Project description:Cell fate transitions are accompanied by global transcriptional, epigenetic and topological changes driven by transcription factors (TFs), as is strikingly exemplified in somatic cell reprogramming to pluripotent stem cells (PSCs) by OCT4, KLF4, SOX2 and cMYC. How TFs orchestrate the complex molecular changes around their targets in a temporal manner remains largely elusive. Here, using KLF4 as a paradigm, we provide the first TF-centric view of chromatin reorganization and the association to 3D enhancer rewiring and the transcriptional changes of linked genes during reprogramming of mouse embryonic fibroblasts to (MEFs) to PSCs. Inducible depletion of KLF factors in PSC caused a genome-wide decrease in connectivity of enhancers and disruption of KLF4 binding site from PSC-specific enhancers was sufficient to reduce expression of genes within the enhancer hub partly by impairing long-range contacts. Our study provides an integrative view of the intricate activities of a master regulator during a controlled cell fate transition and offers novel insights into the order and nature of molecular events that follow TF binding.

Project description:Cell fate transitions are accompanied by global transcriptional, epigenetic and topological changes driven by transcription factors (TFs), as is strikingly exemplified in somatic cell reprogramming to pluripotent stem cells (PSCs) by OCT4, KLF4, SOX2 and cMYC. How TFs orchestrate the complex molecular changes around their targets in a temporal manner remains largely elusive. Here, using KLF4 as a paradigm, we provide the first TF-centric view of chromatin reorganization and the association to 3D enhancer rewiring and the transcriptional changes of linked genes during reprogramming of mouse embryonic fibroblasts to (MEFs) to PSCs. Inducible depletion of KLF factors in PSC caused a genome-wide decrease in connectivity of enhancers and disruption of KLF4 binding site from PSC-specific enhancers was sufficient to reduce expression of genes within the enhancer hub partly by impairing long-range contacts. Our study provides an integrative view of the intricate activities of a master regulator during a controlled cell fate transition and offers novel insights into the order and nature of molecular events that follow TF binding.

Project description:Summary: Cell fate transitions are accompanied by global transcriptional, epigenetic and topological changes driven by transcription factors (TFs), as is strikingly exemplified in somatic cell reprogramming to pluripotent stem cells (PSCs) by OCT4, KLF4, SOX2 and cMYC. How TFs orchestrate the complex molecular changes around their targets in a temporal manner remains largely elusive. Here, using KLF4 as a paradigm, we provide the first TF-centric view of chromatin reorganization and the association to 3D enhancer rewiring and the transcriptional changes of linked genes during reprogramming of mouse embryonic fibroblasts to (MEFs) to PSCs. Inducible depletion of KLF factors in PSC caused a genome-wide decrease in connectivity of enhancers and disruption of KLF4 binding site from PSC-specific enhancers was sufficient to reduce expression of genes within the enhancer hub partly by impairing long-range contacts. Our study provides an integrative view of the intricate activities of a master regulator during a controlled cell fate transition and offers novel insights into the order and nature of molecular events that follow TF binding. Purpose: We captured on a genome-wide scale the binding of KLF4 during iPSC formation and its effects on chromatin state, transcriptional activity and chromatin topology around its targets. Methods: We used a well-characterized reprogramming system to apply genome-wide assays that map KLF4 binding (ChIP-seq), chromatin accessibility (ATAC-seq), enhancer and gene activity (H3K27ac ChIP-seq and RNA-seq), enhancer connectivity (H3K27ac Hi-ChIP) as well as KLF4-centric chromatin looping (KLF4 Hi-ChIP) at different stages during acquisition of pluripotency. Results: Integrative analysis of our results generated a reference map of stage-specific chromatin changes around KLF4 bound loci and established strong links with enhancer. rewiring and concordant transcriptional changes. Genetic manipulation of KLF4 binding from a PSC enhancer further supported the ability of KLF4 to function both as a transcriptional regulator and a chromatin organizer. Conclusions: Our study offers novel insights into the intricate roles of a master regulator during cell fate transition.

Project description:Summary: Cell fate transitions are accompanied by global transcriptional, epigenetic and topological changes driven by transcription factors (TFs), as is strikingly exemplified in somatic cell reprogramming to pluripotent stem cells (PSCs) by OCT4, KLF4, SOX2 and cMYC. How TFs orchestrate the complex molecular changes around their targets in a temporal manner remains largely elusive. Here, using KLF4 as a paradigm, we provide the first TF-centric view of chromatin reorganization and the association to 3D enhancer rewiring and the transcriptional changes of linked genes during reprogramming of mouse embryonic fibroblasts to (MEFs) to PSCs. Inducible depletion of KLF factors in PSC caused a genome-wide decrease in connectivity of enhancers and disruption of KLF4 binding site from PSC-specific enhancers was sufficient to reduce expression of genes within the enhancer hub partly by impairing long-range contacts. Our study provides an integrative view of the intricate activities of a master regulator during a controlled cell fate transition and offers novel insights into the order and nature of molecular events that follow TF binding. Purpose: We captured on a genome-wide scale the binding of KLF4 during iPSC formation and its effects on chromatin state, transcriptional activity and chromatin topology around its targets. Methods: We used a well-characterized reprogramming system to apply genome-wide assays that map KLF4 binding (ChIP-seq), chromatin accessibility (ATAC-seq), enhancer and gene activity (H3K27ac ChIP-seq and RNA-seq), enhancer connectivity (H3K27ac Hi-ChIP) as well as KLF4-centric chromatin looping (KLF4 Hi-ChIP) at different stages during acquisition of pluripotency. Results: Integrative analysis of our results generated a reference map of stage-specific chromatin changes around KLF4 bound loci and established strong links with enhancer. rewiring and concordant transcriptional changes. Genetic manipulation of KLF4 binding from a PSC enhancer further supported the ability of KLF4 to function both as a transcriptional regulator and a chromatin organizer. Conclusions: Our study offers novel insights into the intricate roles of a master regulator during cell fate transition.

Project description:Summary: Cell fate transitions are accompanied by global transcriptional, epigenetic and topological changes driven by transcription factors (TFs), as is strikingly exemplified in somatic cell reprogramming to pluripotent stem cells (PSCs) by OCT4, KLF4, SOX2 and cMYC. How TFs orchestrate the complex molecular changes around their targets in a temporal manner remains largely elusive. Here, using KLF4 as a paradigm, we provide the first TF-centric view of chromatin reorganization and the association to 3D enhancer rewiring and the transcriptional changes of linked genes during reprogramming of mouse embryonic fibroblasts to (MEFs) to PSCs. Inducible depletion of KLF factors in PSC caused a genome-wide decrease in connectivity of enhancers and disruption of KLF4 binding site from PSC-specific enhancers was sufficient to reduce expression of genes within the enhancer hub partly by impairing long-range contacts. Our study provides an integrative view of the intricate activities of a master regulator during a controlled cell fate transition and offers novel insights into the order and nature of molecular events that follow TF binding. Purpose: We captured on a genome-wide scale the binding of KLF4 during iPSC formation and its effects on chromatin state, transcriptional activity and chromatin topology around its targets. Methods: We used a well-characterized reprogramming system to apply genome-wide assays that map KLF4 binding (ChIP-seq), chromatin accessibility (ATAC-seq), enhancer and gene activity (H3K27ac ChIP-seq and RNA-seq), enhancer connectivity (H3K27ac Hi-ChIP) as well as KLF4-centric chromatin looping (KLF4 Hi-ChIP) at different stages during acquisition of pluripotency. Results: Integrative analysis of our results generated a reference map of stage-specific chromatin changes around KLF4 bound loci and established strong links with enhancer. rewiring and concordant transcriptional changes. Genetic manipulation of KLF4 binding from a PSC enhancer further supported the ability of KLF4 to function both as a transcriptional regulator and a chromatin organizer. Conclusions: Our study offers novel insights into the intricate roles of a master regulator during cell fate transition.

Project description:Summary: Cell fate transitions are accompanied by global transcriptional, epigenetic and topological changes driven by transcription factors (TFs), as is strikingly exemplified in somatic cell reprogramming to pluripotent stem cells (PSCs) by OCT4, KLF4, SOX2 and cMYC. How TFs orchestrate the complex molecular changes around their targets in a temporal manner remains largely elusive. Here, using KLF4 as a paradigm, we provide the first TF-centric view of chromatin reorganization and the association to 3D enhancer rewiring and the transcriptional changes of linked genes during reprogramming of mouse embryonic fibroblasts to (MEFs) to PSCs. Inducible depletion of KLF factors in PSC caused a genome-wide decrease in connectivity of enhancers and disruption of KLF4 binding site from PSC-specific enhancers was sufficient to reduce expression of genes within the enhancer hub partly by impairing long-range contacts. Our study provides an integrative view of the intricate activities of a master regulator during a controlled cell fate transition and offers novel insights into the order and nature of molecular events that follow TF binding. Purpose: We captured on a genome-wide scale the binding of KLF4 during iPSC formation and its effects on chromatin state, transcriptional activity and chromatin topology around its targets. Methods: We used a well-characterized reprogramming system to apply genome-wide assays that map KLF4 binding (ChIP-seq), chromatin accessibility (ATAC-seq), enhancer and gene activity (H3K27ac ChIP-seq and RNA-seq), enhancer connectivity (H3K27ac Hi-ChIP) as well as KLF4-centric chromatin looping (KLF4 Hi-ChIP) at different stages during acquisition of pluripotency. Results: Integrative analysis of our results generated a reference map of stage-specific chromatin changes around KLF4 bound loci and established strong links with enhancer. rewiring and concordant transcriptional changes. Genetic manipulation of KLF4 binding from a PSC enhancer further supported the ability of KLF4 to function both as a transcriptional regulator and a chromatin organizer. Conclusions: Our study offers novel insights into the intricate roles of a master regulator during cell fate transition.

Project description:Lineage-specific transcription factors (TFs) operate as master orchestrators of developmental processes by activating select cis-regulatory enhancers and proximal promoters. Direct DNA binding of TFs ultimately drives context-specific recruitment of the basal transcriptional machinery that comprises RNA Polymerase II (RNAPII) and a host of polymerase-associated multiprotein complexes, including the metazoan-specific Integrator complex. Integrator is primarily known to modulate RNAPII processivity and to surveil RNA integrity across coding genes. Here we show an enhancer module of Integrator that directs cell fate specification by promoting epigenetic changes and TF binding at neural enhancers. Depletion of Integrator’s INTS10 upends neural traits and derails cells towards mesenchymal identity. Commissioning of neural enhancers relies on Integrator’s enhancer module, which stabilizes SOX2 binding at chromatin upon exit from pluripotency. We propose Integrator as a functional bridge between enhancers and promoters and a main driver of early development, providing new insight into a growing family of neurodevelopmental syndromes.

Project description:Gene expression is determined by genomic elements called enhancers, which contain short motifs bound by different transcription factors (TFs). However, how enhancer sequences and TF motifs relate to enhancer activity is unknown and general sequence requirements for enhancers or comprehensive sets of important enhancer sequence elements have remained elusive. Here, we computationally dissect thousands of functional enhancer sequences from three different Drosophila cell lines. We find that the enhancers display distinct cis-regulatory sequence signatures, which are predictive of the enhancersM-bM-^@M-^Y cell type-specific or broad activities. These signatures contain transcription factor motifs and a novel class of enhancer sequence elements, dinucleotide repeat motifs (DRMs). DRMs are highly enriched in enhancers, particularly in enhancers that are broadly active across different cell types. We experimentally validate the importance of the identified TF motifs and DRMs for enhancer function and show that they can be sufficient to create an active enhancer de novo from non-functional sequence. The function of DRMs as a novel class of general enhancer features that are also enriched in human regulatory regions might explain their implication in several diseases and provides important insights into gene regulation. STARR-seq was performed in BG3 cells with paired-end sequencing in two replicates and respective inputs.

Project description:To investigate the activity of sponge enhancers in vertebrates transgenic experiments was performed where sponge enhancers were inserted into zebrafish embryos and stable lines generated abstract: Transcription factors (TFs) bind DNA enhancer sequences to regulate gene transcription in animals. Unlike TFs, the evolution of enhancers has been difficult to trace because of their fast evolution. Here, we take enhancers in the sponge Amphimedon queenslandica and test their activity in zebrafish and mouse. Of the five sponge enhancers assessed, three were located in conserved syntenic gene regions that are unique to animals (Islet–Scaper, Ccne1–Uri, Tdrd3–Diaph3). Despite diverging over 700 million years ago and a dearth of sequence identity, sponge enhancers are able to drive cell type-specific reporter gene expression in vertebrates. Analysis of the type and frequency of TF binding motifs in the sponge Islet enhancer allowed for the identification of homologous enhancers in human and mouse, which show remarkably similar reporter expression patterns to the sponge enhancer. These findings uncover an unexpected deep conservation of enhancers and suggest that enhancers established early in metazoan evolution can remain functional through retention of combinations of transcription factor binding motifs despite substantial sequence divergence.

Project description:The transition of pluripotent stem cells (PSCs) from primed to naïve states constitutes a prototypical example of cellular plasticity. The naïve state can be stabilized by defined chemical cocktails that block extracellular signals, notably including the MEK pathway. However, little is known regarding the underlying transcriptional mechanisms. Here, we report that the transcriptional landscape of the naïve state can be mimicked in mouse and human PSCs by stimulating transcriptional enhancers. This is attained by inhibiting the CDK8 and CDK19 kinases, which are negative regulators of Mediator, a critical component of enhancer function. Mechanistically, CDK8/19i triggers a global increase in the recruitment of RNA Pol II at promoters and enhancers, hyperactivating enhancers and their target genes. Lastly, the emergence of naïve pluripotency in the pre-implantation epiblast coincides with a marked reduction in CDK8/19 activity, and CDK8/19i blocks its subsequent developmental progression. These findings suggest that naïve pluripotency during development includes hyperactivation of enhancers and can be captured in vitro, either by blunting extracellular signaling, or by stimulating enhancer-driven transcription. These principles may apply to other cellular transitions.