Channelpedia

PubMed 15621041


Referenced in: none

Automatically associated channels: Kv7.1 , Slo1



Title: Intrinsic mechanism of the enhanced rate-dependent QT shortening in the R1623Q mutant of the LQT3 syndrome.

Authors: Yasushi Oginosawa, Toshihisa Nagatomo, Haruhiko Abe, Naomasa Makita, Jonathan C Makielski, Yasuhide Nakashima

Journal, date & volume: Cardiovasc. Res., 2005 Jan 1 , 65, 138-47

PubMed link: http://www.ncbi.nlm.nih.gov/pubmed/15621041


Abstract
In the type 3 long QT syndrome (LQT3), arrhythmia events tend to occur at rest or during sleep. One of the mutations, R1623Q, is located in the voltage sensor of the cardiac sodium channel (hH1), and patients with R1623Q mutation have been also reported to show bradycardia-dependent cardiac events. Although the mutant channel has been characterized by inactivation gating defects, the intrinsic mechanism(s) that might explain why arrhythmia attack is most prevalent at slower heart rates has not been investigated.cDNA encoding either the wild-type or the R1623Q mutant of hH1 was stably transfected into HEK293 cells. I(Na) was recorded using a whole-cell patch-clamp technique at 23 degrees C.A train of 50 depolarizing pulses from holding potentials (-120 and -80 mV) to -20 mV or a train of 50 action potential waveforms was applied at different frequencies. When using a rectangular waveform voltage clamp protocol, rate-dependent reduction of I(Na) was holding voltage-dependent but was not different between peak I(Na) and late I(Na). However, using the action potential clamp, preferential rate-dependent reduction of the phase 3 I(Na) was obvious as compared with peak I(Na). The discrepancy in the rate-dependent reduction between protocols was attributed to accelerated recovery from inactivation under non-equilibrium condition.The rate dependency of phase 3 I(Na) under non-equilibrium gating is a novel mechanism to explain the enhanced rate-dependent QT-shortening in LQT3 patients. Our findings are important for genotype-phenotype correlations in LQT3 mutants as well as for understanding the function of S4 segment of domain IV region in the cardiac Na(+) channel.