In vitro model of ischemic heart failure using human induced pluripotent stem cell–derived cardiomyocytes
Justin Davis, … , Katherine F. Campbell, Todd J. Herron
Justin Davis, … , Katherine F. Campbell, Todd J. Herron
Published April 20, 2021
Citation Information: JCI Insight. 2021;6(10):e134368. https://doi.org/10.1172/jci.insight.134368.
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Resource and Technical Advance Cardiology Cell biology

In vitro model of ischemic heart failure using human induced pluripotent stem cell–derived cardiomyocytes

Abstract

Human induced pluripotent stem cell–derived cardiomyocytes (hiPSC-CMs) have been used extensively to model inherited heart diseases, but hiPSC-CM models of ischemic heart disease are lacking. Here, our objective was to generate an hiPSC-CM model of ischemic heart disease. To this end, hiPSCs were differentiated into functional hiPSC-CMs and then purified using either a simulated ischemia media or by using magnetic antibody-based purification targeting the nonmyocyte population for depletion from the cell population. Flow cytometry analysis confirmed that each purification approach generated hiPSC-CM cultures that had more than 94% cTnT+ cells. After purification, hiPSC-CMs were replated as confluent syncytial monolayers for electrophysiological phenotype analysis and protein expression by Western blotting. The phenotype of metabolic stress–selected hiPSC-CM monolayers recapitulated many of the functional and structural hallmarks of ischemic CMs, including elevated diastolic calcium, diminished calcium transient amplitude, prolonged action potential duration, depolarized resting membrane potential, hypersensitivity to chemotherapy-induced cardiotoxicity, depolarized mitochondrial membrane potential, depressed SERCA2a expression, reduced maximal oxygen consumption rate, and abnormal response to β1-adrenergic receptor stimulation. These findings indicate that metabolic selection of hiPSC-CMs generated cell populations with phenotype similar to what is well known to occur in the setting of ischemic heart failure and thus provide a opportunity for study of human ischemic heart disease.

Authors

Justin Davis, Ahmad Chouman, Jeffery Creech, Andre Monteiro da Rocha, Daniela Ponce-Balbuena, Eric N. Jimenez Vazquez, Ruthann Nichols, Andrey Lozhkin, Nageswara R. Madamanchi, Katherine F. Campbell, Todd J. Herron

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Figure 7

SERCA2a calcium pump gene therapy reverses hiPSC-CM heart failure phenotype.

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SERCA2a calcium pump gene therapy reverses hiPSC-CM heart failure phenot...
(A) Viral transduction was verified by mCherry live-cell expression in hiPSC-CM monolayers. Further, SERCA2a protein expression was determined by Western Blotting. Quantification indicates that SERCA2a protein expression was reduced in metabolic stress–treated hiPSC-CMs at baseline (MACS = 2.11 ± 0.22, n = 3 vs. metabolic stress = 1.27 ± 0.06, n = 3). AdSERCA2a treatment restored SERCA2a levels to control levels (metabolic stress plus Ad SERCA2a = 2.15 ± 0.17, n = 3; ANOVA, *P < 0.05). (B) Calcium transient measurements indicate that metabolic stress selection media prolongs the cardiac action potential and spontaneous arrhythmias were observed in the metabolic stress selection purification approach. hiPSC-CM monolayers treated with AdSERCA2a did not develop arrhythmias. (C) CaTD50 was prolonged in metabolic stress media–treated cells at baseline and was corrected to control values with AdSERCA2a gene therapy (CaTD50s: MACS baseline = 475.5 ± 18.1 ms; metabolic stress baseline = 577.37 ± 17.7 ms; MACS plus AdSERCA2a = 396.6 ± 11.2 ms; metabolic stress plus Ad SERCA2a = 493.67 ± 19.9 ms; ANOVA, **P = 0.002, ns). CaTD, calcium transient duration; hiPSC-CMs, human induced pluripotent stem cell–derived cardiomyocytes; MACS, magnetic-activated cell sorting.