Abstract P1028: The Epicardium As The Conductor Of Cardiovascular Cells In Cardiac Regeneration

Abstract

Regenerative cardiovascular medicine is emerging as a promising therapeutic alternative to heart transplantation in patients suffering from chronic heart failure. Although promising, challenges to cell therapy for cardiac repair remain, including cell survival, maturation, graft size, revascularisation, and immunogenicity. It has recently been shown that co-transplantation of human embryonic stem cell (hESC)-derived epicardial cells (EPI) with hESC-derived cardiomyocytes (CM) improves cardiac repair processes with respect to engraftment, cell maturation, and graft and host vascularisation. One plausible explanation for the observed benefits of co-transplantation is paracrine-mediated effects. While RNA sequencing data has been used to identify putative players in hESC-EPIs, little is known about their involvement in mediating hESC-CM maturation and revascularization, in particular in communication with endothelial cells (EC). Here, the role of paracrine signalling in hESC-EPI-mediated promotion of hESC-CM maturation and angiogenesis is being investigated with an emphasis on the involvement of extracellular vesicles (EVs). hESC-EPI-EVs improved responsiveness to pacing and coordination of contraction in vitro in hESC-CM cell culture and engineered heart tissues (EHTs). Moreover, hESC-EPI-EVs and hESC-EPI supernatant excluding EVs independently promoted tube formation in in vitro gel-based angiogenesis assays. hESC-EPI supernatant excluding EVs also promoted EC proliferation in MTS assays and EC migration in wound closure assays. Characterisation of the hESC-EPI-EV-cargo on a protein level revealed candidate factors involved in cardiac repair processes. Together with hESC-EPI-EV miRNA-sequencing and hESC-EPI gene expression data key paracrine signalling pathways and candidate factors to manipulate them are being identified and investigated in in vitro angiogenesis and CM maturation assays. Promising angiogenesis promoting candidates are being validated in vivo using yolk-sac membrane and chorioallantoic membrane assays. Identification of the paracrine signalling pathways involved would make it possible to effectively address selected cardiac repair processes, resulting in new approaches to therapy.