EC:1.6.3.1 - FACTA Search

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Query: EC:1.6.3.1 (NADPH oxidase)
11,281 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Oxygen sensors in the body induce various cell activities to avoid any mismatch between oxygen demand and oxygen supply and to maintain an optimal level of oxygen partial pressure (PO2) in various organs. Oxygen sensing seems to be a well conserved process among procaryontic and eucaryontic cells. The molecular mechanism of oxygen sensing is unknown, but it has been suggested that a hemeprotein is involved that does not participate in the mitochondrial energy production. As examplified on the carotid body and on erythropoietin producing HepG2 cells, a cytochrome b was described for the NAD(P)H oxidase of neutrophiles might be an attractive candidate for this hemeprotein. It is hypothesised that hydrogen peroxide (H2O2) produced by this cytochrome b in direct correlation with cellular PO2, serves as a second messenger to regulate potassium channels or gene expression. One might forsee, that this new concept of oxygen sensing could have an impact on all processes in physiology and pathophysiology which are dealing with reactive oxygen intermediates.
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PMID:Mechanisms and meaning of cellular oxygen sensing in the organism. 815 48

Reduced oxygenation of a variety of cells results in transcriptional upregulation of several genes, including the hematopoietic hormone erythropoietin, the angiogenic vascular endothelial growth factor (VEGF), and glycolytic enzymes such as aldolase. Recently, the heme protein cytochrome b558 of the nicotinamide adenine dinucleotide phosphate (NADPH) oxidase complex has been proposed as a key component of the oxygen-sensing mechanism. Cytochrome b558 consists of the p22phox and gp91phox subunits and is essential for superoxide generation in phagocytes and B lymphocytes. Mutations in these subunits result in cytochrome b558-negative chronic granulomatous disease (cytb- CGD), an inherited disorder in humans characterized by reduced microbicidal activity due to deficient superoxide generation. To test whether NADPH oxidase is involved in oxygen sensing, we exposed wild-type B-cell lines as well as cytb- CGD-derived B cell lines, deficient in either p22phox or gp91phox, to hypoxia (1% oxygen) or CoCl2 (100 mumol/L) and compared the mRNA levels of VEGF and aldolase with the untreated controls. Northern blot analysis revealed unimpaired basal and inducible expression of VEGF and aldolase mRNA in all four cytb- CGD-derived B-cell lines compared with wild-type cells. Furthermore, reconstitution of cytochrome b558 expression in cytb- CGD-derived B cells by transfection with p22phox or gp91phox expression vectors did not modify VEGF and aldolase mRNA expression. Thus, cytochrome b558 of the NADPH oxidase complex appears not to be essential for hypoxia-activated gene expression and can be excluded as a candidate for the putative universal oxygen sensor.
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PMID:Hypoxic induction of gene expression in chronic granulomatous disease-derived B-cell lines: oxygen sensing is independent of the cytochrome b558-containing nicotinamide adenine dinucleotide phosphate oxidase. 855

In kidney and liver, fibroblasts and fibroblast-like cells, respectively, are sources of erythropoietin (Epo) formation, and these cells also bear a number of other similarities. Renal Epo expression is localized in peritubular type 1 fibroblasts of the cortical labyrinth, and in the liver, apart from parenchymal cells, transcription is found in Ito cells. Both the renal peritubular cells and Ito cells contain ecto-5'-nucleotidase (5'NT). It had been suggested that 5'NT is involved in the oxygen sensing mechanism via a hydrolysis of AMP to adenosine, which in turn may stimulate EPO synthesis. However, the molecular mechanism of the cellular response to hypoxia is currently not well understood. Based on the notion that a heme protein probably acts as the oxygen sensor, it has recently been proposed that a b-type cytochrome as part of the neutrophil NADPH oxidase may influence intracellular superoxide levels depending on local oxygen tension. Superoxide levels were otherwise shown to determine the EPO production in hepatoma cell lines. By double immunofluorescence labeling the alpha-subunit of cytochrome b558 (alpha-SU) and 5'NT were simultaneously localized in rat kidney and liver, and in the kidney Epo mRNA and alpha-SU were double-labeled. Positive signal for alpha-SU was found in the majority of renal peritubular fibroblasts in the cortex and outer medulla, and in Ito cells. In both organs, the cells that coexpress 5'NT and Epo mRNA also contain an immunoreactivity for alpha-SU. In these cells, cytochrome b558 as part of an NADPH oxidase may be involved in a presumptive oxygen sensing mechanism using H2O2 as a possible second messenger for EPO gene regulation.
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PMID:Immunohistochemical colocalization of the alpha-subunit of neutrophil NADPH oxidase and ecto-5'-nucleotidase in kidney and liver. 902 26

Cobalt and desferrioxamine, like hypoxia, stimulate the production of erythropoietin in HepG2 cells. It is believed that cobalt as well as desferrioxamine interact with the central iron atom of heme proteins by changing their redox state similar to hypoxia. A subsequent decrease of the intracellular H2O2 levels under hypoxia was presumed to be the key event for stimulating erythropoietin production. We therefore investigated whether cobalt and desferrioxamine control the intracellular H2O2 levels that regulate gene expression by interacting with hemeproteins. Deconvolution of light absorption spectra revealed respiratory heme proteins such as cytochrome c, b558 and cytochrome aa3, as well as cytochrome b558, which is a nonrespiratory heme protein found in HepG2 cells. Whereas respiratory heme proteins are located in mitochondria, cytochrome b558 similar to the one described for the neutrophil NADPH oxidase can be visualized in the cell membrane of HepG2 cells by immunohistochemistry. Incubation with cobalt (100 microM/24 hr) interacts predominantly with cytochrome b558 and cytochrome b558. The interaction of cobalt with the respiratory chain results in an increased oxygen consumption of HepG2 cells as revealed by PO2 microelectrode measurements. Desferrioxamine (130 microM/24 hr), however has no influence on the cytochromes. In response to an external application of NADH (1 mM), the membrane bound cytochrome b558 produces two times more O2- than to the external NADPH (1 mM) application. Neither desferrioxamine not cobalt has any influence on the NADH stimulated O2- generation. Incubation with cobalt or with desferrioxamine, however, leads to a decrease of the intracellular H2O2 level as revealed by the dihydrorhodamine 123 technique, perhaps causing the well-known enhanced erythropoietin production. The cobalt-induced H2O2 decrease seems to be caused by an increased activity of the glutathion peroxidase that is also induced under hypoxia. Desferrioxamine, however, leads to an apparent H2O2 decrease only because it seems to inhibit the iron catalyzed reaction of H2O2 with dihydrorhodamine 123, hinting at the occurrence of the Fenton reaction in HepG2 cells. Therefore, it must be determined whether or not degradation products of H2O2 by the Fenton reaction suppress erythropoietin production under normoxia.
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PMID:Cobalt and desferrioxamine reveal crucial members of the oxygen sensing pathway in HepG2 cells. 902 27

The physiological regulation of the red cell mass depends upon enhanced transcription of the erythropoietin (Epo) gene in response to hypoxia. Studies of Epo gene expression have been useful in investigating the mechanism by which cells and tissues sense hypoxia and respond with biologically appropriate alterations in gene expression. It is likely that oxygen sensing involves a heme protein in which cobalt and nickel can substitute for iron in the porphyrin ring. Indirect evidence suggests that the sensor is present in all cells and is a multi-subunit assembly containing an NAD(P)H oxidase capable of generating peroxide and reactive oxygen intermediates, which serve as signaling molecules. The up-regulation of Epo gene transcription by hypoxia is mediated by at least two known DNA-binding transcription factors, hypoxia-inducible factor 1 (HIF-1) and hepatic nuclear factor 4 (HNF-4), which bind to cognate response elements in a critical 3' enhancer approximately 50 bp in length. HIF-1 binding is induced by hypoxia as well as by cobalt. The activation of HIF-1 by hypoxia depends upon the selective protection of its alpha subunit from ubiquitin-dependent proteolysis by means of a mechanism that involves redox chemistry and perhaps phosphorylation. HNF-4 is an orphan nuclear receptor that is constitutively expressed in kidney and liver and which cooperates with HIF-1 to give maximal hypoxic induction. In hypoxic cells, p300 or a related family member forms a macromolecular assembly with HIF-1 and HNF-4, enabling transduction from the Epo 3' enhancer to the apparatus on the promoter responsible for the initiation of transcription.
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PMID:Erythropoietin: a model system for studying oxygen-dependent gene regulation. 951 May 30

In order to elucidate the components of the oxygen sensory complex in HepG2 cells which regulates the production of erythropoietin, we have microinjected recombinant variants of the human small GTP-binding protein hRac1 and measured their effects on the production of reactive oxygen species (ROS) by the dihydrorhodamine-123 technique. The dominant-negative mutant hRac1(T17N) inhibits the NADH-stimulated production of ROS in HepG2 cells, whereas the constitutively activated hRac1(G12V) leads to an increase in intracellular ROS concentration. Reverse transcriptase PCR analysis showed that the hRac1, but not the hRac2, gene is expressed in HepG2 cells. These results demonstrate that hRac1, and not hRac2, is involved in the regulation of ROS production in HepG2 cells and suggest that hRac1 specifically functions in the non-phagocytic NAD(P)H oxidase complex.
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PMID:Rac1, and not Rac2, is involved in the regulation of the intracellular hydrogen peroxide level in HepG2 cells. 957 45

The responses to acute and chronic hypoxia begin with oxygen sensing, and this historical perspective is written in line with this concept. The earliest pertinent work started with studies on fermentation in yeast in the 17th century, before the discovery of oxygen. It required 200 yr to localize the oxygen sensing within the cells and another 100 yr to discover the cellular oxidation reactions. Today, the consensus is that the mitochondrial respiratory chain is in part the site of oxygen sensing. In addition, membrane-bound NAD(P)H oxidase possibly takes part in oxygen sensing. Oxygen-sensing mechanisms occur in a tissue-specific fashion. For example, the carotid body responds to hypoxia promptly by eliciting a ventilatory response, whereas erythropoietin production in response to hypoxia requires more time, involving new expression of genes. The mechanism has therefore moved from the cells to genes.
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PMID:Historical perspectives of cellular oxygen sensing and responses to hypoxia. 1074 43

Oxygen sensing is essential for homeostasis in all aerobic organisms, but its mechanism is poorly understood. Data suggest that a phagocytic-like NAD(P)H oxidase producing reactive oxygen species serves as a primary sensor for oxygen. We have characterized a source of superoxide anions in the kidney that we refer to as a renal NAD(P)H oxidase or Renox. Renox is homologous to gp91(phox) (91-kDa subunit of the phagocyte oxidase), the electron-transporting subunit of phagocytic NADPH oxidase, and contains all of the structural motifs considered essential for binding of heme, flavin, and nucleotide. In situ RNA hybridization revealed that renox is highly expressed at the site of erythropoietin production in the renal cortex, showing the greatest accumulation of renox mRNA in proximal convoluted tubule epithelial cells. NIH 3T3 fibroblasts overexpressing transfected Renox show increased production of superoxide and develop signs of cellular senescence. Our data suggest that Renox, as a renal source of reactive oxygen species, is a likely candidate for the oxygen sensor function regulating oxygen-dependent gene expression and may also have a role in the development of inflammatory processes in the kidney.
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PMID:Identification of renox, an NAD(P)H oxidase in kidney. 1086 23

NADPH oxidase is classically regarded as a key enzyme of neutrophils, where it is involved in the pathogenic production of reactive oxygen species. However, NADPH oxidase-like enzymes have recently been identified in non-neutrophil cells, supporting a separate role for NADPH-oxidase derived oxygen species in oxygen sensitive processes. This article reviews the current literature surrounding the potential role of NADPH oxidase in the oxygen sensing processes which underlie hypoxic pulmonary vasoconstriction, systemic vascular smooth muscle proliferation, carotid and airways chemoreceptor activation, erythropoietin gene expression, and oxytropic responses of plant cells.
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PMID:NADPH oxidase: a universal oxygen sensor? 1102 Jun 63

During phagocytosis, gp91(phox), the catalytic subunit of the phagocyte NADPH oxidase, becomes activated to produce superoxide, a precursor of microbicidal oxidants. Currently increasing evidence suggests that nonphagocytic cells contain similar superoxide-producing oxidases, which are proposed to play crucial roles in various events such as cell proliferation and oxygen sensing for erythropoiesis. Here we describe the cloning of human cDNA that encodes a novel NAD(P)H oxidase, designated NOX4. The NOX4 protein of 578 amino acids exhibits 39% identity to gp91(phox) with special conservation in membrane-spanning regions and binding sites for heme, FAD, and NAD(P)H, indicative of its function as a superoxide-producing NAD(P)H oxidase. The membrane fraction of kidney-derived human embryonic kidney (HEK) 293 cells, expressing NOX4, exhibits NADH- and NADPH-dependent superoxide-producing activities, both of which are inhibited by diphenylene iodonium, an agent known to block oxygen sensing, and decreased in cells expressing antisense NOX4 mRNA. The human NOX4 gene, comprising 18 exons, is located on chromosome 11q14.2-q21, and its expression is almost exclusively restricted to adult and fetal kidneys. In human renal cortex, high amounts of the NOX4 protein are present in distal tubular cells, which reside near erythropoietin-producing cells. In addition, overexpression of NOX4 in cultured cells leads to increased superoxide production and decreased rate of growth. The present findings thus suggest that the novel NAD(P)H oxidase NOX4 may serve as an oxygen sensor and/or a regulator of cell growth in kidney.
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PMID:A novel superoxide-producing NAD(P)H oxidase in kidney. 1103 35

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