Abstract 12269: Investigating Arrhythmogenic Potential of a Novel KCNH2 Mutation Leading to Long QT Syndrome

Abstract

Background: Mutations in the gene KCNH2 have been associated with both Short and Long QT syndrome. In this study, we identified a 1-day old infant that exhibited T-wave alternans coupled with Long QT Syndrome leading to aborted sudden infant death. Methods: Genetic analysis of the patient revealed a mutation in KCNH2 resulting in a proline to leucine substitution at position 632 (P632L). Functional electrophysiological studies were performed with the hERG mutation transiently transfected into either Human Embryonic Kidney (HEK) cells or human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs). The functional effects of P632L were incorporated into biophysical computational models of hiPSC-CM as well as adult human cardiomyocytes to further assess its arrhythmogenic potential. Results: The male infant displayed multiple repolarization disorders including T-wave alternans and a QTc =510 ms that appeared 1 day after birth. Genetic screening revealed a heterozygous missense mutation (P632L) in KCNH2 in the infant. Patch clamp analysis of HEK cells transiently transfected with P632L mutation showed a complete loss of function of HERG current compared to WT HERG. Transient transfection of P632L into WT hiPSC myocytes resulted in prolongation of the hiPSC action potential compared to untransfected hiPSC myocytes. Co-transfection of WT and non-functional P632L channels into HEK cells resulted in a dramatic loss of current suggesting a dominant negative effect. Implementing the effects of a complete block of HERG current in the hiPSC-CM computer model prolonged the action potential by 45% and depolarized the resting membrane potentials. In adult human myocyte models, the effects of HERG blockade were more severe in Purkinje cells than that in ventricular myocytes (71% vs. 16% APD prolongation, respectively). Conclusions: The mutation P632L causes a complete loss of HERG current and results in QT prolongation. Numerical simulations suggest a more severe phenotype in Purkinje cells than in ventricular myocytes which could be proarrhythmic.