Project description:It remains unclear how ESCs rapidly establish enhancer regulatory elements to activate lineage-specific genes at the earliest differentiation stages. Previous studies suggest that some tissue-specific enhancers are pre-marked in ESCs with permissive features that support their competence to induce gene expression in response to the binding of lineage transcription factors (TFs). However, the absence of functional assays to identify chromatin regions with the competence to activate gene expression upon TF binding has impeded to better define any pre-marking features and their role on the transcriptional competence of the chromatin. To address this, we leveraged a CRISPR-activation(a) system to systematically interrogate the presence of chromatin regions able to induce the expression of 5 lineage-specific genes that are inactive in human ESCs (hESCs). Multiple CRISPRa screens discovered 42 regions, which we termed Competent Chromatin Regions (CCRs), that can induce the expression of the 5 lineage genes upon CRISPRa targeting. ChIP seq analyses showed that CCRs do not represent primed or active enhancers, since they are not enriched in H3K4me1 or H3K27ac histone modifications. Instead, CCRs exhibit a significant enrichment in POU sequence motifs, along with higher levels of binding by OCT4 and other pluripotent TFs. CCRs have an enriched presence of several repressive and activating chromatin-associated factors, including the DNA demethylation factors TET1 and QSER1 and various HDAC enzymes, which regulate their transcriptional competence. Although CCRs are exclusively found at the topologically associated domains shared with their related genes, we found they do not require an enrichment in pre-established chromatin contacts to exert their function. To assess the extent of our findings, we simulated the earliest stages of lineage differentiation by inducing the expression of the lineage TF FOXA2 in undifferentiated hESCs and we found it preferentially binds to the regions predicted as CCRs. Our results suggest that the factors enriched at CCRs facilitate the binding of lineage TFs and enable ESCs to promptly activate the expression of lineage genes. This study advances our understanding of pluripotency regulation in ESCs by identifying a novel type of regulatory regions that supports their developmental plasticity.

Project description:It remains unclear how ESCs rapidly establish enhancer regulatory elements to activate lineage-specific genes at the earliest differentiation stages. Previous studies suggest that some tissue-specific enhancers are pre-marked in ESCs with permissive features that support their competence to induce gene expression in response to the binding of lineage transcription factors (TFs). However, the absence of functional assays to identify chromatin regions with the competence to activate gene expression upon TF binding has impeded to better define any pre-marking features and their role on the transcriptional competence of the chromatin. To address this, we leveraged a CRISPR-activation(a) system to systematically interrogate the presence of chromatin regions able to induce the expression of 5 lineage-specific genes that are inactive in human ESCs (hESCs). Multiple CRISPRa screens discovered 42 regions, which we termed Competent Chromatin Regions (CCRs), that can induce the expression of the 5 lineage genes upon CRISPRa targeting. ChIP seq analyses showed that CCRs do not represent primed or active enhancers, since they are not enriched in H3K4me1 or H3K27ac histone modifications. Instead, CCRs exhibit a significant enrichment in POU sequence motifs, along with higher levels of binding by OCT4 and other pluripotent TFs. CCRs have an enriched presence of several repressive and activating chromatin-associated factors, including the DNA demethylation factors TET1 and QSER1 and various HDAC enzymes, which regulate their transcriptional competence. Although CCRs are exclusively found at the topologically associated domains shared with their related genes, we found they do not require an enrichment in pre-established chromatin contacts to exert their function. To assess the extent of our findings, we simulated the earliest stages of lineage differentiation by inducing the expression of the lineage TF FOXA2 in undifferentiated hESCs and we found it preferentially binds to the regions predicted as CCRs. Our results suggest that the factors enriched at CCRs facilitate the binding of lineage TFs and enable ESCs to promptly activate the expression of lineage genes. This study advances our understanding of pluripotency regulation in ESCs by identifying a novel type of regulatory regions that supports their developmental plasticity.

Project description:Foxa2 is required for endoderm differentiation into hepatic lineage. The mechanism of activation for Foxa2 during this developmental process has not been elucidated yet. We established an in vitro system to guide ES cells differentiating into definitive endoderm (DE) cells and the following DE cells to early hepatic cells. ChIP-seq assays have been successfully performed to assess Foxa2 binding profile. Over 50% of Foxa2 target genes in DE cells were found being activated in hepatic cells which were at a stage later than DE stage. Therefore, our finding at genome-wide level proved Foxa2 serving as a pioneer factor at DE stage. Furthermore, Foxa2 could specifically induce H3K4me2 modifications to the promoter/enhancer regions of many hepatic genes to pre-mark the chromatin, and determine the hepatic lineage differentiation competence. Our study illustrated the wide existence of Foxa2M-bM-^@M-^Ys pioneer factor function and uncovered the correlation between pioneer factor and chromatin pre-mark. These findings will be helpful for understanding the developmental process of hepatogenesis and efficiently controlling Foxa2 during hepatic induction for generating functional hepatocytes. Examination of Foxa2 binding sites in mESC-derived DE cells

Project description:The emergence of distinct cell types during embryonic development relies on the ability of progenitor cells to properly interpret environmental cues; yet how this developmental competence is established is unknown. Here we show that epigenetic priming of enhancers signifies developmental competence. Chromatin mapping during endodermal lineage diversification of human pluripotent stem cells revealed en masse acquisition of a poised chromatin state at enhancers for multiple descendant lineages in developmental intermediates. The responsiveness of developmental intermediates to lineage-inductive signals is dependent on a poised enhancer state. We further find that lineage-specific enhancers are first recognized by transcription factors involved in chromatin priming, while subsequent recruitment of lineage-inductive transcription factors leads to enhancer and target gene activation. Together, our results identify acquisition of a poised chromatin state at enhancers as a general mechanism by which progenitor cells gain the competence to rapidly activate lineage-specific genes in response to inductive signals.

Project description:Nanog, a core pluripotency factor in the inner cell mass of blastocysts, is also expressed in unipotent primordial germ cells (PGC) in mice1, where its precise role is yet unclear2-4. We investigated this in an in vitro model, where naïve pluripotent embryonic stem cells (ESCs) cultured in bFGF/ActivinA develop as epiblast-like cells (EpiLCs), and gain competence for PGC-like fate5. Consequently, bone morphogenetic protein (BMP4), or ectopic expression of key germline transcription factors Prdm1/ Prdm14/ Tfap2c, directly induce PGC-like cells (PGCLCs) in EpiLCs, but not in ESCs6-8. Here we report an unexpected discovery that Nanog alone can induce PGCLCs in EpiLCs, independently of BMP4. We propose that following the dissolution of the naïve ESC pluripotency network during establishment of EpiLCs9,10, the epigenome is reset for cell fate determination. Indeed, we found genome-wide changes in NANOG binding pattern between ESCs and EpiLCs, indicating epigenetic resetting of regulatory elements. Accordingly, we show that NANOG can bind and activate enhancers of Prdm1 and Prdm14 in EpiLCs in vitro; BLIMP1 (encoded by Prdm1) then directly induces Tfap2c. Furthermore, while SOX2 and NANOG promote the pluripotent state in ESCs, they show contrasting roles in EpiLCs since Sox2 specifically represses PGCLC induction by Nanog. This study demonstrates a broadly applicable mechanistic principle for how cells acquire competence for cell fate determination, resulting in the context-dependent roles of key transcription factors during development. Refer to individual Series

Project description:Nanog, a core pluripotency factor in the inner cell mass of blastocysts, is also expressed in unipotent primordial germ cells (PGC) in mice1, where its precise role is yet unclear2-4. We investigated this in an in vitro model, where naïve pluripotent embryonic stem cells (ESCs) cultured in bFGF/ActivinA develop as epiblast-like cells (EpiLCs), and gain competence for PGC-like fate5. Consequently, bone morphogenetic protein (BMP4), or ectopic expression of key germline transcription factors Prdm1/ Prdm14/ Tfap2c, directly induce PGC-like cells (PGCLCs) in EpiLCs, but not in ESCs6-8. Here we report an unexpected discovery that Nanog alone can induce PGCLCs in EpiLCs, independently of BMP4. We propose that following the dissolution of the naïve ESC pluripotency network during establishment of EpiLCs9,10, the epigenome is reset for cell fate determination. Indeed, we found genome-wide changes in NANOG binding pattern between ESCs and EpiLCs, indicating epigenetic resetting of regulatory elements. Accordingly, we show that NANOG can bind and activate enhancers of Prdm1 and Prdm14 in EpiLCs in vitro; BLIMP1 (encoded by Prdm1) then directly induces Tfap2c. Furthermore, while SOX2 and NANOG promote the pluripotent state in ESCs, they show contrasting roles in EpiLCs since Sox2 specifically represses PGCLC induction by Nanog. This study demonstrates a broadly applicable mechanistic principle for how cells acquire competence for cell fate determination, resulting in the context-dependent roles of key transcription factors during development. Nanog ChIP-seq

Project description:Foxa2 is required for endoderm differentiation into hepatic lineage. The mechanism of activation for Foxa2 during this developmental process has not been elucidated yet. We established an in vitro system to guide ES cells differentiating into definitive endoderm (DE) cells and the following DE cells to early hepatic cells. ChIP-seq assays have been successfully performed to assess Foxa2 binding profile. Over 50% of Foxa2 target genes in DE cells were found being activated in hepatic cells which were at a stage later than DE stage. Therefore, our finding at genome-wide level proved Foxa2 serving as a pioneer factor at DE stage. Furthermore, Foxa2 could specifically induce H3K4me2 modifications to the promoter/enhancer regions of many hepatic genes to pre-mark the chromatin, and determine the hepatic lineage differentiation competence. Our study illustrated the wide existence of Foxa2’s pioneer factor function and uncovered the correlation between pioneer factor and chromatin pre-mark. These findings will be helpful for understanding the developmental process of hepatogenesis and efficiently controlling Foxa2 during hepatic induction for generating functional hepatocytes.

Project description:Foxa2 is required for endoderm differentiation into the hepatic lineage. The mechanism of activation for Foxa2 during this developmental process has not been elucidated yet. We established an in vitro system to guide ES cells differentiating into definitive endoderm (DE) cells and the following DE cells to early hepatic cells. ChIP-seq assays have been successfully performed to assess the Foxa2 binding profile. Over 50% of Foxa2 target genes in DE cells were found to be activated in hepatic cells which were at a stage later than the DE stage. Therefore, our finding at the genome-wide level proved Foxa2 serves as a pioneer factor at the DE stage. Furthermore, Foxa2 could specifically induce H3K4me2 modifications to the promoter/enhancer regions of many hepatic genes to pre-mark the chromatin, and determine the hepatic lineage differentiation competence. Our study illustrated the wide existence of Foxa2's pioneer factor function and uncovered the correlation between pioneer factor and chromatin pre-mark. These findings will be helpful for understanding the developmental process of hepatogenesis and efficiently controlling Foxa2 during hepatic induction for generating functional hepatocytes.

Project description:Foxa2 is required for endoderm differentiation into the hepatic lineage. The mechanism of activation for Foxa2 during this developmental process has not been elucidated yet. We established an in vitro system to guide ES cells differentiating into definitive endoderm (DE) cells and the following DE cells to early hepatic cells. ChIP-seq assays have been successfully performed to assess the Foxa2 binding profile. Over 50% of Foxa2 target genes in DE cells were found to be activated in hepatic cells which were at a stage later than the DE stage. Therefore, our finding at the genome-wide level proved Foxa2 serves as a pioneer factor at the DE stage. Furthermore, Foxa2 could specifically induce H3K4me2 modifications to the promoter/enhancer regions of many hepatic genes to pre-mark the chromatin, and determine the hepatic lineage differentiation competence. Our study illustrated the wide existence of Foxa2's pioneer factor function and uncovered the correlation between pioneer factor and chromatin pre-mark. These findings will be helpful for understanding the developmental process of hepatogenesis and efficiently controlling Foxa2 during hepatic induction for generating functional hepatocytes. To further gain a genome-wide view of Foxa2's effects on its target gene expression, 3 representative time points from the ES cell differentiation process to hepatic cells were selected for cDNA microarray analysis: 1) Day 0, representing ES cells, where there was no Foxa2 expression; 2) Day 5, representing DE cells; and 3) Day 7, representing early hepatic cells.

Project description:Pluripotent Embryonic Stem Cells (ESCs) can be captured in vitro in different states, ranging from unrestricted ‘naïve’ to more developmentally constrained ‘primed’ pluripotency. Complexes involved in epigenetic regulation and key transcription factors have been shown to be involved in specifying these distinct states. In this study, we use proteomic profiling of the chromatin landscape in naive pluripotent ESCs, Epistem cells (EpiSCs) and early differentiated ESCs to survey the chromatin in naïve and primed pluripotency and during differentiation. We provide a comprehensive overview of epigenetic complexes situated on the chromatin and identify proteins associated with the maintenance and loss of pluripotency. The findings presented here indicate major compositional alterations of epigenetic complexes starting from ESC priming onwards. Our results contribute to the understanding of ESC differentiation and provide a framework for future studies of lineage commitment of ESCs.