Project description:To determine the effects of depleting TIP60, CDK8, or HIF1A on the transcriptional response to hypoxia, we performed RNAseq analysis of four HCT116 colorectal carcinoma cell lines (shNT, HIF1A-/-, shTIP60 and shCDK8) in normoxic and hypoxic (24hrs, 1% O2) conditions. PolyA RNA for two independent biological replicates was purified from HCT116 cells stably expressing an shRNA against a non-targeting control (shNT), TIP60 (shTIP60) or CDK8 (shCDK8), or genetically deleted HIF1A (HIF1A-/-) subjected to 24hrs 1% O2 (hypoxia) or maintained under ambient oxygen (21%; normoxia) was sequenced on the Ion Torrent platform. Reads were aligned to the human genome and gene-level counts were used for differential expression analysis.

Project description:To determine the effects of depleting TIP60, CDK8, or HIF1A on the transcriptional response to hypoxia, we performed RNAseq analysis of four HCT116 colorectal carcinoma cell lines (shNT, HIF1A-/-, shTIP60 and shCDK8) in normoxic and hypoxic (24hrs, 1% O2) conditions.

Project description:To test if CDK8 acts directly at HIF1A target genes, we performed ChIP-seq experiments in HCT116 cells under normoxic and hypoxic conditions. ChIP-seq for CDK8 versus Input under normoxia and 24hrs hypoxia (1% O2).

Project description:We compared transcriptome of real quiescent MuSCs and freshly isolated MuSCs with in-situ fixation,FISC cultured for 24hrs,48hrs and 72hrs by RNA-sequencing.

Project description:We have used a combination of RNAi based functional and molecular genomic approaches to investigate in detail two proteins required for the survival of CRC cells. Set1 has 22 samples, 10 siNeg controls, 6 siRNA transfections for FLASH and NUP62 each. Set2 has 67 samples, siNeg controls at timepoint: 10hrs (5), 24hrs (6), 48hrs (6), 72hrs (5), siRNA FLASH at timepoint: 10hrs (8), 24hrs (8), 48hrs (8), 72hrs (8), untreated controls at timepoint: 10hrs (3), 24hrs (3), 48hrs (4), 72hrs (3).

Project description:To investigate the detailed molecular mechanisms for the regulatory role of HIF-2α in experimental colitis, microarray gene expression analysis was performed on colon RNA isolated from 6- to 8-week-old Hif-2αF/F, Hif-2αlΔIE mice treated with 3%DSS for 3 days. Background & Aims: Hypoxic inflammation is characterized by decreased oxygen tension in inflammatory foci, and is a notable feature in inflammatory bowel disease (IBD). Hypoxic response is mediated by transcription factors hypoxia-inducible factor (HIF)-1α and HIF-2α, both of which are highly induced in IBD. HIF-1α is a protective factor that limits intestinal barrier dysfunction during inflammation. However, the role of HIF-2α has not been assessed in hypoxic inflammation and IBD. Methods: A hypoxia reporter mouse model was used to test the presence of hypoxia and HIF-2α in dextran sulfate sodium (DSS) and Citrobacter rodentium (C.rod)-induced colitis. The role of HIF-2α in these mouse models of colitis was further assessed in mice with an intestinal epithelium-specific gain- and loss-of-function of HIF-2α. Results: Induction of hypoxia and HIF-2α was confirmed in both murine experimental colitis models and human IBD samples. Disruption of HIF-2α attenuated colonic inflammation whereas stabilization of HIF-2α potentiated inflammation in mouse models of colitis. Interestingly, intestine specific overexpression of HIF-2α but not HIF-1α leads to spontaneous colitis and premature death in mice. Further mechanistic analysis showed that HIF-2α is a driver for pro-inflammatory response and is critical regulator of intestinal epithelial-derived tumor necrosis factor (TNF)-α. Blocking TNF-α completely ameliorated HIF-2α potentiated intestinal inflammation. Conclusions: These data demonstrate that HIF-2α is a critical transcription factor essential in intestinal epithelium elicited inflammatory response. Global gene expression profiling in colon RNAs isolated from 7-week-old Hif-2αF/F (n=6, Shah 007) and Hif-2αΔIE (n=5, Shah 008).

Project description:Intestinal epithelial cells exist in physiological hypoxia, leading to hypoxia-inducible factor (HIF) activation and supporting barrier function and cell metabolism of the intestinal epithelium. In contrast, pathological hypoxia is a common feature of some disorders, including inflammatory bowel disease (IBD). This work was aimed at studying HIF-associated changes in the intestinal epithelium in IBD. In the first step, a list of genes responding to chemical activation of hypoxia was obtained in an in vitro intestinal cell model with RNA sequencing. Cobalt (II) chloride and oxyquinoline treatment of both undifferentiated and differentiated Caco-2 cells activate the HIF-signaling pathway according to gene set enrichment analysis. The core gene set responding to chemical hypoxia stimulation in the intestinal model included 115 upregulated and 69 downregulated genes. Of this set, protein product was detected for 32 genes, and fold changes in proteome and RNA sequencing significantly correlate. Analysis of publicly available RNA sequencing set of the intestinal epithelial cells of patients with IBD confirmed HIF-1 signaling pathway activation in sigmoid colon of patients with ulcerative colitis and terminal ileum of patients with Crohn’s disease. Of the core gene set from the gut hypoxia model, expression activation of ITGA5 and PLAUR genes encoding integrin α5 and urokinase-type plasminogen activator receptor (uPAR) was detected in IBD specimens. The interaction of these molecules can activate cell migration and regenerative processes in the epithelium. Transcription factor analysis with the previously developed miRGTF tool revealed the possible role of HIF1A and NFATC1 in the regulation of ITGA5 and PLAUR gene expression.

Project description:Hypoxia exacerbates tissue damage in inflammatory bowel disease (IBD). To counteract the deleterious effects of oxygen deprivation, cells within hypoxic tissues activate multiple adaptive mechanisms. Much attention has focused on adaptive pathways regulated by HIF (hypoxia inducible factor) transcription factors, and pharmacologic HIF stabilization is a promising therapeutic approach for IBD. However, recent evidence suggests that hypoxia-induction of cellular transcriptional programs can be mediated not only by HIF transcription factors, but also by oxygen-sensing epigenetic regulator, UTX. Here, we identify a key role for an UTX in modulating colitis severity. Unlike HIF-mediated pathways that act on gut epithelial cells, UTX-mediated pathways function in a T cell-intrinsic manner to protect against colitis. Hypoxia impairs the histone demethylase activity of UTX, which leads to accumulation of repressive H3K27me3 marks at IL12/STAT4 pathway genes (Il12rb2, Tbx21, and Ifng), decreased CD4+ T cell IFN-γ production, and increased CD4+ regulatory T cells (Tregs). Moreover, T cell specific UTX deletion protects mice from autoimmune colitis, which demonstrates that deactivation of UTX restores immune regulation in hypoxia-associated inflammation. Together these findings suggest that modulating UTX’s histone demethylase activity in T cells may be a new pharmacologic target for harnessing hypoxia-induced adaptive pathways in colitis.

Project description:Hypoxia exacerbates tissue damage in inflammatory bowel disease (IBD). To counteract the deleterious effects of oxygen deprivation, cells within hypoxic tissues activate multiple adaptive mechanisms. Much attention has focused on adaptive pathways regulated by HIF (hypoxia inducible factor) transcription factors, and pharmacologic HIF stabilization is a promising therapeutic approach for IBD. However, recent evidence suggests that hypoxia-induction of cellular transcriptional programs can be mediated not only by HIF transcription factors, but also by oxygen-sensing epigenetic regulator, UTX. Here, we identify a key role for an UTX in modulating colitis severity. Unlike HIF-mediated pathways that act on gut epithelial cells, UTX-mediated pathways function in a T cell-intrinsic manner to protect against colitis. Hypoxia impairs the histone demethylase activity of UTX, which leads to accumulation of repressive H3K27me3 marks at IL12/STAT4 pathway genes (Il12rb2, Tbx21, and Ifng), decreased CD4+ T cell IFN-γ production, and increased CD4+ regulatory T cells (Tregs). Moreover, T cell specific UTX deletion protects mice from autoimmune colitis, which demonstrates that deactivation of UTX restores immune regulation in hypoxia-associated inflammation. Together these findings suggest that modulating UTX’s histone demethylase activity in T cells may be a new pharmacologic target for harnessing hypoxia-induced adaptive pathways in colitis.

Project description:Mammalian cells respond to insufficient oxygen through transcriptional regulators called hypoxia-inducible factors (HIFs). Although transiently protective, prolonged HIF activity drives distinct pathological responses in different tissues. Using a model of chronic HIF1a accumulation in pluripotent-stem-cell-derived oligodendrocyte progenitors (OPCs), we demonstrate that HIF1a activates non-canonical targets to impair generation of oligodendrocytes from OPCs. HIF1a activated a unique set of genes in OPCs through interaction with the OPC-specific transcription factor OLIG2. Non-canonical targets, including Ascl2 and Dlx3, were sufficient to block differentiation through suppression of the oligodendrocyte regulator Sox10. Chemical screening revealed that inhibition of MEK/ERK signaling overcame the HIF1a-mediated block in oligodendrocyte generation by restoring Sox10 expression without affecting canonical HIF1a activity. MEK/ERK inhibition also drove oligodendrocyte formation in hypoxic regions of human oligocortical spheroids. This work defines mechanisms by which HIF1a impairs oligodendrocyte formation and establishes that cell-type-specific HIF1a targets perturb cell function in response to low oxygen.