Background: This study aimed to show the mechanism how the HERG channel gating defects causes life-threatening arrhythmia in the short-QT syndrome, using a simulation model of ventricular action potentials (APs).
Methods and results: To evaluate the electrophysiological consequences of the short-QT syndrome at the level of the cardiac AP, the Markov model of wild-type (WT) KCNH2 channel was modified to obtain a model of the KCNH2 channel with the N588K mutation associated with the short-QT syndrome. Two parameters (betai and betabeta) were changed to reconstruct the N588K mutant Markov model, which successfully reproduced the experimental results of voltage-clamp recordings. The WT and mutant models were then integrated into the Luo-Rudy theoretical model of the cardiac ventricular AP. Unexpectedly, 1 parameter change alone, which caused gain of function, could shorten the AP duration (APD) but failed to induce early after-depolarizations (EADs). Only the condition with the combined gating defects could lead to EAD.
Conclusions: Although the gain of function for KCNH2 shortened APD in the short-QT syndrome, this simulation study suggested that arrhythmogenesis was associated not only with gain of function, but also with accelerated deactivation of KCNH2.