Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:1.17.3.2 (xanthine oxidase)
 8,383 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The involvement of protein kinase C in the initiation of free oxygen radical generation by rat leukocytes in response to the nematode Nippostrongylus brasiliensis was investigated. Inhibitors of protein kinase C, trifluoperazine and 1-(5-isoquinolinylsulfonyl)-2-methylpiperazine (H-7), inhibited free radical generation in response to N. brasiliensis in vitro. Neither inhibitor affected free radical generation by the cell-free xanthine/xanthine oxidase system, indicating that the agents did not scavenge free radicals; they also failed to affect leukocyte viability. Furthermore, activators of protein kinase C, the calcium ionophore A23187 and the diacylglycerol 1-oleoyl-2-acetyl-rac-glycerol (OAG), enhanced free radical generation by leukocytes in response to N. brasiliensis in vitro. Thus, protein kinase C apparently plays an important role in the initiation of free radical generation in response to N. brasiliensis; since free radicals may play a critical role in worm expulsion, this implies that protein kinase C may also be important in the rejection of N. brasiliensis from the small intestine of the rat.
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PMID:A role for protein kinase C in the production of free oxygen radicals in response to Nippostrongylus brasiliensis. 192 60

We have suggested that red blood cell proteolytic systems can degrade oxidatively damaged proteins, and that both damage and degradation are independent of lipid peroxidation (Davies, K. J. A., and Goldberg, A. L. (1987) J. Biol. Chem. 262, 8220-8226. These ideas have now been tested in cell-free extracts of rabbit erythrocytes and reticulocytes. Exposure to oxygen radicals or H2O2 increases the degradation of endogenous proteins in cell-free extracts, as in intact cells. Various radical-generating systems (acetaldehyde or xanthine + xanthine oxidase, ascorbic acid + iron, H2O2 + iron) and H2O2 alone enhanced the rates of proteolysis severalfold. Since these extracts were free of membrane lipids, protein damage and degradation must be independent of lipid peroxidation. An antioxidant buffer consisting of HEPES, glycerol, and dithiothreitol inhibited the increased proteolysis by 60-100%. Mannitol caused a 50-80% reduction in proteolysis suggesting that the hydroxyl radical (.OH), or a species with similar reactivity, may be the initiator of protein damage. When casein or bovine serum albumin were exposed to .OH (generated by H2O2 + Fe2+, or COCo radiation) these proteins were degraded up to 50 times faster than untreated proteins during subsequent incubations with red cell extracts. Mannitol inhibited this increase in proteolysis only if present during .OH exposure; mannitol did not affect the degradative system. Although ATP increased the degradation of untreated proteins 4- to 6-fold in reticulocyte extracts, it had little or no effect on the degradation of proteins exposed to .OH. ATP also did not stimulate hydrolysis of .OH-treated proteins in erythrocyte extracts. Leupeptin did not affect the degradative processes in either extract; thus lysosomal or Ca2+-activated thiol proteases were not involved. We propose that red cells contain a soluble, ATP-independent proteolytic pathway which may protect against the accumulation of proteins damaged by .OH or other active oxygen species.
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PMID:Proteins damaged by oxygen radicals are rapidly degraded in extracts of red blood cells. 359 73

Inhibition of conversion from IMP to uric acid, which interferes with both spectrophotometric and radioisotopic assays of IMP dehydrogenase, by addition of allopurinol (0.1 mM), an inhibitor of xanthine oxidase, to the incubation system made it possible to determine the enzyme activity in crude liver extracts. With this improved assay method, the regulatory properties of the enzyme in crude extracts of liver and Yoshida sarcoma ascites cells were examined. In both tissues IMP dehydrogenase was found in the postmicrosomal supernatant. However, further centrifugation resulted in precipitation of the enzyme, the enzyme from Yoshida sarcoma ascites cells being precipitated more easily than that from rat liver. It was also found that IMP dehydrogenase activity increased during liver regeneration and that this increase was associated with the precipitate from the postmicrosomal fraction. These findings suggest that such a large sedimentable complex including IMP dehydrogenase might be formed in relation to cell growth. Most of the enzyme activity in rat liver and Yoshida sarcoma ascites cells was extracted in the supernatant obtained by centrifugation at 105,000 X g for 4 h after treatment of tissue homogenates with 1 M KCl, 0.75 M (NH4)2SO4, 2 M dimethylsulfoxide, 2 M KSCN, 25% glycerol, or 0.8 M guanidine-HCl. Treatment with 2% deoxycholate, 2% Triton X-100 or 2 M urea gave limited extraction. The enzyme was retained on a phenyl-Sepharose CL-6B or octyl-Sepharose CL-6B column and eluted with 0.8 M guanidine-HCl. These results suggested that the enzyme molecule has not only ionic but also hydrophobic domains, through which it interacts with other molecules of the enzyme itself and/or postmicrosomal cellular components.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:IMP dehydrogenase. I. Studies on regulatory properties of crude tissue extracts based on an improved assay method. 614 Feb 63

DMSO is a hydroxyl radical scavenger that inhibits platelet aggregation in vivo in injured microvessels, and that also inhibits the dilation displayed by pial arterioles following a local injury. The injurious stimulus is a result of local excitation of circulating sodium fluorescein by an appropriate light source. It is likely that this excitation results in the generation of hydroxyl radicals, which are the immediately injurious agent. This postulate is supported not only by the inhibitory effect of DMSO but also by the inhibitory effect of glycerol, another hydroxyl scavenger. Both the hypothesis that DMSO inhibits hydroxyl-mediated dilation, and the hypothesis that free radicals can dilate pial arterioles, are further supported by direct evidence from studies employing local application of xanthine oxidase plus acetaldehyde. This well established radical-generating system dilated pial arterioles. The dilation was inhibited by the local application of superoxide dismutase and also by local application of catalase, as well as by intraperitoneal administration of DMSO. Since DMSO failed to inhibit the dilation produced by increases of inspired CO2, we believe that the inhibitory effect of DMSO on the other dilating stimuli in these studies was due to the hydroxyl scavenging properties of this drug, rather than to other nonspecific effects.
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PMID:Dimethyl sulfoxide effects on platelet aggregation and vascular reactivity in pial microcirculation. 641 Sep 63

Generation of H2O2 by rat liver mitochondria with choline, glycerol 1-phosphate and proline as substrates has been shown by using high-concentration phosphate buffer. Rates obtained under these conditions were higher and more consistent as compared with the earlier reports with high-concentration mannitol/sucrose/Tris buffer. Sulphate ions could replace phosphate indicating a requirement for a high concentration of oxygen-containing anions. H2O2 generation was dependent on the presence of native mitochondria and substrate. Maximal rates with various substrates were found to be the same as with succinate. Values of Km and Vmax for H2O2 generation were considerably less than those obtained for respective dehydrogenase activities, measured by dye reduction. Scavengers of O2-. and OH. inhibited generation of H2O2. ATP, ADP, thyronine derivatives and a number of phenolic compounds also showed very potent inhibitory effects of H2O2 generation, whereas phenyl compound had no effect. Phenolic compounds did not have any effect on mitochondrial superoxide dismutase and choline dehydrogenase activities as well as on O2-. generation by the xanthine-xanthine oxidase system. Inhibition by phenolic compounds may have potential for regulation of the intracellular concentration of H2O2, that is not considered to have a "second messenger' function.
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PMID:Inhibition of H2O2 generation in rat liver mitochondria by radical quenchers and phenolic compounds. 730 14

Hypoxia-induced hepatocyte injury results not only from ATP depletion but also from reductive stress and oxygen activation. Thus the NADH/NAD+ ratio was markedly increased in isolated hepatocytes maintained under 95% N2/5% CO2 in Krebs-Henseleit buffer well before plasma membrane disruption occurred. Glycolytic nutrients fructose, dihydroxyacetone or glyceraldehyde prevented cytotoxicity, restored the NADH/NAD+ ratio, and prevented complete ATP depletion. However, the NADH generating nutrients sorbitol, xylitol, glycerol and beta-hydroxybutyrate enhanced hypoxic cytotoxicity even though ATP depletion was not affected. On the other hand, NADH oxidising metabolic intermediates oxaloacetate or acetoacetate prevented hypoxic cytotoxicity but did not affect ATP depletion. Restoring the cellular NADH/NAD+ ratio with the artificial electron acceptors dichlorophenolindophenol and Methylene blue also prevented hypoxic injury and partly restored ATP levels. Ethanol which further increased the cellular NADH/NAD+ ratio increased by hypoxia also markedly increased toxicity whereas acetaldehyde which restored the normal cellular NADH/NAD+ ratio, prevented toxicity even though hypoxia induced ATP depletion was little affected by ethanol or acetaldehyde. The viability of hypoxic hepatocytes is therefore more dependent on the maintenance of normal redox homeostasis than ATP levels. GSH may buffer these redox changes as hypoxia caused cell injury much sooner with GSH depleted hepatocytes. Hypoxia also caused an intracellular release of free iron and cytotoxicity was prevented by desferoxamine. Furthermore, increasing the cellular NADH/NAD+ ratio markedly increased the intracellular release of iron. Hypoxia-induced hepatocyte injury was also prevented by oxypurinol, a xanthine oxidase inhibitor. Polyphenolic antioxidants or the superoxide dismutase mimic, TEMPO partly prevented cytotoxicity suggesting that reactive oxygen species contributed to the cytotoxicity. The above results suggests that hypoxia induced hepatocyte injury results from sustained reductive stress and oxygen activation.
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PMID:Modulating hypoxia-induced hepatocyte injury by affecting intracellular redox state. 748 48

By correlating lactate/pyruvate ratios and ATP levels, cytotoxicity induced by the mitochondrial respiratory inhibitors or hypoxia:reoxygenation injury can be attributed not only to ATP depletion but also to reductive stress and oxygen activation. Thus hypoxia, cyanide or antimycin markedly increases reductive stress, non-heme Fe release and H2O2 formation in hepatocytes. Cytotoxicity was partly prevented with the ferric chelator desferoxamine, the xanthine oxidase inhibitor oxypurinol and the hydrogen peroxide scavenger glutathione. No lipid peroxidation could be detected and phenolic anti-oxidants had little effect. However, polyphenolic antioxidants or the superoxide dismutase mimics TEMPO or TEMPOL partly prevented cytotoxicity. Furthermore, increasing the hepatocyte NADH/NAD+ ratio with NADH generating compounds such as ethanol, glycerol, or beta-hydroxybutyrate markedly increased cytotoxicity (prevented by desferoxamine) and further increased the intracellular release of non-heme iron. Cytotoxicity could be prevented by glycolytic substrates (eg. fructose, dihydroxyacetone, glyceraldehyde) or the NADH utilising substrates acetoacetate or acetaldehyde which decreased the reductive stress and prevented intracellular iron release. These results suggest that liver injury resulting from insufficient respiration involves reductive stress which releases intracellular Fe, converts xanthine dehydrogenase to xanthine oxidase and causes mitochondrial oxygen activation. The cell's antioxidant defences are compromised and ATP catabolism contributes to oxygen activation.
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PMID:Hepatocyte injury resulting from the inhibition of mitochondrial respiration at low oxygen concentrations involves reductive stress and oxygen activation. 758 49

Microsomes and reconstituted systems containing cytochrome P450 can oxidize glycerol to formaldehyde in a reaction catalyzed by an oxidant produced from the interaction of nonheme iron with H2O2. To evaluate the mechanism for this oxidation, the generation of glycerol radicals by various systems was compared to rates of formaldehyde production from glycerol. Photolysis of H2O2, oxidation of xanthine by xanthine oxidase in the presence of iron catalysts, or NADPH-dependent microsomal electron transfer in the presence of ferric-EDTA produced hydroxyl radicals. In the presence of glycerol these reaction systems produced DMPO-glycerol radical adducts which were detected by ESR spectroscopy. Despite the production of .OH and glycerol spin-trapped adducts by these reaction systems, very low amounts or nondetectable amounts of formaldehyde were produced from the glycerol. However, significant amounts of formaldehyde were observed when microsomes were incubated in the presence of ferric ammonium sulfate or ferric-ATP, although .OH production was lower with these iron catalysts than with ferric-EDTA. These results fail to support correlation between .OH production and oxidation of glycerol to formaldehyde. Under conditions in which glycerol was oxidized to formaldehyde, no glycerol radical species could be observed with DMPO as the spin-trapping agent. These results suggest the oxidant (not .OH) derived from the interaction of H2O2 with iron apparently cleaves glycerol to formaldehyde without the formation of a radical intermediate. Alternatively, the radical intermediate may be produced at a too low concentration to be detected or the radical intermediate may not be formed as a free species and therefore cannot be spin-trapped.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Oxidation of glycerol to formaldehyde by microsomes: are glycerol radicals produced in the reaction pathway? 806 25

We studied the toxicity of free radicals to human mesothelial cells in vitro and to the peritoneal membrane of rats during peritoneal dialysis. Free radicals cause damage to mesothelial cells as measured by release of cytosolic markers such as 86Rb and lactate dehydrogenase. Vitamin E neutralized the toxic effect of free radicals in vitro. Human mesothelial cells exposed over 6 h to a mixture of essential and nonessential amino acids in medium are more vulnerable to the cytotoxic effect of free radicals than control cells exposed to medium alone. Cells exposed previously to glucose or glycerol are less vulnerable than controls. In rats free radicals generated intraperitoneally by a xanthine-xanthine oxidase system induce changes in peritoneal permeability similar to those observed during peritonitis: loss of ultrafiltration, increased glucose absorption from the dialysate and augmented transperitoneal loss of albumin. In addition lipids in the peritoneum became peroxidated. The addition of vitamin E to the peritoneal fluid with xanthine-xanthine oxidase prevents peroxidation of lipids and the subsequent loss of ultrafiltration. Our results show that free radicals may exert a potentially toxic effect on the peritoneal membrane during peritonitis. In such circumstances the addition of free radical scavenger to the dialysis fluid may preserve intact structure and function of peritoneum.
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PMID:Toxicity of free radicals to mesothelial cells and peritoneal membrane. 841 93

Iron catalyzed free radical formation and lipid peroxidation are accepted mechanisms of heme protein-induced acute renal failure. However, the source(s) of those free radicals which trigger lipid peroxidation in proximal tubular cells remains unknown. This study tested the potential involvement of mitochondrial electron transport, xanthine oxidase activity, and arachidonic acid metabolism in the heme-induced peroxidative state. The impact of cytosolic Ca2+ loading also was assessed. Rhabdomyolysis was induced in mice by glycerol injection, and two hours later heme-laden proximal tubular segments (PTS) were isolated for study. PTS from normal mice served as controls. During 30 to 60 minute incubations, heme loaded PTS developed progressive cytotoxicity (LDH release) and iron-dependent lipid peroxidation (malondialdehyde, MDA, generation; inhibited by deferoxamine). Site 2 (antimycin A) or site 3 (cyanide, hypoxia) mitochondrial respiratory chain inhibition completely blocked lipid peroxidation, whereas site 1 inhibition (rotenone) doubled its extent (presumably by shunting NADH through NADH dehydrogenase, a free radical generating system). Conversely, these agents did not substantially alter MDA in normal PTS. Normal and heme loaded PTS developed comparable degrees of LDH release during respiratory blockade irrespective of increased or decreased MDA production (indicating that lipid peroxidation was not a critical determinant of cell death). Neither increasing free arachidonic acid (PLA2 treatment) nor adding cyclooxygenase/lipoxygenase/cytochrome p450 inhibitors conferred a consistent protective effect. Altering free Ca2+ status (chelators; ionophore addition) and xanthine oxidase inhibition had no discernible impacts. Despite mitochondrial free radical production, mitochondrial function, as assessed by the ATP/ADP ratio, seemingly remained intact. In conclusion, (1) the terminal mitochondrial respiratory chain is the dominant source of free radicals which trigger PTS lipid peroxidation; (2) iron is a required secondary factor; (3) although mitochondria fuel lipid peroxidation, they do not appear to be critical targets of the heme-induced oxidant attack.
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PMID:Mitochondrial free radical production induces lipid peroxidation during myohemoglobinuria. 864 15


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