢失活的时间常数大于先前报道的骨骼肌钠通道的时间常数。此外，心脏钠通道的稳态缓慢失活仅完成40%，而骨骼肌通道为80%。这些结果表明，心脏钠通道的缓慢失活适应了正常功能心脏组织中存在的持续去极化。快速失活修饰的IFM1488QQQ心脏通道突变体中缓慢失活的完全缺失表明，这种缓慢失活的损害可能源于快速失活与缓慢失活之间的相互作用。

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