Project description:Endothelial cells (EC) differentiate from multiple sources during embryonic development, including the cardiopharyngeal mesoderm, which gives rise to multiple tissues including the cardiac and branchiomeric muscle. Here, we have used a cardiogenic mesoderm cell differentiation model that also activates an endothelial transcription program. Comparing our chromatin remodeling data with publicly available single-cell RNA-seq data from mouse embryos, we derived a list of over 100 putative regulatory elements activated in EC marker genes. We applied a machine-learning strategy trained with validate enhancers to predict the probability of these sequences to function as enhancers. The computational assay returned over 50% of these sequences to be likely enhancers, some of which previously reported. In addition, using genetic and epigenetic perturbations of some of these elements, we established their requirement for gene expression during endothelial differentiation. Finally, we used the integration of multiple data sources and computational tools to search for transcriptional factor binding motifs related to endothelial cell fate specification. We found motifs of GATA, ETS, and FOS/AP-1 factors as the most significantly enriched in these sequences. Overall, our approach has been efficient in the identification of novel EC regulatory sequences with high likelihood to be enhancers, and validated a subset of them. Motif analyses revealed that the core EC transcription factors GATA/ETS/FOS is a likely driver of EC differentiation in cardiopharyngeal mesoderm.

Project description:Cardiopharyngeal mesoderm contributes to the formation of the heart and head muscles. However, the mechanisms governing cardiopharyngeal mesoderm specification remain unclear. Indeed, there is a lack of an in vitro model replicating the differentiation of both heart and head muscles to study these mechanisms. Such models are required to allow live-imaging and high throughput genetic and drug screening. Here, we show that the formation of self-organizing or pseudo-embryos from mouse embryonic stem cells (mESCs), also called gastruloids, reproduces cardiopharyngeal mesoderm specification towards cardiac and skeletal muscle lineages. By conducting a comprehensive temporal analysis of cardiopharyngeal mesoderm establishment and differentiation in gastruloids and comparing it to mouse embryos, we present the first evidence for skeletal myogenesis in gastruloids. By inferring lineage trajectories from the gastruloids single-cell transcriptomic data, we further suggest that heart and head muscles formed in gastruloids derive from cardiopharyngeal mesoderm progenitors. We identify different subpopulations of cardiomyocytes and skeletal muscles, which most likely correspond to different states of myogenesis with “head-like” and “trunk-like” skeletal myoblasts. These findings unveil the potential of mESC-derived gastruloids to undergo specification into both cardiac and skeletal muscle lineages, allowing the investigation of the mechanisms of cardiopharyngeal mesoderm differentiation in development and how this could be affected in congenital diseases.

Project description:We discovered enhancers that control GATA-2 expression during mouse development and in adult and generated mutant mouse strains that lack these enhancers, and these mice have very specific and important phenotypes that revealed GATA-2 mechanisms to control stem and progenitor cell transitions. In this study we aim to determine what proteins are under control of the GATA-2 -77 enhancer in a pool of heterogeneous blood progenitor cells with the specific focus on Socs2 expression.

Project description:We used the assay for transposon-accessible chromatin using sequencing (ATAC-seq) on FACS-purified cells to profile chromatin accessibility during early cardiopharyngeal fate choices in Ciona. We obtained ~500 million unique reads from samples comprising cardiopharyngeal mesoderm and mesenchymal cells, as well as whole Ciona embryos and genomic DNA control. We combined ATAC-seq peaks from all the replicates to generate an atlas of 56,090 unique and non-overlapping accessible regions (accessome) covering 9.25% of the C. robusta genome. We used the accessome to analyze differential accessibility and integrated expression data to compare the chromatin and gene expression dynamics underlying cardiopharyngeal fate specification. In summary, we revealed that most changes in accessibility occur upon induction of multipotent cardiopharyngeal progenitors from the founder cells. Comparing differential expression to differential accessibility shows that genes activated in the multipotent progenitors tend to have regions that specifically open nearby them. We found that the elements accessible specifically in multipotent cardiopharyngeal progenitors were enriched in Fox, GATA and nuclear receptor binding motifs. CRISPR-mediated loss of Foxf function followed by FACS, ATAC-seq and RNA-seq showed that Foxf is required to open ~22% of the cardiopharyngeal-specific elements. Notably, elements associated with de novo expressed genes, which turn on either in heart or pharyngeal muscle progenitors, were also opening in multipotent progenitors, whereas only ~10% of differentially expressed genes had differentially accessible elements. Finally, we propose a general model for chromatin dynamics whereby most lineage-specific elements open in multipotent progenitors, and control both early pan-cardiopharyngeal and late cell-type-specific expression.

Project description:Vascular endothelial dysfunction underlies the genesis and progression of numerous diseases. Whereas the GATA transcription factor GATA-2 is expressed in endothelial cells and is implicated in coronary heart disease, it has been studied predominantly as a master regulator of hematopoiesis. As many questions remain unanswered regarding GATA-2 function in the vascular biology realm, we used ChIP-seq and loss-of-function strategies to define the GATA-2-instigated genetic network in human endothelial cells. By contrast to erythroid cells, GATA-2 occupied a unique target gene ensemble, consisting of genes encoding key determinants of endothelial cell identity and inflammation. GATA-2-occupied sites characteristically contained motifs that bind Activator Protein-1 (AP-1), a pivotal regulator of inflammatory genes. GATA-2 frequently occupied the same chromatin sites as c-JUN and c-FOS, heterodimeric components of AP-1. Though all three components were required for maximal AP-1 target gene expression, GATA-2 was not required for AP-1 chromatin occupancy. GATA-2 conferred maximal phosphorylation of chromatin-bound c-JUN at Ser 73, which stimulates AP-1-dependent transactivation, in a chromosomal context-dependent manner. This work establishes a link between a GATA factor and inflammation, mechanistic insights underlying GATA-2-AP-1 cooperativity, and a rigorous genetic framework for understanding GATA-2 function in normal and pathophysiological vascular states. For data usage terms and conditions, please refer to http://www.genome.gov/27528022 and http://www.genome.gov/Pages/Research/ENCODE/ENCODEDataReleasePolicyFinal2008.pdf Examination of GATA2 ChIP-seq in HUVEC cells.

Project description:In the heart development, mesodermal progenitor cells in pharyngeal apparatus, termed cardiopharyngeal mesoderm, contribute to both atruim and right ventricle. Tbx1 gene, encoding a T-box transctiption factor and gene haploinsufficient in 22q11.2 deletion syndrome, is required for cardiac outflow tranct and branchiomeric muscle development. To understand how TBX1 affect open chromatin status in cardiopharyngeal mesoderm, we performed ATAC-seq in Tbx1-Cre lineage with/without Tbx1 expression.

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:Vascular endothelial dysfunction underlies the genesis and progression of numerous diseases. Whereas the GATA transcription factor GATA-2 is expressed in endothelial cells and is implicated in coronary heart disease, it has been studied predominantly as a master regulator of hematopoiesis. As many questions remain unanswered regarding GATA-2 function in the vascular biology realm, we used ChIP-seq and loss-of-function strategies to define the GATA-2-instigated genetic network in human endothelial cells. By contrast to erythroid cells, GATA-2 occupied a unique target gene ensemble, consisting of genes encoding key determinants of endothelial cell identity and inflammation. GATA-2-occupied sites characteristically contained motifs that bind Activator Protein-1 (AP-1), a pivotal regulator of inflammatory genes. GATA-2 frequently occupied the same chromatin sites as c-JUN and c-FOS, heterodimeric components of AP-1. Though all three components were required for maximal AP-1 target gene expression, GATA-2 was not required for AP-1 chromatin occupancy. GATA-2 conferred maximal phosphorylation of chromatin-bound c-JUN at Ser 73, which stimulates AP-1-dependent transactivation, in a chromosomal context-dependent manner. This work establishes a link between a GATA factor and inflammation, mechanistic insights underlying GATA-2-AP-1 cooperativity, and a rigorous genetic framework for understanding GATA-2 function in normal and pathophysiological vascular states. For data usage terms and conditions, please refer to http://www.genome.gov/27528022 and http://www.genome.gov/Pages/Research/ENCODE/ENCODEDataReleasePolicyFinal2008.pdf

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:Dynamic gene expression programs determine multipotent cell states and fate choices during development. Multipotent progenitors for cardiomyocytes and branchiomeric head muscles populate the pharyngeal mesoderm of vertebrate embryos, but the mechanisms underlying cardiopharyngeal multipotency and heart vs. head muscle fate choices remain elusive. The tunicate Ciona emerged as a simple chordate model to study cardiopharyngeal development with unprecedented spatio-temporal resolution. We analyzed the transcriptome of single cardiopharyngeal lineage cells isolated at successive time points encompassing the transitions from multipotent progenitors to distinct first and second heart, and pharyngeal muscle precursors. We reconstructed the three cardiopharyngeal developmental trajectories, and characterized gene expression dynamics and regulatory states underlying each fate choice. Experimental perturbations and bulk transcriptome analyses revealed that ongoing FGF/MAPK signaling maintains cardiopharyngeal multipotency and promotes the pharyngeal muscle fate, whereas signal termination permits the deployment of a full pan-cardiac program and heart fate specification. We identified the Dach1/2 homolog as a novel evolutionarily conserved second-heart-field-specific factor and demonstrate, through lineage tracing and CRISPR/Cas9 perturbations, that it operates downstream of Tbx1/10 to actively suppress the first heart lineage program. This data indicates that the regulatory state of multipotent cardiopharyngeal progenitors determines the first vs. second heart lineage choice, and that Tbx1/10 acts as a bona fide regulator of cardiopharyngeal multi potency. We performed bulk RNAseq to profile the FACS purified Ciona Robusta Truck Ventral Cells (TVCs) with FGF-MAPK perturbation conditions to address the question- What is the role of FGF signaling pathway during early cardiopharyngeal specification. we performed bulk RNA sequencing of FACS-purified cardiopharyngeal lineage cells isolated from embryos and larvae expressing either a dominant negative form the fibroblast growth factor receptor (dnFGFR), or a constitutively active form of M-Ras (caM-Ras), the sole Ras homolog in Ciona, under the control of TVC-specific enhancers.