Abstract P1086: Induced Pluripotent Stem Cell-based Cardiac Tissue Modeling Of Mitogenic Cardiomyopathy In Alström Syndrome

Abstract

Introduction: Cardiomyopathies are a prominent cause of heart failure and affect millions worldwide. Mutation in the Alström syndrome 1 (ALMS1) gene causing Alström syndrome (ALMS) , reported an extremely rare type of dilated cardiomyopathy - called mitogenic cardiomyopathy - leading to neonatal heart failure and death in early infancy due to delayed postnatal cardiomyocyte (CM) cell cycle arrest. Methods: Induced pluripotent stem cells (iPSCs) from ALMS patients with or without mitogenic cardiomyopathy were used to generate ALMS patient-specific cardiomyocytes (iPSC-CMs) . The iPSC-CMs were divided into two main groups based on the presence or absence of the mitogenic phenotype. After transcriptome sequencing, differentially expressed genes (FDR < 0.05, logFC > 0.5 | < -0.5) were found by testing (QL F-test) a robust fitted linear model (edgeR). Harnessing recent advances in stem cell differentiation and tissue engineering, we aimed at creating a human engineered heart tissue model as an unprecedented in vitro disease system to study mechanisms responsible for persistent CM proliferation. Results: ALMS1-deficient mitogenic iPSC-CMs exhibited an impaired ability to undergo cell cycle arrest, evidenced by a higher cell percentage in the G2/M phase (19.3% in mitogenic vs . 7.5% in non-mitogenic iPSC-CMs). Furthermore, increased extracellular matrix levels of the fibroblast-derived protein periostin (POSTN) were observed in co-cultures of ALMS1-deficient iPSC-CMs and ALMS1 fibroblasts. Finally, we found preliminary evidence of dysregulation of the Hippo signaling pathway, observing altered cellular localization of its key downstream effector Yes-associated protein (YAP) and dysregulated ratio between phosphor and total YAP protein levels that in combination with transcript alteration of PPIC, SH3BP4, NTN4, LRIG3 suggest perturbations in YAP signaling in ALMS patients. Conclusion: ALMS1-deficient mitogenic iPSC-CMs recapitulate postnatal proliferation, observed in ALMS patients with mitogenic cardiomyopathy. Preliminary molecular analyses in these in vitro (multicellular) models point to an important role for altered YAP signaling and provide novel cues to enhance CM proliferation, a much-sought objective in cardiac repair.