Abstract Funding Acknowledgements Type of funding sources: Public grant(s) – EU funding. Main funding source(s): ESC training grant; DZHK Background Genetic cardiomyopathies contribute to a significant proportion of morbidity and mortality among young people. Over the past decades, a wide range of underlying molecular mechanisms has been discovered. The current project arose from the clinical observation of a left ventricular non-compaction and sudden cardiac death overlap syndrome in a large family in northern Italy. Whole exome sequencing performed on family members of different generations revealed a single nucleotide polymorphism in the RYR2 gene (RYR2 c.5654G>A homozygous – RyR2 p.G1885E - exon37:missense) with an autosomal-recessive inheritance pattern. The mutation is localized in the DR3 region of the RyR2 protein, adjacent to the FKBP12.6 binding site, a protein that is known to stabilize RyR2, preventing aberrant activation of the channel. Methods and Results Patient-derived, human induced pluripotent stem cells (hiPSCs), carrying the variant homo- and heterozygously, were generated by reprogramming patient-derived peripheral blood mononuclear cells using a non-integrative Sendai virus protocol. The lines were fully characterized and expressed high levels of pluripotency markers at the RNA and protein level. Patient lines were all able to efficiently differentiate into cardiomyocytes. Subsequently, 3D strip-format, force-generating Engineered Heart Tissues (EHTs) were cast and structurally and functionally characterized. Contraction analysis over 60 days showed differences in force development of the patient-derived lines. In particular, the EHTs carrying the homozygous pathogenic variant showed progressive reduction in both beating rate and force over time, increased spontaneous arrhythmogenicity and reduced inotropic response after exposure to isoprenaline, compared to the heterozygous line and unrelated healthy controls. Starting from day 30 after casting, patient-derived EHTs developed morphological changes with areas of marked cellular overgrowth and reduced troponin expression. Transcriptomic and proteomic analysis at 30 and 60 days after EHTs generation, as well as in 2D cardiomyocytes, complement the phenotyping and provide molecular insights into the underlying pathophysiology. To directly evaluate pathogenicity of the genetic variant identified, we generated isogenic homo- and heterozygously corrected hiPSCs, using CRISPR/ Cas9 technology, starting from the homozygous patient-line. The characterization of these corrected clones is currently ongoing. The genetically corrected 3D tissue models will be critical not only in defining the role of the novel RyR2 variant in the familial phenotype described, but also to unveil mechanistic roles of ryanodine receptor in cardiac disease. Conclusion We describe a novel recessive RYR2 variant associated with a left ventricular non- compaction and sudden cardiac death overlap syndrome. 3D cardiac tissue modelling based on patient-derived hiPSCs uncovered a proarrhythmic and structural phenotype of the mutated lines.