Project description:LncRNA Hypoxia-inducible factor 1α-antisense 1 (HIF1α-AS1) is located on the antisense strand of the important Hypoxia-inducible factor 1α (HIF1α) gene, but being transcribed in antisense direction along the HIF1α promoter. Here we used the 3’end biotinylated HIF1a-AS1 RNA and a control RNA for RNA Pulldown and searched for interacting proteins in nuclear extracts of human umbilical vein endothelial cells (HUVEC).

Project description:Hyperactivation of Notch signaling and the cellular hypoxic response are frequently observed in cancers, with increasing reports of connections to tumor initiation and progression. The two signaling mechanisms are known to intersect, but while it is well established that hypoxia regulates Notch signaling, less is known about whether Notch can regulate the cellular hypoxic response. We now report that Notch signaling specifically controls expression of HIF2a, a key mediator of the cellular hypoxic response. Transcriptional upregulation of HIF2a by Notch under normoxic conditions leads to elevated HIF2a protein levels in primary breast cancer cells as well as in human breast cancer, medulloblastoma and renal cell carcinoma cell lines. The elevated level of HIF2a protein was in certain tumor cell types accompanied by down-regulation of HIF1a protein levels, indicating that high Notch signaling may drive a HIF1a-to-HIF2a switch. At the transcriptome level, the presence of HIF2a was required for approximately 21% of all Notch-induced genes: among the 1062 genes that were upregulated by Notch in medulloblastoma cells during normoxia, upregulation was abrogated in 227 genes when HIF2a expression was knocked down by HIF2a siRNA. In conclusion, our data show that Notch signaling affects the hypoxic response via regulation of HIF2a, which may be important for future cancer therapies.

Project description:To determine the underlying mechanism of ONECUT2 in prostate cancer hypoxia, we conducted a series of RNA-Seq and ChIP-Seq experiments in LNCaP and PC3 cells under normoxia and hypoxia conditions. We did RNA-Seq in LNCaP cells with or without OC2 overexpression and in PC3 cells with or without OC2 knockdown. We used anti-Flag antibody to perform the ChIP-Seq experiment in PC3 cells with Flag and OC2 fusion protein overexpression. We also performed HIF1A ChIP-Seq in AR-negative prostate cancer cell line PC3 under hypoxia condition with or without ONECUT2 or SMAD3 siRNA knockdown. SMAD3 and HIF2A ChIP-Seq were conducted in PC3 cells under hypoxia condition. To confirm the interactions between transcription factors, we also performed ChIP-reChIP-seq. We did the primary ChIP experiment using anti-SMAD3 antibody and then we subjected the ChIPed chromatin by the primary ChIP to reChIP experiments using anti-HIF1A or anti-HIF2A antibody. The reChIPed DNA was submitted to next generation sequencing.

Project description:Hyperactivation of Notch signaling and the cellular hypoxic response are frequently observed in cancers, with increasing reports of connections to tumor initiation and progression. The two signaling mechanisms are known to intersect, but while it is well established that hypoxia regulates Notch signaling, less is known about whether Notch can regulate the cellular hypoxic response. We now report that Notch signaling specifically controls expression of HIF2a, a key mediator of the cellular hypoxic response. Transcriptional upregulation of HIF2a by Notch under normoxic conditions leads to elevated HIF2a protein levels in primary breast cancer cells as well as in human breast cancer, medulloblastoma and renal cell carcinoma cell lines. The elevated level of HIF2 protein was in certain tumor cell types accompanied by down-regulation of HIF1a protein levels, indicating that high Notch signaling may drive a HIF1a-to-HIF2a switch. At the transcriptome level, the presence of HIF2a was required for approximately 21% of all Notch-induced genes: among the 1062 genes that were upregulated by Notch in medulloblastoma cells during normoxia, upregulation was abrogated in 227 genes when HIF2a expression was knocked down by HIF2a siRNA. In conclusion, our data show that Notch signaling affects the hypoxic response via regulation of HIF2a, which may be important for future cancer therapies.

Project description:Expression profiling of thymic lymphomas derived from HIF1a+/+, p53R270H/R270H; HIF1a+/-, p53R270H/R270H; and HIF1aKI/+, p53R270H/R270H mice. HIF1a and HIF2a share a high degree of sequence homology, but recent work has shown that the two a subunits can have contrasting and tissue-specific effects on tumor growth. To directly compare the role of each HIFa subunit in spontaneous tumorigenesis, we bred a mouse model of expanded HIF2a expression and Hif1a+/- mice to homozygotes for the R270H mutation in p53. Heterozygosity for Hif1a significantly reduced the incidence of thymic lymphomas observed in this model. Moreover, reduced Hif1a levels correlated with decreased stabilization of activated Notch1 and expression of the Notch target genes, Dtx1 and Nrarp. Keywords: genetic modification, disease state analysis Thymic lymphoma tissue was preserved at the time mice were sacrificed. 4-5 samples from each of 3 genotypes (HIF1a+/-, p53R270H/R270H, HIF1aKI/+; p53R270H/R270H; and HIF1a+/+, p53R270H/R270H) were then used for microarray analysis to identify differences in gene expression that could account for changes in tumor onset and incidence.

Project description:Triple Negative Breast cancer accounts for some of the most aggressive types of breast cancer. By interrogating clinical datasets, we found that the activities of p63 and Hypoxia-Inducible-Factors (HIFs), two master regulators of the invasive and metastatic cancer cell phenotype are linked in TNBC through the p63-target Sharp1. Mechanistically, Sharp1 promotes HIF-1α/HIF-2α proteasomal degradation by serving as HIFs presenting factor to the proteasome independently from oxygen levels and prior ubiquitination. To investigate unbiasedly if Sharp1 is a general inhibitor of HIF induced transcriptional program, we compared the transcriptomic profile of cells either overexpressing Sharp1 or depleted of HIF1a and HIF2a. We collected RNA from control MDA-MB-231 cells (shGFP) or MDA-MB-231 cells overexpressing Sharp1 or MDA-MB-231 cells depleted of HIF1a and HIF2a (shHIF). Cells were left untreated in normal culturing conditions before harvesting. Samples were then processed for total RNA extraction and hybridization on Affymetrix microarrays. Four biological replicas (A, B, C, D) were used for each of the 4 conditions (1: shGFP, control cells; 2: shHIF cells; 3: Sharp1-overexpressing cells) for a total of 12 samples.

Project description:Expression profiling of thymic lymphomas derived from HIF1a+/+, p53R270H/R270H; HIF1a+/-, p53R270H/R270H; and HIF1aKI/+, p53R270H/R270H mice. HIF1a and HIF2a share a high degree of sequence homology, but recent work has shown that the two a subunits can have contrasting and tissue-specific effects on tumor growth. To directly compare the role of each HIFa subunit in spontaneous tumorigenesis, we bred a mouse model of expanded HIF2a expression and Hif1a+/- mice to homozygotes for the R270H mutation in p53. Heterozygosity for Hif1a significantly reduced the incidence of thymic lymphomas observed in this model. Moreover, reduced Hif1a levels correlated with decreased stabilization of activated Notch1 and expression of the Notch target genes, Dtx1 and Nrarp. Keywords: genetic modification, disease state analysis

Project description:RNA-Seq analysis was performed from human umbilical vein endothelial cells exposed to constitutively active HIF1a and HIF2a overexpression

Project description:Microarray characterization of Vhl; Vhl, Hif1a; Vhl, Hif2a and Vhl, Hif1a, Hif2a deficient primary kidney cells

Project description:Acute myeloid leukemia (AML) is characterized by an accumulation of aberrant myeloid cells arrested at different stages of differentiation. Therapeutic approaches that prompt AML blasts to differentiate represent an attractive opportunity in the landscape of AML therapies, as they aim to induce terminal maturation and leukemia debulking without intensive cytotoxic treatments. In the present study, we investigate the involvement of HIF1a and HIF2a transcription factors in AML pathogenesis, and position HIF2a as a novel regulator of the AML differentiation block. We performed a comparative analysis of HIF1a and HIF2a function in AML cell lines via their inhibition with genetic or pharmacological strategies and found that both factors promote AML proliferation and clonogenicity. Importantly, specific inhibition of HIF2a provokes AML cell differentiation in cell lines and patient-derived xenograft (PDX) models. Additionally, we demonstrate that HIF2a is positively regulated by the pro-differentiation agent all-trans retinoic acid (ATRA), and its inhibition cooperates with ATRA in triggering AML cell differentiation. In conclusion, we report evidence of a new role of HIF2a in the pathogenesis of AML, and we propose that HIF2a inhibition may open new therapeutic avenues for AML treatment by licensing AML differentiation and synergizing with ATRA towards leukemia exhaustion.