Project description:The embryonic epicardium provides a source of multipotent progenitors for cardiac lineages, including pericytes, fibroblasts and smooth muscle cells. However, it remains unclear if the epicardium comprises of heterogeneous progenitors or if epicardial cells are multipotent. Using scRNA-seq, we analysed the expression profile of epicardial and epicardial-derived cells at E15.5 and found no evidence of discrete epicardial sub-compartments. Our findings also support the notion that epicardial fate is specified after epithelial-mesenchymal transition, not pre-determined.

Project description:The HH16/17 chicken proepicardium (PE) gives rise to the embryonic epicardium (Epi) which significantly contributes formation of the coronary vasculature during cardiac development. In contrast to explanted Epi cells, explanted PE cells can undergo differentiation into a cardiac myocyte phenotype. In order to assess which genes are associated with PE differentiation into distinc cellular lineages, two interconnented microarray gene-expression series were performed. 1: Gene-expression profiles at 12, 24, 36, 48, 60, 72 and 120 hours during cardiac myocyte differentiation from including the HH16/17 PE (t0h) were determined by hybridizing Cy3 and Cy5 labelled amplified RNA to the ArkGen 20K oligo arrays in a 2-color looped experiment design, i.e., hybridization of successive time-points per array, including dye swaps, resulting in four technical replicates for each time point. 2: Gene expression changes during normal embryonic Epi maturation were assess by hybridizing Epi from stages HH25, HH29, HH32 and HH37 in all possible pair-wise combinations, including dye-swaps, leading to 6 replicates per time point. To allow for valid comparisons between the Epi and untreated PE differentiation, these two array series were connected via hybridization of both Epi stage HH25 and HH29 with the PE explant at 48 hours in culture, with dye swaps. Keywords: time course, cardiac myocyte differentiation, embryonic coronary vessel formation, cell type comparison, mRNA expression Proepicardium to cardiac myocyte differentiation: 16 arrays for 8 time points [t0h,t12h,t24h,t36h,t48h,t60h,t72h,t120h]; successive time points hybridized per array in a loop design with dye swaps + Embryonic epicardium dfferentiation: 12 arrays for 4 time points [HH25,HH29,HH32,HH37]; all possible sample combination were hybridized with dye swaps + Epicardium to Proepicardium data connection: 4 arrays; comparing HH25 and HH29 Epicardium to t48h Proepicardium with dye swaps.

Project description:Reactivating the human epicardium post-cardiac injury holds promise for cardiac tissue regeneration. Despite successful differentiation protocols yielding pure, self-renewing epicardial cells from induced pluripotent stem cells (iPSCs), these cells maintain an embryonic, proliferative state, impeding adult epicardial reactivation investigation. We introduce an optimized method that employs mammalian target of rapamycin (mTOR) signaling inhibition in embryonic epicardium, inducing a quiescent state that enhances multi-step epicardial maturation. This yields functionally mature epicardium, valuable for modeling adult epicardial reactivation. Furthermore, we assess cardiac organoids with cardiomyocytes and mature epicardium, probing molecular mechanisms governing epicardial quiescence during cardiac maturation. Our results highlight iPSC-derived mature epicardium's potential in investigating adult epicardial reactivation, pivotal for effective cardiac regeneration. Additionally, the cardiac organoid model offers insight into intricate cardiomyocyte-epicardium interactions in cardiac development and regeneration.

Project description:Nonmuscle myosin IIB (NMIIB; heavy chain encoded by MYH10) is essential for cardiac myocyte cytokinesis. The role of NMIIB in other cardiac cells is not known. Here, we show that NMIIB is required in epicardial formation and functions to support myocardial proliferation and coronary vessel development. Ablation of NMIIB in epicardial cells results in disruption of epicardial integrity with a loss of E-cadherin at cell-cell junctions and a focal detachment of epicardial cells from the myocardium. NMIIB-knockout and blebbistatin-treated epicardial explants demonstrate impaired mesenchymal cell maturation during epicardial epithelial-mesenchymal transition. This is manifested by an impaired invasion of collagen gels by the epicardium-derived mesenchymal cells and the reorganization of the cytoskeletal structure. Although there is a marked decrease in the expression of mesenchymal genes, there is no change in Snail (also known as Snai1) or E-cadherin expression. Studies from epicardium-specific NMIIB-knockout mice confirm the importance of NMIIB for epicardial integrity and epicardial functions in promoting cardiac myocyte proliferation and coronary vessel formation during heart development. Our findings provide a novel mechanism linking epicardial formation and epicardial function to the activity of the cytoplasmic motor protein NMIIB.

Project description:The epicardium is essential during cardiac development, homeostasis and repair and yet fundamental insights into its underlying cell biology, notably epicardium formation, lineage heterogeneity and functional cross-talk with other cell types in the heart, is currently lacking. In this study, we investigated epicardial heterogeneity and the functional diversity of discrete epicardial subpopulations in the developing zebrafish heart. Single-cell RNA-sequencing uncovered three epicardial subpopulations with specific genetic programmes and distinctive spatial distribution within the developing heart. Perturbation of unique gene signatures uncovered distinct functions associated with each subpopulation and established novel epicardial roles in cell adhesion, migration, and chemotaxis as a mechanism for recruitment of leukocytes into the heart. This work elucidates the mutual spatiotemporal relationships between different epicardial subpopulations and assigns unique function to each during cardiac development. Understanding which mechanisms cells employ to establish a functional epicardium and to communicate with other cardiovascular cell types during development will bring us closer to repairing cellular relationships that are disrupted during cardiovascular disease.

Project description:This study is associated with the GEO accession GSE216019. Abstract from article: Re-activating quiescent adult epicardium represents a potential therapeutic approach for human cardiac regeneration. However, the exact molecular differences between inactive adult and active foetal epicardium are not known. Here, we combined foetal and adult human hearts for the first time using single-cell and single-nuclei RNA sequencing, and compared epicardial cells from both stages. We found a migratory fibroblast-like epicardial population only in the foetal heart and foetal epicardium expressed angiogenic gene programs, while the adult epicardium was solely mesothelial and immune-responsive. Furthermore, we predicted that adult hearts may still receive foetal epicardial paracrine communication, including WNT-signalling with endocardium, reinforcing the validity of regenerative strategies that administer or reactivate epicardial cells in situ. Finally, we explained graft efficacy of our human embryonic stem-cell derived epicardium model, by noting its similarity to human foetal epicardium. Overall, our study defines epicardial programs of regenerative angiogenesis absent in adult hearts, contextualises animal studies, and defines epicardial endpoints required for effective human heart regeneration.

Project description:Re-activating quiescent adult epicardium represents a potential therapeutic approach for human cardiac regeneration. However, the exact molecular differences between inactive adult and active foetal epicardium are not known. Here, we combined foetal and adult human hearts for the first time using single-cell and single-nuclei RNA sequencing, and compared epicardial cells from both stages. We found a migratory fibroblast-like epicardial population only in the foetal heart and foetal epicardium expressed angiogenic gene programs, while the adult epicardium was solely mesothelial and immune-responsive. Furthermore, we predicted that adult hearts may still receive foetal epicardial paracrine communication, including WNT-signalling with endocardium, reinforcing the validity of regenerative strategies that administer or reactivate epicardial cells in situ. Finally, we explained graft efficacy of our human embryonic stem-cell derived epicardium model, by noting its similarity to human foetal epicardium. Overall, our study defines epicardial programs of regenerative angiogenesis absent in adult hearts, contextualises animal studies, and defines epicardial states required for effective human heart regeneration.

Project description:Adult zebrafish regenerate heart muscle after severe cardiac damage without significant scarring. The epicardium, a mesothelial cell sheet covering the vetebrate heart, is activated by injury and supports muscle regeneration through paracrine effects and as a source of multipotent cells. The understudied cellular heterogeneity of the adult epicardium during heart regeneration has constrained the effort in mobilizing the epicardium for heart repair. To dissect epicardial cell states and the underlying mechanisms that lead to successful heart regeneration in zebrafish, we performed single-cell RNA-sequencing of isolated epicardial cells from the regenerating adult heart and revealed their dynamic cellular heterogeneity. We defined the epithelial and mesenchymal layers of the epicardium and identified a transiently activated epicardial progenitor cell (aEPC) subpopulation that expresses aldh1a2, ptx3a, col12a1b and marcksb. Upon heart amputation injury, aEPCs emerge from the existing epicardial cells, migrate to enclose the wound, and disappear as regeneration progresses. Genetic lineage tracing combined with modified RNA labelling confirmed an epithelial-mesenchymal transition (EMT) process of aEPCs and their differentiations to pdgfrb+ mural cells and pdgfra+hapln1a+ mesenchymal fibroblast-like cells that support heart regeneration. Genetic ablation of aEPCs blocked wound closure of the injured ventricle, suppressed cardiomyocyte proliferation, and disrupted heart regeneration. Our findings define a transient progenitor state of the adult epicardium that is an indispensable driver of zebrafish heart regeneration and identified ptx3a as a regeneration-specific non-ontogenetic regulator of the epicardium.

Project description:scRNA-seq of E15.5 epicardium and epicardium-derived cells

Project description:The goal of this study was to perform transcriptional profiling of single epicardium-derived cells during early cardiac development. Epicardium enriched Wilms Tumor Gene 1 (Wt1) genetic lineage tracing mouse line (Wt1CreERT2/+; R26mTmG) was utilized to collect fluorescently labeled epicardial cells at embryonic day (E) 12.5 and following epicardial-to-mesenchymal transition at E16.5. Additionally, single cell transcriptional profiling was performed in endothelial cells that were collected from Wt1CreERT2/+ mice and Wt1CreERT2/+;MRTF-A-/-;MRTF-Bflox/flox to generate myocardin-related transcription factor A and B gene deletions in the epicardium and evaluate the impact of deleting a mechanosensitive gene program on coronary vasculature development at E14.5. This transcriptional data provides a resource to determine relative mRNA changes in epicardium-derived cells and endothelial cells during significant stages of cardiac development.