Mammalian cells respond to changes in oxygen availability through a conserved pathway that is regulated by the hypoxia-inducible factor (HIF). The alpha subunit of HIF is targeted for degradation under normoxic conditions by a ubiquitin-ligase complex that recognizes a hydroxylated proline residue in HIF. We identified a conserved family of HIF prolyl hydoxylase (HPH) enzymes that appear to be responsible for this posttranslational modification. In cultured mammalian cells, inappropriate accumulation of HIF caused by forced expression of the HIF-1alpha subunit under normoxic conditions was attenuated by coexpression of HPH. Suppression of HPH in cultured Drosophila melanogaster cells by RNA interference resulted in elevated expression of a hypoxia-inducible gene (LDH, encoding lactate dehydrogenase) under normoxic conditions. These findings indicate that HPH is an essential component of the pathway through which cells sense oxygen.
Mammalian cells adapt to hypoxic conditions through a transcriptional response pathway mediated by the hypoxia-inducible factor, HIF. HIF transcriptional activity is suppressed under normoxic conditions by hydroxylation of an asparagine residue within its C-terminal transactivation domain, blocking association with coactivators.Here we show that the protein FIH-1, previously shown to interact with HIF, is an asparaginyl hydroxylase. Like known hydroxylase enzymes, FIH-1 is an Fe(II)-dependent enzyme that uses molecular O 2 to modify its substrate. Together with the recently discovered prolyl hydroxylases that regulate HIF stability, this class of oxygen-dependent enzymes comprises critical regulatory components of the hypoxic response pathway. Received March 14, 2002; revised version accepted April 30, 2002. Almost all mammalian cells possess the ability to recognize changes in the local availability of oxygen. When oxygen levels are low (hypoxia), a conserved hypoxic response pathway is activated. At the center of this pathway lies the ubiquitously expressed transcription factor hypoxia-inducible factor (HIF) (Semenza 1999). HIF is a heterodimer composed of an alpha subunit, HIF-1␣ or the paralogs HIF-2␣ or HIF-3␣ (Tian et al. 1997;Gu et al. 1998;O'Rourke et al. 1999;Srinivas et al. 1999), and the HIF-1 subunit, also known as the aryl hydrocarbon receptor nuclear translocator (ARNT) (Wang et al. 1995). Whereas HIF-1 expression and activity levels remain largely unaffected by changes in oxygen levels, the HIF-␣ subunit is strongly induced following exposure to hypoxic conditions. Two primary mechanisms by which HIF-␣ activity is regulated by oxygen have been identified. Under normoxic conditions, the oxygen-dependent degradation domain (ODD) within the HIF-␣ subunit is recognized by the product of the von-Hippel Lindau tumor suppressor gene (pVHL) (Maxwell et al. 1999). pVHL is a component of a protein-ubiquitin ligase complex that targets the alpha subunit for degradation by the proteasome (Maxwell et al. 1999;Cockman et al. 2000;Ohh et al. 2000;Tanimoto et al. 2000). pVHL recognition of HIF-␣ is dependent on hydroxylation of proline residues within the ODD (Ivan et al. 2001;Jaakkola et al. 2001;Yu et al. 2001). Under hypoxic conditions, prolyl hydroxylation is blocked, resulting in increased HIF-␣ stability and accumulation (Ivan et al. 2001;Jaakkola et al. 2001;Yu et al. 2001). This posttranslational modification is carried out by a family of prolyl hydroxylase enzymes that bear structural and functional similarities to previously characterized hydroxylases (Bruick and McKnight 2001;Epstein et al. 2001). Like these enzymes, the HIF prolyl hydroxylase enzymes use Fe(II) to bind O 2 to hydroxylate both 2-oxoglutarate and the target proline residue (Bruick and McKnight 2001;Epstein et al. 2001). Because these enzymes bind oxygen directly, it has been speculated that they may be critical oxygen sensors within the hypoxic response pathway.In addition to inducing HIF stability, hypoxic conditions promote the ...
The liver provides for long-term energy needs of the body by converting excess carbohydrate into fat for storage. Insulin is one factor that promotes hepatic lipogenesis, but there is increasing evidence that glucose also contributes to the coordinated regulation of carbohydrate and fat metabolism in liver by mechanisms that are independent of insulin. In this study, we show that the transcription factor, carbohydrate response element-binding protein (ChREBP), is required both for basal and carbohydrate-induced expression of several liver enzymes essential for coordinated control of glucose metabolism, fatty acid, and the synthesis of fatty acids and triglycerides in vivo.
The ability to sense and respond to changes in oxygen availability is critical for many developmental, physiological, and pathological processes, including angiogenesis, control of blood pressure, and cerebral and myocardial ischemia. Hypoxia-inducible factor-1␣ (HIF-1␣) is a basic-helix-loop-helix (bHLH)-containing member of the PER-ARNT-SIM (PAS) family of transcription factors that plays a central role in the response to hypoxia. HIF-1␣, and its relatives HIF-2␣͞endothelial PAS domain protein (EPAS) and HIF-3␣, are induced in response to hypoxia and serve to coordinately activate the expression of target genes whose products facilitate cell survival under conditions of oxygen deprivation. When cells are exposed to chronic hypoxia, the protective response can fail, resulting in apoptosis. This study shows that transcription of the gene encoding Nip3, a proapoptotic member of the Bcl-2 family of cell death factors, is strongly induced in response to hypoxia. The Nip3 promoter contains a functional HIF-1-responsive element (HRE) and is potently activated by both hypoxia and forced expression of HIF-1␣. Exposure of cultured cells to chronic hypoxia results in the accumulation of a protein recognized by antibodies raised against Nip3. This study demonstrates a direct link between HIF-1␣ and a proapoptotic member of the Bcl-2 family and offers a reasonable physiological function for members of the Bcl-2 subfamily, including Nip3 and its close relative Nix. These observations indicate that Nip3 may play a dedicated role in the pathological progression of hypoxia-mediated apoptosis, as observed after ischemic injury.
Carbohydrates mediate their conversion to triglycerides in the liver by promoting both rapid posttranslational activation of ratelimiting glycolytic and lipogenic enzymes and transcriptional induction of the genes encoding many of these same enzymes. The mechanism by which elevated carbohydrate levels affect transcription of these genes remains unknown. Here we report the purification and identification of a transcription factor that recognizes the carbohydrate response element (ChRE) within the promoter of the L-type pyruvate kinase (LPK) gene. The DNA-binding activity of this ChRE-binding protein (ChREBP) in rat livers is specifically induced by a high carbohydrate diet. ChREBP's DNA-binding specificity in vitro precisely correlates with promoter activity in vivo. Furthermore, forced ChREBP overexpression in primary hepatocytes activates transcription from the L-type Pyruvate kinase promoter in response to high glucose levels. The DNA-binding activity of ChREBP can be modulated in vitro by means of changes in its phosphorylation state, suggesting a possible mode of glucoseresponsive regulation. ChREBP is likely critical for the optimal long-term storage of excess carbohydrates as fats, and may contribute to the imbalance between nutrient utilization and storage characteristic of obesity.
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