Channelpedia

PubMed 18048769


Referenced in Channelpedia wiki pages of: none

Automatically associated channels: Nav1.5 , Slo1



Title: Divergent biophysical defects caused by mutant sodium channels in dilated cardiomyopathy with arrhythmia.

Authors: Thao P Nguyen, Dao W Wang, Thomas H Rhodes, Alfred L George

Journal, date & volume: Circ. Res., 2008 Feb 15 , 102, 364-71

PubMed link: http://www.ncbi.nlm.nih.gov/pubmed/18048769


Abstract
Mutations in SCN5A encoding the principal Na+ channel alpha-subunit expressed in human heart (Na(V)1.5) have recently been linked to an inherited form of dilated cardiomyopathy with atrial and ventricular arrhythmia. We compared the biophysical properties of 2 novel Na(V)1.5 mutations associated with this syndrome (D2/S4--R814W; D4/S3--D1595H) with the wild-type (WT) channel using heterologous expression in cultured tsA201 cells and whole-cell patch-clamp recording. Expression levels were similar among WT and mutant channels, and neither mutation affected persistent sodium current. R814W channels exhibited prominent and novel defects in the kinetics and voltage dependence of activation characterized by slower rise times and a hyperpolarized conductance-voltage relationship resulting in an increased "window current." This mutant also displayed enhanced slow inactivation and greater use-dependent reduction in peak current at fast pulsing frequencies. By contrast, D1595H channels exhibited impaired fast inactivation characterized by slower entry into the inactivated state and a hyperpolarized steady-state inactivation curve. Our findings illustrate the divergent biophysical defects caused by 2 different SCN5A mutations associated with familial dilated cardiomyopathy. Retrospective review of the published clinical data suggested that cardiomyopathy was not common in the family with D1595H, but rather sinus bradycardia was the predominant clinical finding. However, for R814W, we speculate that an increased window current coupled with enhanced slow inactivation and rate-dependent loss of channel availability provided a unique substrate predisposing myocytes to disordered Na+ and Ca2+ homeostasis leading to myocardial dysfunction.