Kalliopi Pilichou

Mutations in Desmoglein-2 Gene Are Associated With Arrhythmogenic Right Ventricular Cardiomyopathy

Background— Arrhythmogenic right ventricular cardiomyopathy (ARVC) is an inherited cardiomyopathy characterized by progressive myocardial atrophy with fibrofatty replacement. The recent identification of causative mutations in plakoglobin, desmoplakin (DSP), and plakophilin-2 (PKP2) genes led to the hypothesis that ARVC is due to desmosomal defects. Therefore, desmoglein-2 (DSG2), the only desmoglein isoform expressed in cardiac myocytes, was screened in subjects with ARVC. Methods and Results— In a series of 80 unrelated ARVC probands, 26 carried a mutation in DSP (16%), PKP2 (14%), and transforming growth factor-&bgr;3 (2.5%) genes; the remaining 54 were screened for DSG2 mutations by denaturing high-performance liquid chromatography and direct sequencing. Nine heterozygous DSG2 mutations (5 missense, 2 insertion-deletions, 1 nonsense, and 1 splice site mutation) were detected in 8 probands (10%). All probands fulfilled task force criteria for ARVC. An endomyocardial biopsy was obtained in 5, showing extensive loss of myocytes with fibrofatty tissue replacement. In 3 patients, electron microscopy investigation was performed, showing intercalated disc paleness, decreased desmosome number, and intercellular gap widening. Conclusions— This is the first investigation demonstrating DSG2 gene mutations in a significant number of ARVC-unrelated probands. Cardiac phenotype is characterized clinically by typical ARVC features with frequent left ventricular involvement and morphologically by fibrofatty myocardial replacement and desmosomal remodeling. The presence of mutations in desmosomal encoding genes in 40% of cases confirms that many forms of ARVC are due to alterations in the desmosome complex.

Intercalated disc abnormalities, reduced Na+ current density, and conduction slowing in desmoglein-2 mutant mice prior to cardiomyopathic changes

AIMS Mutations in genes encoding desmosomal proteins have been implicated in the pathogenesis of arrhythmogenic right ventricular cardiomyopathy (ARVC). However, the consequences of these mutations in early disease stages are unknown. We investigated whether mutation-induced intercalated disc remodelling impacts on electrophysiological properties before the onset of cell death and replacement fibrosis. METHODS AND RESULTS Transgenic mice with cardiac overexpression of mutant Desmoglein2 (Dsg2) Dsg2-N271S (Tg-NS/L) were studied before and after the onset of cell death and replacement fibrosis. Mice with cardiac overexpression of wild-type Dsg2 and wild-type mice served as controls. Assessment by electron microscopy established that intercellular space widening at the desmosomes/adherens junctions occurred in Tg-NS/L mice before the onset of necrosis and fibrosis. At this stage, epicardial mapping in Langendorff-perfused hearts demonstrated prolonged ventricular activation time, reduced longitudinal and transversal conduction velocities, and increased arrhythmia inducibility. A reduced action potential (AP) upstroke velocity due to a lower Na(+) current density was also observed at this stage of the disease. Furthermore, co-immunoprecipitation demonstrated an in vivo interaction between Dsg2 and the Na(+) channel protein Na(V)1.5. CONCLUSION Intercellular space widening at the level of the intercalated disc (desmosomes/adherens junctions) and a concomitant reduction in AP upstroke velocity as a consequence of lower Na(+) current density lead to slowed conduction and increased arrhythmia susceptibility at disease stages preceding the onset of necrosis and replacement fibrosis. The demonstration of an in vivo interaction between Dsg2 and Na(V)1.5 provides a molecular pathway for the observed electrical disturbances during the early ARVC stages.

Molecular biology and clinical management of arrhythmogenic right ventricular cardiomyopathy/dysplasia

In the last two decades the extraordinary advances in molecular biology of arrhythmogenic right ventricular cardiomyopathy/dysplasia (ARVC/D) have provided significant insights into our understanding of the disease aetiology by showing that it is a genetic disorder of the cardiac desmosomes and that interactions between mechanical disruption of cell–cell adhesion and defects of desmosomal-mediated intracellular signalling are likely to be involved in the pathogenesis of the ARVC/D phenotype. The discovery of the causative genes for ARVC/D offers the possibility of identifying genetically-affected individuals before potentially malignant clinical phenotype occurs. Moreover, the evaluation of abnormal localisation of desmosomal proteins by immunohistochemical analysis on endomyocardial biopsy samples represents a promising test for ARVC/D diagnosis. Early detection of ARVC/D and preventive therapy of young individuals at highest risk of experiencing sudden cardiac death may be improved by molecular genetic screening within affected families and may alter the clinical management of patients. At present, however, the clinical use of genotyping is limited by the incomplete knowledge of causative mutations and the complex genetic background of the disease, which accounts for the incomplete penetrance and the marked variability of the phenotype expression. This review addresses the advances in the molecular biology of ARVC/D, with particular reference to the genetic basis of the disease, and how these advances have impacted on understanding the disease pathogenesis, on diagnosis and in establishing management strategies.

Compound and digenic heterozygosity predicts lifetime arrhythmic outcome and sudden cardiac death in desmosomal gene-related arrhythmogenic right ventricular cardiomyopathy.

Background—Mutations in genes encoding for desmosomal proteins are the most common cause of arrhythmogenic right ventricular cardiomyopathy (ARVC). We assessed the value of genotype for prediction of lifetime major arrhythmic events and sudden cardiac death (SCD) in desmosomal gene–related ARVC. Methods and Results—The overall study population included 134 desmosomal gene mutation carriers (68 men; median age 36 years [22–52]) from 44 consecutive ARVC families undergoing comprehensive genetic screening. The probability of experiencing a first major arrhythmic event or SCD during a lifetime was determined by using date of birth as start point for the time-to-event analysis, and was stratified by sex, desmosomal genes, mutation types, and genotype complexity (single versus multiple mutations). One hundred thirteen patients (84%) carried a single desmosomal gene mutation in desmoplakin (n=44; 39%), plakophilin-2 (n=38; 34%), desmoglein-2 (n=30; 26%), and desmocollin-2 (n=1; 1%), whereas 21 patients (16%) had a complex genotype with compound heterozygosity in 7 and digenic heterozygosity in 14. Over a median observation period of 39 (22–52) years, 22 patients (16%) from 20 different families had arrhythmic events, such as SCD (n=1), aborted SCD because of ventricular fibrillation (n=6), sustained ventricular tachycardia (n=14), and appropriate defibrillator intervention (n=1). Multiple desmosomal gene mutations and male sex were independent predictors of lifetime arrhythmic events with a hazard ratio of 3.71 (95% confidence interval, 1.54–8.92; P=0.003) and 2.76 (95% confidence interval, 1.19–6.41; P=0.02), respectively. Conclusions—Compound/digenic heterozygosity was identified in 16% of ARVC-causing desmosomal gene mutation carriers and was a powerful risk factor for lifetime major arrhythmic events and SCD. These results support the use of comprehensive genetic screening of desmosomal genes for arrhythmic risk stratification in ARVC.

Arrhythmic Mitral Valve Prolapse and Sudden Cardiac Death

Background— Mitral valve prolapse (MVP) may present with ventricular arrhythmias and sudden cardiac death (SCD) even in the absence of hemodynamic impairment. The structural basis of ventricular electric instability remains elusive. Methods and Results— The cardiac pathology registry of 650 young adults (⩽40 years of age) with SCD was reviewed, and cases with MVP as the only cause of SCD were re-examined. Forty-three patients with MVP (26 females; age range, 19–40 years; median, 32 years) were identified (7% of all SCD, 13% of women). Among 12 cases with available ECG, 10 (83%) had inverted T waves on inferior leads, and all had right bundle-branch block ventricular arrhythmias. A bileaflet involvement was found in 70%. Left ventricular fibrosis was detected at histology at the level of papillary muscles in all patients, and inferobasal wall in 88%. Living patients with MVP with (n=30) and without (control subjects; n=14) complex ventricular arrhythmias underwent a study protocol including contrast-enhanced cardiac magnetic resonance. Patients with either right bundle-branch block type or polymorphic complex ventricular arrhythmias (22 females; age range, 28–43 years; median, 41 years), showed a bileaflet involvement in 70% of cases. Left ventricular late enhancement was identified by contrast-enhanced cardiac magnetic resonance in 93% of patients versus 14% of control subjects (P<0.001), with a regional distribution overlapping the histopathology findings in SCD cases. Conclusions— MVP is an underestimated cause of arrhythmic SCD, mostly in young adult women. Fibrosis of the papillary muscles and inferobasal left ventricular wall, suggesting a myocardial stretch by the prolapsing leaflet, is the structural hallmark and correlates with ventricular arrhythmias origin. Contrast-enhanced cardiac magnetic resonance may help to identify in vivo this concealed substrate for risk stratification.

Clinical phenotype and diagnosis of arrhythmogenic right ventricular cardiomyopathy in pediatric patients carrying desmosomal gene mutations

Background Arrhythmogenic right ventricular cardiomyopathy (ARVC) is an inherited heart muscle disease carrying a risk of sudden death. Information about the clinical features during childhood and the age at disease onset is scanty. Objective The aim of the study was to describe the ARVC phenotype as its initial clinical manifestation in a pediatric population (<18 years) with desmosomal gene mutations. Methods Fifty-three ARVC desmosomal gene mutation carriers (mean age 12.3 ± 3.9 years) were investigated by electrocardiogram (ECG), signal-averaged ECG, 24-hour Holter, echocardiogram, and contrast-enhanced cardiac magnetic resonance (CMR). Results None of the children ≤10 years old fulfilled the 1994 criteria, as opposed to six (33%) aged 11–14 years and eight aged >14 years (42%). At the end of follow-up (9 ± 7 years), 21 (40%) fulfilled the 1994 diagnostic criteria (mean age 16 ± 4 years). By using the 2010 criteria in subjects aged ≤18 years, 53% were unaffected, versus 62% by using the traditional criteria. More than two-thirds of affected subjects had moderate-severe forms of the disease. Contrast-enhanced CMR was performed in 21 (40%); of 13 unaffected gene mutation carriers, six showed ARVC morphological and/or tissue abnormalities. Conclusion In pediatric ARVC mutation carriers, a diagnosis was achieved in 40% of cases, confirming that the disease usually develops during adolescence and young adulthood. The 2010 modified criteria seem to be more sensitive than the 1994 ones in identifying familial pediatric cases. Contrast-enhanced CMR can provide diagnostic information on gene mutation carriers not fulfilling either traditional or modified criteria. Management of asymptomatic gene mutation carriers remains the main clinical challenge.

The ARVD/C Genetic Variants Database: 2014 Update

Arrhythmogenic cardiomyopathy (ACM) is an inherited cardiac disease characterized by myocardial atrophy, fibro‐fatty replacement, and a high risk of ventricular arrhythmias that lead to sudden death. In 2009, genetic data from 57 publications were collected in the arrhythmogenic right ventricular dysplasia/cardiomyopathy (ARVD/C) Genetic Variants Database (freeware available at http://www.arvcdatabase.info), which comprised 481 variants in eight ACM‐associated genes. In recent years, deep genetic sequencing has increased our knowledge of the genetics of ACM, revealing a large spectrum of nucleotide variations for which pathogenicity needs to be assessed. As of April 20, 2014, we have updated the ARVD/C database into the ARVD/C database to contain more than 1,400 variants in 12 ACM‐related genes (PKP2, DSP, DSC2, DSG2, JUP, TGFB3, TMEM43, LMNA, DES, TTN, PLN, CTNNA3) as reported in more than 160 references. Of these, only 411 nucleotide variants have been reported as pathogenic, whereas the significance of the other approximately 1,000 variants is still unknown. This comprehensive collection of ACM genetic data represents a valuable source of information on the spectrum of ACM‐associated genes and aims to facilitate the interpretation of genetic data and genetic counseling.

Arrhythmogenic Cardiomyopathy Transgenic Animal Models Provide Novel Insights Into Disease Pathobiology

Arrhythmogenic right ventricular cardiomyopathy (ARVC) (Online Mendelian Inheritance in Man 107970) is a clinically and genetically heterogeneous heart muscle disorder associated with an increased risk of sudden cardiac death, particularly in young persons and athletes.1–3 The pathological hallmark of ARVC consists of progressive (either diffuse or segmental) loss of cardiac myocytes that are replaced by fibrofatty tissue, leading to electric instability with or without impaired mechanical function.4–6 Right ventricular (RV) aneurysms in the so-called “triangle of dysplasia” are considered a pathognomic feature of the disease. With an estimated prevalence of the disease of ≈1:2500 to 1:5000, ARVC can be listed among the rare cardiovascular disorders.6 The first comprehensive clinical description of ARVC was reported in 1982 by Marcus et al7 in adults with ventricular tachyarrhythmias of left bundle branch block (LBBB) morphology. In 1994, an international task force provided standardized criteria to establish the diagnosis of ARVC,8 and these diagnostic criteria have been updated recently to increase sensitivity but with the important requisite of maintaining specificity.9 Onset of clinical symptoms and signs usually occurs in adolescence or young adulthood10 and often is triggered by effort.11 Main clinical features of the disease comprise arrhythmias of RV origin that are commonly associated with syncope or sudden cardiac death, thus underscoring the crucial role of risk stratification to identify patients who require an implantable cardioverter-defibrillator.12 In 1988, a familial background consistent with an autosomal-dominant trait was described in ≈50% of patients with ARVC.13 To date, human genetics studies have identified 12 independent loci and 8 disease genes for this disorder inherited mostly as autosomal-dominant traits with incomplete penetrance and variable expressivity.2,3 Five of the 8 causative genes encode major components of the cardiac desmosomes, namely plakoglobin …

The changing spectrum of arrhythmogenic (right ventricular) cardiomyopathy

Arrhythmogenic right ventricular cardiomyopathy (ARVC) is a clinically and genetically heterogeneous heart muscle disorder associated with ventricular arrhythmias and risk of sudden death. The disease is heredo-familial, and mutations in desmosomal genes have been identified in about half of patients. Recent experimental models confirm this disease develops after birth due to progressive myocardial dystrophy. Genotype–phenotype correlations, including magnetic resonance and pathology studies on heart specimens, are currently demonstrating that the spectrum of the disease is wider than initially thought and usually referred to with the adjective “right ventricular”, with the evidence of biventricular or even isolated left ventricular forms, so that it is increasingly identified simply as “arrhythmogenic cardiomyopathy”. A revision of the diagnostic criteria encompassing familial, electrocardiographic, arrhythmic, morpho-functional and histopathologic findings, has been made to improve diagnostic sensitivity and specificity, in particular of the concealed forms and left-dominant subtypes of the disease. Experimental models are mandatory to gain an insight into the cascade of cellular and molecular events leading from gene defect to myocardial dystrophy in ARVC.

Nonischemic Left Ventricular Scar as a Substrate of Life-Threatening Ventricular Arrhythmias and Sudden Cardiac Death in Competitive Athletes.

Background—The clinical profile and arrhythmic outcome of competitive athletes with isolated nonischemic left ventricular (LV) scar as evidenced by contrast-enhanced cardiac magnetic resonance remain to be elucidated. Methods and Results—We compared 35 athletes (80% men, age: 14–48 years) with ventricular arrhythmias and isolated LV subepicardial/midmyocardial late gadolinium enhancement (LGE) on contrast-enhanced cardiac magnetic resonance (group A) with 38 athletes with ventricular arrhythmias and no LGE (group B) and 40 healthy control athletes (group C). A stria LGE pattern with subepicardial/midmyocardial distribution, mostly involving the lateral LV wall, was found in 27 (77%) of group A versus 0 controls (group C; P<0.001), whereas a spotty pattern of LGE localized at the junction of the right ventricle to the septum was respectively observed in 11 (31%) versus 10 (25%; P=0.52). All athletes with stria pattern showed ventricular arrhythmias with a predominant right bundle branch block morphology, 13 of 27 (48%) showed ECG repolarization abnormalities, and 5 of 27 (19%) showed echocardiographic hypokinesis of the lateral LV wall. The majority of athletes with no or spotty LGE pattern had ventricular arrhythmias with a predominant left bundle branch block morphology and no ECG or echocardiographic abnormalities. During a follow-up of 38±25 months, 6 of 27 (22%) athletes with stria pattern experienced malignant arrhythmic events such as appropriate implantable cardiac defibrillator shock (n=4), sustained ventricular tachycardia (n=1), or sudden death (n=1), compared with none of athletes with no or LGE spotty pattern and controls. Conclusions—Isolated nonischemic LV LGE with a stria pattern may be associated with life-threatening arrhythmias and sudden death in the athlete. Because of its subepicardial/midmyocardial location, LV scar is often not detected by echocardiography.