Project description:The vertebrate body plan and organs are shaped during a highly conserved embryonic phase called the phylotypic stage, however the mechanisms that guide the epigenome through this transition and their evolutionary conservation remain elusive. Here we report widespread DNA demethylation of thousands of enhancers during the phylotypic period in zebrafish, Xenopus and mouse. These dynamic enhancers are linked to essential developmental genes that display coordinated transcriptional and epigenomic changes in the diverse vertebrates during embryogenesis. Phylotypic stage-specific binding of Tet proteins to (hydroxy)methylated DNA, and enrichment of hydroxymethylcytosine on these enhancers, implicated active DNA demethylation in this process. Furthermore, loss of function of Tet1/2/3 in zebrafish caused reduced chromatin accessibility and increased methylation levels specifically on these enhancers, indicative of DNA methylation being an upstream regulator of phylotypic enhancer function. Overall, our study reveals a novel regulatory module associated with the most conserved phase of vertebrate embryogenesis and uncovers an ancient developmental role for the Tet dioxygenases.

Project description:Metazoan SAGA and ATAC are distinct multi-subunits complexes that share the same catalytic HAT subunit (GCN5 or PCAF). Here we show that these human HAT complexes are targeted to different genomic loci representing functionally distinct regulatory elements both at broadly expressed and tissue specific genes. While SAGA can principally be found at promoters, ATAC is recruited to promoters and enhancers, yet only its enhancer binding is cell-type specific. Furthermore, we show that ATAC functions at a set of enhancers that are not bound by p300, revealing a new class of enhancers not yet identified. These findings demonstrate important functional differences between SAGA and ATAC coactivator complexes at the level of the genome and define a novel role for the ATAC complex in the regulation of a set of enhancers. Examination of SPT20 in two different cell types.

Project description:<p>We characterized the epigenetic landscape of rheumatoid arthritis fibroblast-like synoviocytes (FLS) compared with osteoarthritis FLS. Multiple technologies were used, including ChIP-seq to assay H3K27ac, H3K4me1, H3K4me3, H3K36me3, H3K27me3, and H3K9me3, ATAC-seq for chromatin accessibility, the transcriptome by RNA-seq and whole genomic bisulfite sequencing for DNA methylation. Integrative analysis was performed using a novel unbiased method to identify regions of the genome that have similar epigenetic marks. The regions that distinguished RA and osteoarthritis cells were primarily located in active enhancers and promoters. The regions and genes identified included immunological pathways. In addition, some unexpected pathways, most notably "Huntington&#39;s Disease Signaling", were discovered. The Huntington&#39;s Disease pathway was biologically validated for Huntingtin-interacting protein-1, which regulated invasive behavior of FLS. For a complete description, see R. Ai <i>et al.</i>, Comprehensive epigenetic landscape of rheumatoid arthritis fibroblast-like synoviocytes. <i>Nat Commun</i> 9, 1921 (2018).</p> <p>Sequencing data of study participants are available through dbGaP&#39;s Authorized Access portal, while analyses of the sequencing data may be obtained through NCBI&#39;s GEO portal under <a href="https://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=GSE112658">GSE112658.</a></p>

Project description:We describe that during early zebrafish development, DNA methylation has little influence on enhancer activity, and that hypo-methylation is a unique feature of primed enhancers, whereas active enhancers are generally hyper-methylated. Hypo-methylated enhancers (hypo-enhancers) are enriched close to important transcription factors (TFs) that act later in development, are specifically de-methylated before the mid blastula transition (MBT), and reside in a unique epigenetic environment. Finally, we demonstrate that hypo-enhancers are functionally active later in development and that they are physically associated with the transcriptional start site (TSS) of target-genes, irrespective of target-gene activity. we analyzed 5 novel ChIP-Seq libraries where we used the following AB (H3K27ac,H3K4me1,H3K4me2 and H3K27ac) and an Atac-Seq library.

Project description:We describe sciMET-ATAC, a combinatorial indexing-based technique that is capable of producing single-cell DNA methylation plus chromatin accessibility datasets.

Project description:The goal of this study is genomic chromatin accessibility of 120 hpf zebrafish livers by ATAC-Seq. ATAC-seq (Assay for Transposase-Accessible Chromatin using sequencing) and the DNA methylation profile using reduced representation bisulfite sequencing (RRBS).

Project description:We developed a low input, low sequencing depth method, EpiMethylTag that combines ATAC-seq or ChIP-seq (M-ATAC or M-ChIP) with bisulfite conversion, to simultaneously examine accessibility/TF binding and methylation on the same DNA.

Project description:Chromatin accessibility mapping is a powerful approach to identify potential regulatory elements. In the popular ATAC-seq method, Tn5 transposase inserts sequencing adapters into accessible DNA (‘tagmentation’). CUT&Tag is a tagmentation-based epigenomic profiling method in which antibody tethering of Tn5 to a chromatin epitope of interest profiles specific chromatin features in small samples and single cells. Here we show that by simply modifying the tagmentation conditions for histone H3K4me2/3 CUT&Tag, antibody-tethered tagmentation of accessible DNA sites is redirected to produce accessible DNA maps that are indistinguishable from the best ATAC-seq maps. Thus, DNA accessibility maps can be produced in parallel with CUT&Tag maps of other epitopes with all steps from nuclei to amplified sequencing-ready libraries performed in single PCR tubes in the laboratory or on a home workbench. As H3K4 methylation is produced by transcription at promoters and enhancers, our method identifies transcription-coupled accessible regulatory sites.

Project description:We investigate the impact of DNA methylation on chromatin accessibility during epiblast differentiation. To this end, we used in vitro Epiblast-like cell (EpiLC) differentiation on WT and DNA-methylation free TKO murine ESCs. We next performed ATAC seq using TDE1 Tn5 transposase (Nextera).

Project description:Dual detection of chromatin accessibility and DNA methylation using ATAC-Me