Multiple factors affecting cellular redox status and energy metabolism modulate hypoxia-inducible factor prolyl hydroxylase activity in vivo and in vitro

Prolyl hydroxylation of hypoxible-inducible factor alpha (HIF-alpha) proteins is essential for their recognition by pVHL containing ubiquitin ligase complexes and subsequent degradation in oxygen (O(2))-replete cells. Therefore, HIF prolyl hydroxylase (PHD) enzymatic activity is critical for the regulation of cellular responses to O(2) deprivation (hypoxia). Using a fusion protein containing the human HIF-1alpha O(2)-dependent degradation domain (ODD), we monitored PHD activity both in vivo and in cell-free systems. This novel assay allows the simultaneous detection of both hydroxylated and nonhydroxylated PHD substrates in cells and during in vitro reactions. Importantly, the ODD fusion protein is regulated with kinetics identical to endogenous HIF-1alpha during cellular hypoxia and reoxygenation. Using in vitro assays, we demonstrated that the levels of iron (Fe), ascorbate, and various tricarboxylic acid (TCA) cycle intermediates affect PHD activity. The intracellular levels of these factors also modulate PHD function and HIF-1alpha accumulation in vivo. Furthermore, cells treated with mitochondrial inhibitors, such as rotenone and myxothiazol, provided direct evidence that PHDs remain active in hypoxic cells lacking functional mitochondria. Our results suggest that multiple mitochondrial products, including TCA cycle intermediates and reactive oxygen species, can coordinate PHD activity, HIF stabilization, and cellular responses to O(2) depletion.     

HIF-1 regulation of chondrocyte apoptosis: induction of the autophagic pathway

The goal of our investigation was to explore the mechanism by which hypoxia regulates growth plate chondrocyte survival. At low O2 tension, chondrocytes were refractory to a staurosporine (i.e., apoptosis-inducing) challenge. To determine whether hypoxic survival was due to the expression of HIF-1, we evaluated the response of HIF silenced cells to staurosporine. Both, silenced cells and control chondrocytes were equally sensitive to the apoptogen challenge. To learn if resistance was mediated by the proteins of the autophagic pathway, we examined the expression of Beclin 1 and LC3. Both proteins were present in the growth plate as well as in N1511 chondrocytes. Moreover, silencing of Beclin 1 resulted in enhanced chondrocyte death. Thus, this gene served to maintain chondrocyte survival activity. Besides serving a cytoprotective role, it is known that autophagy can function in cell death. Accordingly, to ascertain if autophagy might also sensitize cells to apoptosis, we activated autophagy and examined viability following exposure to an apoptogen. Treatment with the autophagy inhibitor 3-methyladenine rendered the chondrocytes refractory to killing, suggesting that sustained autophagy promoted cell death. We next examined expression of BID and caspase-8. When autophagy was suppressed, chondrocytes promoted caspase-8 activation and activated BID. Finally, we explored the relationship between HIF-1 and Beclin 1. We noted a decrease in Beclin 1 expression and loss of caspase-8 activation in HIF silenced cells and Beclin 1-Bcl-2 association was maintained upon serum starvation. This study indicates that HIF-1 serves to regulate both autophagy and apoptosis.     

HIF-1 Regulation of Chondrocyte Apoptosis: Induction of the Autophagic Pathway

The goal of our investigation was to explore the mechanism by which hypoxia regulates growth plate chondrocyte survival. At low O2 tension, chondrocytes were refractory to a staurosporine (i.e., apoptosis-inducing) challenge. To determine whether hypoxic survival was due to the expression of HIF-1, we evaluated the response of HIF silenced cells to staurosporine. Both, silenced cells and control chondrocytes were equally sensitive to the apoptogen challenge. To learn if resistance was mediated by the proteins of the autophagic pathway, we examined the expression of Beclin 1 and LC3. Both proteins were present in the growth plate as well as in N1511 chondrocytes. Moreover, silencing of Beclin 1 resulted in enhanced chondrocyte death. Thus, this gene served to maintain chondrocyte survival activity. Besides serving a cytoprotective role, it is known that autophagy can function in cell death. Accordingly, to ascertain if autophagy might also sensitize cells to apoptosis, we activated autophagy and examined viability following exposure to an apoptogen. Treatment with the autophagy inhibitor 3-methyladenine rendered the chondrocytes refractory to killing, suggesting that sustained autophagy promoted cell death. We next examined expression of BID and caspase-8. When autophagy was suppressed, chondrocytes promoted caspase-8 activation and activated BID. Finally, we explored the relationship between HIF-1 and Beclin 1. We noted a decrease in Beclin 1 expression and loss of caspase-8 activation in HIF silenced cells and Beclin 1-Bcl-2 association was maintained upon serum starvation. This study indicates that HIF-1 serves to regulate both autophagy and apoptosis.     

Differential and Reciprocal Regulation between Hypoxia-inducible Factor-α Subunits and Their Prolyl Hydroxylases in Pulmonary Arteries of Rat with Hypoxia-induced Hypertension

Hypoxia-inducible factor (HIF)-α subunits (HIF-1α,HIF-2α and HIF-3α),which play a pivotalrole during the development of hypoxia-induced pulmonary hypertension (HPH),are regulated through post-U'anslational hydroxylation by their three prolyl hydroxylase domain-containing proteins (PHD 1,PHD2 and PHD3).PHDs could also be regulated by HIF.But differential and reciprocal regulation between HIF-α and PHDs duringthe development of HPH remains unclear.To investigate this problem,a rat HPH model was established.Meanpulmonary arterial pressure increased significantly after 7 d of hypoxia.Pulmonary artery remodeling indexand right ventricular hypertrophy became evident after 14 d of hypoxia.HIF-1α and HIF-2α mRNA increasedslightly after 7 d of hypoxia,but HIF-3α increased significantly after 3 d of hypoxia.The protein expressionlevels of all three HIF-α were markedly upregulated after exposure to hypoxia.PHD2 mRNA and proteinexpression levels were upregulated after 3 d of hypoxia;PHD 1 protein declined after 14 d of hypoxia withoutsignificant mRNA changes.PHD3 mRNA and protein were markedly upregulated after 3 d of hypoxia,then themRNA remained at a high level,but the protein declined after 14 d of hypoxia.In hypoxic animals,HIF-lotproteins negatively correlated with PHD2 proteins,whereas HIF-2α and HIF-3α proteins showed negativecorrelations with PHD3 and PHD 1 proteins,respectively.All three HIF-α proteins were positively correlatedwith PHD2 and PHD3 mRNA.In the present study,HIF-α subunits and PHDs showed differential andreciprocal regulation,and this might play a key pathogenesis role in hypoxia-induced pulmonary hypertension.     

Non-hypoxic activation of the negative regulatory feedback loop of prolyl-hydroxylase oxygen sensors

Hypoxia inducible factors (HIF) coordinate cellular responses towards hypoxia. HIFs are mainly regulated by a group of prolyl-hydroxylases (PHDs) that in the presence of oxygen, target the HIFα subunit for degradation. Herein, we studied the role of nitric oxide (NO) in regulating PHD activities under normoxic conditions. In the present study we show that different NO-donors initially inhibited endogenous PHD2 activity which led to accumulation of HIF-1α subsequently to enhance HIF-1 dependent increased PHD2 promoter activity. Consequently PHD2 abundance and activity were strongly induced which caused downregulation of HIF-1α. Interestingly, upregulation of endogenous PHD2 activity by NO was not found in cells that lack an intact pVHL dependent degradation pathway. Recovery of PHD activity required intact cells and was not observed in cell extracts or recombinant PHD2. In conclusion induction of endogenous PHD2 activity by NO is dependent on a feedback loop initiated despite normoxic conditions.     

Regulation of HIF prolyl hydroxylases by hypoxia-inducible factors

Hypoxia and induction of hypoxia-inducible factors (HIF-1alpha and HIF-2alpha) is a hallmark of many tumors. Under normal oxygen tension HIF-alpha subunits are rapidly degraded through prolyl hydroxylase dependent interaction with the von Hippel-Lindau (VHL) tumor suppressor protein, a component of E3 ubuiquitin ligase complex. Using microarray analysis of VHL mutated and re-introduced cells, we found that one of the prolyl hydroxylases (PHD3) is coordinately expressed with known HIF target genes, while the other two family members (PHD1 and 2) did not respond to VHL. We further tested the regulation of these genes by HIF-1 and HIF-2 and found that siRNA targeted degradation of HIF-1alpha and HIF-2alpha results in decreased hypoxia-induced PHD3 expression. Ectopic overexpression of HIF-2alpha in two different cell lines provided a much better induction of PHD3 gene than HIF-1alpha. In contrast, we demonstrate that PHD2 is not affected by overexpression or downregulation of HIF-2alpha. However, induction of PHD2 by hypoxia has HIF-1-independent and -dependent components. Short-term hypoxia (4 h) results in induction of PHD2 independent of HIF-1, while PHD2 accumulation by prolonged hypoxia (16 h) was decreased by siRNA-mediated degradation of HIF-1alpha subunit. These data further advance our understanding of the differential role of HIF factors and putative feedback loop in HIF regulation.     

Hypoxia-induced assembly of prolyl hydroxylase PHD3 into complexes: implications for its activity and susceptibility for degradation by the E3 ligase Siah2

PHD1-3 (prolyl hydroxylases 1-3) catalyse the hydroxylation of HIF (hypoxia-inducible factor)-alpha subunit that triggers the substrate ubiquitination and subsequent degradation. The RING (really interesting new gene) finger E3 ligase Siah2 preferentially targets PHD3 for degradation. Here, we identify the requirements for such selective targeting. Firstly, PHD3 lacks an N-terminal extension found in PHD1 and PHD2; deletion of this domain from PHD1 and PHD2 renders them susceptible to degradation by Siah2. Secondly, PHD3 can homo- and hetero-multimerize with other PHDs. Consequently, PHD3 is found in high-molecular-mass fractions that were enriched in hypoxia. Interestingly, within the lower-molecular-mass complex, PHD3 exhibits higher specific activity towards hydroxylation of HIF-1alpha and co-localizes with Siah2, suggesting that Siah2 limits the availability of the more active form of PHD3. These findings provide new insight into the mechanism underlying the regulation of PHD3 availability and activity in hypoxia by the E3 ligase Siah2.