1268A family with a novel variant in the SLC4A3 gene leading to short QT phenotype - the importance of whole-exome-sequencing and cascade screening

Abstract

Abstract Funding Acknowledgements none Introduction Short QT syndrome (SQTS) is a rare, autosomal dominant disease causing ventricular fibrillation and sudden cardiac death. Genetic testing is recommended according to current guidelines. Mutations in KCNQ1, KCNH2, KCNJ2 and more recently SLC4A3 genes have been implicated in SQTS. These genes encode potassium channel subunits and a bicarbonate transporter regulating intracellular pH. A dominant mutation in this transporter can lead to increased intracellular pH and shortened action potential. Purpose We present a family with a short QT phenotype and recurrent syncope in whom a novel genetic variant was detected by whole-exome sequencing (WES), confirmed by cascade screening. Methods We performed a thorough work-up of the index patient including medical history, physical examination, 12-lead ECG, echocardiography, stress testing, coronary angiography, flecainide challenge, and genetic testing with NGS. QTc was determined using Bazett’s formula. CS of all 1° and two 2° relatives was performed. Results The ECG of the index patient showed a QTc of 340ms and characteristics compatible with a SQTS (figure). Clinical work-up was unremarkable. A first genetic search with next generation sequencing focusing on genes that have been previously involved in the pathogenesis of channelopathies detected a rare known heterozygous missense variant in the KCNH2 gene (Arg328Cys, frequency 0.053%), which was predicted to be pathogenic according to various prediction algorithms (Polyphen, SIFT, Align GVGD, mutation taster). ECG screening of all asymptomatic first-degree family members identified a SQT phenotype in the mother (QTc 355ms), but not in the father (QTc 380ms) and sister (410ms). The KCNH2 variant was found in the father and sister but not the affected mother, which excludes this variant as the causative mutation in this family. Therefore, reanalysis of WES data was performed and revealed a novel heterozygous missense variant p.(Arg370Cys) in the SLC4A3 gene, recently associated with SQTS. A mutation in this gene at the same position has been previously reported in SQTS. The p.(Arg370Cys) mutation was found in the mother but not in the unaffected father or sister. Furthermore the mutation was present in two affected maternal uncles (QTc 319ms and 342ms) supporting the assumption that this was the causative mutation in this family. Conclusions A novel genetic variant in the SLC4A3 gene leading to sQT phenotype could be detected using WES and cascade screening. Predictive bioinformatic algorithms to assess the pathogenicity of missense variants are of limited relevance, but genetic analysis of additional unaffected and affected family members may be instrumental to identify pathogenic DNA sequence variations. Abstract Figure. Pedigree and ECGs of the family