Fbw7 is a ubiquitin-ligase that targets several oncoproteins for proteolysis, but the full range of Fbw7 substrates is not known. Here we show that by performing quantitative proteomics combined with degron motif searches, we effectively screened for a more complete set of Fbw7 targets. We identify 89 putative Fbw7 substrates, including several disease-associated proteins. The transcription factor NF-κB2 (p100/p52) is one of the candidate Fbw7 substrates. We show that Fbw7 interacts with p100 via a conserved degron and that it promotes degradation of p100 in a GSK3β phosphorylation-dependent manner. Fbw7 inactivation increases p100 levels, which in the presence of NF-κB pathway stimuli, leads to increased p52 levels and activity. Accordingly, the apoptotic threshold can be increased by loss of Fbw7 in a p100-dependent manner. In conclusion, Fbw7-mediated destruction of p100 is a regulatory component restricting the response to NF-κB2 pathway stimulation.
Hypoxia-inducible factor 1α (HIF1α) induces the expression of several hundred genes in hypoxia aiming at restoration of oxygen homeostasis. HIF prolyl-4-hydroxylases (HIF-P4Hs) regulate the stability of HIF1α in an oxygen-dependent manner. Hypoxia is a common feature in inflammation and cancer and the HIF pathway is closely linked with the inflammatory NF-κB and tumor suppressor p53 pathways. Here we show that genetic inactivation or chemical inhibition of HIF-P4H-1 leads to downregulation of proinflammatory genes, while proapoptotic genes are upregulated. HIF-P4H-1 inactivation reduces the inflammatory response under LPS stimulus in vitro and in an acute skin inflammation model in vivo. Furthermore, HIF-P4H-1 inactivation increases p53 activity and stability and hydroxylation of proline 142 in p53 has an important role in this regulation. Altogether, our data suggest that HIF-P4H-1 inhibition may be a promising therapeutic candidate for inflammatory diseases and cancer, enhancing the reciprocal negative regulation of the NF-κB and p53 pathways.
Endothelial cells (ECs) form a physical barrier between the lumens and vascular walls of arteries, veins, capillaries, and lymph vessels; thus, they regulate the extravasation of nutrients and oxygen from the circulation into the perivascular space and participate in mechanisms that maintain cardiovascular homeostasis and promote tissue growth and repair. Notably, their role in tissue repair is facilitated, at least in part, by their dependence on glycolysis for energy production, which enables them to resist hypoxic damage and promote angiogenesis in ischemic regions. ECs are also equipped with a network of oxygen-sensitive molecules that collectively activate the response to hypoxic injury, and the master regulators of the hypoxia response pathway are hypoxia-inducible factors (HIFs). HIFs reinforce the glycolytic dependence of ECs under hypoxic conditions, but whether HIF activity attenuates or exacerbates the progression and severity of cardiovascular dysfunction varies depending on the disease setting. This review summarizes how HIF regulates the metabolic and angiogenic activity of ECs under both normal and hypoxic conditions and in a variety of diseases that are associated with cardiovascular complications.
Ischemic heart disease (IHD) is a major cause of mortality and morbidity worldwide, with novel therapeutic strategies urgently needed. Endothelial dysfunction is a hallmark of IHD, contributing to its development and progression. Hypoxia-inducible factors (HIFs) are transcription factors activated in response to low oxygen levels, playing crucial roles in various pathophysiological processes related to cardiovascular diseases. Among the HIF isoforms, HIF2α is predominantly expressed in cardiac vascular endothelial cells and has a key role in cardiovascular diseases. HIFβ, also known as ARNT, is the obligate binding partner of HIFα subunits and is necessary for HIFα’s transcriptional activity. ARNT itself plays an essential role in the development of the cardiovascular system, regulating angiogenesis, limiting inflammatory cytokine production, and protecting against cardiomyopathy. This review provides an overview of the current understanding of HIF2α and ARNT signaling in endothelial cell function and dysfunction and their involvement in IHD pathogenesis. We highlight their roles in inflammation and maintaining the integrity of the endothelial barrier, as well as their potential as therapeutic targets for IHD.
Background: HIF pathway is quickly activated during myocardial ischemia after myocardial infarction(MI), and cardiac microvascular leakage contributes to heart tissue damage. HIF2α isprofoundly expressed in cardiac endothelial cells (ECs) and the embryonic deletion of HIF2Aresults in increased vascular permeability and aberrant ECs behavior. However, the direct roleof endothelial cell-specific HIF2α (ecHIF2α) in ischemic heart disease is not known. Wehypothesized that ecHIF2α expression in response to myocardial infarction (MI) is protectiveagainst heart failure through the reduction of cardiac ECs apoptosis and inflammation. Methods and Results: To address our hypothesis, we generated EC-specific inducible-HIF2α knockout mice (ecHIF2α -/- ) by crossing Hif2a flox/flox mice with Cre ERT2 mice. To assess the functional role of HIF2α inischemic heart injury, we ligated the proximal left anterior descending coronary artery to induceMI using the same age and gender-matched ecHIF2α -/- and control ( Hif2a flox/flox ) mice. Cardiacfunction was determined by echocardiography after two and four weeks of ligation. Analysis ofechocardiography revealed worsened heart function, and Masson’s Trichrome stain displayedincreased fibrosis in ecHIF2α -/- mice. In vitro , ECIS analysis of isolated cardiac microvascularendothelial cells showed decreased endothelial barrier function in ecHIF2α -/- cells. In addition,hypoxic stimulation reduces the tube formation capacity in ecHIF2α-/- cells and is sensitive tohypoxia-induced early-stage apoptosis. Deletion of HIF2α, as well as its binding partner ARNT,increased the expression of several inflammatory genes, including IL-6. Interestingly,overexpression of ARNT alone abolishes the HIF2α deletion-induced inflammatory geneexpression. IL-6 protein levels in HIF2α deleted human aortic endothelial cells (HAoEC) show asignificant reduction (n=3-5, p<0.001) in ARNT overexpressed ECs. Conclusion: Collectively our data revealed an essential role of endothelial HIF2α/ARNT in maintaining cardiacfunctions by increasing endothelial barrier function and decreasing inflammation. Therefore,HIF2A/ARNT could provide a potential therapeutic target for the treatment of ischemic heartdisease.
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