Project description:Gene regulation and genome structure are intimately linked, but accurate predictions of the elements that form topological regulatory assemblies in mammalian genomes remain elusive. To address this challenge, we developed BOUQUET, a graph theory-derived algorithm that uses multiple facets of genome topology to discern and interrogate communities of cis-regulatory elements (CREs). BOUQUET’s unbiased approach reveals otherwise undetectable CRE communities, including those that cross presumed insulating boundaries and comprise different categories of CRE. Critically, some communities, which we term “3D super-enhancers (3D-SEs)”, accrue exceptional amounts of regulatory apparatus. 3D-SEs are associated with cell identity-defining genes across mammalian tissues. Microscopy analyses show co-localization and co-expression of genes from the same 3D-SE community within transcriptional co-factor puncta, resembling microcompartments. Gene pairs within 3D-SE communities are co-expressed, and CREs within 3D-SEs are co-accessible. Overall, our model more accurately represents the architectural complexity of CRE interactions, the coordination between chromatin conformation and gene regulation, and the connection between super-enhancers and cell identity.

Project description:Cis-regulatory elements (CREs) contact target genes to regulate their transcription, but CRE interactions are complex and predicting their function is difficult. Contemporary approaches to predict CRE targets generally assume one-to-one associations and linear genomic proximity. These methods fail to account for long-range CRE contacts caused by folding of the genome, or for circumstances in which a single CRE regulates multiple genes or, conversely, a single gene is regulated by multiple CREs. To address these challenges and investigate CRE accumulation, we developed BOUQUET, an integrative, graph-theory-based approach that utilizes multiple aspects of genome topology to probe communities of CREs, their bound apparatus, and their target genes. BOUQUET discovers CRE communities that are undetectable by existing unbiased methods, such as those with interactions that span insulating loop boundaries as well as regulatory communities that are comprised of clustered promoter elements. A subset of these communities, which we term “3D super-enhancers” (3D SEs), is consistent with aspects of the super-enhancer model and accrues exceptional amounts of regulatory apparatus at crucial cell identity-defining genes. In single-cell analyses, pairs of genes found within the same community are co-expressed, and pairs of CREs are co-accessible, suggesting that the regulation of both types of elements within a topologically defined community is tightly coordinated. In confocal microscopy experiments, we regularly observe co-localization and co-expression of in-community genes, an occurrence which frequently takes place within transcriptional co-factor condensates. Our collective approaches more accurately reflect the complexity of CRE interaction networks, underscores the need for incorporating spatial organization in the study of enhancer biology, and provides a framework for the reinterpretation of SEs, their condensates, and their target genes through the lens of 3D chromatin structure.

Project description:Cis-regulatory elements (CREs) contact target genes to regulate their transcription, but CRE interactions are complex and predicting their function is difficult. Contemporary approaches to predict CRE targets generally assume one-to-one associations and linear genomic proximity. These methods fail to account for long-range CRE contacts caused by folding of the genome, or for circumstances in which a single CRE regulates multiple genes or, conversely, a single gene is regulated by multiple CREs. To address these challenges and investigate CRE accumulation, we developed BOUQUET, an integrative, graph-theory-based approach that utilizes multiple aspects of genome topology to probe communities of CREs, their bound apparatus, and their target genes. BOUQUET discovers CRE communities that are undetectable by existing unbiased methods, such as those with interactions that span insulating loop boundaries as well as regulatory communities that are comprised of clustered promoter elements. A subset of these communities, which we term “3D super-enhancers” (3D SEs), is consistent with aspects of the super-enhancer model and accrues exceptional amounts of regulatory apparatus at crucial cell identity-defining genes. In single-cell analyses, pairs of genes found within the same community are co-expressed, and pairs of CREs are co-accessible, suggesting that the regulation of both types of elements within a topologically defined community is tightly coordinated. In confocal microscopy experiments, we regularly observe co-localization and co-expression of in-community genes, an occurrence which frequently takes place within transcriptional co-factor condensates. Our collective approaches more accurately reflect the complexity of CRE interaction networks, underscores the need for incorporating spatial organization in the study of enhancer biology, and provides a framework for the reinterpretation of SEs, their condensates, and their target genes through the lens of 3D chromatin structure.

Project description:The spatiotemporal control of 3D chromatin structure is fundamental for gene regulation, yet it remains challenging to obtain high-resolution chromatin interacting profiles at cis-regulatory elements (CREs) by chromatin conformation capture (3C)-based methods. Here, we describe the redesigned dCas9-based CAPTURE method for multiplexed, high-throughput and high-resolution analysis of locus-specific chromatin interactions. Using C-terminally biotinylated dCas9, endogenous biotin ligase and pooled sgRNAs, the new system enables quantitative analysis of the spatial configuration of a few to hundreds of enhancers or promoters in a single experiment, enabling systematic comparisons across CREs within and between gene clusters. Multiplexed analyses of erythroid super-enhancers (SEs) reveal SE hierarchical structure and distinct modes of SE-gene interactions. Multiplexed capture of temporal dynamics of promoter-centric interactions establishes the instructive function of enhancer-promoter looping in transcriptional regulation during lineage differentiation. These applications illustrate the ability of multiplexed CAPTURE for decoding the organizational principles of genome structure and function.

Project description:The spatiotemporal control of 3D chromatin structure is fundamental for gene regulation, yet it remains challenging to obtain high-resolution chromatin interacting profiles at cis-regulatory elements (CREs) by chromatin conformation capture (3C)-based methods. Here, we describe the redesigned dCas9-based CAPTURE method for multiplexed, high-throughput and high-resolution analysis of locus-specific chromatin interactions. Using C-terminally biotinylated dCas9, endogenous biotin ligase and pooled sgRNAs, the new system enables quantitative analysis of the spatial configuration of a few to hundreds of enhancers or promoters in a single experiment, enabling systematic comparisons across CREs within and between gene clusters. We reveal the hierarchical structure of super-enhancers (SEs) and distinct modes of SE-gene interactions. Multiplexed capture of temporal dynamics of promoter-centric interactions establishes the instructive function of enhancer-promoter looping in transcriptional regulation during lineage differentiation. These applications illustrate the ability of multiplexed CAPTURE for decoding the organizational principles of genome structure and function.

Project description:The spatiotemporal control of 3D chromatin structure is fundamental for gene regulation, yet it remains challenging to obtain high-resolution chromatin interacting profiles at cis-regulatory elements (CREs) by chromatin conformation capture (3C)-based methods. Here, we describe the redesigned dCas9-based CAPTURE method for multiplexed, high-throughput and high-resolution analysis of locus-specific chromatin interactions. Using C-terminally biotinylated dCas9, endogenous biotin ligase and pooled sgRNAs, the new system enables quantitative analysis of the spatial configuration of a few to hundreds of enhancers or promoters in a single experiment, enabling systematic comparisons across CREs within and between gene clusters. We reveal the hierarchical structure of super-enhancers (SEs) and distinct modes of SE-gene interactions. Multiplexed capture of temporal dynamics of promoter-centric interactions establishes the instructive function of enhancer-promoter looping in transcriptional regulation during lineage differentiation. These applications illustrate the ability of multiplexed CAPTURE for decoding the organizational principles of genome structure and function.

Project description:The spatiotemporal control of 3D chromatin structure is fundamental for gene regulation, yet it remains challenging to obtain high-resolution chromatin interacting profiles at cis-regulatory elements (CREs) by chromatin conformation capture (3C)-based methods. Here, we describe the redesigned dCas9-based CAPTURE method for multiplexed, high-throughput and high-resolution analysis of locus-specific chromatin interactions. Using C-terminally biotinylated dCas9, endogenous biotin ligase and pooled sgRNAs, the new system enables quantitative analysis of the spatial configuration of a few to hundreds of enhancers or promoters in a single experiment, enabling systematic comparisons across CREs within and between gene clusters. We reveal the hierarchical structure of super-enhancers (SEs) and distinct modes of SE-gene interactions. Multiplexed capture of temporal dynamics of promoter-centric interactions establishes the instructive function of enhancer-promoter looping in transcriptional regulation during lineage differentiation. These applications illustrate the ability of multiplexed CAPTURE for decoding the organizational principles of genome structure and function.

Project description:Super-enhancers (SEs) are cis-regulatory elements enriching lineage specific key transcription factors (TFs) to form hotspots. A paucity of identification and functional dissection promoted us to investigate SEs during myoblast differentiation. ChIP-seq analysis of histone marks leads to the uncovering of SEs which remodel progressively during the course of differentiation. Further analyses of TF ChIP-seq enable the definition of SE hotspots co-bound by the master TF, MyoD and other TFs, among which we perform in-depth dissection for MyoD/FoxO3 interaction in driving the hotspots formation and SE activation.

Project description:Super-enhancers (SEs) are cis-regulatory elements enriching lineage specific key transcription factors (TFs) to form hotspots. A paucity of identification and functional dissection promoted us to investigate SEs during myoblast differentiation. ChIP-seq analysis of histone marks leads to the uncovering of SEs which remodel progressively during the course of differentiation. Further analyses of TF ChIP-seq enable the definition of SE hotspots co-bound by the master TF, MyoD and other TFs, among which we perform in-depth dissection for MyoD/FoxO3 interaction in driving the hotspots formation and SE activation.

Project description:Super-enhancers (SEs) are large clusters of transcriptional enhancers that are co-occupied by multiple lineage specific transcription factors driving expression of genes that define cell identity. In embryonic stem cells (ESCs), SEs are highly enriched for Oct4, Sox2, and Nanog in the enhanceosome assembly and express enhancer RNAs (eRNAs). We sought to dissect the molecular control mechanism of SE activity and eRNA transcription for pluripotency and reprogramming. Starting from a protein interaction network surrounding Sox2, a key pluripotency and reprogramming factor that guides the ESC-specific enhanceosome assembly and orchestrates the hierarchical transcriptional activation during the final stage of reprogramming, we discovered Tex10 as a novel pluripotency factor that is evolutionally conserved and functionally significant in ESC self-renewal, early embryo development, and reprogramming. Tex10 is enriched at SEs in a Sox2-dependent manner and coordinates histone acetylation and DNA demethylation of SEs. Our study sheds new light on epigenetic control of SE activity for cell fate determination. Genome binding/occupancy profiling of Tex10 was performed in mouse embryonic stem cells by ChIP sequencing.