Project description:The epicardium is the mesothelial lining of the heart which acts as a source of progenitor cells during heart development, giving rise to an invasive population of mesenchymal cells which differentiate into cardiac fibroblasts, mural cells, and other cell types essential for heart structure and function. Previously, we showed that epicardial-specific deletion of the gene encoding SRY-box transcription factor 9 (SOX9) impairs epicardial-derived cell invasion and reduces their contribution to the atrioventricular valve mesenchyme. In this study, we use single-cell RNA-sequencing to investigate broader roles of Sox9 in the epicardium as it relates to epicardial invasion, differentiation, and vascular development. We identified transcriptional changes indicative of decreased epicardial-to-mesenchymal transformation consistent with histological observations. Sox9-deficient epicardial cells exhibited elevated expression of vascular smooth muscle cell genes, suggesting that Sox9 may influence epicardial cell fate decisions. Immunofluorescence analyses revealed defective epicardial attachment and decreased epicardial-derived cell invasion into the ventricular myocardium associated with delayed coronary plexus formation. This study expands our understanding of the role of Sox9 in epicardial biology, demonstrating an important function in regulating epicardial cell invasion, differentiation, and coronary vasculature development. These insights provide a foundation for further investigations into epicardial-mediated mechanisms underlying congenital heart abnormalities.

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, three interconnented microarray gene-expression time series were performed at time 0, 24, 72 and 120h after incubation with specific growth conditions: 1: Bmp2 + U0126: differentiation towards a cardiomyocyte phenotype 2: F2f2 + Vegf: differentiation towards a vascular epithelial phenotype 3: Fgf2: differentiation towards a epicardial phenotype

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 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, three interconnented microarray gene-expression time series were performed at time 0, 24, 72 and 120h after incubation with specific growth conditions: 1: Bmp2 + U0126: differentiation towards a cardiomyocyte phenotype 2: F2f2 + Vegf: differentiation towards a vascular epithelial phenotype 3: Fgf2: differentiation towards a epicardial phenotype Gene-expression profiles 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.

Project description:The epicardium, an epithelium covering the heart, is essential for cardiac development. During embryogenesis, the epicardium provides instructive signals for the growth and maturation of cardiomyocytes and for coronary angiogenesis. We generated an in vitro model of human embryonic epicardium derived from human pluripotent stem cells (hPSC-epi). These cells were able to differentiate into cardiac fibroblasts (cf) and smooth muscle cells (smc) in vitro (hPSC-epi-cf and hPSC-epi-smc respectively). Furthermore, we showed that they improved maturation of hPSC-derived cardiomyocytes (hPSC-cardio) in vitro while neural crest cells derived from hPSC (hPSC-NC) could not. Furthermore, they improved survival of hPSC-cardio and stimulated angiogenesis when injected in a rat model of myocardium infarction. We performed mRNA sequencing of the hPSC-epi, hPSC-epi-cf, hPSC-smc and hPSC-NC in order to identify the secreted molecules specifically produced by the hPSC-epi and/or its derivatives in comparison with the hPSC-NC. Vascular smooth muscle cells have different embryonic origins and different properties depending on their location in the body. The coronary smooth muscle cells come from the epicardium while the aortic ones come from the mesoderm or the neural crest. We performed mRNA sequencing of human coronary artery smc and human aortic smc to identify a specific signature of the coronary smc. We also compared the genes expressed in the hPSC-epi-smc and the smc derived from hPSC-derived lateral plate mesoderm.

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:Identification of epicardium-enriched genes in the embryonic heart. The epicardium encapsulates the heart and functions as a source of multipotent progenitor cells and paracrine factors essential for cardiac development and repair. Injury of the adult heart results in re-activation of a developmental gene program in the epicardium, but the transcriptional basis of epicardial gene expression has not been delineated. We established a mouse embryonic heart organ culture and gene expression system that facilitated the identification of epicardial enhancers activated during heart development and injury. Epicardial activation of these enhancers depends on a combinatorial transcriptional code centered on CCAAT/enhancer binding protein (C/EBP) transcription factors. Disruption of C/EBP signaling in the adult epicardium reduced injury-induced neutrophil infiltration and improved cardiac function. These findings reveal a transcriptional basis for epicardial activation and heart injury, providing a platform for enhancing cardiac regeneration. Total RNA obtained from lacZ-positive epicardial cells isolated from the E11.5 Tcf21lacZ hearts compared to total dissociated heart cells

Project description:The contractile ability of the mammalian heart critically relies on blood coronary circulation, essential to provide oxygen and nutrients to myocardial cells. In addition, the lymphatic vasculature is essential for the myocardial immune response, extracellular fluid homeostasis and response to injury. Recent studies identified different origins of coronary lymphatic endothelial cells, however, the cues that govern coronary lymphangiogenesis remain unknown. Here we show that the coronary lymphatic vasculature develops in intimate contact with the epicardium and with epicardial-derived cells. The epicardium expresses the lymphangiogenic cytokine VEGFC and its conditional elimination from the epicardium abrogates coronary lymphatic vasculature development. Interestingly, VEGFD is also expressed in the epicardium and cooperates with VEGFC in coronary lymphangiogenesis, but it does so only in females, uncovering an unsuspected sex-specific role for this cytokine. These results identify a role for the epicardium/subepicardium as a signalling niche required for coronary lymphangiogenesis and VEGFC/D as essential mediators of this role.

Project description:By contrast with mammals, adult zebrafish have a high capacity to regenerate damaged or lost myocardium through proliferation of spared cardiomyocytes. The epicardial sheet covering the heart is activated by injury and aids muscle regeneration through paracrine effects and as a multipotent cell source, and has received recent attention as a target in cardiac repair strategies. While it is recognized that epicardium is required for muscle regeneration and itself has high regenerative potential, the extent of cellular heterogeneity within epicardial tissue is largely unexplored. In this study, we performed transcriptome analysis on dozens of epicardial lineage cells purified from zebrafish harboring a transgenic reporter for the pan-epicardial gene tcf21. Hierarchical clustering analysis suggested the presence of at least three epicardial cell subsets defined by expression signatures. We validated many new pan-epicardial and epicardial markers by alternative expression assays. Additionally, we explored the function of the scaffolding protein and main component of caveolae, caveolin-1 (cav1), which was present in each epicardial subset. In BAC transgenic zebrafish, cav1 regulatory sequences drove strong expression in ostensibly all epicardial cells and in coronary vascular endothelial cells. Moreover, cav1 mutant zebrafish generated by genome editing showed grossly normal heart development and adult cardiac anatomy, but displayed profound defects in injury-induced cardiomyocyte proliferation and heart regeneration. Our study defines a new platform for the discovery of epicardial lineage markers, genetic tools, and mechanisms of heart regeneration. Deep sequencing of isolated single epicardial cells

Project description:Platelet-derived growth factor (PDGF) signaling regulates perivascular cell or mural cell association with the blood-vessel endothelial cells. Mural cells express the receptor of the signaling, pdgfrb. Besides mural cells the outer epithelial layer of the heart, epicardium and epicardial derived cells express pdgfrb. In this dataset we characterized pdgfrb expressing cells in adult zebrafish heart ventricles in AB wildtype fish, pdgfrb loss-of-function mutant fish. Since pdgfrb is activated in injured zebrafish heart, we aslo compared pdgfrb expressing cells in injured (amputated, 7 days post amputation) heart ventricle with similar cells in uninjured hearts.