[Sinus node dysfunction, Brugada syndrome and long QT syndrome affecting the same patient†: when genetics can't make head or tail of it]. / Dysfonction sinusale, syndrome de Brugada et syndrome du QT long chez un même patient - Quand la génétique y perd son latin.

The gene SCN5A encodes the cardiac sodium channel which, through the conduction of Na+ current into the cell, generates the fast upstroke of the action potential of cardiomyocytes. Pathogenic variants of SCN5A have been causally associated to several hereditary cardiac diseases including, among others, Brugada syndrome, congenital long QT syndrome and sinus node dysfunction. Recently, overlap syndromes have been described that are characterized by the simultaneous expression of mixed clinical phenotypes among two or more hereditary cardiac diseases associated to the gene SCN5A (HCD-SCN5A). For this reason, it is time to rethink about HCD-SCN5A as different expressions of the same complex spectrum encompassing multiple clinical phenotypes with pronounced overlaps instead of as distinct clinical entities.

Le gène SCN5A code pour le canal sodique cardiaque qui est responsable de la pente de dépolarisation rapide du potentiel d'action. Plusieurs cardiopathies héréditaires (CH) ont été associées à des variants pathogènes du gène SCN5A incluant, entre autres, le syndrome de Brugada, le syndrome du QT long congénital et la dysfonction sinusale. Récemment, des syndromes de chevauchement ont été également décrits, s'exprimant, chez un même patient, par un phénotype clinique mixte comprenant une combinaison des manifestations rapportées ci-dessus. Dans ce contexte, nous devrions donc reconsidérer cliniquement les CH impliquant le gène SCN5A comme des expressions différentes d'un même éventail de phénotypes cliniques avec chevauchements marqués plutôt que comme des entités cliniques distinctes et isolées.

Identification and molecular characterisation of Lausanne Institutional Biobank participants with familial hypercholesterolaemia - a proof-of-concept study.

AIMS: We aimed to identify familial hypercholesterolaemia mutation carriers among participants to the Lausanne Institutional Biobank (BIL). Our experimental workflow was designed as a proof-of-concept demonstration of the resources and services provided by our integrated institutional clinical research support platform. METHODS: Familial hypercholesterolaemia was used as a model of a relatively common yet often underdiagnosed and inadequately treated Mendelian disease. Clinical and laboratory information was extracted from electronic hospital records. Patients were selected using elevated plasma cholesterol levels (total cholesterol ≥7.5 mM or low-density lipoprotein cholesterol ≥5 mM), premature coronary artery disease status and age (18-60 yr) as main inclusion criteria. LDLR, APOB and PCSK9 were analysed by high-throughput DNA sequencing. The most relevant mutations were confirmed by Sanger sequencing. RESULTS: Of 23 737 patients contacted by the BIL, 17 760 individuals consented to participate and 13 094 wished to be recontacted if there were findings requiring clinical action. Plasma cholesterol records were available for 5111 participants, of whom 94 were selected for genetic screening. Twenty-five of the tested patients presented with premature coronary artery disease while 69 had no such diagnosis. Seven heterozygous carriers of eight rare coding missense variants were identified. Three mutations were pathogenic (APOB p.R3527Q) or likely pathogenic (LDLR p.C27W, LDLR p.P526S) for hypercholesterolaemia, while the others were either benign or of unknown significance. One patient was a double heterozygote for variants APOB p.R3527Q and LDLR p.P526S. CONCLUSION: This work illustrates how clinical and translational research can benefit from a dedicated platform integrating both a hospital-based biobank and a data support team.

Genetic analysis of cardiac SCN5A Gene in Iranian patients with hereditary cardiac arrhythmias.

OBJECTIVE: SCN5A encodes alpha subunit of the major sodium channel (Nav1.5) in human cardiac tissue. Malfunction of this cardiac sodium channel is associated with a variety of cardiac arrhythmias and myocardial inherited diseases. METHODS: Fifty-three members from three families each diagnosed with long-QT syndrome type 3 (LQTS3), Brugada syndrome (BrS), or sick sinus syndrome (SSS) were included in this observational, cross-sectional study. In this study, we analyzed the sequences of coding region of the SCN5A gene. RESULTS: Eleven members of the LQTS family (39%) showed p.Gln1507-Lys1508-Pro1509del mutation, 8 of BrS family (50%) showed p.Arg222Ter nonsense mutation, and 5 of 9 SSS family members (55%) showed a novel p.Met1498Arg mutation in the SCN5A gene. CONCLUSION: p.Gln1507-Lys1508-Pro1509del mutation, p.Arg222Ter nonsense mutation, and p.Met1498Arg in LQTS, BrS, and SSS, respectively, are reported for the first time in the Iranian population. Information regarding underlying genetic defects would be necessary for verifying certain clinically diagnosed arrhythmia types, carrier screening in affected families, and more precise therapy of the patients are required.