Project description:Screening for genes up in Etv2+ cells within Flk-1+ ES derived mesoderm Microarray analysis performed to screen for the candidate genes regulated by Etv2. Differentiated Flk-1+ mesoderm can be devided into Etv2+ or-. Etv2+ cells are assumed to be committed to hemato/endothelial cells. Comparison of two populations can reveal genes relevant in this commitment. Extract RNA from sorted Flk-1+/Etv2- vs Flk-1+/Etv2+ populations.Etv2-Venus KI ES cells were differentiated on OP9 for 4-5 days and Flk-1+ population was separated into Etv2-Venus+ or- cells. Total RNA was purified from each population for analysis.

Project description:Screening for genes up in Etv2+ cells within Flk-1+ ES derived mesoderm Microarray analysis performed to screen for the candidate genes regulated by Etv2. Differentiated Flk-1+ mesoderm can be devided into Etv2+ or-. Etv2+ cells are assumed to be committed to hemato/endothelial cells. Comparison of two populations can reveal genes relevant in this commitment.

Project description:The development of a vascular network is essential to nourish tissues and sustain organ function throughout life. Endothelial cells (ECs) are the building blocks of blood vessels, yet our understanding of EC specification in vertebrates remains incomplete. cloche/npas4l mutants have broadly been used as an avascular model in zebrafish, but little is known about the molecular mechanism of action of Npas4l. Here, to identify the direct and indirect target genes of this transcription factor, we combined complementary genome-wide approaches, including transcriptome analyses and chromatin immunoprecipitation (ChIP). The cross-analysis of these datasets indicate that Npas4l functions as a master regulator by directly inducing a wave of transcription factor genes crucial for hematoendothelial specification in vertebrates, including etv2, tal1, and lmo2. We identified additional target genes acting downstream of npas4l and investigated the function of a subset of them using CRISPR/Cas9 technology. Phenotypic characterization of tspan18b mutants reveals a novel role for tspan18b in developmental angiogenesis, confirming the reliability of the datasets generated. Collectively, these data represent a useful resource for future studies aimed to investigate novel genes with a potential role in vascular development and EC fate determination in vertebrates.

Project description:The development of a vascular network is essential to nourish tissues and sustain organ function throughout life. Endothelial cells (ECs) are the building blocks of blood vessels, yet our understanding of EC specification in vertebrates remains incomplete. cloche/npas4l mutants have broadly been used as an avascular model in zebrafish, but little is known about the molecular mechanism of action of Npas4l. Here, to identify the direct and indirect target genes of this transcription factor, we combined complementary genome-wide approaches, including transcriptome analyses and chromatin immunoprecipitation (ChIP). The cross-analysis of these datasets indicate that Npas4l functions as a master regulator by directly inducing a wave of transcription factor genes crucial for hematoendothelial specification in vertebrates, including etv2, tal1, and lmo2. We identified additional target genes acting downstream of npas4l and investigated the function of a subset of them using CRISPR/Cas9 technology. Phenotypic characterization of tspan18b mutants reveals a novel role for tspan18b in developmental angiogenesis, confirming the reliability of the datasets generated. Collectively, these data represent a useful resource for future studies aimed to investigate novel genes with a potential role in vascular development and EC fate determination in vertebrates.

Project description:The development of a vascular network is essential to nourish tissues and sustain organ function throughout life. Endothelial cells (ECs) are the building blocks of blood vessels, yet our understanding of EC specification in vertebrates remains incomplete. cloche/npas4l mutants have broadly been used as an avascular model in zebrafish, but little is known about the molecular mechanism of action of Npas4l. Here, to identify the direct and indirect target genes of this transcription factor, we combined complementary genome-wide approaches, including transcriptome analyses and chromatin immunoprecipitation (ChIP). The cross-analysis of these datasets indicate that Npas4l functions as a master regulator by directly inducing a wave of transcription factor genes crucial for hematoendothelial specification in vertebrates, including etv2, tal1, and lmo2. We identified additional target genes acting downstream of npas4l and investigated the function of a subset of them using CRISPR/Cas9 technology. Phenotypic characterization of tspan18b mutants reveals a novel role for tspan18b in developmental angiogenesis, confirming the reliability of the datasets generated. Collectively, these data represent a useful resource for future studies aimed to investigate novel genes with a potential role in vascular development and EC fate determination in vertebrates.

Project description:The development of a vascular network is essential to nourish tissues and sustain organ function throughout life. Endothelial cells (ECs) are the building blocks of blood vessels, yet our understanding of EC specification in vertebrates remains incomplete. cloche/npas4l mutants have broadly been used as an avascular model in zebrafish, but little is known about the molecular mechanism of action of Npas4l. Here, to identify the direct and indirect target genes of this transcription factor, we combined complementary genome-wide approaches, including transcriptome analyses and chromatin immunoprecipitation (ChIP). The cross-analysis of these datasets indicate that Npas4l functions as a master regulator by directly inducing a wave of transcription factor genes crucial for hematoendothelial specification in vertebrates, including etv2, tal1, and lmo2. We identified additional target genes acting downstream of npas4l and investigated the function of a subset of them using CRISPR/Cas9 technology. Phenotypic characterization of tspan18b mutants reveals a novel role for tspan18b in developmental angiogenesis, confirming the reliability of the datasets generated. Collectively, these data represent a useful resource for future studies aimed to investigate novel genes with a potential role in vascular development and EC fate determination in vertebrates.

Project description:Etv2-mediated hemangiogenic fate commitment of mesoderm

Project description:Fractionation of EML cells isolated based on surface expression of immunophenotypic markers reveals the existence of a subpopulation that has undergone spontaneous commitment to an erythroid fate. Uncommitted fractions were compared to committed cells, derived from both spontaneous (EryCP) and cytokine-driven (Ediff) commitment. EML cells were separated by flow cytometry based on their expression of the markers Sca1, CD34 and cKit as described.

Project description:Fractionation of EML cells isolated based on surface expression of immunophenotypic markers reveals the existence of a subpopulation that has undergone spontaneous commitment to an erythroid fate. Uncommitted fractions were compared to committed cells, derived from both spontaneous (EryCP) and cytokine-driven (Ediff) commitment.

Project description:The ability to differentiate human induced pluripotent stem cells (hiPSCs) efficiently into defined cardiac lineages, such as cardiomyocytes and cardiac endothelial cells, is crucial to study human heart development and model cardiovascular diseases in vitro. The mechanisms underlying the specification of these cell types during human development are not well-understood which limits fine-tuning and broader application of cardiac model systems. Here, we used the expression of ETV2, a master regulator of hematoendothelial specification in mice, to identify functionally distinct subpopulations during the co-differentiation of endothelial cells and cardiomyocytes from hiPSCs. Targeted analysis of single-cell RNA sequencing data revealed differential ETV2 dynamics in the two lineages. A newly created fluorescent reporter line allowed us to identify early lineage-predisposed states and show that a transient ETV2-high state initiates the specification of endothelial cells. We further demonstrated, unexpectedly, that functional cardiomyocytes can originate from progenitors expressing ETV2 at a low level. Our study thus sheds light on the in vitro differentiation dynamics of two important cardiac lineages.