Project description:Purpose: Evaluate changes in chromatin accessibility between human embryonic stem cells and surface ectoderm cells with and without the transcription factor p63. Method: Chromatin accessibility profiles for human embryonic stem cells and surface ectoderm with and without p63 were generated by deep sequencing, in duplicate, with the Illumina NextSeq sequencer. Quality reads were assessed by fastq. Reads were aligned using Bowtie2, PCR duplicates and mitochondrial DNA were discarded, and peak calling was completed using MACS2. Non-reproducible peaks were filtered out by IDR with an FDR of 5%. Results: p63 fails to modify chromatin accessibility when ectopically expressed in human embryonic stem cells; differentiation of human embryonic stem cells to surface ectoderm results in the closure of some regions open in pluripotent cells and the opening of new regions; and loss of p63 in the surface ectoderm results in increased accessibility of 1/3 of the regions opened during surface ectoderm differentiation. Conclusion: p63's ability to modify chromatin accessibility is dependent upon the underlying epigenetic landscape, and when it can modify the landscape, it does so by closing regions that become open during ectoderm differentiation.

Project description:Purpose: Assess changes in p63 binding in human embryonic stem cells and surface ectoderm; evaluate differences in the following histone marks: H3K27me3, H3K27ac, H3K4me1, and H3K4me3 in the surface ectoderm with and without p63; and examine changes in H3K27me3 between human embyronic stem cells and surface ectoderm with and without p63. Methods: p63 ChIP-seq libraries were generated in p63 gain-of-function human embryonic stem cells and wild-type surface ectoderm. H3K27me3 ChIP-seq libraries were generated in wild-type and p63 gain-of-function human embryonic stem cells as well as wild-type and p63 knockout surface ectoderm. H3K27ac, H3K4me1, and H3K4me3 ChIP-seq libraries were generated in wild-type and p63 knockout surface ectoderm. All ChIP-seq experiments were performed in duplicate and sequenced on Illumina NextSeq 500 sequencer. To ensure quality reads, fastq files were analyzed using FASTQC. Bowtie was used for read mapping and the parameters were as follows: -p 24 -S -a -m 1 --best --strata. For peak calling using MACS2, default settings were specified with a p-value of 0.05. To ensure quality peaks, IDR was run on all files, specifying FDR of 1% or 5% (or 10% for some broadPeak histone marks). Results: Limited changes in p63 binding in human embryonic stem cells and surface ectoderm; global loss of H3K37me3 without p63 in the surface ectoderm; limited differences in H3K27ac, H3K4me1, and H3K4me3 +/- p63 in the surface ectoderm; and increase in H3K27me3 with ectopic expression of p63 in human embryonic stem cells. Conclusion: p63 is able to bind it's surface ectoderm target sites regardless of the epigenetic landscape; p63 promotes H3K27me3 accumulation; and p63 does not regulate histone marks H3K27ac, H3K4me1, or H3K4me3

Project description:Purpose: Evaluate p63 regulation of gene expression in human embryonic stem cells and the surface ectoderm Methods: RNA profiles for human embyronic stem cells and surface ectoderm cells with and without p63 using deep sequencing, in duplicate, on Illumina NextSeq 500 sequencer. Quality of reads were checked by fastqc. Reads were aligned to hg19 genome using tophat and FPKM values were generated using Homer. Results: p63 is largely unable to regulate gene expression in pluripotent cells, but acts primarily as a repressor in the surface ectoderm. Conclusion: p63 regulation of gene expression is dependent on the changes the cell undergoes during surface ectoderm commitment

Project description:Purpose: Validate HiChIP-identified long-range chromatin interactions at the TFAP2C locus, in a viewpoint-specific manner. Methods: UMI-4C libraries targeting 3 individual viewpoints at the TFAP2C locus were generated in duplicate, in surface ectoderm cells with and without p63. Replicates were sequenced on Illumina NextSeq sequencer, and reads were aligned and filtered for valid long-range interactions using HiCPro. Results: Dynamic long-range interactions at the TFAP2C locus were detected with and without p63 in surface ectoderm cells. Conclusion: Long-range interactions detected via HiChIP were confirmed in the surface ectoderm by this technique, validating the HiChIP method through an orthogonal approach.

Project description:Genome-wide chromatin accessibility in pluripotent and surface ectoderm cells with and without p63

Project description:Cohesin HiChIP datasets of pluripotent and surface ectoderm cells with and without p63

Project description:RNA-seq profiles of pluripotent and surface ectoderm cells with and without p63

Project description:UMI-4C in wild-type and p63-null surface ectoderm cells

Project description:Three-dimensional (3D) chromatin structure plays a crucial role in development and diseases, which are associated with transcriptional changes. However, given the heterogeneity in single-cell chromatin architecture and transcription, the regulatory relationship between 3D chromatin structure and gene expression is difficult to explain based on the cell populations. Here we developed a single-cell multimodal omics method for simultaneously detecting chromatin architecture and mRNA expression by sequencing (scCARE-seq). Applying scCARE-seq to examine chromatin architecture and transcription from naïve to primed single mouse embryonic stem cells (mESCs), we observed correlated changes between 3D chromatin structure and expression in the cell fate transition. In addition, we defined cell cycle phase of each cell through chromatin architecture extracted by CARE-seq, and found that periodic changes in chromatin architecture were in parallel with transcription during the cell cycle. These findings indicate that scCARE-seq allows comprehensive analysis of chromatin architecture and transcription in the same single cell.

Project description:Recent advances in human pluripotent stem cell (hPSC) technology provide a unique resource for skin tissue replacement, but the detailed understanding of regulatory mechanisms limits standardization and broad clinical application. Here, we interrogate chromatin accessibility and transcriptome dynamics during hPSC-derived epidermal differentiation, and discover two critical transition periods: surface ectoderm initiation and keratinocyte maturation. Using inference network modeling, we develop a computational framework for each transition, and identify TFAP2 and TP63 and their cofactors as key regulators. Surprisingly, functional studies demonstrate the sufficiency of TFAP2C to initiate surface ectoderm differentiation by activating the early TF network and its chromatin landscape changes, while loss of TFAP2C inhibits early commitment. TFAP2Cinitiated cells are competent to further differentiate into functional keratinocytes in selective media, accompanied by activation of the keratinocyte maturation network and decline of the early network. Mechanistically, TFAP2C activates the expression and increases binding site accessibility and positive autoregulation of the master regulator P63, while loss of P63 results in failure to close TFAP2-initiated early program and leads to maturation and survival defects, revealing a positive-negative feedback loop that ensures complete transition from progenitor to maturation tissue. Our work reveals the logic underlying dynamic epigenome-transcription factor interactions during human epidermal lineage commitment that will facilitate improved tissue engineering and regenerative medicine.