Arrhythmogenic right ventricular cardiomyopathy (ARVC) is characterised by progressive fibrofatty replacement of right ventricular myocardium. Earlier studies described ARVC as non-inflammatory, non-coronary disorder associated with arrhythmias, heart failure and sudden death due to functional exclusion of the right ventricle. Molecular genetic studies have identified nine different loci associated with ARVC; accordingly each locus is implicated for each type of ARVC (ARVC1-ARVC9). So far five genes have been identified as containing pathogenic mutations for ARVC. Though mutations in each of the gene/s indicate disruption of different pathways leading to the condition, the exact pathogenesis of the condition is still obscure. This review tries to understand the pathogenesis of the condition by examining the individual proteins implicated and relate them to the pathways that could play a role in the aetiology of the condition. Cardiac ryanodine receptor (RYR-2), which regulates intra-cellular Ca 2+ concentration by releasing Ca 2+ reserves from the sarcoplasmic reticulum (SR), was the first gene for ARVC. The mutation in this gene is believed to disrupt coupled gating of RYR-2, causing after-depolarisation, leading to arrhythmias followed by structural changes due to altered intra-cellular Ca 2+ levels. Three other genes implicated for ARVC, plakoglobin (Naxos disease), desmoplakin (ARVC8) and plakophilin (ARVC9) have prompted the speculation that ARVC is primarily a disease of desmosomes. But identification of TGFb-3 for ARVC1 and the role of all these three genes (plakoglobin, desmoplakin and plakophilin) in cardiac morphogenesis indicate some kind of signal-transducing pathway disruption in the condition. The finding that ARVC as a milder form of Uhl's anomaly indicates similar ontogeny for the condition. Further, discovery of apoptotic cells in the autopsy of the right ventricular myocardium of ARVC patients does indicate a common pathway for different types of ARVCs, which is more specific for the right ventricular myocardium involving desmosomal plaque proteins, growth factors and Ca 2+ receptors.
BACKGROUND:Arrhythmogenic right ventricular cardiomyopathy (ARVC) is a progressive condition with right ventricular myocardium being replaced by fibro-fatty tissue. The spectrum of the expression may range from benign palpitations to the most malignant sudden death. Most of the mutations identified for the condition are localized in desmosomal proteins although three other nondesmosomal genes (cardiac ryanodine receptor-2, TGF-β3, and TMEM43) have also been implicated in ARVC. Both desmosomal and nondesmosomal genes were screened in a set of patients from local population.MATERIALS AND METHODS:A set of 34 patients from local population were included in this study. Diagnosis was based on the criteria proposed by task force of European Society of Cardiology/International Society and Federation of Cardiology. Polymerase chain reaction-based single-strand conformation polymorphism analysis was carried out, and samples with abnormal band pattern were commercially sequenced.RESULTS:Screening of cardiac ryanodine receptor revealed an insertion of a base in the intronic region of exon-28 in a patient, leading to a creation of a cryptic splice site. Screening of plakohilin-2 for mutations revealed an abnormal band pattern in three patients. Two of them had similar abnormal band pattern for exon-3.1. Sequencing revealed a novel 2 base pair deletion (433_434 delCT), which would lead to premature truncation of the protein (L145EfsX8). Another patient showed abnormal band pattern for exon-3.2 and sequencing revealed a missense mutation C792T leading to amino acid change P244L, in N-terminal, and this substitution may cause disturbances in the various protein–protein interactions.CONCLUSION:This study reports novel cardiac ryanodine receptor (RyR-2) mutations and Pkp-2 for the first time from Indian population.
BACKGROUND:Arrythmogenic Right Ventricular Cardiomyopathy (ARVC) is a primary myocardial disorder morphologically characterized by subtle to severe replacement of the right ventricular myocardium by fatty and fibrous tissue. ARVC is known to be highly prevalent in European population with recent reports implicating it to be a major cause of sudden death in young individuals even from American and Asian population.AIM:To implicate or exclude TMEM43 (ARVC-5), DSP(ARVC-8) genes and the yet to be identified gene at ARVC-6 locus in the pathogenesis in three families affected with ARVC from India.MATERIALS AND METHODS:Three families comprising of 42 affected/unaffected members were included in the study. Three microsatellite markers, D3S3613 (ARVC5) D10S1664 (ARVC6), D6S309 (ARVC8) were genotyped by PCR-based native PAGE. Two-point Linkage analysis was performed using LINKAGE program version 5.2RESULTS AND DISCUSSION:LOD scores from linkage analysis for the microsatellite marker D10S1664 (ARVC-6) in families KS and REV have shown positive value hinting the involvement of this locus in the etiology of ARVC, while linkage analysis in the SB family ruled out involvement of DSP, TMEM43 and ARVC-6, as negative LOD scores were obtained with all three loci. Therefore, linkage analysis carried out in the present study indicates that ARVC-6 (cumulative LOD score is equal to plus 1.203376 at θ is equal to 0.05) could be the locus harboring the mutated gene in two out of three families.
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