Project description:We report a computational approach for investigation of chromatin state plasticity. We applied this approach to investigate an ENCODE ChIP-seq dataset profiling the genome-wide distribution of H3K27me3 in 19 human cell lines. We found that high plasticity regions (HPRs) can be divided into two functionally and mechanistically distinct groups, consisting of CpG island proximal and distal regions. We identified cell-type specific regulators correlating with H3K27me3 patterns at distal HPRs in ENCODE cell lines. Furthermore, we applied this approach to investigate mechanisms for poised enhancer establishment in primary human erythroid precursors. We predicted and validated a previously unrecognized role of TAL1 in modulating H3K27me3 patterns through interaction with additional cofactors, such as GFI1B. Our integrative approach provides mechanistic insights into chromatin state plasticity and is broadly applicable to other epigenetic marks.

Project description:We report the comparative investigation of genome-wide chromatin state maps, transcription factor (TF) occupancy, and gene expression profiles from developing red cell precursors at two developmental stages. Contrasting the similarities and differences between fetal and adult erythropoiesis provides important insights into the erythroid gene expression programs and gene regulatory networks. Specifically, comparative analyses of human erythropoiesis identify developmental stage-specific enhancers as primary determinants of stage-specific gene expression programs. We find that master regulators, such as GATA1 and TAL1, cooperatively act within active enhancers but have little predictive value for stage-specific enhancer activity. Instead, a set of stage-specific co-regulators collaborates with master regulators and contributes to differential gene expression. We further identify and validate IRF2, IRF6, and MYB as effectors of adult-stage expression program. Thus, the combinatorial assembly of master regulators and transcriptional co-regulators at developmental stage-specific enhancers controls gene expression programs and temporal regulation of transcriptional networks in a mammalian genome. Examination of various histone modifications and transcription factor occupancy by ChIP-seq in fetal and adult proerythroblasts.

Project description:T-cell acute lymphoblastic leukemia’s (T-ALL) are malignant proliferations of thymocytes occurring through a large diversity of genomic and epigenetic alteration. TAL1 is amongst the most frequently deregulated oncogenes. Known TAL1 dysregulation mechanisms consist of t(1;14) translocations and SIL-TAL deletions. Yet, over half of TAL1+ cases lack TAL1 lesions, pointing to unrecognized (epi)genetic deregulation mechanisms. In such “unresolved cases”, TAL1 expression can be mono-allelic, compatible with a direct alteration in cis within or around the TAL1 gene, or bi-allelic, likely reflecting indirect deregulation in trans. Using ChIP-seq, we show that TAL1 is normally silenced in the T-cell lineage, and that the polycomb H3K27me3 repressive mark is focally diminished in TAL1+ T-ALLs. Sequencing revealed that >20% of mono-allelic TAL1+ patients without previously known alterations display micro-insertions or RAG1/2-mediated episomal reintegration in a single site 5’ to TAL1. Using “allelic-ChIP” and CrispR assays, we demonstrate that such insertions induce selective switch from H3K27me3 to H3K27ac at the inserted but not the germline allele. We also show that, despite a considerable mechanistic diversity, the mode of oncogenic TAL1 activation, rather than expression levels, impact on clinical outcome. Altogether, these studies reveal a new adverse mechanism of mono-allelic oncogenic activation through site-specific epigenetic de-silencing. ChIP-seq experiments were designed to asses the dynamic enrichment of H3K27me3 and H3K27ac marks on the genome and understand the mechanisms underlying the TAL1 expression cys-regulation.

Project description:The regulatory elements that direct tissue-specific gene expression in the developing mammalian embryo remain largely unknown. Although chromatin profiling has proven to be a powerful method for mapping regulatory sequences in cultured cells, chromatin states characteristic of active developmental enhancers have not been directly identified in embryonic tissues. Here we use whole transcriptome analysis coupled with genome-wide profiling of H3K27ac and H3K27me3 to map chromatin states and enhancers in mouse embryonic forelimb and hindlimb. We show that gene expression differences between forelimb and hindlimb, and between limb and other embryonic cell types, are correlated with tissue-specific H3K27ac signatures at promoters and distal sites. Using H3K27ac profiles, we identified 28,377 putative enhancers, many of which are likely to be limb-specific based on strong enrichment near genes highly expressed in the limb and comparisons with tissue-specific p300 sites and known enhancers. We describe a chromatin state signature associated with active developmental enhancers, defined by high levels of H3K27ac marking, nucleosome displacement, hypersensitivity to sonication, and strong depletion of H3K27me3. We also find that developmental enhancers exhibit components of this signature, including hypersensitivity, H3K27ac enrichment and H3K27me3 depletion, at lower levels in tissues in which they are not active. Our results establish histone modification profiling as a tool for developmental enhancer discovery, and suggest that enhancers maintain an open chromatin state in multiple embryonic tissues independent of their activity level. Examination of genome wide H3K27ac and H3K27me3 histone modifications and gene expression in early mouse embryonic limb tissue.

Project description:Mechanisms of plasticity to acquire different cell fates are critical for adult stem cell (SC) potential, yet are poorly understood. Reduced global histone methylation is an epigenetic state known to mediate plasticity in cultured embryonic SCs and T cell progenitors. We used mouse hair follicle stem cells (HFSCs) at two different hair cycle stages (early anagen and late catagen) to compare the genome-wide changes in the levels of histone modification marks H3K4me3, H3K9me3, and H3K27me3. Hair follicle stem cells from Early Anagen (EA-HFSCs) and Late Catagen (LC-HFSCs), and their non-HFSCs counterparts (nEA-HFSCs and nLC-HFSCs), were FACS-isolated for Chromatin Immunoprecipitation followed by sequencing (ChIP-seq) analysis of H3K4me3, H3K9me3, and H3K27me3.

Project description:This SuperSeries is composed of the following subset Series: GSE36984: Expression Profiling of Primary Human Fetal and Adult Hematopoietic Stem/Progenitor Cells (HSPCs) and Differentiating Proerythroblasts (ProEs) GSE36985: Comparative profiling of chromatin state maps and transcription factor occupancy during human fetal and adult erythropoiesis GSE36988: Expression Profiling of Primary Human Proerythroblasts (ProEs) After IRF2, IRF6, and MYB shRNA Knockdown Refer to individual Series

Project description:We performed ChIP-seq to chart genome-wide maps of H3K27me3 in brown preadipocytes and mature brown adipocytes. We observed a subset of brown fat-specific genes, but not common fat genes or white fat-specific genes, possess the H3K27me3 mark in preadipocytes, and this mark is erased in mature adipocytes. H3K27me3 ChIP-seq in brown preadipocytes and mature adipocytes.

Project description:To date, speculations on the molecular roles of Tbr2 transcription factor during specification, maintenance and differentiation of cortical specific Intermediate Neural Progenitors are coming from the analysis of loss- and gain-of-function experiments. However since its capacity to bind the DNA to extert its function we did Chromatin Immuno-Precipitation followed by deep sequencing to profile its target on the genome. We performed this approach directly in vivo to respect the physiological and peculiar enviroment of its action during cortical development. Moreover we did the same approach for Neurogenin 2 proneural gene. Interestingly the vast majority of the Neurog2 peaks are in common with Tbr2 dataset suggesting a co-operation between the two factors confirmed by biochemical and functional assays. Finally we compared Tbr2 dataset with the DNA regions bound by the H3K27me3 histone demethylase Jmjd3 (NCBI:Kdm6b) obtained by others. Interestingly we were able to find regions in common linked to important genes for neuronal differentiation. 3 samples, one input chromatin, one ChIP for Tbr2 and one ChIP for Neurog2

Project description:Enhancers of transcription activate transcription via binding of sequence-specific transcription factors to their target sites in chromatin. In this report, we identify GATA1-bound enhancers genome-wide and find a global reorganization of the nucleosomes at these enhancers during differentiation of hematopoietic stem cells (HSCs) to erythrocytes. We show that the catalytic subunit BRG1 of BAF complexes localizes to these enhancers during differentiation and generates a longer nucleosome repeat length surrounding the GATA1 sites by shifting the flanking nucleosomes away. Intriguing, we find that the nucleosome shifting specifically facilitates binding of TAL1 but not GATA1, which subsequently activates transcription of target genes. Human hematopoietic stem cells (referred as CD34+ cells) were differentiated into erythroid lineage expressing the cell surface marker CD36 (referred as CD36+ cells). To study the function of ATP-dependent chromatin remodeling BAF complexes in the establishment of erythroid specific enhancers during differentiation, we mapped the genome-wide binding sites of GATA1 and TAL1, the key transcription regulators of erythroid differentiation, in CD36+ cells, then determined the genomic positions of the catalytic subunit BRG1 of the BAF complexes and the nucleosome landscapes, by ChIP-Seq and Mnase-Seq, respectively, for both HSCs and the differentiated cells. We compared changes in nucleosome landscapes with BRG1 binding at GATA1 and TAL1 binding sites and found that BRG1 binding is correlated with nucleosome shifting away from the binding sites, which is critical for TAL1 binding. To confirm that BRG1 is responsible for the nucleosome shift, we knocked down BRG1 in CD36+ cells and analyzed the nucleosome changes in the knockdown cells. The data indicated that inhibition of BRG1 caused a nucleosome shift towards the GATA1 or TAL1 sites, indicating that BRG1 is indeed responsible for the observed nucleosome shift.

Project description:Erythropoiesis is dependent on the activity of transcription factors, including the erythroid-specific erythroid Kruppel-like factor (EKLF). ChIP followed by massively parallel sequencing (ChIP-Seq) is a powerful, unbiased method to map transfactor occupancy. We used ChIP-Seq to study the interactome of EKLF in mouse erythroid progenitor cells and more differentiated erythroblasts. We correlated these results with the nuclear distribution of EKLF, RNA-Seq analysis of the transcriptome, and the occupancy of other erythroid transcription factors. In progenitor cells, EKLF is found predominantly at the periphery of the nucleus, where EKLF primarily occupies the promoter regions of genes and acts as a transcriptional activator. In erythroblasts, EKLF is distributed throughout the nucleus, and erythroblast-specific EKLF occupancy is predominantly in intragenic regions. In progenitor cells, EKLF modulates general cell growth and cell cycle regulatory pathways, whereas in erythroblasts EKLF is associated with repression of these pathways. The EKLF interactome shows very little overlap with the interactomes of GATA1, GATA2, or TAL1, leading to a model in which EKLF directs programs that are independent of those regulated by the GATA factors or TAL1. (Blood.2011;118(17):e139-e148) We used ChIP-Seq to study the interactome of EKLF in mouse erythroid progenitor cells and more differentiated erythroblasts and RNA-Seq analysis of the transcriptome.