UNIPROT:P04040 - FACTA Search

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Query: UNIPROT:P04040 (Catalase)
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Cell-free supernatant from formylmethionyl-leucyl-phenylalanine (fMLP)-activated granulocytes causes a time- and concentration-dependent stimulation of prostaglandin E2 (PGE2) production in amnion cells. PGE2 concentration in the culture medium after 36 h treatment with granulocyte supernatant (from 40 x 10(6) granulocytes/ml of amnion cell medium), 1.49 +/- 0.71 pg/ng DNA (n = 13), was significantly higher (p = 0.0015) than in control cells (0.33 +/- 0.23 pg/ng DNA, n = 13). Indomethacin abolished this stimulation. Granulocyte supernatant and human epidermal growth factor (hEGF) had an additive effect on amnion cell PGE2 production. Catalase, superoxide dismutase (SOD), protease inhibitors or the platelet-activating factor (PAF) antagonist L-659,989 had no effect. Actinomycin D, cycloheximide and mepacrine reduced the PGE2 production. The phospholipase A2 activity present in granulocyte supernatants was resistant to heating, whereas heating decreased their PGE2-stimulating activity by 92%. Exogenous phospholipase A2 had no effect on PGE2 synthesis. The granulocyte product could be precipitated with ammonium sulphate. On gel filtration of supernatant, two peaks of PGE2-synthesis stimulating activity were obtained (molecular weights 12,000 and 60,000). This data serve to explain the association of chorioamnionitis with preterm labor: activated granulocytes release a protein(s) that induces prostaglandin production in amnion cells, and thus promote labor.
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PMID:A product of activated human granulocytes stimulates prostaglandin E2 synthesis in human amnion cells. 188 40

Normal human neutrophils triggered by precipitating immune complexes (IC), soluble IC (sIC) or heat-aggregated IgG (HAIgG) displayed low levels of cytotoxicity towards nonsensitized target cells. Catalase, but not heated catalase, completely impaired this nonspecific cytotoxicity (NSC), suggesting a key role for hydrogen peroxide (H2O2) in the lysis of target cells. Superoxide dismutase (SOD) and certain HO. and 1O2 scavengers were unable to exert significant effects. Three haem-enzyme inhibitors, sodium azide, sodium cyanide and 3-amino-1,2,4-triazole did not decrease neutrophil NSC, but markedly enhanced it. This data suggest that the mechanism involved was not dependent upon myeloperoxidase (MPO). The analysis of neutrophil-mediated ADCC indicates that oxygen-dependent but MPO-independent mechanisms appeared to be operative in this system. It was also found that the microfilament disrupting agents, cytochalasin B (CB) and dihydrocytochalasin B (dhCB), as well as the chemotactic peptide N-formyl-methionyl-leucyl-phenylalanine (FMLP), significantly enhanced NSC. In contrast, these compounds partially inhibited ADCC. This cytotoxic system provides a suitable model to study events that may occur during the course of immune complex diseases and also permits the evaluation of alternative lytic mechanisms triggered through neutrophil Fc gamma receptors.
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PMID:Neutrophil-mediated cytotoxicity triggered by immune complexes: the role of reactive oxygen metabolites. 282 3

Prostaglandin H synthase, the primary enzyme in the pathway to the prostaglandins, requires the continued presence of a hydroperoxide activator for its enzyme activity. Phagocytic leukocytes from either humans or guinea pigs produced activator hydroperoxides in quantities sufficient to enhance prostaglandin synthesis in cells. Compounds that stimulated the oxidative burst (e.g., phorbol myristate acetate, opsonized zymosan, and N-formyl-L-methionyl-L-leucyl-L-phenylalanine) enhanced the overall production of the activators. Accumulation of activator(s) was promoted by exogenous Fe+3 (2 mumol/L), adenosine diphosphate (10 mumol/L), and unsaturated fatty acids (1 to 30 mumol/L) and was completely inhibited by glutathione peroxidase (0.5 U/ml). Catalase (500 U/ml) decreased the amount of activator by 70% when added during the incubation but by only 40% when added after the incubation. Thus, the activator appeared to be partly H2O2 and partly a lipid hydroperoxide. The addition of H2O2 in quantities similar to those produced by phagocytes increased prostaglandin formation by twofold in incubations with U937 cells and carbon 14-labeled arachidonic acid (2 mumol/L). These results indicate a new role for the oxygen metabolites from leukocytes in providing an intercellular signal that can stimulate prostaglandin synthesis.
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PMID:In vitro formation of activators for prostaglandin synthesis by neutrophils and macrophages from humans and guinea pigs. 309 22

1. Phenylalanine hydroxylase is inhibited by its cofactor, 6,7-dimethyltetrahydropterin. The rate of inactivation, which is irreversible, increases with the concentration of cofactor. 2. Catalase, in sufficient amount relative to cofactor, prevents this inactivation. More tyrosine is formed in the presence of added catalase. 3. Dithiothreitol in the presence of liver extract also prevents inactivation of the enzyme by the cofactor and stimulates hydroxylation of phenylalanine, probably by protecting the cofactor from oxidation and regenerating it from a dihydropterin reaction product. Dithiothreitol restores linearity of rate at very low enzyme concentrations. 4. Dimethyltetrahydropterin is unstable when the solution is exposed to air but is stabilized by dithiothreitol the aerobic oxidation of which is greatly accelerated by dimethyltetrahydropterin. 5. NADH together with liver extract stabilizes the cofactor but not phenylalanine hydroxylase. 6. It is suggested that either hydrogen peroxide or an organic peroxide formed by oxidation in air of the cofactor is the substance attacking phenylalanine hydroxylase, dithiothreitol and cofactor.
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PMID:The inactivation of phenylalanine hydroxylase by 2-amino-4-hydroxy-6,7-dimethyltetrahydropteridine and the aerobic oxidation of the latter. The effects of catalase, dithiothreitol and reduced nicotinamide-adenine dinucleotide. 433 93

Phenylalanine hydroxylase was prepared from rat liver and purified 200-fold to about 90% purity. All the enzymic activity of the liver appeared in a single protein of mol.wt. approx. 110000, but omission of dithiothreitol and of a preliminary filtration step to remove lipids resulted in partial conversion into a second enzymically active protein of mol.wt. approx. 250000. The K(m) and V(max.) values of the enzyme for phenylalanine, p-fluorophenylalanine and dimethyltetrahydropterin were measured; p-chlorophenylalanine inhibited the enzyme by competing with phenylalanine. Disc gel electrophoresis at pH7.2 showed a single protein band containing all the enzymic activity, but at pH8.7 the enzyme dissociated into two inactive fragments of similar but not identical molecular weight. The molecule of phenylalanine hydroxylase contained two atoms of iron, one atom of copper and one molecule of FAD; molybdenum was absent. Treatment with chelating agents showed that both non-haem iron and copper were necessary for enzymic activity. The molecule contained five thiol groups, and thiol-binding reagents inhibited the enzyme. Catalase or peroxidase enhanced enzymic activity fivefold; it is postulated that catalase (or other peroxidase) plays a part in the hydroxylation reaction independent of the protection by catalase of enzyme and cofactor from inactivation by a hydroperoxide.
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PMID:The isolation and properties of phenylalanine hydroxylase from rat liver. 485 20

1. Phenylalanine is converted into tyrosine by incubation in air with 6,7-dimethyltetrahydropterin, which is a cofactor for the enzymic hydroxylation. This can cause serious inaccuracies in assays of phenylalanine hydroxylase. 2. The non-enzymic reaction is not specific for l-phenylalanine. 3. m-Tyrosine, o-tyrosine and dihydroxyphenylalanines are formed in addition to p-tyrosine; their chromatographic separation and assay are described. 4. l-[(14)C]Phenylalanine as purchased or soon after purification contains p- and m-tyrosine, both of which can cause errors in the assay of phenylalanine hydroxylase. 5. Catalase prevents the non-enzymic hydroxylation. Thiol compounds in low concentrations stimulate the reaction but in high concentrations are inhibitory. Fe(2+) and metal complexing agents have small stimulatory effects. 6. The mechanism of the non-enzymic reaction and its possible relation to the enzymic hydroxylation of phenylalanine are discussed; it is suggested that phenylalanine is attacked by a peroxide of the cofactor.
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PMID:The non-enzymic hydroxylation of phenylalanine to tyrosine by 2-amino-4-hydroxy-6,7-dimethyl-5,6,7,8-tetrahydropteridine. 500 99

1. Oxygen was taken up rapidly when pyridoxal or pyridoxal phosphate was added to mixtures of pea-seedling extracts and Mn(2+) ions. 2. The increases in total oxygen uptake were proportional to the pyridoxal or pyridoxal phosphate added and were accompanied by the disappearance of these compounds. 3. In addition to Mn(2+) ions, the reactions depended on two factors in the extracts, a thermolabile one in the non-diffusible material and a thermostable one in the diffusate; these factors could be replaced in the reactions by horse-radish peroxidase (donor-hydrogen peroxide oxidoreductase, EC 1.11.1.7) and amino acids respectively. 4. When pyridoxal phosphate was added to mixtures of amino acids and Mn(2+) ions oxygen uptake was rapid after a lag period of 30-90min.; the lag period was shortened to a few minutes by peroxidase, particularly in the presence of traces of p-cresol, or by light. 5. When pyridoxal replaced pyridoxal phosphate relatively high concentrations were required and peroxidase had only a small activating effect. 6. Pyridoxal or pyridoxal phosphate disappeared during the reactions and carbon dioxide and ammonia were formed. 7. With phenylalanine as the amino acid present, benzaldehyde was identified as a reaction product. 8. It is suggested that the reactions are oxidations of the Schiff bases formed between pyridoxal or pyridoxal phosphate and amino acids, mediated by a manganese oxidation-reduction cycle, and resulting in oxidative decarboxylation and deamination of the amino acids.
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PMID:The oxidation of Schiff bases of pyridoxal and pyridoxal phosphate with amino acids by manganous ions and peroxidase. 594 50

In order to screen for new microbial D-amino acid oxidase activities a selective and sensitive peroxidase/o-dianisidine assay, detecting the formation of hydrogen peroxide was developed. Catalase, which coexists with oxidases in the peroxisomes or the microsomes and, which competes with peroxidase for hydrogen peroxide, was completely inhibited by o-dianisidine up to a catalase activity of 500 nkat ml(-)(1). Thus, using the peroxidase/o-dianisidine assay and employing crude extracts of microorganisms in a microplate reader, a detection sensitivity for oxidase activity of 0.6 nkat ml(-)(1) was obtained.Wild type colonies which were grown on a selective medium containing D-alanine as carbon, energy and nitrogen source were examined for D-amino acid oxidase activity by the peroxidase/o-dianisidine assay. The oxidase positive colonies possessing an apparent oxidase activity > 2 nkat g dry biomass(-)(1) were isolated. Among them three new D-amino acid oxidase-producers were found and identified as Fusarium oxysporum, Verticilium lutealbum and Candida parapsilosis. The best new D-amino oxidase producer was the fungus F. oxysporum with a D-amino acid oxidase activity of about 900 nkat g dry biomass(-)(1) or 21 nkat mg protein(-)(1). With regard to the use as a biocatalytic tool in biotechnology the substrate specificities of the three new D-amino acid oxidases were compared with those of the known D-amino acid oxidases from Trigonopsis variabilis, Rhodotorula gracilis and pig kidney under the same conditions. All six D-amino acid oxidases accepted the D-enantiomers of alanine, valine, leucine, proline, phenylalanine, serine and glutamine as substrates and, except for the D-amino acid oxidase from V. luteoalbum, D-tryptophane, D-tyrosine, D-arginine and D-histidine were accepted as well. The relative highest activities (>95%) were measured versus D-alanine (C. parapsilosis, F. oxysporum, T. variabilis), D-methionine (V. luteoalbum, R. gracilis), D-valine (T. variabilis, R. gracilis) and D-proline (pig kidney). The D-amino oxidases from F. oxysporum and V. luteoalbum were able to react with the industrially important substrate cephalosporin C although the D-amino acid oxidase from T. variabilis was at least about 20-fold more active with this substrate.As the results of our studies, a reliable oxidase assay was developed, allowing high throughput screening in a microplate reader. Furthermore, three new microbial D-amino acid oxidase-producers with interesting broad substrate specificities were introduced in the field of biotechnology.
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PMID:Detection and substrate selectivity of new microbial D-amino acid oxidases. 1102 24

Catalase-peroxidases (KatGs) are multifunctional heme peroxidases exhibiting an overwhelming catalase activity and a substantial peroxidase activity of broad specificity. Here, we show that catalase-peroxidases are also haloperoxidases capable of oxidizing chloride, bromide, and iodide in a peroxide- and enzyme-dependent manner. Recombinant KatG and the variants R119A, W122F, and W122A from the cyanobacterium Synechocystis PCC 6803 have been tested for their halogenation activity. Halogenation of monochlorodimedon (MCD), formation of triiodide and tribromide, and bromide- and chloride-mediated oxidation of glutathione have been tested. Halogenation of MCD by chloride, bromide, and iodide was shown to be catalyzed by wild-type KatG and the variant R119A. Generally, rates of halogenation increased in the order Cl(-) < Br(-) < I(-) and/or by decreasing pH. The halogenation activity of R119A was about 7-9% that of the wild-type enzyme. Upon exchange of the distal Trp122 by Phe and Ala, both the catalase and halogenation activities were lost but the overall peroxidase activity was increased. The findings suggest that the same redox intermediate is involved in H(2)O(2) and halide oxidation and that distal Trp122 is involved in both two-electron reactions. That halides compete with H(2)O(2) for the same redox intermediate is also emphasized by the fact that the polarographically measured catalase activity is influenced by halides, with bromide being more effective than chloride.
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PMID:Catalase-peroxidase from synechocystis is capable of chlorination and bromination reactions. 1156 49

The effects of gold-chloroquine derivatives with the formula [Au(PR3)(CQ)]PF6 (where R = Ph (1), Et or Me) on the superoxide anion production by human neutrophils (PMNs, polymorphonuclear cells) were investigated. When these complexes (0.1-3 mumol/l) were added to PMNs prior to the activators formyl-methionyl-leucyl-phenylalanine (fMLP) or phorbol myristate acetate (PMA), they inhibited isoluminol-horseradish peroxidase-dependent chemiluminescence (CLisol). The inhibition was a direct result of effects on PMNs since chemiluminescence in the cell-free system (horseradish peroxidase-hydrogen peroxidase-isoluminol) was not affected. The above mentioned concentrations of the complexes did not show in vitro toxicity on the cells. On the other hand, when 1 mumol/l of complex 1 was added to cells after stimulation, the chemiluminescence of PMNs stimulated by PMA was inhibited, but not the chemiluminescence stimulated by fMLP. The gold-chloroquine binding was essential for the referred activity as chemiluminescence was not influenced by the precursors chloroquine (CAS 54-05-7) and AuCl(PPh3). Furthermore, the extent of inhibition of chemiluminescence in PMNs activated by PMA did not increase with the duration of preincubation in presence of 1 mumol/l of 1. Extensive washing of cells after preincubation with 1 mumol/l of 1 reversed the aforementioned inhibition. All these results show that the gold-chloroquine binding can lead to compounds with specific properties that could make them useful in the treatment of some inflammatory diseases.
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PMID:Effects of gold-chloroquine complexes on respiratory burst of polymorphonuclear leukocytes. 1210 48

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