UNIPROT:P04040 - FACTA Search

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Query: UNIPROT:P04040 (Catalase)
3,577 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Xanthine (X) and xanthine oxidase (XO) were injected intratracheally (IT) in hamsters at Day 0 (38 mg X, 100 micrograms XO) and Day 5 (38 mg X, 250 micrograms XO). Control hamsters received saline or X (38 mg) plus boiled XO (100, 250 micrograms). Cytoplasmic superoxide dismutase (SOD) activity increased from control of 286 to 337 and 335 units/lung at Days 12 and 19, respectively, but decreased to 228 units/lung at Day 33; mitochondrial SOD activity increased at Day 12 from control of 57 to 71 units/lung and then decreased at Days 26 and 33 to 42 and 33 units/lung, respectively. Glutathione peroxidase (GP) and glutathione reductase (GR) activities rose from their control values of 1161 and 1151 to 1561 and 2287 units/lung at Day 12, respectively; thereafter, GR activity decreased to 512 and 462 units/lung at Days 19 and 26, respectively. Glutathione transferase declined at Day 12 but increased at Day 26 after initial treatment. Glucose-6-phosphate dehydrogenase activity declined from control of 1071 to 693 units/lung at Day 2 and returned to control thereafter. Catalase activity remained unaffected. Hydroxyproline was increased from 903 micrograms/lung in control to 1080, 1301, 1195, and 1148 micrograms/lung at Days 12, 19, 26, and 33, respectively. Malonaldehyde increased from 40 nmole/lung in control to 70 and 113 nmole/lung at Days 12 and 33, respectively. The ratio of right ventricle to left ventricle and septum increased significantly from control of 0.277 to 0.318 at Day 33. Histopathology at Days 2 and 4 revealed peribronchiolar and arteriolar inflammation, and diffuse alveolitis. By Day 12 there were thickened alveolar septa and foci of fibrotic consolidation.
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PMID:Effects of intratracheal administration of xanthine plus xanthine oxidase on lung antioxidant enzymes, lipid peroxidation, and collagen in hamsters. 319 17

In the mid-fifth instar larvae of the cabbage looper moth, Trichoplusia ni, the subcellular distribution of total superoxide dismutase was as follows: 3.05 units (70.0%), 0.97 units (22.3%), and 0.33 units (7.6%) mg-1 protein in the mitochondrial, cytosolic and nuclear fractions, respectively. No superoxide dismutase activity was detected in the microsomal fraction. Catalase activity was unusually high and as follows: 283.4 units (47.3%), 150.1 units (25.1%), 142.3 units (23.8%), and 22.9 units (3.8%) mg-1 protein in the mitochondrial, cytosolic, microsomal (containing peroxisomes), and nuclear fractions. No glutathione peroxidase activity was found, but appreciable glutathione reductase activity was detected with broad subcellular distribution as follows: 3.86 units (36.1%), 3.68 units (34.0%), 2.46 units (23.0%), and 0.70 units (6.5%) mg-1 protein in the nuclear, mitochondrial, and cytosolic fractions, respectively. The unusually wide intracellular distribution of catalase in this phytophagous insect is apparently an evolutionary adaptation to the absence of glutathione peroxidase; hence, lack of a glutathione peroxidase-glutathione reductase role in alleviating stress from lipid peroxidation. Catalase working sequentially to superoxide dismutase, may nearly completely prevent the formation of the lipid peroxidizing .OH radical from all intracellular compartments by the destruction of H2O2 which together with O2- is a precursor of .OH.
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PMID:Antioxidant enzymes of larvae of the cabbage looper moth, Trichoplusia ni: subcellular distribution and activities of superoxide dismutase, catalase and glutathione reductase. 324 4

The human promyelocytic leukemia cell line HL-60 undergoes induced myeloid differentiation, with acquisition of most polymorphonuclear leukocyte (PMN) functions, including generation of toxic oxygen species. We examined the concurrent changes in the cellular detoxifying defenses against superoxide and H2O2: superoxide dismutase, catalase, and the glutathione cycle. During induced differentiation, total superoxide dismutase activity declined to a level slightly more than 2-fold that of PMN, largely due to a decrease in Mn-superoxide dismutase; CuZn-superoxide dismutase showed virtually no change. Catalase activity declined only slightly (but significantly) to a level 1.3 that of PMN. GSH peroxidase activity fell and then rose back to its original level, remaining throughout differentiation more than 10-fold higher than activity in PMN. GSSG reductase activity declined to a level of 73% that of uninduced cells but twice that of PMN. GSH and GSSG contents both decreased, reaching equivalence to those of PMN. Concurrently, the ability of the cells to generate H2O2 increased 11-fold, a change similar to that previously reported for superoxide production. Thus, there is a paradoxical inverse relationship between the development of active oxygen generation and scavenging systems during myeloid differentiation in HL-60 cells.
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PMID:Changes in superoxide dismutase, catalase, and the glutathione cycle during induced myeloid differentiation. 346 51

The effects of scavengers of active oxygen species on cadmium chloride (CdCl2)-induced inhibition of cell growth and DNA synthesis and on the metal-induced clastogenesis were investigated to evaluate whether cadmium could induce a prooxidant state in cultured Chinese hamster V79 cells. Inhibition by CdCl2 of cell growth and [3H]thymidine incorporation into the acid-insoluble fraction of cells and the metal-induced clastogenesis were suppressed in part by the presence of the diffusible radical scavenger, butylated hydroxytoluene (BHT). The action of BHT was concentration-dependent and did not affect the intracellular level of cadmium. D-Mannitol, a hydroxyl radical scavenger, also significantly suppressed Cd-induced inhibition of cell growth and [3H]thymidine incorporation. Catalase was marginally suppressive on Cd-induced inhibition of cell growth. These results suggest that cadmium can induce a prooxidant state in cultured mammalian cells. The mechanism by which cadmium induces a prooxidant state was investigated by measuring the effect of cadmium on those enzymes which constitute a cellular defense against active oxygen and on the level of the intracellular antioxidant, glutathione (GSH). 2-h treatments with CdCl2 over a concentration range of 2-10 X 10(-5) M did not influence superoxide dismutase, catalase, GSH peroxidase or GSSG reductase. In contrast, the level of glutathione was decreased to approximately 40% by treatment with 2 X 10(-5) M cadmium. The decrease in glutathione level may be responsible for a role by active oxygen in Cd-induced inhibition of cell growth and DNA synthesis and the metal-induced clastogenesis.
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PMID:Indirect evidence for the induction of a prooxidant state by cadmium chloride in cultured mammalian cells and a possible mechanism for the induction. 365 23

Catalase (H2O2:H2O2 oxidoreductase, EC 1.11.1.6) is of historical interest for having been the subject of some of the earliest investigations of enzymes. A feature of catalase that has been poorly understood for several decades, however, is the mechanism by which catalase remains active in the presence of its own substrate, hydrogen peroxide. We reported recently that catalase contains tightly bound NADPH. The present study with bovine and human catalase revealed that NADPH both prevents and reverses the accumulation of compound II, an inactive form of catalase that is generated slowly when catalase is exposed to hydrogen peroxide. Since the effect of NADPH occurs even at NADPH concentrations below 0.1 microM, the protective mechanism is likely to operate in vivo. This discovery of the role of catalase-bound NADPH brings a unity to the concept of two different mechanisms for disposing of hydrogen peroxide (catalase and the glutathione reductase/peroxidase pathway) by revealing that both mechanisms are dependent on NADPH.
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PMID:The function of catalase-bound NADPH. 380 1

The ability of aurothioglucose and D(-)-penicillamine hydrochloride to inhibit selenium-dependent glutathione peroxidase (SeGSH-Px) in vitro and to increase exudative diathesis in vitamin E-deficient chickens was studied. Aurothioglucose and penicillamine competitively inhibited SeGSH-Px in inverse proportion to the concentration of hydrogen peroxide and reduced glutathione, respectively, in chick liver postmitochondrial supernatant assay preparations. Neither drug inhibited glutathione reductase or superoxide dismutase at the concentrations tested; however, both inhibited catalase in a semilogarithmic fashion. This was true for both the purified bovine enzyme and chick liver homogenate. Aurothioglucose and penicillamine injected subcutaneously at the back of the neck increased exudative diathesis in vitamin E-deficient chickens fed 0.1 ppm Se, and effectively overcame the protective effect of selenium 72 h after injection in chicks fed vitamin E-free, low selenium diets supplemented with 0.0-0.1 ppm Se. Assays of plasma and of liver, lung and kidney postmitochondrial supernatants indicated that all observed reductions in SeGSH-Px activity preceded increases in exudative diathesis. Plasma and liver SeGSH-Px activities were lower at early times (6-24 h) after treatment with high doses of either drug. Lung SeGSH-Px activities were only lower in chicks receiving 240 mg penicillamine/kg 6 h after treatment; kidney SeGSH-Px activities were only lower in chicks treated with the highest dose of aurothioglucose 48 h after treatment. Brain SeGSH-Px activities were unaffected by drug treatment and the heart had higher SeGSH-Px activities only at 6 h after treatment with the highest dose of either drug compared to saline controls. Catalase activities in liver homogenates were only significantly altered by penicillamine; the highest dose caused the activity to be higher than that in saline-treated chicks. The cause of the lower SeGSH-Px activities could be either lower enzyme concentrations in tissues of the drug-treated groups and/or direct inhibition. Whatever the mechanism, it is concluded that exudative diathesis can be used to determine which drugs reduce SeGSH-Px activity in the chick.
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PMID:Drug-induced changes in selenium-dependent glutathione peroxidase activity in the chick. 393 15

The catalase activity of cultured rat hepatocytes was inhibited by 90% pretreatment with 20 mM aminotriazole without effect on the activities of glutathione peroxidase or glutathione reductase, or on the viability of the cells over the subsequent 24 h. Glutathione reductase was inhibited by 85% by pretreatment with 300 microM 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU) without effect on glutathione peroxidase, catalase, or on viability. Both pretreatments sensitized the hepatocytes to the cytotoxicity of H2O2 generated either by glucose oxidase (0.05-0.5 units/ml) or by the autoxidation of the one-electron-reduced state of menadione (50-250 microM). Aminotriazole pretreatment had no effect on the GSH content of the hepatocytes. BCNU reduced GSH levels by 50%. Depletion of GSH levels to less than 20% of control by treatment with diethyl maleate, however, did not sensitize the cells to either glucose oxidase or menadione, indicating that the effect of BCNU is related to inhibition of the GSH-GSSG redox cycle rather than to the depletion of GSH. With glucose oxidase, most of the cell killing in hepatocytes pretreated with either aminotriazole or BCNU occurred between 1 and 3 h. The antioxidant diphenylphenylenediamine (DPPD) had no effect on viability at 3 h. Catalase added to the culture medium 1 h after the addition of glucose oxidase prevented the cell killing measured at 3 h. The sulfhydryl reagents dithiothreitol (200 microM), N-acetyl-L-cysteine (4 mM), and alpha-mercaptopropionyl-L-glycine (2.5 mM) prevented the cell killing with exogenous H2O2 in hepatocytes sensitized by the inhibition of catalase or glutathione reductase. With menadione, there was no killing of nonpretreated hepatocytes at 1 h, and DPPD did not prevent the cell death after 3 h. Aminotriazole pretreatment enhanced the cell killing at 3 h but not at 1 h, and DPPD was not protective. Catalase added to the medium at 1 h inhibited the cell death measured at 3 h. In contrast, menadione killed hepatocytes pretreated with BCNU within 1 h. DPPD prevented cell death at 1 h, and there was evidence of lipid peroxidation in the accumulation of malondialdehyde in the culture medium. Catalase added with menadione did not prevent the cell killing at 1 h but did prevent it at 3 h. These data indicate that catalase and the GSH-GSSG cycle are active in the defense of hepatocytes against the toxicity of H2O2.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Endogenous defenses against the cytotoxicity of hydrogen peroxide in cultured rat hepatocytes. 396 66

This study investigated the effect (in vivo) of centrophenoxine (Helfergin) on the activity of antioxidant enzymes (glutathione peroxidase GSH-PER, glutathione reductase GSSG-RED, superoxide dismutase SOD and catalase) in subcellular fractions from the regions of the brain (cerebrum, cerebellum and brain stem) of rats aged 6, 9 and 12 months. In all age groups, normal (control) activity of GSH-PER, GSSG-RED and SOD in the three brain regions was higher in the soluble fractions than in the particulate fractions. The three regions of the brain showed different levels of the enzyme activities. Enzymes in soluble fractions (except GSSG-RED in cerebrum of rats aged 12 months) did not change with age. In particulate fractions, however, the enzymes showed age-related changes: GSH-PER decreased with age in cerebellum and brain stem, but showed an age-related increase in cerebrum, GSSG-RED and SOD increased with age in all the three brain regions. Catalase activity in all the three brain regions remained unchanged in all age groups. Six week administration of centrophenoxine (once a day in doses of 80 mg/Kg and 120 mg/Kg) to the experimental animals produced increases in the activity of SOD, GSH-PER and GSSG-RED in particulate fractions from all the three brain regions. In the soluble fractions, however, only SOD and GSH-PER activity was increased. In vitro also centrophenoxine stimulated the activity of GSH-PER. A dosage of 80 mg/Kg produced greater changes than a 120 mg/Kg dosage. The drug had no effect on the activity of catalase. Centrophenoxine also reduced lipofuscin deposits (studied both biochemically and histochemically) thus indicating that the drug inhibited lipofuscin accumulation by elevating the activity of the antioxidant enzymes. The data suggest that alleviation of senescence by centrophenoxine may, at least, partly be due to activation by it of antioxidant enzymes.
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PMID:Effect of centrophenoxine on the antioxidative enzymes in various regions of the aging rat brain. 641 80

Our previous studies have demonstrated a decreased glutathione feroxidase (GSH-Px) activity of erythrocytes and leucocytes from multiple sclerosis (MS) patients. In the present communication these activities were compared with the activities of associated enzymes (glutathione reductase (GSSG-RD), glucose-6-phosphate dehydrogenase (G-6-PD) and catalase). All enzymic activities were compared between MS patients, other neurologic patients (ON patients) and normal control individuals. Compared to data of ON patients and normal controls, in MS the ratio of GSHPx/GSSGRD in lympho- and granulocytes was significantly decreased (2 alpha less than or equal to 0.05) by 35% and 51%, respectively. The significant correlation between GSSG-RD and the GSH-Px activity (2 alpha less than or equal to 0.05, r = 0.501) found in control lymphocytes was not present in MS lymphocytes. However, the lymphocyte GSH-Px activities of controls as well as of MS correlated with the corresponding serum selenium levels (2 alpha less than or equal to 0.05, r = 0.594 and 2 alpha less than or equal to 0.01, r = 0.967, respectively). The G-6-PD activity was insignificantly increased by 41% in MS lymphocytes compared to normal control. Catalase activity was unchanged in lymphocytes but decreased 50% in MS granulocytes compared to normal control. No significant differences were found between MS and the ON group. The catalase activity of MS erythrocytes was increased by 63% (2 alpha less than or equal to 0.05) in comparison with both the normal control and ON data.
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PMID:Glutathione peroxidase and reductase, glucose-6-phosphate dehydrogenase and catalase activities in multiple sclerosis. 669 53

The effects of dietary vitamin E and selenium on the oxidant defense system (glutathione peroxidase, catalase, glutathione reductase, reduced glutathione, and superoxide dismutase) were investigated in the chick. Two-week-old chicks were reared using a vitamin E-free, low-selenium, semipurified basal diet alone or supplemental with vitamin E (100 IU/kg) and/or selenium (.10 ppm). Whereas vitamin E sustained chick growth, survival, and protection from exudative diathesis (ED), it did not significantly affect the enzymatic components of the oxidant defense system. Dietary selenium promoted chick growth and protection against ED in the absence of vitamin E and sustained glutathione peroxidase activity in several tissues. The latter effect was associated with decreases in reduced glutathione concentrations observed in liver and blood. Catalase and superoxide dismutase activities were increased in liver and brain in selenium deficiency. Glutathione reductase activities in liver, kidney, lung, and brain were not affected by diet.
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PMID:Influences of dietary vitamin E and selenium on the oxidant defense system of the chick. 732 95

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