Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P47989 (xanthine oxidase)
 8,633 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Our previous studies had suggested a link between bile salt stimulation of colonic epithelial proliferation and the release and oxygenation of arachidonate via the lipoxygenase pathway. In the present study, we examined the role of reactive oxygen versus end products of arachidonate metabolism via the cyclooxygenase and lipoxygenase pathways in bile salt stimulation of rat colonic epithelial proliferation. Intracolonic instillation of 5 mM deoxycholate increased mucosal ornithine decarboxylase activity and [3H]thymidine incorporation into DNA. Responses to deoxycholate were abolished by the superoxide dismutase mimetic CuII (3,5 diisopropylsalicylic acid)2 (CuDIPS), and by phenidone or esculetin, which inhibit both lipoxygenase and cyclooxygenase activities. By contrast, indomethacin potentiated the response. Phenidone and esculetin suppressed deoxycholate-induced increases in prostaglandin E2 (PGE2), leukotriene B4 (LTB4), and 5, 12, and 15-hydroxyeicosatetraenoic acid (HETE), whereas CuDIPS had no effect. Indomethacin suppressed only PGE2. Deoxycholate (0.5-5 mM) increased superoxide dismutase sensitive chemiluminescence 2-10-fold and stimulated superoxide production as measured by cytochrome c reduction in colonic mucosal scrapings or crypt epithelium. Bile salt-induced increases in chemiluminescence were abolished by CuDIPS, phenidone, and esculetin, but not by indomethacin. Intracolonic generation of reactive oxygen by xanthine-xanthine oxidase increased colonic mucosal ornithine decarboxylase activity and [3H]thymidine incorporation into DNA approximately twofold. These effects were abolished by superoxide dismutase. The findings support a key role for reactive oxygen, rather than more distal products of either the lipoxygenase or cyclooxygenase pathways, in the stimulation of colonic mucosal proliferation by bile salts.
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PMID:Role of reactive oxygen in bile salt stimulation of colonic epithelial proliferation. 300 68

Mitomycin C (MC) is a naturally occurring anticancer agent which has been shown to be more cytotoxic to hypoxic tumor cells than to their aerobic counterparts. The mechanism of action of this agent is thought to involve biological reductive activation, to a species that alkylates DNA. A comparison of the cytotoxicity of MC to EMT6 tumor cells with that of the structural analogues porfiromycin (PM), N-(N',N'-dimethylaminomethylene)amine analogue of mitomycin C (BMY-25282), and N-(N',N'-dimethylaminomethylene)amine analogue of porfiromycin (BL-6783) has demonstrated that PM is considerably less cytotoxic to aerobic EMT6 cells than MC, whereas BMY-25282 and BL-6783 are significantly more toxic. The relative abilities of each of these compounds to generate oxygen free radicals following biological activation were measured. Tumor cell sonicates, reduced nicotinamide adenine dinucleotide phosphate-cytochrome c reductase, xanthine oxidase, and mitochondria were used as the biological reducing systems. All four mitomycin antibiotics produced oxygen radicals following biological reduction, a process that may account for the aerobic cytotoxicity of agents of this class. The generation of relative amounts of superoxide and hydroxyl radical were also measured in EMT6 cell sonicates. BMY-25282 and BL-6783 produced significantly greater quantities of oxygen free radicals with the EMT6 cell sonicate, reduced nicotinamide adenine dinucleotide phosphate-cytochrome c reductase, and mitochondria than did MC and PM. In contrast, BMY-25282 and BL-6783 did not generate detectable levels of free radicals in the presence of xanthine oxidase, whereas this enzyme was capable of generating free radicals with MC and PM as substrates. MC consistently produced greater amounts of free radicals than PM with all of the reducing systems. BMY-25282, BL-6783, and MC all generated hydroxyl radicals, while PM did not appear to form these radicals. The findings indicate that a correlation exists between the ability of the mitomycin antibiotics to generate oxygen radicals and their cytotoxicity to aerobic EMT6 tumor cells.
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PMID:Generation of reactive oxygen radicals through bioactivation of mitomycin antibiotics. 301 Dec 50

The antitumor antibiotic mitomycin C is shown to form a covalent complex with calf thymus DNA under anaerobic conditions in the presence of either NADPH cytochrome c reductase/NADPH, xanthine oxidase/NADH, or the chemical reducing system H2/PtO2. Digestion of the complex with DNase I/snake venom diesterase/alkaline phosphatase yields a single mitomycin deoxyguanosine adduct as the major DNA alkylation product, identified as N2-(2'' beta,7''-diaminomitosen-1'' alpha-yl) 2'-deoxyguanosine (Structure 2). Two minor adducts, 2-5% each of the total adduct pool, are isolated and identified as the 1'' beta stereoisomer of 2 (Structure 3), and 10''-decarbamoyl-2 (Structure 7). The same results were obtained with M13 DNA and poly(dG-dC).poly(dG-dC); however, in the latter case, a minor adduct apparently possessing two deoxyguanosine and one mitomycin unit is isolated. Digestion of the covalent mitomycin-calf thymus DNA complex with nuclease P1 yields four dinucleotide adducts, all of which consist of 2 linked at its 3' end to each of the four possible 5' nucleotides (A, T, G, and C). Upon treatment of each dinucleotide adduct with snake venom diesterase/alkaline phosphatase, 2 is released along with the corresponding free nucleoside. In apparent conflict with the present results, previous reports from another laboratory have indicated that modification of calf thymus DNA by mitomycin C under conditions identical to those described here result in the isolation of three mitomycin C mononucleotide adducts possessing linkages of the drug to N2 and O6 of guanine and N6 of adenine. Evidence is shown suggesting that the latter adducts are actually three of the above four dinucleotide derivatives of 2 obtained independently by us and, thus, all of them in fact possess an identical N2-mitosenylguanine adduct moiety. Model-building studies indicate an excellent fit of the guanine N2-linked drug molecule inside the minor groove of B-DNA with no appreciable distortion of the DNA structure.
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PMID:Reaction of DNA with chemically or enzymatically activated mitomycin C: isolation and structure of the major covalent adduct. 301 44

Dinitropyrenes are contaminants in diesel emissions that are mutagenic in bacteria and mammalian cells, and tumorigenic in laboratory animals. In this project, we investigated the factors that contributed to the extreme genotoxicity of dinitropyrenes in bacteria and determined if these factors were important in mammalian cells. Xanthine oxidase, a mammalian nitroreductase, catalyzed the conversion of the dinitropyrenes to DNA-bound products, but the level of binding did not exceed that observed with 1-nitropyrene. This suggested that factors in addition to nitroreduction were important in the metabolic activation of dinitropyrenes. 1-Nitro-6-nitrosopyrene and 1-nitro-8-nitrosopyrene were synthesized and reacted with DNA under reducing conditions. The same C8-substituted deoxyguanosine adducts were formed that were found in the xanthine oxidase-catalyzed reactions, which confirmed that incubation with this nitroreductase generated reactive N-hydroxy arylamine intermediates. In incubations with rat and human liver microsomes and cytosol, 1-nitropyrene and 1,3-dinitropyrene were reduced to a lesser extent than 1,6- and 1,8-dinitropyrene, which was in accord with their relative mutagenicities. Each of the cytosolic incubations were similar in that oxygen decreased aminopyrene, but not nitrosopyrene, formation. The data indicated that reduced derivatives of the nitrosopyrenes were redox cycling with oxygen, which decreased cytosolic aminopyrene formation. In cytosolic incubations, oxygen inhibited the reduction of 1-nitropyrene and 1,3-dinitropyrene to a greater extent than 1,6- and 1,8-dinitropyrene. By comparison, in microsomal investigations, the nitroreduction of each nitrated pyrene was equally oxygen-sensitive. This apparently was caused by the initial nitroanion radicals reacting with oxygen to decrease nitrosopyrene formation. Although more extensive nitroreduction of each compound was detected in anaerobic incubations, aerobic reduction of these compounds did occur and may be important during in vivo exposure to nitrated pyrenes. When rat liver cytosol was incubated with the nitrated pyrenes, very low levels of DNA binding were detected. Addition of acetyl coenzyme A (AcCoA) to these incubations increased the binding of the dinitropyrenes 20- to 40-fold, while the binding of 1-nitropyrene was not affected. The extent of AcCoA- dependent binding of the dinitropyrenes reflected the amount of nitroreduction; however, the increase in binding did not occur with dog liver cytosol, which was known to be deficient in N-acetylases. These results indicated that cytosolic nitroreductases catalyzed the formation of N-hydroxy arylamine intermediates, which in the case of dinitropyrenes were converted to reactive N-acetoxy arylamines by cytosolic AcCoA-dependent acetylases.
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PMID:The metabolic activation and DNA adducts of dinitropyrenes. 307 23

After anaerobic reductive activation by either NADPH cytochrome P-450 reductase (EC 1.6.2.4) or xanthine oxidase (EC 1.2.3.2), mitomycin C readily alkylated DNA. When the mitomycin C-alkylated DNA is digested by DNase, snake venom phosphodiasterase, and alkaline phosphatase, only partial release of the monofunctionally linked mitomycin C nucleotide adduct occurs. Cross-linked adducts are not released into dinucleotides but resist nuclease digestion and remain in oligonucleotides and insoluble precipitates. Kinetic analyses show that the nuclease-resistant fraction which is indicative of DNA cross-linking by mitomycin C takes place quite readily. This nuclease-resistant fraction is particularly significant when the amount of total bound mitomycin C is less than 15 mumol/mmol of DNA. The cross-linked mitomycin C product accounts for more than half of the total alkylation under all pH conditions tested. Our data suggest that particular DNA sites are available for DNA cross-linking by mitomycin C, and these sites are probably the preferred and immediate alkylating targets. Furthermore, DNA cross-links by mitomycin C are not the secondary product of monofunctional adducts. Activity of both flavoenzymes is pH dependent, hence, mitomycin C activation and the rate of DNA alkylation are pH dependent. At elevated mitomycin C alkylation of DNA, the highest amount of cross-linking occurs at neutral pH. High pressure liquid chromatographic separation of the nuclease-digested DNA detected one major and two less prominent mitomycin C adducts. These were verified to be mononucleotide mitosene types by UV spectra showing maximum absorbance at 312 and 250 nm. The major adduct was purified and identified as O6-(2'-deoxyguanosyl)-2,7-diaminomitosene by NMR, indicating that the O6 position of guanine is a preferred site in DNA for at least monofunctional linkage formation.
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PMID:DNA alkylation by enzyme-activated mitomycin C. 308 8

The reduction of the hypoxic cell toxin 3-amino-1,2,4-benzotriazine-1,4-dioxide (SR 4233) was investigated using pulse radiolysis, radiation chemical reduction, and xanthine oxidase. Evidence was found that the one-electron reduction product of the parent compound is an oxidizing radical that caused single- and double-strand breaks in plasmid DNA and that produced a malondialdehyde-like thiobarbituric acid adduct from 2-deoxy-D-ribose. Possible forms of the reactive radical, either carbon- or nitrogen-centered, are suggested. The "natural" lifetime of the radical was sufficiently long that it could diffuse over significant distances within hypoxic cells and thus inflict oxidative damage on cellular targets. The radical reacted with O2 at a rate comparable to those of the nitroimidazoles misonidazole and metronidazole. Thus, the selectivity for hypoxic cells is probably due to the elimination of "futile" reduction when the cellular oxygen concentration is sufficiently low.
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PMID:Molecular mechanisms for the hypoxia-dependent activation of 3-amino-1,2,4-benzotriazine-1,4-dioxide (SR 4233). 312 84

The relative amounts of monofunctional and bifunctional alkylation products of DNA with mitomycin C (MC) depend on whether one or both masked alkylating functions of MC are activated reductively; adduct 8 is the result of one function and adducts 7 and 9, formed as a pair, are the result of both functions being activated [Tomasz, M., Lipman, R., Chowdary, C., Pawlak, J., Verdine, G. L., & Nakanishi, K. (1987) Science (Washington, D.C.) 235, 1204-1208]. To determine the mechanism governing this differential reactivity of MC with DNA, MC-Micrococcus luteus DNA complexes formed under varying conditions in vitro were digested to nucleosides and adducts. Adduct distribution, analyzed by high-performance liquid chromatography, served as the measure of monofunctional and bifunctional activation. H2/PtO2 and xanthine oxidase/reduced nicotinamide adenine dinucleotide (NADH) activated MC mostly monofunctionally, and Na2S2O4 activated the drug bifunctionally under comparable conditions. Excess MC selectively suppressed, but excess PtO2 selectively promoted, bifunctional activation by H2/PtO2; excess xanthine oxidase and/or NADH also had promoting effects. O2 tested in the Na2S2O4 system was inhibitory. 10-Decarbamoyl-MC acted strictly monofunctionally under all conditions. Monoadducts bound to DNA were converted to bis adducts upon rereduction. A mechanism with the following features was derived: (i) Activation of MC at C-1 and C-10 is sequential (C-1 first). (ii) A one-time reduction is sufficient for both. (iii) Activation of the second function may be selectively inhibited by kinetic factors or O2. (iv) 7 and 9 are coproducts of bifunctional activation; their ratio depends on the DNA base sequence. (v) Activation of the second function involves an iminium intermediate. Direct applications to the action of MC in vivo are discussed.
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PMID:Mechanism of monofunctional and bifunctional alkylation of DNA by mitomycin C. 313 45

We have shown that the xanthine oxidase-catalyzed anaerobic reduction of nitrofurazone in the presence of added DNA leads to the formation of covalently bound adducts. Further, by systematically decreasing the pH of the reaction mixture, we have demonstrated that generation of the reactive species is facilitated under mildly acidic conditions. From these observations, we conclude that it is the nitrenium ion formed from nitrofurazone which binds to DNA.
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PMID:Evidence for the involvement of a nitrenium ion in the covalent binding of nitrofurazone to DNA. 324 12

Cultured canine gastric chief cells exposed to a toxic oxygen metabolite-generating system (xanthine plus xanthine oxidase) demonstrated minimal cytolysis, suggesting that these cells have important endogenous antioxidant mechanisms. We have quantified the role of glutathione for protection against toxic oxygen metabolites by measuring cell lysis by lactate dehydrogenase release after variable depletion and repletion of cellular glutathione content. In the absence of exogenous oxidant stress, the glutathione content of chief cells can be depleted to less than 0.2 nmol total glutathione/micrograms DNA or 22% of control without cell lysis over 5 h. However, when challenged with the oxygen metabolite-generating system, cytolysis was greatly enhanced by glutathione depletion. Oxygen metabolite-mediated cytolysis after glutathione depletion was inhibited by exogenous catalase, thiourea, and deferoximine, but not superoxide dismutase or mannitol. These data suggested that hydrogen peroxide and hydroxyl radical mediated cytolysis in glutathione-depleted chief cells. If a substrate for glutathione synthesis, N-acetyl-L-cysteine, was provided to the depleted cells for 1 h before challenge with the oxygen radical-generating system, cell lysis was markedly decreased. However, if glutathione synthesis was blocked during the repletion period by buthionine sulfoximine, protection was not restored. The data supported an important role for glutathione as an endogenous antioxidant, which modulated the sensitivity of cultured chief cells to toxic oxygen metabolite injury.
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PMID:Glutathione modulates toxic oxygen metabolite injury of canine chief cell monolayers in primary culture. 327 18

1-Nitropyrene, 1-nitrosopyrene and 1-aminopyrene were investigated for their ability to induce covalently bound DNA adducts in calf thymus DNA and Chinese hamster lung fibroblasts. Xanthine oxidase catalysed the induction of one major and one minor DNA adduct in 1-nitropyrene- or 1-nitrosopyrene-treated calf thymus DNA, whilst 1-aminopyrene was inactive. These compounds did not form detectable DNA adducts in the absence of xanthine oxidase. The major DNA adduct produced by 1-nitropyrene and 1-nitrosopyrene in calf thymus DNA co-migrated on h.p.l.c., and the structure was consistent with that previously described by others as N-(deoxyguanosin-8-yl)-1-aminopyrene. The compounds were investigated for their ability to form DNA adducts in Chinese hamster lung fibroblasts. 1-Nitropyrene (5.2 pmol/mg DNA/h) and 1-nitrosopyrene (129 pmol/mg DNA/h) formed a single DNA adduct in Chinese hamster lung cells which co-eluted on h.p.l.c. with the C-8 deoxyguanosine adduct isolated from 1-nitropyrene-treated calf thymus DNA. 1-Nitrosopyrene was the most efficient compound investigated for the production of the C-8 guanine adducts. In contrast, 1-aminopyrene (14.7 pmol/mg DNA/h) induced the formation of a DNA adduct which did not co-elute with the C-8 guanine adduct. The data presented here suggest that 1-nitropyrene and 1-aminopyrene are metabolized to reactive intermediates which form different DNA adducts in Chinese hamster lung fibroblasts.
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PMID:The induction of DNA adducts in mammalian cells exposed to 1-nitropyrene and its nitro-reduced derivatives. 333 73


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