Scientific Reports (Dec 2022)

Mechanism based therapies enable personalised treatment of hypertrophic cardiomyopathy

  • Francesca Margara,
  • Yiangos Psaras,
  • Zhinuo Jenny Wang,
  • Manuel Schmid,
  • Ruben Doste,
  • Amanda C. Garfinkel,
  • Giuliana G. Repetti,
  • Jonathan G. Seidman,
  • Christine E. Seidman,
  • Blanca Rodriguez,
  • Christopher N. Toepfer,
  • Alfonso Bueno-Orovio

DOI
https://doi.org/10.1038/s41598-022-26889-2
Journal volume & issue
Vol. 12, no. 1
pp. 1 – 17

Abstract

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Abstract Cardiomyopathies have unresolved genotype–phenotype relationships and lack disease-specific treatments. Here we provide a framework to identify genotype-specific pathomechanisms and therapeutic targets to accelerate the development of precision medicine. We use human cardiac electromechanical in-silico modelling and simulation which we validate with experimental hiPSC-CM data and modelling in combination with clinical biomarkers. We select hypertrophic cardiomyopathy as a challenge for this approach and study genetic variations that mutate proteins of the thick (MYH7 R403Q/+) and thin filaments (TNNT2 R92Q/+, TNNI3 R21C/+) of the cardiac sarcomere. Using in-silico techniques we show that the destabilisation of myosin super relaxation observed in hiPSC-CMs drives disease in virtual cells and ventricles carrying the MYH7R403Q/+ variant, and that secondary effects on thin filament activation are necessary to precipitate slowed relaxation of the cell and diastolic insufficiency in the chamber. In-silico modelling shows that Mavacamten corrects the MYH7R403Q/+ phenotype in agreement with hiPSC-CM experiments. Our in-silico model predicts that the thin filament variants TNNT2R92Q/+ and TNNI3R21C/+ display altered calcium regulation as central pathomechanism, for which Mavacamten provides incomplete salvage, which we have corroborated in TNNT2R92Q/+ and TNNI3R21C/+ hiPSC-CMs. We define the ideal characteristics of a novel thin filament-targeting compound and show its efficacy in-silico. We demonstrate that hybrid human-based hiPSC-CM and in-silico studies accelerate pathomechanism discovery and classification testing, improving clinical interpretation of genetic variants, and directing rational therapeutic targeting and design.