Project description:Chromatin structure is a key determinant of gene expression in eukaryotes but it has not previously been possible to define the full structure of regulatory elements at the scale of the proteins determining gene expression. Here we generate multidimensional chromosome conformation capture (3C) maps at single base-pair resolution using Micro Capture-C (MCC). This allows contacts between individual transcription factor binding sites within regulatory elements to be defined. Using degrons-we investigate the structural role of transcription factors and the Mediator complex. We show that the biophysical properties of nucleosomes and DNA can replicate the nanoscale chromatin structures observed with MCC using a detailed chemically specific, molecular dynamics approach. The ultra-high resolution 3C enable molecular dynamics approaches to be linked to larger scale nuclear architecture defined by super-resolution microscopy and allow us to propose a unified model to describe chromatin structure based on these orthogonal approaches.

Project description:Chromatin structure is a key determinant of gene expression in eukaryotes but it has not previously been possible to define the full structure of regulatory elements at the scale of the proteins determining gene expression. Here we generate multidimensional chromosome conformation capture (3C) maps at single base-pair resolution using Micro Capture-C (MCC). This allows contacts between individual transcription factor binding sites within regulatory elements to be defined. Using degrons-we investigate the structural role of transcription factors and the Mediator complex. We show that the biophysical properties of nucleosomes and DNA can replicate the nanoscale chromatin structures observed with MCC using a detailed chemically specific, molecular dynamics approach. The ultra-high resolution 3C enable molecular dynamics approaches to be linked to larger scale nuclear architecture defined by super-resolution microscopy and allow us to propose a unified model to describe chromatin structure based on these orthogonal approaches.

Project description:Chromatin structure is a key determinant of gene expression in eukaryotes but it has not previously been possible to define the full structure of regulatory elements at the scale of the proteins determining gene expression. Here we generate multidimensional chromosome conformation capture (3C) maps at single base-pair resolution using Micro Capture-C (MCC). This allows contacts between individual transcription factor binding sites within regulatory elements to be defined. Using degrons-we investigate the structural role of transcription factors and the Mediator complex. We show that the biophysical properties of nucleosomes and DNA can replicate the nanoscale chromatin structures observed with MCC using a detailed chemically specific, molecular dynamics approach. The ultra-high resolution 3C enable molecular dynamics approaches to be linked to larger scale nuclear architecture defined by super-resolution microscopy and allow us to propose a unified model to describe chromatin structure based on these orthogonal approaches.

Project description:Chromatin structure is a key determinant of gene expression in eukaryotes but it has not previously been possible to define the full structure of regulatory elements at the scale of the proteins determining gene expression. Here we generate multidimensional chromosome conformation capture (3C) maps at single base-pair resolution using Micro Capture-C (MCC). This allows contacts between individual transcription factor binding sites within regulatory elements to be defined. Using degrons-we investigate the structural role of transcription factors and the Mediator complex. We show that the biophysical properties of nucleosomes and DNA can replicate the nanoscale chromatin structures observed with MCC using a detailed chemically specific, molecular dynamics approach. The ultra-high resolution 3C enable molecular dynamics approaches to be linked to larger scale nuclear architecture defined by super-resolution microscopy and allow us to propose a unified model to describe chromatin structure based on these orthogonal approaches.

Project description:By using a novel chromatin conformation capture (3C) method (Micro Capture-C (MCC)), which allows physical contacts to be determined at base-pair resolution. We demonstrate interactions between different classes of regulatory elements in unprecedented detail.

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:Chromosome conformation capture (3C) provides an adaptable tool through which to study diverse biological questions. Currently, 3C techniques provide either low-resolution interaction profiles across the entire genome, e.g. HiC, or high-resolution interaction profiles at up to several hundred loci, e.g. NG Capture-C and 4C-seq. Generation of high-resolution, genome-wide interaction profiles can feasibly be achieved through efficiency improvements to current high-resolution methods. To this end we systematically tested and removed areas inefficiency in NG Capture-C to develop a new method Nuclear Capture-C, which provides a 300% increase in informative sequencing content. Using Nuclear Capture-C we target 8,026 erythroid promoters in triplicate, showing that this method can achieve high-resolution genome-wide 3C interaction profiles at scale.

Project description:NG Capture-C provides high resolution chromatin conformation capture (3C) interaction maps. NG Capture-C was carried out in erythroid and hESC cells at the Hba, Hbb, Myc, and Slc25a37 locus to generate sequence libraries for analytical software testing.

Project description:By using a novel chromatin conformation capture (3C) method (Micro Capture-C (MCC)), which allows physical contacts to be determined at base-pair resolution. We demonstrate interactions between different classes of regulatory elements in unprecedented detail. T119_S12-S17 and E14_S10-S14 contains data of viewpoint from enhancers that are active in both ES and erythroid cells. NIPBL, CTCF and Rad21 CHIP libraries were prepared and analyzed as previously reported in Hanssen LLP. et al., 2017.

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.