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: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:GRHL3 binding and the enhancer landscape are reorganized during transitions between different functional states of epidermal keratinocytes
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:GRHL3 binding and the enhancer landscape are reorganized during transitions between different functional states of epidermal keratinocytes [siGRHL3-migration]
Project description:GRHL3 binding and the enhancer landscape are reorganized during transitions between different functional states of epidermal keratinocytes [ChIP-seq]
Project description:GRHL3 binding and the enhancer landscape are reorganized during transitions between different functional states of epidermal keratinocytes [siREST-migration]
Project description:GRHL3 binding and the enhancer landscape are reorganized during transitions between different functional states of epidermal keratinocytes [siREST-proliferation]