Pharmacological response of human cardiomyocytes derived from virus-free induced pluripotent stem cells

Abstract

Generation of human induced pluripotent stem cell (hiPSC) lines by reprogramming of fibroblast cells with virus-free methods offers unique opportunities for translational cardiovascular medicine. The aim of the study was to reprogramme fibroblast cells to hiPSCs and to study cardiomyogenic properties and ion channel characteristics of the virus-free hiPSC-derived cardiomyocytes. The hiPSCs generated by episomal vectors generated teratomas in severe combined immunodeficient mice, readily formed embryoid bodies, and differentiated into cardiomyocytes with comparable efficiency to human embryonic stem cells. Temporal gene expression of these hiPSCs indicated that differentiation of cardiomyocytes was initiated by increasing expression of cardio/mesodermal markers followed by cardiac-specific transcription factors, structural, and ion channel genes. Furthermore, the cardiomyocytes showed characteristic cross-striations of sarcomeric proteins and expressed calcium-handling and ion channel proteins, confirming their cardiac ontogeny. Microelectrode array recordings established the electrotonic development of a functional syncytium that responded predictably to pharmacologically active drugs. The cardiomyocytes showed a chronotropic dose-response (0.1-10 µM) to isoprenaline and Bay K 8644. Furthermore, carbamycholine (5 µM) suppressed the response to isoprenaline, while verapamil (2.5 µM) blocked Bay K 8644-induced inotropic activity. Moreover, verapamil (1 µM) reduced the corrected field potential duration by 45%, tetrodotoxin (10 µM) shortened the minimal field potential by 40%, and E-4031 (50 nM) prolonged field repolarization. Virus-free hiPSCs differentiate efficiently into cardiomyocytes with cardiac-specific molecular, structural, and functional properties that recapitulate the developmental ontogeny of cardiogenesis. These results, coupled with the potential to generate patient-specific hiPSC lines, hold great promise for the development of an in vitro platform for drug pharmacogenomics, disease modelling, and regenerative medicine.