Background: Human pluripotent stem cell-derived cardiomyocytes (hPSC-CMs) have tremendous promise for application in cardiac regeneration, but their translational potential is limited by an immature phenotype. We hypothesized that large-scale manufacturing of mature hPSC-CMs could be achieved via culture on polydimethylsiloxane (PDMS) lined roller bottles and that the transplantation of these cells would mediate better structural and functional outcomes than with conventional immature hPSC-CM populations. Methods: We comprehensively phenotyped hPSC-CMs after in vitro maturation for 20 and 40 days on either PDMS or standard tissue culture plastic (TCP) substrates. All hPSC-CMs were generated using a transgenic hPSC line that stably expressed a voltage-sensitive fluorescent reporter to facilitate in vitro and in vivo electrophysiological studies, and cardiomyocyte populations were also analyzed in vitro by immunocytochemistry, ultrastructure and fluorescent calcium imaging, as well as bulk and single-cell transcriptomics. We next compared outcomes after the transplantation of these populations into a guinea pig model of myocardial infarction (MI) using endpoints including histology, optical mapping of graft- and host-derived action potentials, echocardiography, and telemetric electrocardiographic (ECG) monitoring. Results: We demonstrated the economic generation of >1x10 8 mature hPSC-CMs per PDMS-lined roller bottle. Compared to their counterparts generated on TCP substrates, PDMS-matured hPSC-CMs exhibited increased cardiac gene expression and more mature structural and functional properties in vitro. More importantly, intra-cardiac grafts formed with PDMS-matured myocytes showed greatly enhanced structure and alignment, better host-graft electromechanical integration, less pro-arrhythmic behavior, and greater beneficial effects on contractile function. Conclusions: In summary, we describe practical methods for the scaled generation of mature hPSC-CMs and provide the first evidence that the transplantation of more mature cardiomyocytes yields better outcomes in vivo.
Background Human embryonic stem cell-derived cardiomyocytes (hESC-CMs) show tremendous promise for cardiac regeneration, but the successful development of hESC-CM-based therapies requires improved tools to investigate their electrical behavior in recipient hearts. While optical voltage mapping is a powerful technique for studying myocardial electrical activity ex vivo, we have previously shown that intra-cardiac hESC-CM grafts are not labeled by conventional voltage-sensitive fluorescent dyes. We hypothesized that the water-soluble voltage-sensitive dye di-2-ANEPEQ would label engrafted hESC-CMs and thereby facilitate characterization of graft electrical function and integration. Methods We developed and validated a novel optical voltage mapping strategy based on the simultaneous imaging of the calcium-sensitive fluorescent protein GCaMP3, a graft-autonomous reporter of graft activation, and optical action potentials (oAPs) derived from di-2-ANEPEQ, which labels both graft and host myocardium. Cardiomyocytes from three different GCaMP3+ hESC lines (H7, RUES2, or ESI-17) were transplanted into guinea pig models of subacute and chronic infarction, followed by optical mapping at 2 weeks post-transplantation. Results Use of a water-soluble voltage-sensitive dye revealed pro-arrhythmic properties of GCaMP3+ hESC-CM grafts from all three lines including slow conduction velocity, incomplete host-graft coupling, and spatially heterogeneous patterns of activation that varied beat-to-beat. GCaMP3+ hESC-CMs from the RUES2 and ESI-17 lines both showed prolonged oAP durations both in vitro and in vivo. Although hESC-CMs partially remuscularize the injured hearts, histological evaluation revealed immature graft structure and impaired gap junction expression at this early timepoint. Conclusion Simultaneous imaging of GCaMP3 and di-2-ANEPEQ allowed us to acquire the first unambiguously graft-derived oAPs from hESC-CM-engrafted hearts and yielded critical insights into their arrhythmogenic potential and line-to-line variation.
Human embryonic stem cell-derived cardiomyocytes (hESC-CMs) have tremendous promise for application in cardiac repair, but their immature phenotype greatly limits their translational potential. The present study was designed to two hypotheses: 1) that previously reported methods to promote the maturation of hESC-CMs by culture on soft polydimethylsiloxane (PDMS) substrates can be upscaled to the quantities required for transplantation studies; and 2) that PDMS-matured hESC-CMs will stably engraft in injured hearts and form graft myocardium with enhanced structural and functional properties. First, we cultured hESC-CMs on either PDMS or tissue culture plastic (TCP) for 20 and 40 days, then phenotyped the resultant populations. All hESC-CMs were engineered to express the fluorescent voltage-sensitive protein ASAP1 to facilitate in vitro and in vivo electrophysiological studies. Relative to their counterparts on TCP, hESC-CMs on PDMS at both time-points exhibited increased cardiac gene expression as well as a more mature structural and electrophysiological phenotype in vitro. Single-cell transcriptomics confirmed enrichment of cardiac maturation markers including gene pathways involved in cardiac contraction, extracellular matrix organization, sarcomerogenesis, and adult heart development in PDMS versus TCP cultures. Next, we transplanted day 20 or 40 TCP vs PDMS ASAP1+ hESC-CMs into injured guinea pig hearts. Recipient hearts were later analyzed by ex vivo optical voltage mapping studies and histology. While CMs from both substrates showed similar capacity for engraftment, grafts formed with PDMS-matured myocytes had more mature structural properties including enhanced alignment, sarcomere lengths and maturation marker expression. Most importantly, graft formed with PDMS-matured myocytes showed improved electrophysiological properties including better host-graft electromechanical integration and more rapid and uniform propagation. We conclude that large quantities of matured hESC-CMs can indeed be economically produced by these methods. Moreover, PDMS-matured myocytes form large intramyocardial grafts with enhanced cardiac structure and electrical function, thereby establishing that maturation prior to transplantation meaningfully improves outcomes in vivo.
An amendment to this paper has been published and can be accessed via the original article.
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