Abstract

Hypertrophic cardiomyopathy (HCM), an inheritable cardiac condition characterized by idiopathic left ventricular hypertrophy, can cause sudden cardiac death or heart failure. Autosomal-dominant missense mutations in MYH7 (encoding the sarcomeric βMHC protein) account for 33% of genotype-positive HCM cases. While pathogenic MYH7 variants are clinically-actionable, 75% of MYH7 missense variants in ClinVar are variants of unknown significance (VUS). Gene-editing human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) can help determine the function of MYH7 VUS, however, the discovery of new variants by genetic testing outpaces the ability to gene-edit hiPSCs. Thus, we developed a novel method called CR ISPR a On- T arget E diting R etrieval (CRaTER) which increases the success of gene-editing by 25-fold compared to current methods. We leveraged CRaTER to enrich for hiPSCs edited with a library of MYH7 missense variants and recovered 113 different heterozygous variants. As deleterious mutations can reduce protein stability, we flow sorted MYH7 variant hiPSC-CMs into bins based on differing βMHC abundance followed by next generation sequencing of each bin to calculate variant abundance scores. This assay identified 31 MYH7 missense variants as functionally abnormal (lower abundance scores than synonymous controls), including all known pathogenic variants in the library. This βMHC depletion phenotype was validated in clonal hiPSC-CMs and supported by western blotting of myocardium from a patient with a pathogenic MYH7 missense mutation. Furthermore, we rescued βMHC protein levels by genetically ablating the gene encoding for Muscle RING-finger protein-1, an E3 protein ligase that targets βMHC for degradation, and found that the cardiomyocyte hypertrophy induced by the pathogenic MYH7 E848G HCM variant was significantly blunted. In summary, CRaTER enables the generation of gene-edited hiPSC lines at unprecedented scale. Functional analysis of MYH7 variant hiPSC-CMs reveals a novel correlation between loss of βMHC protein and clinical pathogenicity that can be leveraged for clinical variant interpretation. Interventions that prevent the loss of βMHC may potentially be therapeutic for MYH7 -associated HCM.

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