Abstract P2036: Induced Pluripotent Stem Cell- Derived Cardiomyocytes Provide New Insights Of The Pathogenic Consequences Of The Novel Frameshift Variant (c.5769delG) In MYH7 Gene

Background: the genetic basis of hypertrophic cardiomyopathy is pleiotropic; A novel disease causing frameshift variant (c.5769delG, MYH7 ) in the beta-myosin heavy chain gene has been recently described. However, the mechanisms involved have not been adequately defined. We have used iPSC-CMs to investigate the underlying mechanisms. Methods: We have generated patient-specific iPSCs from clinically and genetically defined HCM patients carrying the pathogenic variant (c.5769delG) (n=3) and compared them to iPSCs from healthy controls (n=3). Optical mapping of calcium transients and cell action potential were performed under different stimulation conditions. iPSC-CMs contractility was recorded via widefield microscopy. Gene and protein expression analyses were performed using RT-PCR, immunoblotting and immunocytochemistry. RNA sequencing data from patients’ myocardial tissues was analyzed to validate gene expression data from iPSC-CMs. Results: HCM iPSCs-CMs showed a significant decrease in calcium release duration (i.e., time to peak) with decrease in calcium transient amplitude, compared to controls. This was associated with an accelerated contraction and a decreased contraction amplitude. Nonetheless, action potential analysis showed no significant changes. Transcriptome analysis of iPSC-CMs and patients’ myocardial tissues showed a significant down regulation of SERCA/ATP2A2 , MYH6 and KCNIP2 . Conclusion: iPSC-CMs provided new insights of the pathogenic consequences of the novel variant in MYH7 gene on calcium handling and contractility. Key words: Hypertrophic Cardiomyopathy, Disease model, MYH7 , iPSC-CMs, Calcium Handling, Contractility.