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.     

Interaction of the PAS B domain with HSP90 accelerates hypoxia-inducible factor-1alpha stabilization.

Hypoxia-inducible factor (HIF) alpha subunits are induced under hypoxic conditions, when limited oxygen supply prevents prolyl hydroxylation-dependent binding of the ubiquitin ligase pVHL and subsequent proteasomal degradation. A short normoxic half-life of HIF-alpha and a very rapid hypoxic protein stabilization are crucial to the cellular adaptation to changing oxygen supply. However, the molecular requirements for the unusually rapid mechanisms of protein synthesis, folding and nuclear translocation are not well understood. We and others previously found that the chaperone heat-shock protein 90 (HSP90) can interact with HIF-1alpha in vitro. Here we show that HSP90 also interacts with HIF-2alpha and HIF-3alpha, suggesting a general involvement of HSP90 in HIF-alpha stabilization. The PAS B domain, common to all three alpha subunits, was required for HSP90 interaction. ARNT competed with HSP90 for binding to the PAS B domain since an excess of either component inhibited the activity of the other. HSP90 as well as the heterocomplex members HSP70 and p23, but not HSP40, were detected in immunoprecipitations of endogenous cellular HIF-1alpha. While HSP90 and HSP70 bound to HIF-1alpha predominantly under normoxic conditions, ARNT bound to HIF-1alpha primarily under hypoxic conditions, suggesting that ARNT displaced HSP90 from HIF-1alpha following nuclear translocation. Hypoxic accumulation of HIF-1alpha was delayed in a novel cell model deficient for HSP90beta as well as after treatment of wild-type cells with the HSP90 inhibitor geldanamycin, suggesting that HSP90 activity is involved in the rapid HIF-1alpha protein induction.     

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.     

HIF-1alpha, HIF-2alpha and VHL mRNA expression in different cell lines during hypoxia

Hypoxia inducible factor-1alpha (HIF-1alpha) mRNA expression is significantly decreased under hypoxia in different cell lines exposed directly to hypoxia or treated with dimethyloxalylglycine which mimics hypoxic effects under normoxic conditions. However, the decreased expression of HIF-1alpha mRNA is accompanied by an increase of HIF-1alpha protein (pHIF-1alpha) level as well as by overexpression of known HIF-dependent genes (VEGF, Glut1, PFKFB-3 and PFKFB-4) under hypoxic conditions or with the use of dimethyloxalylglycine. Expression of HIF-1alpha mRNA also depends on iron because desferrioxamine and cobalt chloride produce similar to hypoxia effects on the levels of this mRNA. It was shown that HIF-1alpha mRNA expression did not change significantly in some cell lines (SKBR3, MDA-MB468 and BT549) under hypoxia. However, in these cell lines hypoxia decreases expression of HIF-2alpha mRNA, another member of HIF-alpha gene family, as a result of cell specific regulation of HIF-alpha genes under hypoxia. Moreover, hypoxia slightly induces expression of PFKFB-4 mRNA in SKBR3, MDA-MB468 and BT549 as compared to other cell lines where this effect of hypoxia was much stronger and adaptation to hypoxia is controlled by HIF-1alpha. Hypoxia slightly reduces expression of tumor suppressor VHL which targets HIF-1alpha for ubiquitination. Thus, our results clearly demonstrated down regulation of HIF-1alpha or HIF-2alpha in different cell lines by hypoxia.     

Two transactivation domains of hypoxia-inducible factor-1alpha regulated by the MEK-1/p42/p44 MAPK pathway

At a low-oxygen tension, cells increase the expression of several genes (such as erythropoietin, the vascular endothelial growth factor, and glycolytic enzymes) in order to adapt to hypoxic stress. A common transactivator, named the hypoxia-inducible factor 1 (HIF-1) activates these genes. HIF-1 is a heterodimeric transactivator that is composed of alpha and beta subunits. HIF-1 activity is primarily determined by the hypoxia-induced stabilization of the alpha subunit, whereas the HIF-1beta subunit is expressed constitutively. Our previous observation implied that the MEK-1/p42/p44 MAPK pathway is involved in the hypoxia-induced transactivation ability, but not in the stabilization and DNA binding of HIF-1alpha. In this paper, we dissected the transactivation domain of HIF-1alpha in more detail, and tested the correlation between specific domains of HIF-1alpha and specific signaling pathways. We designed several fusion proteins that contain deletion mutants of HIF-1alpha that is linked to the DNA binding domain of the yeast protein Gal4. By using the Gal4-driven reporter system, we tested the transactivation activities of the Gal4/HIF-1alpha fusion proteins in Hep3B cells. Our findings suggest that tyrosine kinases, the MEK-1/p42/p44 MAPK pathway, but not the PI-3 kinase/Akt pathway, are involved in the hypoxia-induced transactivation of HIF-1alpha. We have shown that the functional transactivation activities are located at both 522-649 and 650-822 amino acids of HIF-1alpha. Treatment of PD98059, a MEK-1 inhibitor, blocked the hypoxia-induced transactivation abilities of both the 522-649 and 650-822 amino acids of the C-terminal half of HIF-1alpha. This implies that the MEK-1/p42/p44 MAPK signaling pathway cannot distinguish between the two hypoxia-induced transactivation domains.