Project description:We discover that ER71/ETV2 initiates hemangiogenic program by activating blood and endothelial cell lineage specifying genes while enhancing FLK1 expression and expanding hemangioblast population. Furthermore, ER71/ETV2 establishes an ETS hierarchy by directly activating Ets genes in hematopoietic and endothelial cell lineage development. As such, ER71/ETV2-initiated blood and endothelial cell program is maintained by ER71/ETV2 downstream ETS factors through an ETS switching mechanism.

Project description:We discover that ER71/ETV2 initiates hemangiogenic program by activating blood and endothelial cell lineage specifying genes while enhancing FLK1 expression and expanding hemangioblast population. Furthermore, ER71/ETV2 establishes an ETS hierarchy by directly activating Ets genes in hematopoietic and endothelial cell lineage development. As such, ER71/ETV2-initiated blood and endothelial cell program is maintained by ER71/ETV2 downstream ETS factors through an ETS switching mechanism. ChIP-seq analysis of ER71 in differentiated embryonic stem cells

Project description:ETV2/ER71 regulates hematovascular lineage generation and vascularization through an H3K9 demethylase, KDM4A

Project description:Samples 1-6: HDFs transduced with ER71/ETV2 were sorted on KDR expression at day 7. The isolated KDR+ cells together with human umbilical venous endothelial cells (HUVECs) and untransduced HDFs were subjected to genomic gene expression profiling. A significant number of genes related with vessel development and angiogenesis was significantly upregulated in KDR+ cells, compared to control HDFs. These findings strongly argue that ER71/ETV2 directly reprograms human fibroblasts to functional endothelial-like cells, which could be useful for disease investigation as well as autologous cell therapy. Samples 7-12: HDFs transduced with ER71/ETV2 were sorted on KDR expression at day 7. The isolated KDR+ cells were further cultured up to day 93. The further cultured cells together with human umbilical venous endothelial cells (HUVECs) and untransduced HDFs were subjected to genomic gene expression profiling. A significant number of genes related with vessel development and angiogenesis was significantly upregulated in the further cultured cells, compared to control HDFs. These findings strongly argue that ER71/ETV2 directly reprograms human fibroblasts to functional endothelial-like cells, which could be useful for disease investigation as well as autologous cell therapy. Samples 1-6: HDFs transduced with ER71/ETV2 were sorted on KDR expression at day 7. The isolated KDR+ cells together with human umbilical venous endothelial cells (HUVECs) and untransduced HDFs were subjected to genomic gene expression profiling. Samples 7-12: HDFs transduced with ER71/ETV2 were sorted on KDR expression at day 7. The isolated KDR+ cells were further cultured up to day 93. The further cultured cells together with human umbilical venous endothelial cells (HUVECs) and untransduced HDFs were subjected to genomic gene expression profiling.

Project description:ER71 mutant embryos are nonviable and lack hematopoietic and endothelial lineages. To further define the functional role for ER71 in cell lineage decisions, we generated genetically modified mouse models. We engineered an ER71-EYFP transgenic mouse model by fusing the 3.9 kb ER71 promoter to the EYFP reporter gene. Using FACS and transcriptional profiling, we examined the EYFP+ populations of cells in ER71 mutant and wildtype littermates. In the absence of ER71, we observed an increase in the number of EYFP expressing cells, increased expression of the cardiac molecular program and decreased expression of the hemato-endothelial program compared to the wildtype littermate controls. We have also generated a novel ER71-Cre transgenic mouse model using the same 3.9 kb ER71 promoter. Genetic fate mapping studies revealed that the ER71 expressing cells daughter hematopoietic and endothelial lineages in the wildtype background. In the absence of ER71, these cell populations contributed to alternative mesodermal lineages including the cardiac lineage. To extend these analyses, we used an inducible ES/EB system and observed that ER71 overexpression repressed cardiogenesis. Together, these studies identify ER71 as a critical regulator of mesodermal fate decisions, acting to specify the hematopoietic and endothelial lineages at the expense of cardiac lineages. This enhances our understanding of the mechanisms that govern mesodermal fate decisions early during embryogenesis.

Project description:Samples 1-6: HDFs transduced with ER71/ETV2 were sorted on KDR expression at day 7. The isolated KDR+ cells together with human umbilical venous endothelial cells (HUVECs) and untransduced HDFs were subjected to genomic gene expression profiling. A significant number of genes related with vessel development and angiogenesis was significantly upregulated in KDR+ cells, compared to control HDFs. These findings strongly argue that ER71/ETV2 directly reprograms human fibroblasts to functional endothelial-like cells, which could be useful for disease investigation as well as autologous cell therapy. Samples 7-12: HDFs transduced with ER71/ETV2 were sorted on KDR expression at day 7. The isolated KDR+ cells were further cultured up to day 93. The further cultured cells together with human umbilical venous endothelial cells (HUVECs) and untransduced HDFs were subjected to genomic gene expression profiling. A significant number of genes related with vessel development and angiogenesis was significantly upregulated in the further cultured cells, compared to control HDFs. These findings strongly argue that ER71/ETV2 directly reprograms human fibroblasts to functional endothelial-like cells, which could be useful for disease investigation as well as autologous cell therapy.

Project description:ER71 mutant embryos are nonviable and lack hematopoietic and endothelial lineages. To further define the functional role for ER71 in cell lineage decisions, we generated genetically modified mouse models. We engineered an ER71-EYFP transgenic mouse model by fusing the 3.9 kb ER71 promoter to the EYFP reporter gene. Using FACS and transcriptional profiling, we examined the EYFP+ populations of cells in ER71 mutant and wildtype littermates. In the absence of ER71, we observed an increase in the number of EYFP expressing cells, increased expression of the cardiac molecular program and decreased expression of the hemato-endothelial program compared to the wildtype littermate controls. We have also generated a novel ER71-Cre transgenic mouse model using the same 3.9 kb ER71 promoter. Genetic fate mapping studies revealed that the ER71 expressing cells daughter hematopoietic and endothelial lineages in the wildtype background. In the absence of ER71, these cell populations contributed to alternative mesodermal lineages including the cardiac lineage. To extend these analyses, we used an inducible ES/EB system and observed that ER71 overexpression repressed cardiogenesis. Together, these studies identify ER71 as a critical regulator of mesodermal fate decisions, acting to specify the hematopoietic and endothelial lineages at the expense of cardiac lineages. This enhances our understanding of the mechanisms that govern mesodermal fate decisions early during embryogenesis. 12samples were analyzed, including triplicates of WT; EYFP positive, WT EYFP negative, ER71 MT; EYFP positive and ER71 MT; EYFP negative cells

Project description:Ets transcription factor ER71 is critical for Flk-1 mesoderm specification to different cell lineages. In this dataset, we determine to investigate the mechanisms by which ER71 regulates hematopoietic and endothelial cell versus cardiac cell lineage development.

Project description:Ets transcription factor ER71 is critical for Flk-1 mesoderm specification to different cell lineages. In this dataset, we determine to investigate the mechanisms by which ER71 regulates hematopoietic and endothelial cell versus cardiac cell lineage development. Expression of all four Flk-1+ mesoderm populations (i.e. Er71 overexpressed versus control, Er71 deficient versus control Flk-1+ mesoderm) was compared. Specifically, we sorted Flk-1+ mesoderm from day 3 differentiated embryonic stem(ES) cells, including induced Er71 and control ES cells, as well as Er71+/+ as well as Er71-/- ES cells .

Project description:During embryogenesis, the endothelial and the hematopoietic lineages first appear during gastrulation in the blood island of the yolk sac. We have previously reported that an Ets variant gene 2 (Etv2/ER71) mutant embryo lacks hematopoietic and endothelial lineages, however, the precise roles of Etv2 in yolk sac development remains unclear. We carried out a transcriptome analysis using an ES cell line that can inducibly express Etv2. Cells were induced for 12 hours at day 3 of differentiation. An ES cell line (dervied from mouse of background strain 129P2/Ola) with a doxycycline inducible expression casette of Etv2 (ER71 A2Lox.cre) was differentiated in hanging drops. At 3 days of differentiation, cells were treated with doxycycline for 12 hours, and subsequently Flk1(+) cells were sorted. Experiment was done in triplicate and untreated cells were used for control.