Project description:The genetic regulatory network controlling early fate choices during human blood cell development are not well understood. We use human pluripotent stem cell reporter lines to track the development of endothelial and haematopoietic populations in an in vitro model of human yolk-sac development. We identified SOX17-CD34+CD43- endothelial cells at day 2 of blast colony development, as a haemangioblast-like branch point from which SOX17-CD34+CD43+ blood cells and SOX17+CD34+CD43- endothelium subsequently arose. Most human blood cell development was dependent on RUNX1. Deletion of RUNX1 only permitted a single wave of yolk sac-like primitive erythropoiesis, but no yolk sac myelopoiesis or aorta-gonad-mesonephros (AGM)-like haematopoiesis. Blocking GFI1/1B activity with a small molecule inhibitor abrogated all blood cell development, even in cell lines with an intact RUNX1 gene. Together, our data defines the hierarchical requirements for both RUNX1 and GFI1/1B during early human haematopoiesis arising from a yolk sac-like SOX17- haemogenic endothelial intermediate.

Project description:The genetic regulatory network controlling early fate choices during human blood cell development are not well understood. We use human pluripotent stem cell reporter lines to track the development of endothelial and haematopoietic populations in an in vitro model of human yolk-sac development. We identified SOX17-CD34+CD43- endothelial cells at day 2 of blast colony development, as a haemangioblast-like branch point from which SOX17-CD34+CD43+ blood cells and SOX17+CD34+CD43- endothelium subsequently arose. Most human blood cell development was dependent on RUNX1. Deletion of RUNX1 only permitted a single wave of yolk sac-like primitive erythropoiesis, but no yolk sac myelopoiesis or aorta-gonad-mesonephros (AGM)-like haematopoiesis. Blocking GFI1/1B activity with a small molecule inhibitor abrogated all blood cell development, even in cell lines with an intact RUNX1 gene. Together, our data defines the hierarchical requirements for both RUNX1 and GFI1/1B during early human haematopoiesis arising from a yolk sac-like SOX17- haemogenic endothelial intermediate.

Project description:During embryogenesis, hematopoietic stem progenitor cells (HSPCs) are believed to be derived from hemogenic endothelial cells (HECs). Moreover, arterial feature is proposed to be a prerequisite for the HECs to generate HSPCs with lymphoid potential. Whereas the molecular basis of the hematopoietic stem cell-competent HECs has been delicately elucidated within the embryo proper, the functional and molecular heterogeneity of HECs in the extra-embryonic yolk sac (YS) remains largely unresolved. In this study, we firstly identified six molecularly different endothelial populations in the mid-gestational YS through integrated analysis of several single-cell RNA sequencing (scRNA-seq) datasets, and validated the arterial vasculature distribution of Gja5+ ECs by using a Gja5-EGFP reporter mouse model. We further explored the hemogenic potential of different EC populations based on their Gja5- EGFP and CD44 expression. The lineage differentiation potentials of ECs were spatiotemporally different and the B lymphoid potential was detected in the YS ECs as early as embryonic day (E) 8.5 regardless of their arterial feature. Unexpectedly, capacity of generating hematopoietic progenitors with in vivo lymphoid potential was found in non-arterial in addition to arterial YS ECs at E10.0-E10.5. Importantly, the distinct identities of E10.0-E10.5 ECs with a hemogenic potential between those from YS and from intra-embryonic caudal region were revealed by further scRNA-seq analysis. Taken together, these findings extend our knowledge about the hemogenic potential of ECs from anatomically and molecularly different vascular beds, providing a theoretical basis for better understanding the sources of HSPCs during mammalian development.

Project description:Development of the dorsal aorta is a key step in the establishment of the adult blood-forming system, since hematopoietic stem and progenitor cells (HSPCs) arise from ventral aortic endothelium in all vertebrate animals studied. Work in zebrafish has demonstrated that arterial and venous endothelial precursors arise from distinct subsets of lateral plate mesoderm. Here, we profile the transcriptome of the earliest detectable endothelial cells (ECs) during zebrafish embryogenesis to demonstrate that tissue-specific EC programs initiate much earlier than previously appreciated, by the end of gastrulation. Classic studies in the chick embryo showed that paraxial mesoderm generates a subset of somite-derived endothelial cells (SDECs) that incorporate into the dorsal aorta to replace HSPCs as they exit the aorta and enter circulation. We describe a conserved program in the zebrafish, where a rare population of endothelial precursors delaminates from the dermomyotome to incorporate exclusively into the developing dorsal aorta. Whereas SDECs lack hematopoietic potential, they act as a local niche to support the emergence of HSPCs from neighboring hemogenic endothelium. Thus, at least three subsets of ECs contribute to the developing dorsal aorta: vascular ECs, hemogenic ECs, and SDECs. Taken together, our findings indicate that the distinct spatial origins of endothelial precursors dictate different cellular potentials within the developing dorsal aorta.

Project description:Hematopoietic cells arise from spatiotemporally restricted domains in the developing embryo. Although studies of non-mammalian animal and in vitro embryonic stem cell models suggest a close relationship among cardiac, endocardial, and hematopoietic lineages, it remains unknown whether the mammalian heart tube serves as a hemogenic organ akin to the dorsal aorta. Here, we examined the hemogenic activity of the developing endocardium. Mouse heart explants generated myeloid and erythroid colonies in the absence of circulation. Hemogenic activity arose from a subset of endocardial cells in the outflow cushion and atria earlier than in the aorta-gonad-mesonephros region, and was transient and definitive in nature. Interestingly, key cardiac transcription factors, Nkx2-5 and Isl1, were expressed in and required for the hemogenic activity of the endocardium. Together, these data suggest that a subset of endocardial and yolk sac endothelial cells expressing cardiac markers serve as a de novo source for transient definitive hematopoietic progenitors. Two independent biological duplicates of freshly isolated mouse tissues (caudal half, heart tube, yolk sac) were sorted for CD31+/CD41-/CD45- cells.

Project description:This SuperSeries is composed of the following subset Series: GSE25079: Epistasis analysis of Runx1 and Gata1 over HoxA3 in hemogenic endothelium GSE25080: Genes regulated by HoxA3 in endothelial and hematopoietic progenitors Refer to individual Series

Project description:Extra-embryonic mesoderm (ExM), the earliest cells that traverse through the primitive streak, give rise to the endothelium as well as hematopoietic progenitors in the developing yolk-sac (YS). How a specific subset of ExM becomes committed to a hematopoietic fate remains unclear. Here we report that Eomesodermin (Eomes), a T-box transcription factor, is transiently expressed in ExM progenitors that generate virtually all YS hematopoietic and endothelial cells. Using an embryonic stem cell (ESC) differentiation system, we find that Eomes activity is essential for the production of primitive erythrocytes and for the normal development of Runx1+ HE that generates the definitive hematopoietic progenitors. RNA-Seq and ATAC-Seq experiments reveal that Eomes governs the accessibility of numerous hematopoietic enhancers that SCL normally utilizes to specify primitive erythrocytes and HE in Flk-1hi/PdgfRa- hematovascular mesoderm. ChIP-seq experiments suggest that Eomes coordinates the development of hemogenic competent mesoderm in the context of Activin/Nodal and Tead-Yap signaling. Finally, single-cell- RNA-seq (scRNAseq) shows that in the absence of Eomes function diversion towards an endothelial rather than hematopoietic fate occurs after the initial specification of Flk-1+/SCL+ hematovascular mesoderm. Collectively, these experiments demonstrate that Eomes sits at the top of the transcriptional hierarchy, functioning upstream of Runx1 expression and SCL functional activity, and promotes hemogenic competence of the entire YS mesodermal lineage.

Project description:Extra-embryonic mesoderm (ExM), the earliest cells that traverse through the primitive streak, give rise to the endothelium as well as hematopoietic progenitors in the developing yolk-sac (YS). How a specific subset of ExM becomes committed to a hematopoietic fate remains unclear. Here we report that Eomesodermin (Eomes), a T-box transcription factor, is transiently expressed in ExM progenitors that generate virtually all YS hematopoietic and endothelial cells. Using an embryonic stem cell (ESC) differentiation system, we find that Eomes activity is essential for the production of primitive erythrocytes and for the normal development of Runx1+ HE that generates the definitive hematopoietic progenitors. RNA-Seq and ATAC-Seq experiments reveal that Eomes governs the accessibility of numerous hematopoietic enhancers that SCL normally utilizes to specify primitive erythrocytes and HE in Flk-1hi/PdgfRa- hematovascular mesoderm. ChIP-seq experiments suggest that Eomes coordinates the development of hemogenic competent mesoderm in the context of Activin/Nodal and Tead-Yap signaling. Finally, single-cell- RNA-seq (scRNAseq) shows that in the absence of Eomes function diversion towards an endothelial rather than hematopoietic fate occurs after the initial specification of Flk-1+/SCL+ hematovascular mesoderm. Collectively, these experiments demonstrate that Eomes sits at the top of the transcriptional hierarchy, functioning upstream of Runx1 expression and SCL functional activity, and promotes hemogenic competence of the entire YS mesodermal lineage.

Project description:Extra-embryonic mesoderm (ExM), the earliest cells that traverse through the primitive streak, give rise to the endothelium as well as hematopoietic progenitors in the developing yolk-sac (YS). How a specific subset of ExM becomes committed to a hematopoietic fate remains unclear. Here we report that Eomesodermin (Eomes), a T-box transcription factor, is transiently expressed in ExM progenitors that generate virtually all YS hematopoietic and endothelial cells. Using an embryonic stem cell (ESC) differentiation system, we find that Eomes activity is essential for the production of primitive erythrocytes and for the normal development of Runx1+ HE that generates the definitive hematopoietic progenitors. RNA-Seq and ATAC-Seq experiments reveal that Eomes governs the accessibility of numerous hematopoietic enhancers that SCL normally utilizes to specify primitive erythrocytes and HE in Flk-1hi/PdgfRa- hematovascular mesoderm. ChIP-seq experiments suggest that Eomes coordinates the development of hemogenic competent mesoderm in the context of Activin/Nodal and Tead-Yap signaling. Finally, single-cell- RNA-seq (scRNAseq) shows that in the absence of Eomes function diversion towards an endothelial rather than hematopoietic fate occurs after the initial specification of Flk-1+/SCL+ hematovascular mesoderm. Collectively, these experiments demonstrate that Eomes sits at the top of the transcriptional hierarchy, functioning upstream of Runx1 expression and SCL functional activity, and promotes hemogenic competence of the entire YS mesodermal lineage.

Project description:Extra-embryonic mesoderm (ExM), the earliest cells that traverse through the primitive streak, give rise to the endothelium as well as hematopoietic progenitors in the developing yolk-sac (YS). How a specific subset of ExM becomes committed to a hematopoietic fate remains unclear. Here we report that Eomesodermin (Eomes), a T-box transcription factor, is transiently expressed in ExM progenitors that generate virtually all YS hematopoietic and endothelial cells. Using an embryonic stem cell (ESC) differentiation system, we find that Eomes activity is essential for the production of primitive erythrocytes and for the normal development of Runx1+ HE that generates the definitive hematopoietic progenitors. RNA-Seq and ATAC-Seq experiments reveal that Eomes governs the accessibility of numerous hematopoietic enhancers that SCL normally utilizes to specify primitive erythrocytes and HE in Flk-1hi/PdgfRa- hematovascular mesoderm. ChIP-seq experiments suggest that Eomes coordinates the development of hemogenic competent mesoderm in the context of Activin/Nodal and Tead-Yap signaling. Finally, single-cell- RNA-seq (scRNAseq) shows that in the absence of Eomes function diversion towards an endothelial rather than hematopoietic fate occurs after the initial specification of Flk-1+/SCL+ hematovascular mesoderm. Collectively, these experiments demonstrate that Eomes sits at the top of the transcriptional hierarchy, functioning upstream of Runx1 expression and SCL functional activity, and promotes hemogenic competence of the entire YS mesodermal lineage.