Reversible inactivation of HIF-1 prolyl hydroxylases allows cell metabolism to control basal HIF-1

Redox regulation of the hypoxia-inducible factor

Reactive oxygen species (ROS) have long been considered only as cyto- and genotoxic. However, there is now compelling evidence that ROS also act as second messengers in response to various stimuli, such as growth factors, hormones and cytokines. The hypoxia-inducible transcription factor (HIF) is a master regulator of oxygen-sensitive gene expression. More recently, HIF has also been shown to respond to non-hypoxic stimuli. Interestingly, recent reports indicate that ROS regulate HIF stability and transcriptional activity in well-oxygenated cells, as well as under hypoxic conditions. Consequently, ROS appear to be key players in regulating HIF-dependent pathways under both normal and pathological circumstances. This review summarizes the current understanding of the role of ROS in the regulation of the mammalian HIF system.

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.

Lactate dehydrogenase 5 expression in operable colorectal cancer: strong association with survival and activated vascular endothelial growth factor pathway--a report of the Tumour Angiogenesis Research Group

PURPOSE

Lactate dehydrogenase 5 (LDH-5) regulates, under hypoxic conditions, the anaerobic transformation of pyruvate to lactate for energy acquisition. Several studies have shown that serum LDH may be an ominous prognostic marker in malignant tumors. The clinical significance of tissue LDH-5, however, remains largely unexplored.

PATIENTS AND METHODS

We investigated the immunohistochemical expression of LDH-5 in a series of 128 stage II/III colorectal adenocarcinomas treated with surgery alone. In addition, markers of tumor hypoxia (hypoxia-inducible factor 1 alpha [HIF1alpha]), angiogenesis (vascular endothelial growth factor [VEGF] and phosporylated kinase domain receptor [pKDR]/flk-1 receptor) and the tumor vascular density (CD31 positive standard vascular density [sVD] and pKDR positive activated vascular density [aVD]) were assessed.

RESULTS

The expression of LDH-5, together with that of HIF1alpha and pKDR, was both nuclear and cytoplasmic. Assessment, with minimal interobserver variability, was achieved using a previously described scoring system. LDH-5 was significantly associated with HIF1alpha (P = .01), aVD (P = .001) and, particularly, with pKDR expression in cancer cells (P = .0001). Tissue LDH-5 expression was linked with elevated serum LDH levels, but serum levels failed to reflect tissue expression in 71% of LDH-5 positive cases. In univariate analysis tissue LDH-5 was associated with poor survival (P = .0003, HR 15.1), whereas in multivariate analysis this isoenzyme was the strongest independent prognostic factor (P = .0009). VEGF, pKDR, aVD, sVD and vascular invasion were all significantly related to unfavorable prognosis.

CONCLUSION

The immunohistochemical assessment of tissue LDH-5 and pKDR provides important prognostic information in operable colorectal cancer. The strong association between LDH-5 and pKDR expression would justify their use as surrogate markers to screen patients for tyrosine kinase inhibitor therapy.

A Phenotypic Perspective on Mammalian Oxygen Sensor Candidates

Chronic hypoxic stimulation in mammals can induce several phenotypic changes, such as polycythemia, pulmonary vascular changes, pulmonary hypertension, and carotid body (CB) enlargement. These phenotypic alterations provide a tool to test whether an oxygen sensor candidate is involved in an organism's response to environmental hypoxia. Here I evaluate the phenotypic evidence for several commonly considered oxygen sensor candidates. Germline mutations in NADPH oxidase, mitochondrial complexes I, III, IV, and heme oxygenase 2 genes cause different phenotypic consequences, suggesting distinct physiological roles rather than oxygen sensing. Germline mutations in VHL and HIF1 prolyl hydroxylase 2 genes cause polycythemia consistent with their role in oxygen homeostasis. However, it is unclear whether environmental variations affecting oxygen availability modify their phenotype, as would be expected from a defect in an oxygen sensor. Succinate dehydrogenase (SDH); mitochondrial complex II) germline mutations cause CB paragangliomas and there is evidence that the severity and the population genetics of paragangliomas may be influenced by altitude. Thus, from a phenotypic perspective, succinate dehydrogenase (SDH) appears to be a well-supported oxygen sensor candidate. It is suggested that a universal oxygen sensor candidate must be supported by evidence from multiple layers of biological complexity.

Expression and actions of HIF prolyl-4-hydroxylase in the rat kidneys

Hypoxia inducible factor (HIF) prolyl-4-hydroxylase domain-containing proteins (PHDs) promote the degradation of HIF-1alpha. Because HIF-1alpha is highly expressed in the renal medulla and HIF-1alpha-targeted genes such as nitric oxide synthase, cyclooxygenase, and heme oxygenase are important in the regulation of renal medullary function, we hypothesized that PHD regulates HIF-1alpha levels in the renal medulla and, thereby, participates in the control of renal Na(+) excretion. Using real-time RT-PCR, Western blot, and immunohistochemical analyses, we have demonstrated that all three isoforms of PHD, PHD1, PHD2, and PHD3, are expressed in the kidneys and that PHD2 is the most abundant isoform. Regionally, all PHDs exhibited much higher levels in renal medulla than cortex. A furosemide-induced increase in renal medullary tissue Po(2) significantly decreased PHD levels in renal medulla, whereas hypoxia significantly increased mRNA levels of PHDs in cultured renal medullary interstitial cells, indicating that O(2) regulates PHDs. Functionally, the PHD inhibitor l-mimosine (l-Mim, 50 mg x kg(-1) x day(-1) i.p. for 2 wk) substantially upregulated HIF-1alpha expression in the kidneys, especially in the renal medulla, and remarkably enhanced (by >80%) the natriuretic response to renal perfusion pressure in Sprague-Dawley rats. Inhibition of HIF transcriptional activity by renal medullary transfection of HIF-1alpha decoy oligodeoxynucleotides attenuated l-Mim-induced enhancement of pressure natriuresis, which confirmed that HIF-1alpha mediated the effect of l-Mim. These results indicate that highly expressed PHDs in the renal medulla make an important contribution to the control of renal Na(+) excretion through regulation of HIF-1alpha and its targeted genes.

Oxygen-sensing in tumors

PURPOSE OF REVIEW

Tumor hypoxia induces cancer cell treatment resistance, angiogenesis, invasiveness, and overall poor clinical outcome. Cellular adaptations to hypoxia are largely driven by hypoxia-induced alterations in gene transcription, mRNA translation, and protein stability. This review will summarize recent advances in the understanding of mammalian oxygen-sensing mechanisms in normal and cancerous cells.

RECENT FINDINGS

Specific molecular candidates have been identified that are involved in the primary sensing of hypoxia or its secondary consequences. Chief amongst these are the iron and 2-oxoglutarate-dependent dioxygenases that hydroxylate the alpha subunits of hypoxia-inducible transcription factors. This oxygen-dependent reaction, which prevents the transcription of many genes, is relieved under hypoxia. Evidence for the regulated expression and decay of the hypoxia-inducible transcription factor hydroxylating enzymes suggests that the sensitivity of transcriptional responses to hypoxia can be dynamically adjusted. Recent results also argue that these hydroxylating enzymes may be able to sense not only oxygen availability, but also the accumulation of bioenergetic intermediates and reactive oxygen species. In cancer cells, changes in these metabolites may accompany hypoxia or may occur independently. Several organellar compartments including plasma membrane, mitochondria and endoplasmic reticulum also appear to contribute to oxygen sensing through the generation of metabolites or through regulation of protein translation.

SUMMARY

Oxygen-sensing mechanisms induce prominent clinically relevant changes in cancer cells and tumor biology through the control of gene expression. Significant overlap exists between oxygen-sensing mechanisms and other metabolic and cell stress sensing pathways, which allows nonhypoxic cell stresses to activate hypoxia-inducible responses.

Mitochondrial disorders in renal tumors

As early as 1930, Warburg discovered that metabolic alterations were associated with carcinogenesis and that cancer cells fermented even in the presence of oxygen using glycolysis to fulfill their energy needs, though less efficiently than with respiration. The kidney requiring a very active energy production for its pumping functions has a high mitochondrial activity. Kidney tumors can exist either in relatively benign forms, as for example, in oncocytomas that are crowded with mitochondria or in very aggressive forms such as in clear cell renal carcinomas that exhibit strongly down-regulated mitochondrial activities. These carcinomas can produce metastases that are resistant to anti-mitotic drugs and current treatments only delay the fatal issue. In this review, the mitochondrial alterations observed in various forms of renal tumors will be discussed with the aim of understanding how the knowledge of mitochondrial impairment mechanisms could be helpful to develop new anti-cancer strategies.

Proteomic Analysis of Colorectal Cancer Reveals Alterations in Metabolic Pathways

Colorectal cancer is the second leading killer cancer worldwide and presently the most common cancer among males in Singapore. The study aimed to detect changes of protein profiles associated with the process of colorectal tumorigenesis to identify specific protein markers for early colorectal cancer detection and diagnosis or as potential therapeutic targets. Seven pairs of colorectal cancer tissues and adjacent normal mucosa were examined by two-dimensional gel electrophoresis at basic pH range (pH 7-10). Intensity changes of 34 spots were detected with statistical significance. 16 of the 34 spots were identified by MALDI-TOF/TOF tandem mass spectrometry. Changes in protein expression levels revealed a significantly enhanced glycolytic pathway (Warburg effect), a decreased gluconeogenesis, a suppressed glucuronic acid pathway, and an impaired tricarboxylic acid cycle. Observed changes in protein abundance were verified by two-dimensional DIGE. These changes reveal an underlying mechanism of colorectal tumorigenesis in which the roles of impaired tricarboxylic acid cycle and the Warburg effect may be critical.

HIF-1: hypoxia-inducible factor or dysoxia-inducible factor?

Hypoxia-inducible factor 1 (HIF-1) activates the transcription of genes involved in diverse aspects of cellular and integrative physiology, including energy metabolism, cell growth, survival, invasion, migration or angiogenesis. The activity of this transcription factor is known to be increased by hypoxia, but also by a growing number of apparently unrelated factors that can activate it even in nonhypoxic conditions. Here I propose a model in which an alteration in oxygen metabolism is the key cellular event involved in HIF-1 activation under hypoxic and nonhypoxic conditions. This new perspective unifies previously unrelated observations and predicts cellular processes and therapeutic strategies that may modify HIF-1 activity. This may have relevance, for instance, to cancer, as HIF-1 overexpression is observed in many human cancers and has been associated with increased patient mortality.

Hypobaric hypoxia affects endogenous levels of α-keto acids in murine heart ventricles

Alpha-keto acids have recently been identified as potent regulators of cellular adaptations to hypoxia. Their actual intracellular concentrations under such conditions are unknown. Here, we determined concentrations of alpha-ketobutyrate, alpha-ketoglutarate, alpha-ketoisocaproate, alpha-ketoisovalerate, alpha-keto-beta-methylvalerate, phenylpyruvate, and pyruvate by a recently developed ultra-sensitive fluorescence HPLC method in ventricular myocardium of mice exposed to hypobaric hypoxia for up to 3 weeks. We observed characteristic alterations of cardiac alpha-keto acid concentrations that are specific for individual alpha-keto acids, show significant side differences (right versus left ventricles), and are suited to trigger some of the cardiac metabolic and structural adaptations to chronic hypoxia.

Comparison of metabolic pathways between cancer cells and stromal cells in colorectal carcinomas: a metabolic survival role for tumor-associated stroma

Understanding tumor metabolism is important for the development of anticancer therapies. Immunohistochemical evaluation of colorectal adenocarcinomas showed that cancer cells share common enzyme/transporter activities suggestive of an anaerobic metabolism [high lactate dehydrogenase 5 (LDH5)/hypoxia-inducible factor alphas (HIFalphas)] with high ability for glucose absorption and lactate extrusion [high glucose transporter 1 (GLUT1)/monocarboxylate transporter (MCT1)]. The tumor-associated fibroblasts expressed proteins involved in lactate absorption (high MCT1/MCT2), lactate oxidation (high LDH1 and low HIFalphas/LDH5), and reduced glucose absorption (low GLUT1). The expression profile of the tumor-associated endothelium indicated aerobic metabolism (high LDH1 and low HIFalphas/LDH5), high glucose absorption (high GLUT1), and resistance to lactate intake (lack of MCT1). It is suggested that the newly formed stroma and vasculature express complementary metabolic pathways, buffering and recycling products of anaerobic metabolism to sustain cancer cell survival. Tumors survive and grow because they are capable of organizing the regional fibroblasts and endothelial cells into a harmoniously collaborating metabolic domain.