异氟烷对电压门控性钠离子通道的亚型选择性作用。

Isoform-selective effects of isoflurane on voltage-gated Na+ channels.

作者信息

OuYang Wei, Hemmings Hugh C

机构信息

Department of Anesthesiology, Weill Cornell Medical College, NY, NY 10021, USA.

出版信息

Anesthesiology. 2007 Jul;107(1):91-8. doi: 10.1097/01.anes.0000268390.28362.4a.

DOI:10.1097/01.anes.0000268390.28362.4a

PMID:17585220

Abstract

BACKGROUND

Voltage-gated Na channels modulate membrane excitability in excitable tissues. Inhibition of Na channels has been implicated in the effects of volatile anesthetics on both nervous and peripheral excitable tissues. The authors investigated isoform-selective effects of isoflurane on the major Na channel isoforms expressed in excitable tissues.

METHODS

Rat Nav1.2, Nav1.4, or Nav1.5 alpha subunits heterologously expressed in Chinese hamster ovary cells were analyzed by whole cell voltage clamp recording. The effects of isoflurane on Na current activation, inactivation, and recovery from inactivation were analyzed.

RESULTS

The cardiac isoform Nav1.5 activated at more negative potentials (peak INa at -30 mV) than the neuronal Nav1.2 (0 mV) or skeletal muscle Nav1.4 (-10 mV) isoforms. Isoflurane reversibly inhibited all three isoforms in a concentration- and voltage-dependent manner at clinical concentrations (IC50 = 0.70, 0.61, and 0.45 mm, respectively, for Nav1.2, Nav1.4, and Nav1.5 from a physiologic holding potential of -70 mV). Inhibition was greater from a holding potential of -70 mV than from -100 mV, especially for Nav1.4 and Nav1.5. Isoflurane enhanced inactivation of all three isoforms due to a hyperpolarizing shift in the voltage dependence of steady state fast inactivation. Inhibition of Nav1.4 and Nav1.5 by isoflurane was attributed primarily to enhanced inactivation, whereas inhibition of Nav1.2, which had a more positive V1/2 of inactivation, was due primarily to tonic block.

CONCLUSIONS

Two principal mechanisms contribute to Na channel inhibition by isoflurane: enhanced inactivation due to a hyperpolarizing shift in the voltage dependence of steady state fast inactivation (Nav1.5 approximately Nav1.4 > Nav1.2) and tonic block (Nav1.2 > Nav1.4 approximately Nav1.5). These novel mechanistic differences observed between isoforms suggest a potential pharmacologic basis for discrimination between Na channel isoforms to enhance anesthetic specificity.

摘要

背景

电压门控钠通道调节可兴奋组织中的膜兴奋性。钠通道的抑制与挥发性麻醉药对神经和外周可兴奋组织的作用有关。作者研究了异氟烷对可兴奋组织中表达的主要钠通道亚型的亚型选择性作用。

方法

通过全细胞膜片钳记录分析在中国仓鼠卵巢细胞中异源表达的大鼠Nav1.2、Nav1.4或Nav1.5α亚基。分析了异氟烷对钠电流激活、失活和从失活中恢复的影响。

结果

心脏亚型Nav1.5比神经元Nav1.2（0 mV）或骨骼肌Nav1.4（-10 mV）亚型在更负的电位下激活（-30 mV时INa峰值）。在临床浓度下，异氟烷以浓度和电压依赖性方式可逆地抑制所有三种亚型（从-70 mV的生理钳制电位开始，Nav1.2、Nav1.4和Nav1.5的IC50分别为0.70、0.61和0.45 mM）。从-70 mV的钳制电位比-100 mV的抑制作用更强，尤其是对于Nav1.4和Nav1.5。由于稳态快速失活的电压依赖性发生超极化偏移，异氟烷增强了所有三种亚型的失活。异氟烷对Nav1.4和Nav1.5的抑制主要归因于失活增强，而对失活V1/2更正的Nav1.2的抑制主要归因于强直阻滞。