Project description:The genomic mechanisms underlying progressive, irreversible cell lineage commitments and differentiation, which include large scale chromatin re-organization, transcription factor binding, and chromatin modifications, have been well defined. However, we know little about the chromatin changes during transitions between transient cell states such as cell migration. Here we demonstrate the formation of unique complements of typical enhancers and super-enhancers as human progenitor keratinocytes either differentiate or migrate. Unique super-enhancers for each cellular state are linked to gene expression that confer functions associated with each cell state, and sequence variants associated with skin diseases are enriched within super-enhancers. GRHL3, a factor that promotes both differentiation and migration, exhibits prominent super-enhancer interactions in differentiating keratinocytes, while during migration, it preferentially binds to promoters along with REST, repressing the expression of migration inhibitors. Key epidermal differentiation transcription factor genes, including GRHL3, are located within super-enhancers, and many of these transcription factors in turn bind to and regulate super-enhancers. Of note, GRHL3 also represses the formation of a number of progenitor and non-keratinocyte super-enhancers in differentiating keratinocytes. Thus, coordinated GRHL3 binding and enhancer rearrangements regulate the functional states of keratinocytes.

Project description:The genomic mechanisms underlying progressive, irreversible cell lineage commitments and differentiation, which include large scale chromatin re-organization, transcription factor binding, and chromatin modifications, have been well defined. However, we know little about the chromatin changes during transitions between transient cell states such as cell migration. Here we demonstrate the formation of unique complements of typical enhancers and super-enhancers as human progenitor keratinocytes either differentiate or migrate. Unique super-enhancers for each cellular state are linked to gene expression that confer functions associated with each cell state, and sequence variants associated with skin diseases are enriched within super-enhancers. GRHL3, a factor that promotes both differentiation and migration, exhibits prominent super-enhancer interactions in differentiating keratinocytes, while during migration, it preferentially binds to promoters along with REST, repressing the expression of migration inhibitors. Key epidermal differentiation transcription factor genes, including GRHL3, are located within super-enhancers, and many of these transcription factors in turn bind to and regulate super-enhancers. Of note, GRHL3 also represses the formation of a number of progenitor and non-keratinocyte super-enhancers in differentiating keratinocytes. Thus, coordinated GRHL3 binding and enhancer rearrangements regulate the functional states of keratinocytes.

Project description:The genomic mechanisms underlying progressive, irreversible cell lineage commitments and differentiation, which include large scale chromatin re-organization, transcription factor binding, and chromatin modifications, have been well defined. However, we know little about the chromatin changes during transitions between transient cell states such as cell migration. Here we demonstrate the formation of unique complements of typical enhancers and super-enhancers as human progenitor keratinocytes either differentiate or migrate. Unique super-enhancers for each cellular state are linked to gene expression that confer functions associated with each cell state, and sequence variants associated with skin diseases are enriched within super-enhancers. GRHL3, a factor that promotes both differentiation and migration, exhibits prominent super-enhancer interactions in differentiating keratinocytes, while during migration, it preferentially binds to promoters along with REST, repressing the expression of migration inhibitors. Key epidermal differentiation transcription factor genes, including GRHL3, are located within super-enhancers, and many of these transcription factors in turn bind to and regulate super-enhancers. Of note, GRHL3 also represses the formation of a number of progenitor and non-keratinocyte super-enhancers in differentiating keratinocytes. Thus, coordinated GRHL3 binding and enhancer rearrangements regulate the functional states of keratinocytes.

Project description:While the genomic mechanisms underlying progressive, irreversible cell lineage commitments are well-studied, we know little about the chromatin changes during transient cell states such as cell migration. Interestingly, a large number of SEs in NHEK-D and NHEK-M overlap genes encoding transcription factors with important roles in promotion of epidermal differentiation, including GRHL3, TP63, RUNX1, NOTCH3 and FOS. To test the role of these SE-associated transcription factors in a systematic manner, and to place GRHL3 in the context of other keratinocyte differentiation regulators, we used siRNAs to individually knock down GRHL3 and 50 other transcriptional regulators in NHEK-D. These transcriptional regulators were selected based on expression changes during human keratinocyte differentiation. Many have been previously implicated in epidermal differentiation in mice and humans; the genes encoding 22 of them are associated with SEs. To assess the effect of the knockdowns on keratinocyte differentiation, we monitored the expression of approximately 14,000 genes with custom-made Agilent microarrays. Among the 14,000 genes whose expression we monitored were all genes expressed in human keratinocytes and all transcriptional regulators. This 51 x 14,000 gene expression matrix provided a rich dataset to explore gene regulatory networks in epidermal differentiation.

Project description:The process of differentiation is tightly controlled, and such complex coordination of gene expression requires many layers of regulation. One such mechanism of regulation occurs through distal genomic regions called enhancers, which are believed to act as concentrating sites for transcription factors, like GRHL3, and other regulators, forming loops to contact promoters and enhance transcription. Active enhancers have been shown to have high levels of H3K4me1 and H3K27ac modified nucleosomes, with low levels of H3K4me3, while poised developmental enhancers have been shown to have H3K27me3 in place of H3K27ac. Additionally, in each cell type, a select few enhancers have been found to be unusually long (more than 12.5kb) and show high intensity of transcription factor binding and chromatin enhancer signature marks. These regions, termed super enhancers, are frequently tissue-specific and are thought to regulate the unique gene expression programs in each tissue. ChIP-Seq analysis revealed GRHL3 binding to be strongly enriched within enhancers and super enhancers in differentiating keratinocytes, however the effect of GRHL3 binding on enhancer and super enhancer activity and function is not known.

Project description:The transcriptional basis for disrupted epidermal differentiation arising from TP63 AEC mutations remains to be elucidated. Here we present an organotypic model of AEC dysfunction that phenocopies differentiation defects observed in AEC patient skin. Transcriptional analysis of model AEC tissue revealed impaired induction of differentiation regulators, including OVOL1, GRHL3, KLF4, PRDM1 and ZNF750. Genome wide binding analyses of TP63 during epidermal differentiation showed direct binding of OVOL1, GRHL3, and ZNF750 promoters suggesting AEC mutants prevent normal activation of these targets by direct transcriptional interference. Remarkably, exogenous ZNF750 restores impaired epidermal differentiation caused by AEC mutation. Thus, repression of ZNF750 is central to disrupted epidermal differentiation in model AEC tissue. ChIP-Seq analysis: Examination of p63 binding in proliferating and differentiating human keratinocytes

Project description:Human primary keratinocytes were depleted of GRHL3 by siRNA and induced to differentiated for 2 days by addition of Calcium Primary normal human keratinocytes were transfected with GRHL3 or scrambled control siRNA using RNAi max (Life Technologies). 24 hours post transfection medium was raised to 1.8mM to induce differentiation. Cells were collected 48 hours later.

Project description:Mediator complex regulates transcription by connecting enhancers to promoters. High Mediator binding density defines super enhancers, which regulate cell-identity genes and oncogenes. Protein interactions of Mediator may explain its role in these processes but have not been identified comprehensively. Here we purify Mediator from neural stem cells (NSCs) and identify 75 protein-protein interaction partners. We identify super enhancers in NSCs and show that Mediator-interacting chromatin modifiers colocalise with Mediator at enhancers and super enhancers. Transcription factor families with high affinity for Mediator dominate enhancers and super enhancers and can explain genome-wide Mediator localization. We identify E-box transcription factor Tcf4 as a key regulator of NSCs. Tcf4 interacts with Mediator, colocalises with Mediator at super enhancers and regulates neurogenic transcription factor genes with super enhancers and broad H3K4me3 domains. Our data suggest that high binding-affinity for Mediator is an important organizing feature in the transcriptional network that determines NSC identity.

Project description:<p>Transcription factor p63 is a key regulator of epidermal keratinocyte proliferation and differentiation. Mutations in the p63 DNA-binding domain are associated with Ectrodactyly Ectodermal Dysplasia Cleft Lip/Palate (EEC) syndrome. Underlying molecular mechanism of these mutations however remain unclear. Here we characterized the transcriptome and epigenome of p63 mutant keratinocytes derived from EEC patients. The transcriptome of p63 mutant keratinocytes deviated from the normal epidermal cell identity. Epigenomic analyses showed an altered enhancer landscape in p63 mutant keratinocytes contributed by loss of p63-bound active enhancers and by unexpected gain of enhancers. The gained enhancers were frequently bound by deregulated transcription factors such as RUNX1. Reversing RUNX1 overexpression partially rescued deregulated gene expression and the altered enhancer landscape. Our findings identify an unreported disease mechanism whereby mutant p63 rewires the enhancer landscape and affects epidermal cell identity, consolidating the pivotal role of p63 in controlling the enhancer landscape of epidermal keratinocytes.</p>

Project description:Super-enhancers may regulate target genes through chromatin looping. We connected super-enhancers in the K562 chronic myelogenous leukemia cell line with chromatin interactions identified from Chromatin Interaction Analysis with Paired-End Tag (ChIA-PET) data. Gene expression at proximal elements that are connected with distal super-enhancers showed significantly higher cell-type specificity than at proximal elements connected with other elements or not involved in interaction. 4C and Episwitch analysis of chromatin interactions showed that certain chromatin interactions are cell-specific, but others are more general. While super-enhancers upstream of c-MYC at the MYC-335 element can be found in other cancers, only super-enhancers downstream of c-MYC can be found in K562. 4C analysis of the c-MYC promoter revealed no chromatin interactions that are directed upstream of c-MYC, but only downstream of c-MYC, in the PVT1 long non-coding RNA gene. Cell-specific usage of super-enhancers could explain why the MYC-335 element that is associated with many solid cancers such as colorectal cancer and breast cancer, but not with leukemia. Surprisingly, we found that a chromatin interaction between c-MYC and a c-MYC super-enhancer is lost in chronic myelogenous leukemia patient blood as compared with blood from individuals without the disease through Oxford Biodynamicsâ?? Episwitch analysis. These results provide evidence for fine-tuning of expression patterns, such as cell-specific regulation of target genes by distal super-enhancers through chromatin interactions and an association between chromatin interactions and disease, and highlight that super-enhancers are more complex than previously described. Examination of several chromatin interactions involving super-enhancers using 4C-Seq and Episwitch (TM)