Bradycardia in a long QT type 2 family: coinciding KCNH2 and HCN4 variants

Abstract

Abstract Funding Acknowledgements Type of funding sources: Public grant(s) – National budget only. Main funding source(s): the Dutch Research Council: NWO Talent Scheme Background A large multigenerational family harboring a pathogenic KCNH2 variant (L69P) was identified. This gene encodes the hERG channel, responsible for the cardiac rapid delayed rectifier K+ current (IKr). Pathogenic variants in KCNH2 can cause Long QT syndrome type 2 (LQTS2). Interestingly, in addition to LQTS2 we observed a high incidence of bradycardia in this family. Bradycardia is a known feature of some types of LQTS. However, evidence of bradycardia in LQTS2 is limited to a few sporadic cases. Purpose This study aims to identify the genetic variants and biophysiological changes in ion channel function, explanatory of the phenotypes LQTS2 and bradycardia. Methods An overview of the phenotype and genetic information of the index and family members was generated , including symptoms and electrocardiogram (ECG) parameters. QTc was calculated using Bazetts’ correction. Segregation of the identified genetic variants with LQTS and bradycardia were determined by LOD score. Biophysiological properties of the encoded ion channels was measured by manual whole-cell patch-clamp experiments. Results On the basis of linkage analysis, the pathogenic variant KCNH2-p.L69P was found to be unrelated to the bradycardia. Therefore, Sanger sequencing of HCN4, encoding the channel responsible for the hyperpolarization-activated current (If), an important current for sinoatrial node automaticity, was performed. We identified the HCN4-p.R666W variant in multiple family members, which co-segregated with bradycardia (LOD-score 3.2). Patients carrying both variants had more severe phenotypes than carriers of a single variant. Patch-clamp experiments in HEK293A-cells expressing wild type, or KCNH2-p.L69P show a reduced current density, and an altered time component of the fast deactivation, explaining the observed LQTS2. Functional assays of HCN4-p.R666W will elucidate the biophysiological changes possibly underlying the bradycardia. Conclusion we present a large multigenerational family that harbors a likely pathogenic variant in HCN4 in conjunction with a pathogenic variant of KCNH2. Double carriers were more affected than single carriers, arguing for continued alertness and deep phenotyping even in families with known pathogenic variants. Furthermore, we identified functional changes in the kinetics of the hERG channel encoded by KCNH2-p.L69P, elucidating the molecular mechanism underlying LQTS2 in this family.