Project description:we combined Assay for Transposase-Accessible Chromatin and lattice light-sheet PALM microscopy (3D ATAC-PALM) to selectively image key features of the 3D accessible genome in single cells. We found that accessible chromatin domains (ACDs) form spatially segregated clusters in the nucleus. Rapid depletion of CTCF or Cohesin (RAD21 subunit) induced extensive 3D spatial mixing of ACD clusters and reduced physical separation between ACDs within chromosomes. Experimental perturbations and modeling suggest that both weak, multivalent, dynamic protein-protein interactions together with loop extrusion influence ACD organization. Live-cell studies suggest that ACD clustering regulates transcription factor binding site distribution, target search kinetics and binding dynamics. Here we report the ATAC-seq results from Tn5 PA549 and nextera Tn5 upon various chemical and genetic perturbations.

Project description:3D ATAC-PALM: Super-resolution Imaging of the Accessible Genome

Project description:Epstein-Barr virus nuclear antigen 2 (EBNA2) is a transactivator of viral and cellular gene expression, which plays a critical role in the Epstein-Barr virus-associated diseases. It was reported that EBNA2 regulates gene expression by manipulating epigenetics, but the details are unclear. Recent studies showed that liquid-liquid phase separation plays an essential role in epigenetic and transcriptional regulation. Through the recently developed ATAC-see technology, we observed that EBNA2 reorganized chromatin topology to form accessible chromatin domains (ACDs) of the host genome by phase separation. The N-terminal region of EBNA2, which is necessary for phase separation, is sufficient to induce ACDs. The C-terminal domain of EBNA2 promotes the acetylation of accessible chromatin regions by recruiting histone acetylase p300 to ACDs. According to these observations, we proposed a model of EBNA2 reorganizing chromatin topology for its acetylation through phase separation to explain the mechanism of EBNA2 hijacking the host genome by controlling its epigenetics. Our findings help to understand the molecular mechanism of the EBV-associated diseases and develop therapeutics for these diseases.

Project description:In order to completely understand the spatial choreography of the accessible genome in the 3D intact nucleus, we had developed a new technique termed assay of transposase accessible chromatin by visualization (ATAC-see). In brief, we had labeled the adaptor in hypersensitive Tn5 transposase with fluorophore dye and performed the Tn5 tagmentation on the fixed culture cells slide. We had performed ATAC-see in different types of cells and found out there are cell types specific spatial choreography of the accessible genome in the 3D intact nucleus, which is tightly linked to cell types specific function. Importantly, we could images the open chromatin distribution and do the sequencing on the exactly same sample, which offer a powerful tool to understand how the open chromatin organize in the 3D nucleus and how the open chromatin regulate gene expression.

Project description:Regulated chromatin states control genome accessibility and thus influence gene expression. Here we report an analysis pipeline termed ATAC-mass that capitalizes on isotopic labeling to detect the accessible genome by multiplexed ion beam imaging (MIBI) and mass cytometry. With MIBI the accessible genome can be visualized at approximately 100-nm resolution simultaneously with metabolic labeling to enable multi-parameter three-dimensional imaging of nuclear features. Extension of this approach to non-spatial mass cytometry enabled the simultaneous measurement of multiple parameters and total genome accessibility in millions of individual cells. We used ATAC-mass to analyze natural killer cells after stimulation with interleukin (IL)-12 or IL-18 -- demonstrating that IL-18 treatment leads to increased total genome accessibility. Analysis of the spatial organization of open chromatin suggest that IL-12 and IL-18 both induce an increase in chromatin accessibility in noncompacted DNA regions. Deep sequencing of the genomic distribution of open chromatin revealed that IL-18 increased the accessibility of quiescent enhancers whereas genomic loci that become more accessible by IL-12 stimulation are mainly localized in the active promoter regions. This integration of epigenomics, proteomics and high-resolution imaging at the single-cell level provides a tool that can enhance our appreciation of the molecular mechanisms underlying gene regulation.

Project description:We performed the assay for transposase-accessible chromatin using sequencing (ATAC-seq) using 88 tissue samples to profile open chromatin regions in the cattle genome.

Project description:Assay for Transposable Accessible Chromatin (ATAC) reveals a genome wide view of areas of open chromatin at very high resolution, which are often associated with regulatory activity. The ATAC-seq technology uses a Tn5 transposase loaded with nex-generation sequencing primers in order to simultaneously fragment areas of open chromatin and ligate adapters.

Project description:We performed the assay for transposase-accessible chromatin using sequencing (ATAC-seq) on a liver sample collected from one Holstein Friesian healthy male at one month of age to profile open chromatin regions genome-wide to identify putative regulatory elements related to phenotype of interest.

Project description:Enhancer-promoter dynamics are crucial for the spatiotemporal control of gene expression, but it remains unclear whether these dynamics are controlled by chromatin regulators, such as the nucleosome remodelling and deacetylase (NuRD) complex. The NuRD complex binds to all active enhancers to modulate transcription and here we use Hi-C experiments to show that it blurs TAD boundaries and increases the proximity of intermediate-range (~1 Mb) genomic sequences and enhancer-promoter interactions. To understand whether NuRD alters the dynamics of 3D genome structure, we developed an approach to segment and extract key biophysical parameters from 3D single-molecule trajectories of the NuRD complex determined using live-cell imaging. Unexpectedly, this revealed that the intact NuRD complex decompacts chromatin structure and makes NuRD-bound enhancers move faster, increasing the overall volume of the nucleus that these key regulatory regions explore. Interestingly, we also uncovered a rare fast-diffusing state of NuRD bound enhancers that exhibits directed motion. The NuRD complex reduces the amount of time that enhancers remain in this fast-diffusing state, which we propose might otherwise re-organise enhancer-promoter proximity.

Project description:In mammals, extensive chromatin reorganization is essential for reprogramming terminally committed gametes to a totipotent state during preimplantation development. However, the global chromatin landscape and its dynamics in this period remain unexplored. Here we report a genome-wide map of accessible chromatin in mouse preimplantation embryos using an improved assay for transposase-accessible chromatin with high throughput sequencing (ATAC-seq) approach with CRISPR/Cas9-assisted mitochondrial DNA depletion. We show that despite extensive parental asymmetry in DNA methylomes, the chromatin accessibility between the parental genomes is globally comparable after major zygotic genome activation (ZGA). Accessible chromatin in early embryos is widely shaped by transposable elements and overlaps extensively with putative cis-regulatory sequences. Unexpectedly, accessible chromatin is also found near the transcription end sites of active genes. By integrating the maps of cis-regulatory elements and single-cell transcriptomes, we construct the regulatory network of early development, which helps to identify the key modulators for lineage specification. Finally, we find that the activities of cis-regulatory elements and their associated open chromatin diminished before major ZGA. Surprisingly, we observed many loci showing non-canonical, large open chromatin domains over the entire transcribed units in minor ZGA, supporting the presence of an unusually permissive chromatin state. Together, these data reveal a unique spatiotemporal chromatin configuration that accompanies early mammalian development. Mouse preimplantation embryos were obtained from crosses of C57BL/6N and DBA/2N. ATAC-seq was performed in these embryos at various stages in preimplantation development.