Johan Martijn Bos

Molecular Basis for Clinical Heterogeneity in Inherited Cardiomyopathies Due to Myopalladin Mutations

Abnormalities in Z-disc proteins cause hypertrophic (HCM), dilated (DCM) and/or restrictive cardiomyopathy (RCM), but disease-causing mechanisms are not fully understood. Myopalladin (MYPN) is a Z-disc protein expressed in striated muscle and functions as a structural, signaling and gene expression regulating molecule in response to muscle stress. MYPN was genetically screened in 900 patients with HCM, DCM and RCM, and disease-causing mechanisms were investigated using comparative immunohistochemical analysis of the patient myocardium and neonatal rat cardiomyocytes expressing mutant MYPN. Cardiac-restricted transgenic (Tg) mice were generated and protein-protein interactions were evaluated. Two nonsense and 13 missense MYPN variants were identified in subjects with DCM, HCM and RCM with the average cardiomyopathy prevalence of 1.66%. Functional studies were performed on two variants (Q529X and Y20C) associated with variable clinical phenotypes. Humans carrying the Y20C-MYPN variant developed HCM or DCM, whereas Q529X-MYPN was found in familial RCM. Disturbed myofibrillogenesis with disruption of α-actinin2, desmin and cardiac ankyrin repeat protein (CARP) was evident in rat cardiomyocytes expressing MYPN(Q529X). Cardiac-restricted MYPN(Y20C) Tg mice developed HCM and disrupted intercalated discs, with disturbed expression of desmin, desmoplakin, connexin43 and vinculin being evident. Failed nuclear translocation and reduced binding of Y20C-MYPN to CARP were demonstrated using in vitro and in vivo systems. MYPN mutations cause various forms of cardiomyopathy via different protein-protein interactions. Q529X-MYPN causes RCM via disturbed myofibrillogenesis, whereas Y20C-MYPN perturbs MYPN nuclear shuttling and leads to abnormal assembly of terminal Z-disc within the cardiac transitional junction and intercalated disc.

YIELD OF GENETIC TESTING AMONG PATIENTS WITH HYPERTROPHIC CARDIOMYOPATHY DIAGNOSED AFTER 65 YEARS OF AGE

Hypertrophic cardiomyopathy (HCM) is a disease of profound phenotypic and genotypic heterogeneity. While HCM-associated mutations are identified usually in patients diagnosed at younger age, the yield of genetic testing and phenotype of patients diagnosed with HCM after 65 years of age (late-

SCN5A mutations in 442 neonates and children: genotype–phenotype correlation and identification of higher-risk subgroups

Aims To clarify the clinical characteristics and outcomes of children with SCN5A-mediated disease and to improve their risk stratification. Methods and results A multicentre, international, retrospective cohort study was conducted in 25 tertiary hospitals in 13 countries between 1990 and 2015. All patients ≤16 years of age diagnosed with a genetically confirmed SCN5A mutation were included in the analysis. There was no restriction made based on their clinical diagnosis. A total of 442 children {55.7% boys, 40.3% probands, median age: 8.0 [interquartile range (IQR) 9.5] years} from 350 families were included; 67.9% were asymptomatic at diagnosis. Four main phenotypes were identified: isolated progressive cardiac conduction disorders (25.6%), overlap phenotype (15.6%), isolated long QT syndrome type 3 (10.6%), and isolated Brugada syndrome type 1 (1.8%); 44.3% had a negative electrocardiogram phenotype. During a median follow-up of 5.9 (IQR 5.9) years, 272 cardiac events (CEs) occurred in 139 (31.5%) patients. Patients whose mutation localized in the C-terminus had a lower risk. Compound genotype, both gain- and loss-of-function SCN5A mutation, age ≤1 year at diagnosis in probands and age ≤1 year at diagnosis in non-probands were independent predictors of CE. Conclusion In this large paediatric cohort of SCN5A mutation-positive subjects, cardiac conduction disorders were the most prevalent phenotype; CEs occurred in about one-third of genotype-positive children, and several independent risk factors were identified, including age ≤1 year at diagnosis, compound mutation, and mutation with both gain- and loss-of-function.

QT prolongation and sudden cardiac death risk in hypertrophic cardiomyopathy

Abstract Introduction: Risk assessment for sudden cardiac death (SCD) in hypertrophic cardiomyopathy (HCM) remains complex. The goal of this study was to assess electrocardiogram (ECG)-derived risk factors on SCD in a large HCM population Methods: Retrospective review of adults with HCM evaluated at Mayo Clinic, Rochester, MN from 1 December 2002 to 31 December 2012 was performed. Data inclusive of ECG and 24-hour ambulatory Holter monitor were assessed. SCD events were documented by ventricular fibrillation (VF) noted on implantable cardioverter defibrillator (ICD), or appropriate VT or VF-terminating ICD shock. Results: Overall, 1615 patients (mean age 53.7 ± 15.2 years; 943 males, 58.4%) were assessed, with mean follow-up 2.46 years and 110 SCD events. Via logistic regression (n = 820), the odds of SCD increased with increasing number of conventional risk factors. With one risk factor the OR was 4.88 (p < .0001; CI 2.22–10.74), two risk factors the OR was 6.922 (p < .0001; CI 2.94–16.28) and three or more risk factors, the OR was 13.997 (p < .0001; CI 5.649–34.68). Adding QTc > 450 to this logistic regression model had OR 1.722 (p = .04, CI 1.01–2.937) to predict SCD. QTc ≥ 450 was a significant predictor for death (HR 1.88, p = .021, CI 1.10–3.20). There was no correlation between sinus bradycardia, sinus tachycardia, first degree AV block, atrial fibrillation, left bundle branch block, right bundle branch block, premature atrial complexes, premature ventricular complexes, supraventricular tachycardia, PR interval, QRS interval and SCD. Conclusions: Prolonged QTc was a risk factor for SCD and death even when controlling for typical risk factors.

Prevalence and clinical phenotype of concomitant long QT syndrome and arrhythmogenic bileaflet mitral valve prolapse

BACKGROUND Mitral valve prolapse (MVP), including the recently described arrhythmogenic bileaflet MVP syndrome (ABiMVPS), is associated with repolarization abnormalities and may represent an underestimated cause of sudden cardiac death. The impact of concomitant MVP or ABiMVPS on long QT syndrome (LQTS) clinical severity is unknown. METHODS AND RESULTS Retrospective review of 754 LQTS patients [445 females (58%) and mean QTc 471 ± 41 ms] with available echocardiographic data was performed to identify LQTS patients with not only MVP, but also a pro-arrhythmic ABiMVPS phenotype defined as bileaflet MVP, inferolateral T-wave inversions, and frequent complex ventricular ectopy/arrhythmia. As expected, 18/754 (2%) LQTS patients had concomitant MVP. Of these, 5/18 (28%) LQTS patients with MVP satisfied ABiMVPS diagnostic criteria. No difference in symptomatology, degree of QT prolongation, or clinical management was observed between LQTS patients with and without MVP. In contrast, LQTS plus ABiMVPS resulted in a severe cardiac phenotype as illustrated by symptomatic status (LQTS-ABiMVPS; 5/5; 100%; vs LQTS: 279/736; 39%; p = .008), degree of baseline QTc prolongation (LQTS-ABiMVPS: 536 ± 58 ms; vs LQTS: 470 ± 40 ms; p = .009), and number of patients experiencing ≥1 on-therapy break-through cardiac event (LQTS-ABiMVPS: 4/5; 80%; vs LQTS: 48/736; 7%; p < .001]. Lastly, individuals with LQTS plus ABiMVPS were more likely to experience appropriate ICD therapies post-cardiac denervation (LQTS-ABiMVPS: 2/3; 67% vs LQTS: 4/49; 8%; p = .03]. CONCLUSIONS AND RELEVANCE The co-existence of LQTS and ABiMVPS may lead to a rare, but malignant, clinical entity characterized by potentially life-threatening arrhythmias despite maximal LQTS therapy.

An autoantibody identifies arrhythmogenic right ventricular cardiomyopathy and participates in its pathogenesis

Aims Arrhythmogenic right ventricular cardiomyopathy (ARVC) is characterized by right ventricular myocardial replacement and life-threatening ventricular arrhythmias. Desmosomal gene mutations are sometimes identified, but clinical and genetic diagnosis remains challenging. Desmosomal skin disorders can be caused by desmosomal gene mutations or autoantibodies. We sought to determine if anti-desmosome antibodies are present in subjects with ARVC. Methods and results We evaluated ARVC subjects and controls for antibodies to cardiac desmosomal cadherin proteins. Desmoglein-2 (DSG2), desmocollin-2, and N-cadherin proteins on western blots were exposed to sera, in primary and validation cohorts of subjects and controls, as well as the naturally occurring Boxer dog model of ARVC. We identified anti-DSG2 antibodies in 12/12 and 25/25 definite ARVC cohorts and 7/8 borderline subjects. Antibody was absent in 11/12, faint in 1/12, and absent in 20/20 of two control cohorts. Anti-DSG2 antibodies were present in 10/10 Boxer dogs with ARVC, and absent in 18/18 without. In humans, the level of anti-DSG2 antibodies correlated with the burden of premature ventricular contractions (r = 0.70), and antibodies caused gap junction dysfunction, a common feature of ARVC, in vitro. Anti-DSG2 antibodies were present in ARVC subjects regardless of whether an underlying mutation was identified, or which mutation was present. A disease-specific DSG2 epitope was identified. Conclusion Anti-DSG2 antibodies are a sensitive and specific biomarker for ARVC. The development of autoimmunity as a result of target-related mutations is unique. Anti-DSG2 antibodies likely explain the cardiac inflammation that is frequently identified in ARVC and may represent a new therapeutic target.

Effect of Ondansetron on QT Interval in Patients Cared for in the PICU.

Objectives: There is no evidence regarding the effect of ondansetron on the QT interval in pediatric patients in the ICU. This study aimed to describe the effect of ondansetron on the corrected QT interval in patients cared for in the PICU. Design: Retrospective cohort, consecutive enrollment study. Setting: Single-center, tertiary-level, medical/surgical PICU. Patients: All patients less than 8 years old who received ondansetron over an 11-month period were included. Exclusion criteria were atrial arrhythmia, bundle-branch block, known congenital long QT syndrome, and concomitant administration of proarrhythmic antiarrhythmic agents. Interventions: None. Measurements and Main Results: Overall, 210 doses of ondansetron were administered to 107 patients, with a mean age 10.5 ± 4.8 years; 49% were men. Corrected QT interval increased to 460–500 ms in 29% and to more than 500 ms in 11% of events of ondansetron administration. The mean baseline corrected QT interval even before ondansetron administration was higher for these groups (460–500 and > 500 ms; 457 ± 33 and 469 ± 45, respectively; p ⩽ 0.05). In multivariate analysis, both groups were associated significantly with underlying electrolyte abnormalities (odds ratio, 2.2; 95% CI, 1.1–4.4 and odds ratio, 5.1; 95% CI, 1.8–15.7, respectively); the group with corrected QT interval more than 500 ms was also significantly associated with organ dysfunction (odds ratio, 3.2; 95% CI, 1.1–9.4). As the numbers of risk factors increased from only ondansetron to three additional QT aggravating factors (electrolyte abnormalities, administration of other QT-prolonging drugs, and organ dysfunction), the likelihood of being associated with corrected QT interval more than 500 ms increased. Conclusions: Prolonged QT interval is observed commonly in PICUs following the administration of ondansetron. Underlying risk factors, such as electrolyte abnormalities and organ dysfunction, seem to pose the highest risk of prolongation of QT interval in these patients. The awareness of prevalent risk factors for increased corrected QT interval may help identify patients at high risk for arrhythmias.

SYSTOLIC ANTERIOR MOTION OF THE ANTERIOR MITRAL LEAFLET AND HYPERTROPHIC CARDIOMYOPATHY: A PREDICTOR OF NON-GENETIC, NON-FAMILIAL DISEASE?

Hypertrophic cardiomyopathy (HCM) is marked by profound phenotypic and genotypic heterogeneity. Systolic anterior motion (SAM) of the anterior mitral leaflet is a classically described feature of HCM but its genetic predilection is unknown. Our study cohort consisted of 213 (74 male, mean age 51

Hypertrophic Cardiomyopathy in the Era of Genomic Medicine

Abstract Hypertrophic cardiomyopathy (HCM) is a relatively common, primary disorder of the myocardium characterized by unexplained left ventricular hypertrophy affecting perhaps as many as 1 in 500 people. HCM is underscored by profound phenotypic and genotypic heterogeneity, with currently more than 20 genes associated with HCM. The underlying genetic mechanism for approximately 30%–60% of HCM remains elusive. Although many genotype–phenotype relationships have been observed, only a few carry enough clinical significance to aid physicians predicting genotype, course, and prognosis of the disease. Current treatment for HCM is aimed at symptom relief, but (animal) studies and clinical trials are underway to test (genotype-specific) pharmacologic treatments for prevention or regression of cardiac hypertrophy. This chapter details the clinical presentation of HCM, its genetic and nongenetic predisposition, important genotype–phenotype relationships, implications for genetic counseling and family screening, and treatment options for the disease.