Project description:Most cell fate trajectories during development follow a diverging, tree-like branching pattern, but the opposite can occur when distinct progenitors contribute to the same cell type. During this convergent differentiation, it is unknown if cells ‘remember’ their origins transcription- ally or whether this influences cell behavior. Most coronary blood vessels of the heart develop from two different progenitor sources- the endocardium (Endo) and sinus venosus (SV)—but whether transcriptional or functional differences related to origin are retained is unknown. We addressed this by combining lineage tracing with single-cell RNA sequencing (scRNAseq) in embryonic and adult mouse hearts. Shortly after coronary development begins, capillary endothelial cells (ECs) transcriptionally segregated into two states that retained progenitor-specific gene expression. Later in development, when the coronary vasculature is well established but still remodeling, capillary ECs again segregated into two populations, but transcriptional differences were primarily related to tissue localization rather than lineage. Specifically, ECs in the heart septum expressed genes indic- ative of increased local hypoxia and decreased blood flow. Adult capillary ECs were more homoge- neous with respect to both lineage and location. In agreement, SV- and Endo-derived ECs in adult hearts displayed similar responses to injury. Finally, scRNAseq of developing human coronary vessels indicated that the human heart followed similar principles. Thus, over the course of development, transcriptional heterogeneity in coronary ECs is first influenced by lineage, then by location, until heterogeneity declines in the homeostatic adult heart. These results highlight the plasticity of ECs during development, and the validity of the mouse as a model for human coronary development. 

Project description:Coronaries are essential for myocardial growth and heart function. Notch is crucial for mouse embryonic angiogenesis, but its role in coronary development remains uncertain. We show Jag1, Dll4 and activated Notch1 receptor expression in sinus venosus (SV) endocardium. Endocardial Jag1 removal blocks SV capillary sprouting, while Dll4 inactivation stimulates excessive capillary growth, suggesting that ligand antagonism regulates coronary primary plexus formation. Later endothelial ligand removal, or forced expression of Dll4 or the glycosyltransferase MFng, blocks coronary plexus remodeling, arterial differentiation, and perivascular cell maturation. Endocardial deletion of Efnb2 phenocopies the coronary arterial defects of Notch mutants. Angiogenic rescue experiments in ventricular explants, or in primary human endothelial cells, indicate that EphrinB2 is a critical effector of antagonistic Dll4 and Jag1 functions in arterial morphogenesis. Thus, coronary arterial precursors are specified in the SV prior to primary coronary plexus formation and subsequent arterial differentiation depends on a Dll4-Jag1-EphrinB2 signaling cascade.

Project description:Coronary blood vessel formation is a highly regulated process in which endothelial cells (ECs) play an essential role. During the last years, new pieces of evidence have demonstrated WT1 expression in coronary ECs. However, its role in coronary blood vessel formation was almost unknown. Here we generated an inducible endothelial-specific Wt1KO mouse model (Wt1KOΔEC). The analysis of these mutant mice has demonstrated that deletion of Wt1 in coronary ECs impairs coronary blood vessels and myocardium development. The transcriptomic analysis of coronary ECs from Wt1KOΔEC mice demonstrated that deletion of Wt1 has a great impact on the molecular signature of coronary ECs that correlate with defects in cell proliferation, migration, and differentiation. These results provide novel insights into the role of WT1 in heart development and demonstrate that WT1 in ECs is required for coronary blood vessel formation.

Project description:Mature endothelial cells (ECs) are heterogeneous, with subtypes defined by tissue origin and by position within the vascular bed. Here, we performed scRNA-seq with mouse embryonic ECs and identified 19 subclusters, including Etv2+Bnip3+ early EC progenitors. Most of these subtypes were grouped by their vascular-bed types, while ECs from brain, heart and liver were grouped by their tissue origins. Compared to arterial ECs (aECs), embryonic venous (vECs) and capillary ECs (cECs) shared less markers with their adult counterparts. cECs showed some venous characteristics. One cEC cluster with both venous and capillary features served as a branch point for aEC and vEC lineages. aECs and vECs showed distinct transcriptional regulatory networks.

Project description:Aims: Coronary vasculature formation is a critical event during cardiac development, essential for heart function throughout perinatal and adult life. However, current understanding of coronary vascular development has largely been derived from transgenic mouse models. The aim of this study was to characterise the transcriptome of the human fetal cardiac endothelium using single-cell RNA sequencing (scRNA-seq) to provide critical new insights into the cellular heterogeneity and transcriptional dynamics that underpin endothelial specification within the vasculature of the developing heart. Methods and Results: We acquired scRNA-seq data of over 10,000 fetal cardiac endothelial cells (EC), revealing divergent EC subtypes including endocardial, capillary, venous, arterial, and lymphatic populations. Gene regulatory network analyses predicted roles for SMAD1 and MECOM in determining the identity of capillary and arterial populations, respectively. Trajectory inference analysis suggested an endocardial contribution to the coronary vasculature and subsequent arterialisation of capillary endothelium accompanied by increasing MECOM expression. Comparative analysis of equivalent data from murine cardiac development demonstrated that transcriptional signatures defining endothelial subpopulations are largely conserved between human and mouse. Furthermore, we revealed that knockdown of MECOM in human embryonic stem cell-derived EC (hESC-EC) resulted in an increase in venous EC marker expression, validating our prediction of its role in arterial EC identity. Conclusions: scRNA-seq of the human fetal cardiac endothelium identified distinct EC populations. A predicted endocardial contribution to the developing coronary vasculature was identified, as well as subsequent arterial specification of capillary EC. Loss of MECOM in hESC-EC increased venous EC marker expression, suggesting a role in maintaining arterial EC identity.

Project description:The heterogeneity of endothelial cells (ECs), lining blood vessels, across tissues remains incompletely inventoried. We constructed an atlas of >32,000 single-EC transcriptomic data from 11 tissues of the model organism Mus musculus. We propose a new classification of EC phenotypes based on transcriptome signatures and inferred putative biological features. We identified top-ranking markers for ECs from each tissue. ECs from different vascular beds (arteries, capillaries, veins, lymphatics) resembled each other across tissues, but only arterial, venous and lymphatic (not capillary) ECs shared markers, illustrating a greater heterogeneity of capillary ECs. We identified high-endothelial-venule and lacteal-like ECs in the intestines, and angiogenic ECs in healthy tissues. Metabolic transcriptomes of ECs differed amongst spleen, lung, liver, brain and testis, while being similar for kidney, heart, muscle and intestines. Within tissues, metabolic gene expression was heterogeneous amongst ECs from different vascular beds, altogether highlighting large EC heterogeneity.

Project description:A better understanding of the pathways that regulate regeneration of the coronary vasculature is of fundamental importance for the advancement of strategies to treat patients with heart disease. By analyzing single cell transcriptome of resident cardiac endothelial cells (ECs) in adult mouse hearts under both healthy and myocardial infarction (MI) settings, we provide molecular definitions of murine cardiac endothelial heterogeneity and characterizations of pro-angiogenic resident ECs.

Project description:The heterogeneity of embryonic endothelial cells (ECs) especially the distinction of arteriovenous ECs remains incompletely characterized. We established a mouse single-EC transcriptomic landscape at mid-to-late gestation stage and identified 19 subclusters, including Etv2+Bnip3+ early ECs and 2 specialized ECs. Most of these subtypes were grouped by their vascular-bed types, while ECs from brain, heart and liver were grouped by their tissue origins. Unlike arterial ECs (aECs), embryonic venous (vECs) and capillary ECs (cECs) shared less markers with their adult counterparts. Notably, capillary clusters showed some venous characteristics and one of them served as an intermediate state of arteriovenous specification. Compared to the more early stage, a clear arteriovenous branch which also going through a venous plexus was identified. aECs and vECs showed distinct transcriptional modules including specific regulatory networks of transcription factors. Especially, USF1 and MECOM were verified functioning in arteriovenous differentiation through human induced pluripotent stem cells (hiPSC) differentiation models. We therefore provide a new map of endothelial heterogeneity highlighting regulation of arteriovenous specification.

Project description:MHCaCre induced knockout of Fog2flox. Aberrant transcriptional regulation contributes to the pathogenesis of both congenital and adult forms of heart disease. While the transcriptional regulator FOG2 is known to be essential for heart morphogenesis and coronary development, its tissue specific function has not been previously investigated. Additionally, little is known about the role of FOG2 in the adult heart. Here we use spatiotemporally regulated inactivation of Fog2 to delineate its function both in embryo and adult heart. Early cardiomyocyte-restricted loss of Fog2 recapitulated the cardiac and coronary defects of the Fog2 germline knockouts. Later cardiomyocyte-restricted loss of Fog2 (Fog2MC) did not result in defects in cardiac structure or coronary vessel formation. However, Fog2MC adult mice had severely depressed ventricular function and died at 8-14 weeks. Fog2MC adult hearts displayed a paucity of coronary vessels. This was associated with myocardial hypoxia, increased cardiomyocyte apoptosis, and cardiac fibrosis. Induced inactivation of Fog2 in adult heart resulted in similar phenotype, as did ablation of FOG2 interaction with the transcription factor GATA4. Loss of FOG2 or FOG2-GATA4 interaction altered expression of a panel of angiogenesis-related genes. Collectively, our data indicated that FOG2 regulates adult heart function and coronary angiogenesis. Experiment Overall Design: Fog2flox/delta; MHCaCre (3) compared to Fog2flox/delta; no Cre (3). One heart per sample.

Project description:Aims: To gain insight into heterogeneity of pacemaker and conduction cells within the sinoatrial node (SAN) and characterize the transcriptome of cardiac endothelial cells (ECs) at single-cell resolution. Methods and results: Single-cell transcriptome analysis of fluorescence activated cell sorting (FACS)-purified SAN cells and surrounding atrial cells from HCN4-GFP knockin mice at postnatal day 2 were performed. Subcluster analysis of SAN cardiomyocyte cluster identified three HCN4+ cell subtypes, including pacemaker cells (PCs), recently identified transitional cells (TCs), and a novel population of His-like conduction cells marked by His-bundle specific marker genes. We additionally refined the molecular signatures of PCs and TCs, and identified Vsnl1, Myl2 and Kcne1 as biomarkers of PCs, TCs and His-like respectively that persistently expressed in the SAN from E15.5 to adult. Furthermore, we observed three endothelial progenitor subtypes (endocardial progenitors, coronary vascular endothelial progenitors, and transitional endothelium migrated from endocardium to coronary vessels) in mouse heart and human fetal heart. These endothelial progenitor subtypes were further identified by mouse lineage tracing analysis. Conclusion: Our study provides a more comprehensive understanding of molecular and cellular signatures underlying pacemaking and conduction of the SAN, and offers new insight into lineage differentiation and diversification of cardiac ECs.