KCNH2 mutation c.3099_3112del causes congenital long QT syndrome type 2 with gender differences.

INTRODUCTION: Long QT Syndrome (LQTS) is an inherited disease with an abnormal electrical conduction system in the heart that can cause sudden death as a result of QT prolongation. LQT2 is the second most common subtype of LQTS caused by loss of function mutations in the potassium voltage-gated channel subfamily H member 2 (KCNH2) gene. Although more than 900 mutations are associated with the LQTS, many of these mutations are not validated or characterized. METHODS AND RESULTS: Sequencing analyses of genomic DNA of a family with LQT2 identified a putative mutation. i.e., KCNH2(NM_000238.3): c.3099_3112del, in KCNH2 gene which appeared to be a definite pathogenic mutation. The family pedigree information showed a gender difference in clinical features and T-wave morphology between male and female patients. The female with mutation exhibited recurring ventricular arrhythmia and syncope, while two male carriers did not show any symptoms. In addition, T-wave in females was much flatter than in males. The female proband showed a positive reaction to the lidocaine test. Lidocaine injection almost completely blocked ventricular arrhythmia and shortened the QT interval by ≥30 ms. Treatment with propranolol, mexiletine, and implantation of cardioverter-defibrillators prevented the sustained ventricular tachycardia, ventricular fibrillation, and syncope, as assessed by a 3-year follow-up evaluation. CONCLUSIONS: A putative mutation c.3099_3112del in the KCNH2 gene causes LQT2 syndrome, and the pathogenic mutation mainly causes symptoms in female progeny.

Genetic variants in Colombian patients with inherited cardiac conditions.

BACKGROUND: Clinical and molecular diagnosis of inherited cardiac conditions is key to find at-risk subjects and avoid preventable deaths. This study aimed to identify genetic variants in a sample of Colombian patients diagnosed with inherited cardiac conditions. METHODS: Next-generation sequencing (Illumina platform) using a 231 gene panel was performed in blood samples of 25 unrelated patients with age disease onset between 9 and 55 years. RESULTS: Genetic testing yield was 52%. Two novel likely pathogenic/ pathogenic variants were found: a DSP nonsense variant in a patient with arrhythmogenic cardiomyopathy and a KCNE1 frameshift variant in two patients with long QT syndrome. Younger individuals (<18 years) had the highest genetic testing yield (66.6%) compared to 50% and 20% in young adults and patients over 40 years, respectively. All subjects affected with long QT syndrome with a severe event while exercising had a positive genetic test. They also had four times more loss of consciousness events and, resuscitated sudden cardiac arrest was more representative. CONCLUSION: This study is the first one undertaken in Colombia to evaluate inherited cardiac conditions. It highlights the need to perform mutational analysis to provide adequate genetic counseling and to be able to identify patients at risk of severe events.

Phenotypes of mutations related to voltage-dependent sodium channels on children and adolescents.

Cardiac channelopathies are a heterogeneous group of inherited cardiac diseases that are associated with mutations in the genes that encode the expression of cardiac ion channels. In view of this, it can be mentioned that the main hereditary arrhythmias in children and adolescents, caused by dysfunction of the ion channels, are Brugada Syndrome (BrS) and Long QT Syndrome (LQTS). However, few studies address the physiological effects of these conditions on children and adolescents. Thus, the aim of this study is to describe the mutation phenotype related to voltage-gated sodium channels in children and adolescents. A search was performed in the literature of PubMed, Scielo, and Google scholar. The search was limited to articles written in the last 5 years, so articles published between 2014 and 2019 were included. Among 2196 studies identified through a systematic literature review, 30 studies related to the theme were identified for a complete review and after applying exclusion criteria, 4 articles were included in the results of this study. As the most frequently observed channelopathy, BrS was also more identified in children and adolescents, characterized by episodes of syncope or sudden cardiac death. LQTS shows clinical manifestations with a mild phenotype and good prognosis, although it is necessary to monitor and correct serum electrolyte disturbances to prevent ventricular arrhythmias and, consequently, sudden death in patients with the pathology. The aim of this study is to find the general phenotypes related to genetic mutations of voltage-gated sodium channels, in a population aged from 7- to 14-year-old.

Structural Modelling of KCNQ1 and KCNH2 Double Mutant Proteins, Identified in Two Severe Long QT Syndrome Cases, Reveals New Insights into Cardiac Channelopathies.

Congenital long QT syndrome (LQTS) is a cardiac channelopathy characterized by a prolongation of the QT interval and T-wave abnormalities, caused, in most cases, by mutations in KCNQ1, KCNH2, and SCN5A. Although the predominant pattern of LQTS inheritance is autosomal dominant, compound heterozygous mutations in genes encoding potassium channels have been reported, often with early disease onset and more severe phenotypes. Since the molecular mechanisms underlying severe phenotypes in carriers of compound heterozygous mutations are unknown, it is possible that these compound mutations lead to synergistic or additive alterations to channel structure and function. In this study, all-atom molecular dynamic simulations of KCNQ1 and hERG channels were carried out, including wild-type and channels with compound mutations found in two patients with severe LQTS phenotypes and limited family history of the disease. Because channels can likely incorporate different subunit combinations from different alleles, there are multiple possible configurations of ion channels in LQTS patients. This analysis allowed us to establish the structural impact of different configurations of mutant channels in the activated/open state. Our data suggest that channels with these mutations show moderate changes in folding energy (in most cases of stabilizing character) and changes in channel mobility and volume, differentiating them from each other and from WT. This would indicate possible alterations in K+ ion flow. Hetero-tetrameric mutant channels showed intermediate structural and volume alterations vis-à-vis homo-tetrameric channels. These findings support the hypothesis that hetero-tetrameric channels in patients with compound heterozygous mutations do not necessarily lead to synergistic structural alterations.

Clinical Spectrum of SCN5A Channelopathy in Children with Primary Electrical Disease and Structurally Normal Hearts.

Sodium voltage-gated channel α subunit 5 (SCN5A)-mutations may cause an array of arrhythmogenic syndromes most frequently as an autosomal dominant trait, with incomplete penetrance, variable expressivity and male predominance. In the present study, we retrospectively describe a group of Mexican patients with SCN5A-disease causing variants in whom the onset of symptoms occurred in the pediatric age range. The study included 17 patients with clinical diagnosis of primary electrical disease, at least one SCN5A pathogenic or likely pathogenic mutation and age of onset <18 years, and all available first- and second-degree relatives. Fifteen patients (88.2%) were male, and sixteen independent variants were found (twelve missense, three truncating and one complex inframe deletion/insertion). The frequency of compound heterozygosity was remarkably high (3/17, 17.6%), with early childhood onset and severe disease. Overall, 70.6% of pediatric patients presented with overlap syndrome, 11.8% with isolated sick sinus syndrome, 11.8% with isolated Brugada syndrome (BrS) and 5.9% with isolated type 3 long QT syndrome (LQTS). A total of 24/45 SCN5A mutation carriers were affected (overall penetrance 53.3%), and penetrance was higher in males (63.3%, 19 affected/30 mutation carriers) than in females (33.3%, 5 affected/15 carriers). In conclusion, pediatric patients with SCNA-disease causing variants presented mainly as overlap syndrome, with predominant loss-of-function phenotypes of sick sinus syndrome (SSS), progressive cardiac conduction disease (PCCD) and ventricular arrhythmias.

E1784K, the most common Brugada syndrome and long-QT syndrome type 3 mutant, disrupts sodium channel inactivation through two separate mechanisms.

Inheritable and de novo variants in the cardiac voltage-gated sodium channel, Nav1.5, are responsible for both long-QT syndrome type 3 (LQT3) and Brugada syndrome type 1 (BrS1). Interestingly, a subset of Nav1.5 variants can cause both LQT3 and BrS1. Many of these variants are found in channel structures that form the channel fast inactivation machinery, altering the rate, voltage dependence, and completeness of the fast inactivation process. We used a series of mutants at position 1784 to show that the most common inheritable Nav1.5 variant, E1784K, alters fast inactivation through two separable mechanisms: (1) a charge-dependent interaction that increases the noninactivating current characteristic of E1784K; and (2) a hyperpolarized voltage dependence and accelerated rate of fast inactivation that decreases the peak sodium current. Using a homology model built on the NavPaS structure, we find that the charge-dependent interaction is between E1784 and K1493 in the DIII-DIV linker of the channel, five residues downstream of the putative inactivation gate. This interaction can be disrupted by a positive charge at position 1784 and rescued with the K1493E/E1784K double mutant that abolishes the noninactivating current. However, the double mutant does not restore either the voltage dependence or rates of fast inactivation. Conversely, a mutant at the bottom of DIVS4, K1641D, causes a hyperpolarizing shift in the voltage dependence of fast inactivation and accelerates the rate of fast inactivation without causing an increase in noninactivating current. These findings provide novel mechanistic insights into how the most common inheritable arrhythmogenic mixed syndrome variant, E1784K, simultaneously decreases transient sodium currents and increases noninactivating currents, leading to both BrS1 and LQT3.

R534C mutation in hERG causes a trafficking defect in iPSC-derived cardiomyocytes from patients with type 2 long QT syndrome.

Patient-specific cardiomyocytes obtained from induced pluripotent stem cells (CM-iPSC) offer unprecedented mechanistic insights in the study of inherited cardiac diseases. The objective of this work was to study a type 2 long QT syndrome (LQTS2)-associated mutation (c.1600C > T in KCNH2, p.R534C in hERG) in CM-iPSC. Peripheral blood mononuclear cells were isolated from two patients with the R534C mutation and iPSCs were generated. In addition, the same mutation was inserted in a control iPSC line by genome editing using CRISPR/Cas9. Cells expressed pluripotency markers and showed spontaneous differentiation into the three embryonic germ layers. Electrophysiology demonstrated that action potential duration (APD) of LQTS2 CM-iPSC was significantly longer than that of the control line, as well as the triangulation of the action potentials (AP), implying a longer duration of phase 3. Treatment with the IKr inhibitor E4031 only caused APD prolongation in the control line. Patch clamp showed a reduction of IKr on LQTS2 CM-iPSC compared to control, but channel activation was not significantly affected. Immunofluorescence for hERG demonstrated perinuclear staining in LQTS2 CM-iPSC. In conclusion, CM-iPSC recapitulated the LQTS2 phenotype and our findings suggest that the R534C mutation in KCNH2 leads to a channel trafficking defect to the plasma membrane.

F463L increases the potential of dofetilide on human ether-a-go-go-related gene (hERG) channels.

Mutations in genes related to long QT syndrome (LQTS) is recognized as an independent risk of drug-induced LQTS. We previously screened a mutation F463L in a Chinese patient with LQT2, syncope, and epilepsy. Here, we planned to illustrate how F463L influences the action of dofetilide on hERG channels. F463L-hERG plasmids were transfected into the stable Human Embryonic Kidney 293 (HEK293) cells expressing WT-hERG to generate heterozygous mutant (WT + F463L-hERG). Whole-cell patch clamp and laser confocal scanning microscopy were used to evaluate electrophysiological consequences and the membrane distribution of hERG protein. In comparison of WT-hERG channels exposed to dofetilide, heterozygous F463L-hERG channels showed a reduction in the density of tail currents when exposed amidarone. F463L-hERG also altered the action of dofetilide on the gating properties of hERG channels. Images of dofetilide-treated cells expressing heterozygous F463L showed a severe retention and reduction of protein expression on the membrane compared to WT. In conclusion, dofetilide displays a powerful inhibitory effect on the currents from cells expressing heterozygous F463L, thus showing an additive suppression of currents by F463L with dofetilide.

Evaluation of electrocardiographic parameters in patients with hearing loss genotyped for the connexin 26 gene (GJB2) mutations / Avaliação dos parâmetros eletrocardiográficos em pacientes com perda auditiva genotipada para mutações do gene conexina 26 (GJB2)

Abstract Introduction: Several studies have associated congenital sensorineural hearing loss in children with prolongation of the cardiac parameter QTc. The cause of this association is unknown. At the same time, mutations in GJB2, which encodes connexin 26, are the most common cause of congenital hearing impairment. Objective: To compare electrocardiographic parameters (PR interval, QRS complex, and QTc interval) in patients with hearing loss who were tested for mutations in GJB2 and GJB6 to investigate whether these mutations affect electrical activity of the heart. Methods: 346 patients (176 males, 170 females) with sensorineural hearing loss of 30 dB HL or more, aged 21.8 ± 19.9 years (including 147 children <14 years), underwent both genetic study for GJB2 and GJB6 mutations and electrocardiography. Results: Mutations in GJB2, including homozygotes and heterozygotes, were found in 112 (32%) patients. There were no significant differences in ECG parameters between groups of patients with and without mutations in GJB2. No differences were observed either in men (mean PR with mutation: 155 ± 16.6 vs. 153.6 ± 30.1 without; QRS: 99.9 ± 9.9 vs. 101.1 ± 15.4; QTc: 414.9 ± 29.9 vs. 412.4 ± 25.7) or women (mean PR with: 148.7 ± 21 vs. 143.8 ± 22.8 without; QRS: 94.8 ± 7.6 vs. 92.9 ± 9.6; QTc: 416.8 ± 20.6 vs. 424.9 ± 22.8). In similar fashion, we did we find any significant differences between groups of children with and without GJB2 mutations (mean PR with: 126.3 ± 19.6 vs. 127 ± 19.7 without; QRS: 80.7 ± 9.5 vs. 79.4 ± 11.6; QTc: 419.7 ± 23.5 vs. 419.8 ± 24.8). Conclusion: No association was found between the presence of GJB2 mutations encoding connexin 26 in patients with hearing loss and their ECG parameters (PR, QRS, QTc).

Resumo Introdução: Vários estudos têm associado a perda auditiva neurossensorial congênita em crianças ao prolongamento do parâmetro cardíaco QTc. A causa dessa associação é desconhecida. Ao mesmo tempo, as mutações no GJB2, que codifica a conexina 26, são a causa mais comum de deficiência auditiva congênita. Objetivo: Comparar parâmetros eletrocardiográficos (intervalo PR, complexos QRS e intervalo QTc) em pacientes com perda auditiva que foram testados para mutações no GJB2 e GJB6 para investigar se essas mutações afetam a atividade elétrica do coração. Método: Foram submetidos a estudo genético para mutações de GJB2 e GJB6 e eletrocardiograma 346 pacientes (176 homens, 170 mulheres) com perda auditiva neurossensorial de 30 dB ou mais, com média de 21,8 ± 19,9 anos (incluindo 147 crianças <14 anos). Resultados: Mutações no GJB2, inclusive homozigóticos e heterozigóticos, foram encontradas em 112 (32%) pacientes. Não houve diferenças significativas nos parâmetros de ECG entre grupos de pacientes com e sem mutações no GJB2. Não foram observadas diferenças em homens (PR médio com mutação: 155 ± 16,6 vs. 153,6 ± 30,1 sem mutação; QRS: 99,9 ± 9,9 vs. 101,1 ± 15,4; QTc: 414,9 ± 29,9 vs. 412,4 ± 25,7) nem em mulheres (PR médio com: 148,7 ± 21 vs. 143,8 ± 22,8, sem; QRS: 94,8 ± 7,6 vs. 92,9 ± 9,6; QTc: 416,8 ± 20,6 vs. 424,9 ± 22,8). Da mesma forma, encontramos diferenças significativas entre os grupos de crianças com e sem mutações de GJB2 (PR médio com: 126,3 ± 19,6 vs. 127 ± 19,7, sem; QRS: 80,7 ± 9,5 vs. 79,4 ± 11,6; QTc: 419,7 ± 23,5 vs. 419,8 ± 24,8). Conclusão: Não foi encontrada associação entre a presença de mutações de GJB2 que codificam conexina 26 em pacientes com perda auditiva e seus parâmetros de ECG (PR, QRS, QTc).

Tetrameric Assembly of K+ Channels Requires ER-Located Chaperone Proteins.

Tetrameric assembly of channel subunits in the endoplasmic reticulum (ER) is essential for surface expression and function of K+ channels, but the molecular mechanism underlying this process remains unclear. In this study, we found through genetic screening that ER-located J-domain-containing chaperone proteins (J-proteins) are critical for the biogenesis and physiological function of ether-a-go-go-related gene (ERG) K+ channels in both Caenorhabditis elegans and human cells. Human J-proteins DNAJB12 and DNAJB14 promoted tetrameric assembly of ERG (and Kv4.2) K+ channel subunits through a heat shock protein (HSP) 70-independent mechanism, whereas a mutated DNAJB12 that did not undergo oligomerization itself failed to assemble ERG channel subunits into tetramers in vitro and in C. elegans. Overexpressing DNAJB14 significantly rescued the defective function of human ether-a-go-go-related gene (hERG) mutant channels associated with long QT syndrome (LQTS), a condition that predisposes to life-threatening arrhythmia, by stabilizing the mutated proteins. Thus, chaperone proteins are required for subunit stability and assembly of K+ channels.

Evaluation of electrocardiographic parameters in patients with hearing loss genotyped for the connexin 26 gene (GJB2) mutations.

INTRODUCTION: Several studies have associated congenital sensorineural hearing loss in children with prolongation of the cardiac parameter QTc. The cause of this association is unknown. At the same time, mutations in GJB2, which encodes connexin 26, are the most common cause of congenital hearing impairment. OBJECTIVE: To compare electrocardiographic parameters (PR interval, QRS complex, and QTc interval) in patients with hearing loss who were tested for mutations in GJB2 and GJB6 to investigate whether these mutations affect electrical activity of the heart. METHODS: 346 patients (176 males, 170 females) with sensorineural hearing loss of 30dB HL or more, aged 21.8±19.9 years (including 147 children <14 years), underwent both genetic study for GJB2 and GJB6 mutations and electrocardiography. RESULTS: Mutations in GJB2, including homozygotes and heterozygotes, were found in 112 (32%) patients. There were no significant differences in ECG parameters between groups of patients with and without mutations in GJB2. No differences were observed either in men (mean PR with mutation: 155±16.6 vs. 153.6±30.1 without; QRS: 99.9±9.9 vs. 101.1±15.4; QTc: 414.9±29.9 vs. 412.4±25.7) or women (mean PR with: 148.7±21 vs. 143.8±22.8 without; QRS: 94.8±7.6 vs. 92.9±9.6; QTc: 416.8±20.6 vs. 424.9±22.8). In similar fashion, we did we find any significant differences between groups of children with and without GJB2 mutations (mean PR with: 126.3±19.6 vs. 127±19.7 without; QRS: 80.7±9.5 vs. 79.4±11.6; QTc: 419.7±23.5 vs. 419.8±24.8). CONCLUSION: No association was found between the presence of GJB2 mutations encoding connexin 26 in patients with hearing loss and their ECG parameters (PR, QRS, QTc).

Semiconductor Whole Exome Sequencing for the Identification of Genetic Variants in Colombian Patients Clinically Diagnosed with Long QT Syndrome.

BACKGROUND AND OBJECTIVE: Inherited long QT syndrome (LQTS) is a cardiac channelopathy characterized by a prolongation of QT interval and the risk of syncope, cardiac arrest, and sudden cardiac death. Genetic diagnosis of LQTS is critical in medical practice as results can guide adequate management of patients and distinguish phenocopies such as catecholaminergic polymorphic ventricular tachycardia (CPVT). However, extensive screening of large genomic regions is required in order to reliably identify genetic causes. Semiconductor whole exome sequencing (WES) is a promising approach for the identification of variants in the coding regions of most human genes. METHODS: DNA samples from 21 Colombian patients clinically diagnosed with LQTS were enriched for coding regions using multiplex polymerase chain reaction (PCR) and subjected to WES using a semiconductor sequencer. RESULTS: Semiconductor WES showed mean coverage of 93.6 % for all coding regions relevant to LQTS at >10× depth with high intra- and inter-assay depth heterogeneity. Fifteen variants were detected in 12 patients in genes associated with LQTS. Three variants were identified in three patients in genes associated with CPVT. Co-segregation analysis was performed when possible. All variants were analyzed with two pathogenicity prediction algorithms. The overall prevalence of LQTS and CPVT variants in our cohort was 71.4 %. All LQTS variants previously identified through commercial genetic testing were identified. CONCLUSION: Standardized WES assays can be easily implemented, often at a lower cost than sequencing panels. Our results show that WES can identify LQTS-causing mutations and permits differential diagnosis of related conditions in a real-world clinical setting. However, high heterogeneity in sequencing depth and low coverage in the most relevant genes is expected to be associated with reduced analytical sensitivity.

Arritmias genéticas: como investigar e como tratar? / Inherited arrhythmias: how to investigate and how to treat?

As arritmias hereditárias são responsáveis por uma proporção significante de mortes cardíacas súbitas em indivíduos jovens aparentemente saudáveis. As canalopatias, como síndrome de Brugada, síndrome do QT longo/curto e taquicardia ventricular polimórfica catecolaminérgica, contribuem com essa incidência e não são marcadas por anomalias estruturais. A cardiomiopatia genética, como cardiomiopatia arritmogênica doventrículo direito e cardiomiopatia hipertrófica, também são causas de morte súbita por arritmia. Novos consensos têm sido publicados para orientar melhor as ferramentas dediagnóstico, os escores de estratificação e o tratamento. Os testes genéticos têm papel importante no diagnóstico, na estratificação de risco e no tratamento de pacientes e de suas famílias. Os avanços da genética molecular nas duas últimas décadas revelaram a base genética subjacente da doença, e podem levar a tratamentos mais personalizados...

Inherited arrhythmias account for a significant proportion of sudden cardiac deaths in apparently healthy and young individuals. Ion channelopathies such as Brugada syndrome, long/short QT syndrome and catecholaminergic polymorphic ventricular tachycardiacontribute to this incidence and are marked by no structural abnormalities. Genetic cardiomyopathy such as Right Ventricular Arrhythmogenic Cardiomyopathy and HypertrophicCardiomyopathy are also causes of arrhythmogenic sudden death. New consensuses are published to better guide the diagnostic tools, stratification scores and treatment. Genetic testing plays somehow an important role in the diagnosis, risk-stratification and treatment of patients and family members. Molecular genetic advances in the last 2 decades have revealed the underlying genetic basis and these may lead to a personalized medicine...

Síndrome de Andersen-Tawil / Andersen-Tawil Syndrome

A síndrome de Andersen-Tawil é uma condição rara composta por arritmias ventriculares, paralisia periódica e dimorfismo. É uma doença de canal iônico cardíaco, possui herança de forma autossômica dominante e é classificada como tipo 7 da síndrome do QT longo congênito. A síndrome de Andersen-Tawil é a única canalopatia que une a excitabilidade dos músculos cardíaco e esquelético. Os pacientes podem ser assintomáticos ou minimamente sintomáticos, apesar da elevada carga de arritmia com ectopia ventricular frequente e taquicardia ventricular bidirecional. No entanto, continuam a ser pacientes com risco de arritmias potencialmente fatais, incluindo torsades de pointes e fibrilação ventricular, embora com menor frequência que as observadas em outras síndromes de arritmia genética. Nesta revisão a doença foi abordada sob o ponto de vista dos diagnósticos clínico e molecular, com ênfase nas manifestações cardíacas...

Andersen-Tawil syndrome is a rare condition consisting of ventricular arrhythmias, periodic paralysis, and dysmorphic features. It is a cardiac ion channel disease, with autosomal dominant inheritance and is classifiedas type 7 of the congenital long QT syndromes. Andersen-Tawil syndrome is a unique channelopathy which linkscardiac and skeletal muscle excitability. Patients may be asymptomatic, or minimally symptomatic despite a higharrhythmia burden with frequent ventricular ectopy and bidirectional ventricular tachycardia. However, patients remain at risk for life-threatening arrhythmias, including torsades de pointes and ventricular fibrillation, although less frequently than observed in other genetic arrhythmia syndromes. In this review we address the disease from the point of view of clinical and molecular diagnosis with emphasis on cardiac manifestations...

Genetic variants for long QT syndrome among infants and children from a statewide newborn hearing screening program cohort.

OBJECTIVES: Autosomal recessive long QT syndrome (LQTS), or Jervell and Lange-Nielsen syndrome (JLNS), can be associated with sensorineural hearing loss. We aimed to explore newborn hearing screening combined with electrocardiograms (ECGs) for early JLNS detection. STUDY DESIGN: In California, we conducted statewide, prospective ECG screening of children ≤ 6 years of age with unilateral or bilateral, severe or profound, sensorineural or mixed hearing loss. Families were identified through newborn hearing screening and interviewed about medical and family histories. Twelve-lead ECGs were obtained. Those with positive histories or heart rate corrected QT (QTc) intervals ≥ 450 ms had repeat ECGs. DNA sequencing of 12 LQTS genes was performed for repeat QTc intervals ≥ 450 ms. RESULTS: We screened 707 subjects by ECGs (number screened/number of responses = 91%; number of responses/number of families who were mailed invitations = 54%). Of these, 73 had repeat ECGs, and 19 underwent gene testing. No subject had homozygous or compound heterozygous LQTS mutations, as in JLNS. However, 3 individuals (with QTc intervals of 472, 457, and 456 ms, respectively) were heterozygous for variants that cause truncation or missplicing: 2 in KCNQ1 (c.1343dupC or p.Glu449Argfs*14; c.1590+1G>A or p.Glu530sp) and 1 in SCN5A (c.5872C>T or p.Arg1958*). CONCLUSIONS: In contrast to reports of JLNS in up to 4% of children with sensorineural hearing loss, we found no examples of JLNS. Because the 3 variants identified were unrelated to hearing, they likely represent the prevalence of potential LQTS mutations in the general population. Further studies are needed to define consequences of such mutations and assess the overall prevalence.

Síndrome de QT corto / Short QT syndrome

El síndrome de QT corto es una canalopatía hereditaria caracterizada por un anormal acortamiento del intervalo QT (IQT), por un riesgo incrementado para el desarrollo de fibrilación auricular y/o arritmias ventriculares malignas y por la ausencia de cardiopatía estructural. Es una enfermedad heterogénea y se han identificado mutaciones en los genes codificadores de los canales de potasio y de calcio. Un incremento en las corrientes neta de salida de potasio o una disminución en al entrada de calcio favorecen el acortamiento heterogéneo de la repolarización ventricular. La marcada abreviación de la longitud de onda del circuito es un factor arritmogénico adicional. El curso clínico oscila desde formas asintomáticas hasta fibrilación auricular paroxística o permanente, síncope, arritmias ventriculares y muerte súbita. El electrocardiograma muestra IQT 220-360 ms, ondas T altas y puntiagudas, prolongación del intervalo pico-final de la onda T e IQT rígido. Es poco frecuente, pero importante por el riesgo elevado de muerte súbita, que en ocasiones puede ser el debut. Puede presentarse solapado al síndrome de Brugada y a la repolarización precoz. El diagnóstico precisa excluir las causas secundarias que acortan el IQT y la no identificación de una mutación no lo excluye. La estimulación eléctrica programada tiene pobre valor diagnóstico y pronóstico. En los sujetos con muerte súbita abortada o con arritmias ventriculares con compromiso hemodinámica, el desfibrilador es la terapéutica de elección. La quinidina es una opción terapéutica alternativa(AU)

The short QT syndrome is an inherited channelopathy characterized by an abnormal shortening of the QT interval (QTI), an increased risk of developing atrial fibrillation and/or malignant ventricular arrhythmias, and the absence of structural heart disease. It is a heterogeneous disease and mutations have been identified in the genes encoding potassium and calcium channels. An increase in potassium net efflux or a decrease in calcium influx facilitate the heterogeneous shortening of ventricular repolarization. A marked shortening of the wavelength of the circuit is an additional arrhythmogenic factor. The clinical course ranges from asymptomatic forms to paroxysmal or permanent atrial fibrillation, syncope, ventricular arrhythmias and sudden death. The ECG shows QTI 220-360 ms, high and sharp T waves, prolongation of the final peak interval of the T wave, and QTI drive. It is a rare disease whose importance lies in the high risk of sudden death, which may sometimes be its debut. It may overlap Brugada syndrome and early repolarization. Diagnosis requires excluding secondary causes of QTI shortening. Failure to identify a mutation does not exclude it. Programmed electrical stimulation has a low diagnostic and prognostic value. Defibrillation is the therapy of choice for patients with aborted sudden death or ventricular arrhythmias with hemodynamic compromise. Quinidine is an alternative therapeutic option(AU)

Síndrome de QT corto / Short QT syndrome

El síndrome de QT corto es una canalopatía hereditaria caracterizada por un anormal acortamiento del intervalo QT (IQT), por un riesgo incrementado para el desarrollo de fibrilación auricular y/o arritmias ventriculares malignas y por la ausencia de cardiopatía estructural. Es una enfermedad heterogénea y se han identificado mutaciones en los genes codificadores de los canales de potasio y de calcio. Un incremento en las corrientes neta de salida de potasio o una disminución en al entrada de calcio favorecen el acortamiento heterogéneo de la repolarización ventricular. La marcada abreviación de la longitud de onda del circuito es un factor arritmogénico adicional. El curso clínico oscila desde formas asintomáticas hasta fibrilación auricular paroxística o permanente, síncope, arritmias ventriculares y muerte súbita. El electrocardiograma muestra IQT 220-360 ms, ondas T altas y puntiagudas, prolongación del intervalo pico-final de la onda T e IQT rígido. Es poco frecuente, pero importante por el riesgo elevado de muerte súbita, que en ocasiones puede ser el debut. Puede presentarse solapado al síndrome de Brugada y a la repolarización precoz. El diagnóstico precisa excluir las causas secundarias que acortan el IQT y la no identificación de una mutación no lo excluye. La estimulación eléctrica programada tiene pobre valor diagnóstico y pronóstico. En los sujetos con muerte súbita abortada o con arritmias ventriculares con compromiso hemodinámica, el desfibrilador es la terapéutica de elección. La quinidina es una opción terapéutica alternativa

The short QT syndrome is an inherited channelopathy characterized by an abnormal shortening of the QT interval (QTI), an increased risk of developing atrial fibrillation and/or malignant ventricular arrhythmias, and the absence of structural heart disease. It is a heterogeneous disease and mutations have been identified in the genes encoding potassium and calcium channels. An increase in potassium net efflux or a decrease in calcium influx facilitate the heterogeneous shortening of ventricular repolarization. A marked shortening of the wavelength of the circuit is an additional arrhythmogenic factor. The clinical course ranges from asymptomatic forms to paroxysmal or permanent atrial fibrillation, syncope, ventricular arrhythmias and sudden death. The ECG shows QTI 220-360 ms, high and sharp T waves, prolongation of the final peak interval of the T wave, and QTI drive. It is a rare disease whose importance lies in the high risk of sudden death, which may sometimes be its debut. It may overlap Brugada syndrome and early repolarization. Diagnosis requires excluding secondary causes of QTI shortening. Failure to identify a mutation does not exclude it. Programmed electrical stimulation has a low diagnostic and prognostic value. Defibrillation is the therapy of choice for patients with aborted sudden death or ventricular arrhythmias with hemodynamic compromise. Quinidine is an alternative therapeutic option

Investigação de variantes gênicas de canais iônicos em pacientes com síndrome do QT longo / Investigation of ion channel gene variants in patients with long QT syndrome / Investigación de variantes génicas de canales iónicos en pacientes con síndrome del QT largo

FUNDAMENTO: A síndrome do QT longo (SQTL) é uma síndrome arrítmica herdada com aumento do intervalo QT e risco de morte súbita. Mutações nos genes KCNQ1, KCNH2 e SCN5A respondem por 90 por cento dos casos com genótipo determinado, e a genotipagem é informativa para aconselhamento genético e melhor manejo da doença. OBJETIVO: Investigação molecular e análise computacional de variantes gênicas de KCNQ1, KCNH2 e SCN5A associadas à SQTL em famílias portadoras da doença. MÉTODOS: As regiões codificantes dos genes KCNQ1, KCNH2 e SCN5A de pacientes com SQTL e familiares foram sequenciadas e analisadas utilizando o software Geneious ProTM. RESULTADOS: Foram investigadas duas famílias com critérios clínicos para SQTL. A probanda da Família A apresentava QTC = 562 ms, Escore de Schwartz = 5,5. A genotipagem identificou a mutação G1714A no gene KCNH2. Foi observado QTC = 521 ± 42 ms nos familiares portadores da mutação contra QTC = 391 ± 21 ms de não portadores. A probanda da Família B apresentava QTc = 551 ms, Escore de Schwartz = 5. A genotipagem identificou a mutação G1600T, no mesmo gene. A análise dos familiares revelou QTC = 497 ± 42 ms nos portadores da mutação, contra QTC = 404 ± 29 ms nos não portadores. CONCLUSÃO: Foram encontradas duas variantes gênicas previamente associadas à SQTL em duas famílias com diagnóstico clínico de SQTL. Em todos os familiares portadores das mutações foi observado o prolongamento do intervalo QT. Foi desenvolvida uma estratégia para identificação de variantes dos genes KCNQ1, KCNH2 e SCN5A, possibilitando o treinamento de pessoal técnico para futura aplicação na rotina diagnóstica.

BACKGROUND: The long QT syndrome (LQTS) is an inherited arrhythmia syndrome with increased QT interval and risk of sudden death. Mutations in genes KCNQ1, KCNH2 and SCN5A account for 90 percent of cases with genotype determined, and genotyping is informative for genetic counseling and better disease management. OBJECTIVE: Molecular investigation and computational analysis of gene variants of KCNQ1, KCNH2 and SCN5A associated with LQTS, in families with the disease. METHODS: The coding regions of genes KCNQ1, KCNH2 and SCN5A in patients with LQTS and their family members were sequenced and analyzed using Geneious ProTM software. RESULTS: Two families with clinical criteria for LQTS were investigated. The proband of Family A had QTC = 562 ms, Schwartz Score = 5.5. The genotyping identified the G1714A mutation in the KCNH2 gene. QTC = 521 ± 42 ms was observed in family members carrying the mutation against QTC = 391 ± 21 ms for non-carriers. The proband of Family B had QTc = 551 ms, Schwartz Score = 5.5. The genotyping identified the G1600T mutation, in the same gene. The analysis of family members revealed QTC = 497 ± 42 ms in mutation carriers, compared with QTC = 404 ± 29 ms in non-carriers. CONCLUSION: Two gene variants previously associated with LQTS were found in two families clinically diagnosed with LQTS. The prolongation of the QT interval was observed in all family members carrying the mutations. A strategy was developed to identify variants of genes KCNQ1, KCNH2 and SCN5A, making it possible to train technical staff for future application to diagnosis routine.

FUNDAMENTO: El síndrome del QT largo (SQTL) es un síndrome arrítmico heredado con aumento del intervalo QT y riesgo de muerte súbita. Mutaciones en los genes KCNQ1, KCNH2 y SCN5A responden por 90 por ciento de los casos con genotipo determinado, y el genotipaje es informativo para aconsejamiento genético y mejor manejo de la enfermedad. OBJETIVO: Investigación molecular y análisis computacional de variantes génicas de KCNQ1, KCNH2 y SCN5A asociadas a la SQTL en familias portadoras de la enfermedad. MÉTODOS: Las regiones codificantes de los genes KCNQ1, KCNH2 y SCN5A de pacientes con SQTL y familiares fueron secuenciadas y analizadas utilizando el software Geneious Pro®. RESULTADOS: Fueron investigadas dos familias con criterios clínicos para SQTL. La probanda de la Familia A presentaba QT C = 562 ms, Escore de Schwartz = 5,5. El genotipaje identificó la mutación G1714A en el gen KCNH2. Fue observado QT C = 521 ± 42 ms en los familiares portadores de la mutación contra QT C = 391 ± 21 ms de no portadores. La probanda de la Familia B presentaba QT C = 551 ms, Escore de Schwartz = 5. El genotipaje identificó la mutación G1600T, en el mismo gen. El análisis de los familiares reveló QT C = 497 ± 42 ms en los portadores de la mutación, contra QT C = 404 ± 29 ms en los no portadores. CONCLUSIÓN: Fueron encontradas dos variantes génicas previamente asociadas a la SQTL en dos familias con diagnóstico clínico de SQTL. En todos los familiares portadores de las mutaciones fue observada la prolongación del intervalo QT. Fue desarrollada una estrategia para identificación de variantes de los genes KCNQ1, KCNH2 y SCN5A, posibilitando el entrenamiento de personal técnico para futura aplicación en la rutina diagnóstica.

Investigation of ion channel gene variants in patients with long QT syndrome.

BACKGROUND: The long QT syndrome (LQTS) is an inherited arrhythmia syndrome with increased QT interval and risk of sudden death. Mutations in genes KCNQ1, KCNH2 and SCN5A account for 90% of cases with genotype determined, and genotyping is informative for genetic counseling and better disease management. OBJECTIVE: Molecular investigation and computational analysis of gene variants of KCNQ1, KCNH2 and SCN5A associated with LQTS, in families with the disease. METHODS: The coding regions of genes KCNQ1, KCNH2 and SCN5A in patients with LQTS and their family members were sequenced and analyzed using Geneious ProTM software. RESULTS: Two families with clinical criteria for LQTS were investigated. The proband of Family A had QTC = 562 ms, Schwartz Score = 5.5. The genotyping identified the G1714A mutation in the KCNH2 gene. QTC = 521 ± 42 ms was observed in family members carrying the mutation against QTC = 391 ± 21 ms for non-carriers. The proband of Family B had QTc = 551 ms, Schwartz Score = 5.5. The genotyping identified the G1600T mutation, in the same gene. The analysis of family members revealed QTC = 497 ± 42 ms in mutation carriers, compared with QTC = 404 ± 29 ms in non-carriers. CONCLUSION: Two gene variants previously associated with LQTS were found in two families clinically diagnosed with LQTS. The prolongation of the QT interval was observed in all family members carrying the mutations. A strategy was developed to identify variants of genes KCNQ1, KCNH2 and SCN5A, making it possible to train technical staff for future application to diagnosis routine.