Exome-chip meta-analysis identifies novel loci associated with cardiac conduction, including ADAMTS6

Background: Genome-wide association studies conducted on QRS duration, an electrocardiographic measurement associated with heart failure and sudden cardiac death, have led to novel biological insights into cardiac function. However, the variants identified fall predominantly in non-coding regions and their underlying mechanisms remain unclear.Results: Here, we identify putative functional coding variation associated with changes in the QRS interval duration by combining Illumina HumanExome BeadChip genotype data from 77,898 participants of European ancestry and 7695 of African descent in our discovery cohort, followed by replication in 111,874 individuals of European ancestry from the UK Biobank and deCODE cohorts. We identify ten novel loci, seven within coding regions, including ADAMTS6, significantly associated with QRS duration in gene-based analyses. ADAMTS6 encodes a secreted metalloprotease of currently unknown function. In vitro validation analysis shows that the QRS-associated variants lead to impaired ADAMTS6 secretion and loss-of function analysis in mice demonstrates a previously unappreciated role for ADAMTS6 in connexin 43 gap junction expression, which is essential for myocardial conduction.Conclusions: Our approach identifies novel coding and non-coding variants underlying ventricular depolarization and provides a possible mechanism for the ADAMTS6-associated conduction changes

Discovery of novel heart rate-associated loci using the Exome Chip

Resting heart rate is a heritable trait, and an increase in heart rate is associated with increased mortality risk. Genome-wide association study analyses have found loci associated with resting heart rate, at the time of our study these loci explained 0.9% of the variation. This study aims to discover new genetic loci associated with heart rate from Exome Chip meta-analyses. Heart rate was measured from either elecrtrocardiograms or pulse recordings. We meta-analysed heart rate association results from 104 452 European-ancestry individuals from 30 cohorts, genotyped using the Exome Chip. Twenty-four variants were selected for follow-up in an independent dataset (UK Biobank, N = 134 251). Conditional and gene-based testing was undertaken, and variants were investigated with bioinformatics methods.We discovered five novel heart rate loci, and one new independent low-frequency non-synonymous variant in an established heart rate locus (KIAA1755). Lead variants in four of the novel loci are non-synonymous variants in the genes C10orf71, DALDR3, TESK2 and SEC31B. The variant at SEC31B is significantly associated with SEC31B expression in heart and tibial nerve tissue. Further candidate genes were detected from long-range regulatory chromatin interactions in heart tissue (SCD, SLF2 and MAPK8). We observed significant enrichment in DNase I hypersensitive sites in fetal heart and lung. Moreover, enrichment was seen for the first time in human neuronal progenitor cells (derived from embryonic stem cells) and fetal muscle samples by including our novel variants.Our findings advance the knowledge of the genetic architecture of heart rate, and indicate new candidate genes for follow-up functional studies

Cardiac Sodium Channel (Dys)Function and Inherited Arrhythmia Syndromes

Normal cardiac sodium channel function is essential for ensuring excitability of myocardial cells and proper conduction of the electrical impulse within the heart. Cardiac sodium channel dysfunction is associated with an increased risk of arrhythmias and sudden cardiac death. Over the last 20 years, (combined) genetic, electrophysiological, and molecular studies have provided insight into the (dys)function and (dys)regulation of the cardiac sodium channel under physiological circumstances and in the setting of SCN5A mutations identified in patients with inherited arrhythmia syndromes. Although our understanding of these sodium channelopathies has increased substantially, important issues remain incompletely understood. It has become increasingly clear that sodium channel distribution, function, and regulation are more complicated than traditionally assumed. Moreover, recent evidence suggests that the sodium channel may play additional, as of yet unrecognized, roles in cardiomyocyte function, which in turn may ultimately also impact on arrhythmogenesis. In this chapter, an overview is provided of the structure and function of the cardiac sodium channel and the clinical and biophysical characteristics of inherited sodium channel dysfunction. In addition, more recent insights into the electrophysiological and molecular aspects of sodium channel dysregulation and dysfunction in the setting of SCN5A mutations are discussed