Genetic analysis of patients with arrhythmogenic right ventricular cardiomyopathy (ARVC) and functional characterization of patient-specific cardiomyocytes derived from hiPSCs (hiPSC-CM

Arrhythmogenic right ventricular cardiomyopathy (ARVC) has a genetic origin and is mainly characterized by the replacement of myocardial cells with fibroadipose tissue. The disease has a prevalence of approximately 1: 3.500, being more frequently diagnosed in young individuals, athletes and males. Currently, several mutations associated with ARVC have been described in 12 different genes. However, there are few studies in the literature that describe the mutational spectrum of the disease using a comprehensive panel of potentially causal genes in populations other than European-descent cohorts. Next Generation Sequencing (NGS) as a tool for molecular diagnosis of the disease allows an advance in the correlation between genotypic and clinical phenotypic aspects and has potential benefits that grow along with the challenges in its interpretation. In addition, the use of hiPSCs as an in vitro model of certain heart diseases, allows to specifically evaluate the relationship of the genotype with the different cellular phenotypic consequences of ARVC. However, the molecular mechanisms of the disease are still poorly understood and there are no studies in the literature that include both the mutational profile (with an extensive panel of genes) and functional study of different causal variants, with the use of hiPSC-CMs. The aim of this thesis was to describe the prevalence of causal variants in ARVC-associated genes in the Brazilian population, and to characterize, from a functional point of view, cardiomyocytes derived from hiPSC (hiPSC-CMs) from patients with identified mutations, in order to associate the mutational profile and cellular phenotypic expression. Forty-seven unrelated probands, 38 (80.85%) male, mean age 40.2 ± 15.56 years, with clinical diagnosis of ARVC, were submitted to a cardiomyopathy-related gene panel sequencing, comprising 12 genes, using next-generation sequencing (NGS). Variants were interpreted and classified according to the ACMG criteria. Pathogenic or Likely Pathogenic variants were found in eighteen probands (38.3%), with the largest number of occurrences in the PKP2 gene (38.8%). Among the 18 positive cases, thirteen different variants were found, four of them novel mutations in desmosomal genes, without previous description in the literature. Variants of uncertain significance (VUS) were found in 16 patients. The presence of a causal variant was present in all asymptomatic probands and was significantly associated with probands who have a family history of sudden cardiac death under 35 years. For the cellular modeling, from urinary progenitor cells (UPCs) and fibroblasts, hiPSCs from two patients were generated by episomal transfection. The first patient had a missense variant in the PKP2 gene, while the second had an insertion in the DSC2 gene. The hiPSCs were characterized for its pluripotency potential and subsequently differentiated into cardiomyocytes (hiPSC-CMs). Our results demonstrated significant phenotypic differences between the ARVC-CMs compared to the control-CMs, such as: significant reductions in the expression of desmosomal proteins and structurally altered desmosomes; presence of lipid droplet accumulation markers and increased regulation of the proadipogenic transcription factor PPAR-gamma; prolonged field potential duration (FPD) and action potential in 90% repolarization (APD90); slower conduction velocity and a lower active contraction force. In conclusion, this is the first work to characterize the genetic profile of ARVC, covering all genes described to date related to the disease, in the Brazilian population. The data obtained in this study suggests that patients with a family history of sudden cardiac death ( < 35 years) are more likely to carry a causal variant. In addition, our findings suggest that patients with causal variant in the PKP2 gene have a greater severity of the phenotypic presentation of arrhythmia. Our cellular model, which contemplated patient-specific cells with different causal variants of the previous studies, suggests that it is possible to study the effect of the genetic changes in ARVC, and may be an addition to the tools available to study the mechanism of this complex disease (AU)