Project description:Epigenome and transcriptome characterization of RUNX1 deficient hematopoietic cells. We hypothesized that epigenetic alterations in key inflammatory pathway genes are acquired in RUNX1 deficient granulocyte-monocyte progenitors (GMPs) and are propagated to neutrophils. We deleted RUNX1 using Cebpa-Cre, which deletes primarily in GMPs. We analyzed the basal transcriptional changes caused by the loss of RUNX1 in purified GMPs and neutrophils by bulk RNA-seq. We evaluated if the loss of RUNX1 leads to changes in chromatin accessibility in GMPs and neutrophils by ATAC-seq. We determined that there was increased chromatin accessibility of transposable elements (TEs) in RUNX1 deficient cells. To determine if we could detect dsRNA from TEs, we pulled down dsRNA using the 9D5 antibody and performed RNA-seq. To gain insight into how RUNX1 loss affects active enhancers, we performed H3K27ac ChIP-seq on control and Runx1 deficient neutrophils. We also evaluated if RUNX1 mutations in patient neutrophils lead to changes in chromatin accessibility by ATAC-seq. We then performed Hi-C to evaluate the global high-order chromatin organization in GMPs and neutrophils. Finally, we performed RUNX1 CUT&RUN to determine RUNX1 occupancy sites in GMPs.

Project description:Epigenome and transcriptome characterization of RUNX1 deficient hematopoietic cells. We hypothesized that epigenetic alterations in key inflammatory pathway genes are acquired in RUNX1 deficient granulocyte-monocyte progenitors (GMPs) and are propagated to neutrophils. We deleted RUNX1 using Cebpa-Cre, which deletes primarily in GMPs. We analyzed the basal transcriptional changes caused by the loss of RUNX1 in purified GMPs and neutrophils by bulk RNA-seq. We evaluated if the loss of RUNX1 leads to changes in chromatin accessibility in GMPs and neutrophils by ATAC-seq. We determined that there was increased chromatin accessibility of transposable elements (TEs) in RUNX1 deficient cells. To determine if we could detect dsRNA from TEs, we pulled down dsRNA using the 9D5 antibody and performed RNA-seq. To gain insight into how RUNX1 loss affects active enhancers, we performed H3K27ac ChIP-seq on control and Runx1 deficient neutrophils. We also evaluated if RUNX1 mutations in patient neutrophils lead to changes in chromatin accessibility by ATAC-seq. We then performed Hi-C to evaluate the global high-order chromatin organization in GMPs and neutrophils. Finally, we performed RUNX1 CUT&RUN to determine RUNX1 occupancy sites in GMPs.

Project description:Epigenome and transcriptome characterization of RUNX1 deficient hematopoietic cells. We hypothesized that epigenetic alterations in key inflammatory pathway genes are acquired in RUNX1 deficient granulocyte-monocyte progenitors (GMPs) and are propagated to neutrophils. We deleted RUNX1 using Cebpa-Cre, which deletes primarily in GMPs. We analyzed the basal transcriptional changes caused by the loss of RUNX1 in purified GMPs and neutrophils by bulk RNA-seq. We evaluated if the loss of RUNX1 leads to changes in chromatin accessibility in GMPs and neutrophils by ATAC-seq. We determined that there was increased chromatin accessibility of transposable elements (TEs) in RUNX1 deficient cells. To determine if we could detect dsRNA from TEs, we pulled down dsRNA using the 9D5 antibody and performed RNA-seq. To gain insight into how RUNX1 loss affects active enhancers, we performed H3K27ac ChIP-seq on control and Runx1 deficient neutrophils. We also evaluated if RUNX1 mutations in patient neutrophils lead to changes in chromatin accessibility by ATAC-seq. We then performed Hi-C to evaluate the global high-order chromatin organization in GMPs and neutrophils. Finally, we performed RUNX1 CUT&RUN to determine RUNX1 occupancy sites in GMPs.

Project description:Epigenome and transcriptome characterization of RUNX1 deficient hematopoietic cells. We hypothesized that epigenetic alterations in key inflammatory pathway genes are acquired in RUNX1 deficient granulocyte-monocyte progenitors (GMPs) and are propagated to neutrophils. We deleted RUNX1 using Cebpa-Cre, which deletes primarily in GMPs. We analyzed the basal transcriptional changes caused by the loss of RUNX1 in purified GMPs and neutrophils by bulk RNA-seq. We evaluated if the loss of RUNX1 leads to changes in chromatin accessibility in GMPs and neutrophils by ATAC-seq. We determined that there was increased chromatin accessibility of transposable elements (TEs) in RUNX1 deficient cells. To determine if we could detect dsRNA from TEs, we pulled down dsRNA using the 9D5 antibody and performed RNA-seq. To gain insight into how RUNX1 loss affects active enhancers, we performed H3K27ac ChIP-seq on control and Runx1 deficient neutrophils. We also evaluated if RUNX1 mutations in patient neutrophils lead to changes in chromatin accessibility by ATAC-seq. We then performed Hi-C to evaluate the global high-order chromatin organization in GMPs and neutrophils. Finally, we performed RUNX1 CUT&RUN to determine RUNX1 occupancy sites in GMPs.

Project description:Epigenome and transcriptome characterization of RUNX1 deficient hematopoietic cells. We hypothesized that epigenetic alterations in key inflammatory pathway genes are acquired in RUNX1 deficient granulocyte-monocyte progenitors (GMPs) and are propagated to neutrophils. We deleted RUNX1 using Cebpa-Cre, which deletes primarily in GMPs. We analyzed the basal transcriptional changes caused by the loss of RUNX1 in purified GMPs and neutrophils by bulk RNA-seq. We evaluated if the loss of RUNX1 leads to changes in chromatin accessibility in GMPs and neutrophils by ATAC-seq. We determined that there was increased chromatin accessibility of transposable elements (TEs) in RUNX1 deficient cells. To determine if we could detect dsRNA from TEs, we pulled down dsRNA using the 9D5 antibody and performed RNA-seq. To gain insight into how RUNX1 loss affects active enhancers, we performed H3K27ac ChIP-seq on control and Runx1 deficient neutrophils. We also evaluated if RUNX1 mutations in patient neutrophils lead to changes in chromatin accessibility by ATAC-seq. We then performed Hi-C to evaluate the global high-order chromatin organization in GMPs and neutrophils. Finally, we performed RUNX1 CUT&RUN to determine RUNX1 occupancy sites in GMPs.

Project description:Epigenome and transcriptome characterization of RUNX1 deficient hematopoietic cells. We hypothesized that epigenetic alterations in key inflammatory pathway genes are acquired in RUNX1 deficient granulocyte-monocyte progenitors (GMPs) and are propagated to neutrophils. We deleted RUNX1 using Cebpa-Cre, which deletes primarily in GMPs. We analyzed the basal transcriptional changes caused by the loss of RUNX1 in purified GMPs and neutrophils by bulk RNA-seq. We evaluated if the loss of RUNX1 leads to changes in chromatin accessibility in GMPs and neutrophils by ATAC-seq. We determined that there was increased chromatin accessibility of transposable elements (TEs) in RUNX1 deficient cells. To determine if we could detect dsRNA from TEs, we pulled down dsRNA using the 9D5 antibody and performed RNA-seq. To gain insight into how RUNX1 loss affects active enhancers, we performed H3K27ac ChIP-seq on control and Runx1 deficient neutrophils. We also evaluated if RUNX1 mutations in patient neutrophils lead to changes in chromatin accessibility by ATAC-seq. We then performed Hi-C to evaluate the global high-order chromatin organization in GMPs and neutrophils. Finally, we performed RUNX1 CUT&RUN to determine RUNX1 occupancy sites in GMPs.

Project description:Examination of open chromatin regions between clonal neutrophil progenitor populations. Conditionally immortalized CD45.1 naive paired granulocyte-monocyte progenitors (GMPs) and their mature neutrophil counterpart were profiled in an in vitro cell system. We identified 29,966 differentially accessible regions (DARs) between GMPs and neutrophils, from a total of 74,009 consensus peaks of chromatin accessibility. There is some correlation of open chromatin between GMP and mature neutrophil clones.

Project description:Chromatin accessibility is a hallmark of active regulatory function in the genome and variation of chromatin accessibility across individuals has been shown to contribute to complex traits and disease susceptibility. However, the mechanisms responsible for chromatin variation among different individuals and how this variation contributes to phenotypic diversity remain poorly understood. We examined chromatin accessibility variation in liver tissue from seven strains of adult mice that have phenotypic diversity in response to a high-fat/high-sucrose diet. Remarkably, nearly 40% of the loci with the greatest degree of chromatin variability across the strains are associated with transposable elements (TEs), with evolutionarily younger TEs being particularly enriched for regions of chromatin variation. We found that evolutionary younger and older TEs have differential chromatin accessibility profiles and are enriched for binding sites of different transcription factors, indicating the role of TEs in the evolution of regulatory networks in the liver. We also demonstrate that TE polymorphisms and epigenetic regulation of TEs contribute to regulatory variation across different strains through providing binding sites for liver transcription factors. Intriguingly, variable chromatin loci that are associated with liver metabolism are primarily TE-associated. We demonstrate that TEs contribute to regulatory variation in liver and have downstream effects on metabolism. Our data reveal TEs as a novel and important contributor to regulatory and phenotypic variation in the liver and suggest that regulatory variation at TEs is a major contributor to phenotypic variation in populations. Examination of chromatin accessibility with FAIRE-seq in livers of male mice (A/J, AKR/J, BALB/cJ, C57BL/6J, C3H/HeJ, CBA/J, DBA/2J, BXH2/TyJ, and BXH19/TyJ) fed a high-fat, high-sucrose diet.

Project description:Hereditary Leiomyomatosis and renal cell cancer is caused by fumarate hydratase loss of heterozygosity and subsequence accumulation of fumarate. Fumarate is known to activate the anti-oxidant response and is key for cellular survival. Fumarate succinates KEAP1 which releases NRF2 to activate the antioxidant response. The role of fumarate on the global regulatory chromatin landscape is less understood. Here, by integrating chromatin accessibility and histone ChIP-seq profiles, we identify complex transcription factor networks involved in the highly remodelled chromatin landscape of FH-deficient cells. We implicate FOXA2 in the maintenance of FH-deficient cells by regulating anti-oxidant response genes and subsequent metabolic output, independent of NRF2. These results identify new redox and amino acid metabolism regulators and provide new avenues for therapeutic intervention.

Project description:<p>Gene expression is a biological process regulated at different molecular levels, including chromatin accessibility, transcription, and RNA maturation and transport. In addition, these regulatory mechanisms have strong links with cellular metabolism. Here we present a multi-omics dataset that captures different aspects of this multi-layered process in yeast. We obtained RNA-seq, metabolomics, and H4K12Ac ChIP-seq data for wild-type and mip6delta strains during a heat-shock time course. Mip6 is an RNA-binding protein that contributes to RNA export during environmental stress and is informative of the contribution of post-transcriptional regulation to control cellular adaptations to environmental changes. The experiment was performed in quadruplicate, and the different omics measurements were obtained from the same biological samples, which facilitates the integration and analysis of data using covariance-based methods. We validate our dataset by showing that ChIP-seq, RNA-seq and metabolomics signals recapitulate existing knowledge about the response of ribosomal genes and the contribution of trehalose metabolism to heat stress.</p>