UNIPROT:P04040 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P04040 (Catalase)
3,577 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Either metal ions, H2O2, t-butyl hydroperoxide (tBHP), or cumene hydroperoxide (CHP) was added to the medium of cultured human keratinocytes, and the activities of key peroxide-metabolizing enzymes were examined in a sonicated cell supernatant from the treated cells. 200 microM Fe++ +200 microM Fe was without effect on any enzyme activity. 700 microM CHP or tBHP decreased glutathione (GSH) peroxidase activity by 90% after 5 h and by 100% at 20 h, even if the CHP or tBHP was removed from the media after 90 min. H2O2 at 700 microM caused a brief 17% decrease in activity, which was followed by complete recovery. GSH peroxidase was found to be rapidly inactivated in vitro by CHP, but the enzyme was also inactivated at 37 degrees C even in the absence of CHP. GSH prevented both types of inactivation. Consistent with this in vitro data, in vivo depletion of the GSH pool with buthionine sulfoximine led to lower levels of GSH peroxidase and increased sensitivity to peroxide-induced inactivation. Neither GSH reductase nor GSH S-transferase were inactivated by any treatment although CHP did cause a small increase in the activity of the latter, which was not due to induction. The activity of glucose-6-phosphate dehydrogenase was decreased 50% following treatment for 5 h with 700 microM CHP or tBHP, whereas H2O2 treatment caused a brief 15% decline, followed by recovery. The effects of peroxides were not altered by changing the concentration of Ca++ in the media. Catalase was unaffected by concentrations of peroxide up to 700 microM. Inhibition of catalase with aminotriazole slightly enhanced the toxicity of 700 microns H2O2. In summary, organic hydroperoxides at relatively low concentrations inactive key enzymes of the glutathione pathway, but hydrogen peroxide does not.
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PMID:Inactivation of enzymes of the glutathione antioxidant system by treatment of cultured human keratinocytes with peroxides. 849 23

Patients with asthma generate increased amounts of reactive oxygen species (ROS) from peripheral blood cells and cells recovered by bronchoalveolar lavage (BAL). ROS produce many of the pathophysiologic changes associated with asthma and may contribute to its pathogenesis. Although antioxidant defenses inhibit the changes produced by ROS, no data are available on local antioxidant defenses in asthma. The present study was designed to begin to explore these defenses by measuring superoxide dismutase (SOD) and catalase activities and total glutathione (GSH) levels in BAL fluid from normal subjects and patients with mild asthma. Baseline pulmonary function and methacholine bronchoprovocation tests were performed on all subjects. BAL was achieved by instilling five 20-ml aliquots of phosphate-buffered saline in each of three lung segments. The fluids recovered from the first 20-ml aliquot and that from the next four aliquots were labeled bronchial and alveolar fluid, respectively. Patients with asthma had a lower FEV1 (p < 0.005), less BAL fluid recovered (p < 0.05), and an increased percentage of bronchial eosinophils (p < 0.05). There were no differences in BAL total cell count or protein concentration. Catalase activity was not consistently detected in the unconcentrated BAL fluid from either group. SOD activity was found in both bronchial and alveolar samples, but it was similar in the two groups of subjects. The GSH concentration in bronchial fluid was higher in the patients with asthma (23.9 +/- 6.2 vs 13.0 +/- 1.8 microM/mg protein; p < 0.05); a similar trend was seen in the alveolar fluid (36.5 +/- 9.4 vs 23.3 +/- 3.0 microM/mg protein).(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Increased levels of glutathione in bronchoalveolar lavage fluid from patients with asthma. 850 57

Oxygen-reactive species are by-products of biological redox reactions and are involved in the development and aging processes. In order to test whether the time-dependent changes in the hepatic antioxidant defense are related to changes in DNA ploidy, we studied in rats, aged 2-8 months, the enzymes and metabolites related to the primary cell defense against oxidative stress, as well as the distribution of DNA into the cell cycle phases. Catalase and glutathione peroxidase, together with glutathione reductase and mitochondrial superoxide dismutase, underwent progressive and significant time course increases. Although no temporal changes were observed in the concentration of protein thiol groups and malondialdehyde in rats in the same age period, glutathione redox state, detected by the GSH/GSSG ratio decreased significantly to 41% (P<0.001) of the initial value. DNA content was assayed by flow cytometry in isolated hepatocytes, and changes in DNA ploidy and distribution in the cell cycle phases were determined. A sharp decrease in diploid population from rats aged 1-8 months (92.9% --> 11.1%) and a pronounced increase in hepatocyte polyploid populations in the same age period (2.6% --> 87.3%) were observed. However, liver cell population involved in S phase (DNA synthesis) was unchanged. These results indicate that the cell defense mechanisms against oxygen toxicity increased in liver of rats from 2-8 months in order to suppress the oxidative imbalance. During the 6-month period of a rat's life (2-8 months), the significant alterations of GSH/GSSG ratio to a more oxidative state have no influence on the proliferating capacity of the cells.
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PMID:Variations of hepatic antioxidant systems and DNA ploidy in rats aged 2 to 8 months. 860 69

This investigation examines the contribution of glutathione peroxidase (GSHPx-1) in degrading H2O2 in lens preparations. Rabbit (N/N1003A) and normal and GSHPx-1 transfected mouse (alpha TN4-1) lens epithelial cell lines and normal and GSHPx-1 transgenic and knockout mouse lenses were utilized. GSHPx-1 activity in the cell lines was increased from two-fold to about four-fold, in the lenses from transgenics more than four-fold and the lenses from knockouts had less than 3% of normal GSHPx-1 activity. The transgenic and knockout mice as well as their lenses appeared normal for up to 3 to 4 months, the longest period of observation. The preparations were subjected to oxidative stress by placing them either in a medium containing 120 or 300 microM H2O2 or utilizing photochemical stress where the H2O2 levels normally rise to about 100 microM over a few hours in the presence of a normal lens. With all preparations, it was found that either markedly increasing or eliminating GSHPx-1 activity had only a small effect on the system's ability to metabolize H2O2, 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU), an inhibitor of GSSG reductase (GSSG Red) and 3-aminotriazole (3-AT), an inhibitor of catalase, also had little effect. However, the addition of both inhibitors caused a marked decrease in H2O2 degradation. Examination of the distribution of GSHPx-1 in the lens indicated that the activity per milligram of protein was evenly distributed between the epithelium and the remainder of the lens in the normal lens and was about 1.7-fold greater in the epithelium of transgenic lenses than in the remainder of the lens. Surprisingly, the distribution of GSSG Red was quite different with eight- to ten-fold more activity in the epithelium. Catalase was also found to be concentrated in the epithelium. With H2O2 exposure, a rapid loss of non-protein thiol (NP-thiol) was found in cell cultures and in the epithelia of cultured lenses. However, the remainder of the lens showed little change in NP-thiol. The variation of GSHPx-1 activity did not influence the NP-thiol changes which occurred more rapidly and to a greater extent in the presence of BCNU. The addition of BCNU also caused a decrease in total lens NP-thiol. Examination of thymidine incorporation and choline transport, indicators of nuclear and membrane function, also reflects the H2O2 degradation data, showing little difference in the degree to which H2O2 effects these parameters in lenses from normal and transgenic animals. Catalase activity is four- to six-fold greater than GSHPX-1 activity in the alpha TN4-1 cell lines, about three-fold lower in the rabbit cell line and, remarkably, about 18-fold lower than the peroxidase in the normal mouse lens. In spite of such observations, the consistent overall conclusion is that GSHPx-1 and catalase function together but when GSHPx-1 is knocked out or GSSG Red is inhibited, catalase is able to protect the system from H2O2 stress. Indeed, the young mouse does not appear to require GSH Px-1 for normal function.
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PMID:Variation in cellular glutathione peroxidase activity in lens epithelial cells, transgenics and knockouts does not significantly change the response to H2O2 stress. 875 21

1. The present study was undertaken to investigate the effects of hypobaric hypoxia, equivalent to an altitude of 5500 m, on antioxidant enzymes in rats. 2. Malondialdehyde levels in serum, heart, lung, liver and kidney of hypobaric-hypoxic rats were all significantly higher than in control rats by day 21 of exposure (P < 0.05), indicating increased oxidative stress. 3. Superoxide dismutase (SOD) catalyses the conversion of the superoxide anion to H2O2 and O2. The concentration of immunoreactive Mn-SOD in the serum of hypobaric-hypoxic rats was raised significantly from day 5 onwards, whereas in liver and lung, it had decreased significantly by day 21 (P < 0.05). 4. Glutathione peroxidase (GSH-Px) catalyses H2O2 and certain lipid peroxides. By day 21, GSH-Px activity had increased significantly in the heart and lungs, but decreased significantly in the liver (P < 0.05). 5. Catalase catalyses H2O2. Catalase activity in the liver and kidney of hypobaric-hypoxic rats was significantly decreased on day 1 (P < 0.05) though levels then recovered. 6. Mn-SOD mRNA in the liver of hypobaric-hypoxic rats was induced during the experiment, the effect being exceptionally marked, especially during the first 3 days of exposure to hypobaric hypoxia. 7. These results suggest that the liver may be more vulnerable than the other organs tested to oxidative stress under hypobaric hypoxia.
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PMID:Effects of hypobaric hypoxia on antioxidant enzymes in rats. 878 50

The role of free radicals in p-aminophenol (PAP)-induced nephrotoxicity and effects of reduced glutathione (GSH) were investigated. We injected PAP in one group of rats and PAP plus GSH in a second group. All parameters were measured in the renal tissue. Superoxide dismutase (SOD) activity in the PAP + GSH group (7.1 +/- 0.36 U/mg protein) was found to be significantly higher than in the control group (4.9 +/- 0.13) (P < 0.001). Catalase (CAT) was found to be significantly low in both groups (P < 0.001 in the PAP group (13.48 +/- 0.85 U/mg protein), P < 0.01 in the PAP + GSH group (18.75 +/- 1.17) as compared to the control group (41.03 +/- 0.93)). Glutathione peroxidase (GPx) in the PAP and PAP + GSH groups was found to be significantly high (P < 0.01 in the PAP group (5.32 +/- 0.033 U/mg protein), P < 0.001 in the PAP + GSH group (6.48 +/- 0.1)) as compared to the control group (2.93 +/- 0.093)). Similarly, glutathione reductase (GSSGR) in the PAP (0.023 +/- 0.002 U/mg protein), and PAP + GSH (0.025 +/- 0.001) groups was found to be significantly high as compared to the control group (0.014 +/- 0.001) (P < 0.001). GSH in the PAP (161.93 +/- 8.3 mg/mg protein) and PAP + GSH (170.7 +/- 4.51) groups were found to be significantly higher than the control group (104.91 +/- 3.0) (P < 0.001). Malondialdehyte (MDA) in the PAP (11.2 +/- 0.62 nmol/mg protein) and PAP + GSH (9.72 +/- 0.46) groups was found to be significantly higher than in the control group (5.54 +/- 0.51)(P < 0.001). Free radicals might have a major role in the PAP-induced nephrotoxicity. GSH increased nephrotoxicity.
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PMID:The role of free radicals in p-aminophenol-induced nephrotoxicity: does reduced glutathione have a protective effect? 881 62

Seventy male factory workers were studied. The lead concentrations in their blood (Pb-B) were 16.55 +/- 11.53 micrograms/100 ml (range 1.5 to 50.2 micrograms/100 ml). The subjects were divided into three groups according to Pb-B (in microgram/100 ml): group A, Pb-B < or = 10 (n = 22); group B, 10 < Pb-B < or = 20 (n = 30); group C, Pb-B > 20 (n = 18). The mean +/- S.D. in each group was 5.57 +/- 2.53, 15.02 +/- 2.75, and 32.52 +/- 9.49 micrograms/100 ml, respectively. Pb in plasma was 0.011 +/- 0.010, 0.017 +/- 0.033, and 0.021 +/- 0.021 microgram/liter, and Pb in the RBC was 0.281 +/- 0.246, 0.701 +/- 0.325, and 1.626 +/- 0.861 micrograms/g Hb, respectively. In addition to Pb concentration, the concentrations of 34 elements in the plasma or in the RBC were determined. Se concentrations in RBC in each group were 0.618 +/- 0.139, 0.670 +/- 0.207, and 0.728 +/- 0.200 microgram/g Hb, and the mean values were significantly different between groups A and C (p < 0.05). For Se concentration in plasma, the mean +/- S.D. in each group was 0.132 +/- 0.035, 0.130 +/- 0.031, and 0.126 +/- 0.021 microgram/ml, respectively, and there was no significant difference between groups. On the other hand, when the activities of total SOD, Mn-SOD, Cu, Zn-SOD, and catalase in the plasma and the activities of GSH-Px both in the plasma and in the RBC were assayed, some differences were found. The activities in GSH-Px in RBC were 17.19 +/- 5.03, 17.59 +/- 3.95, and 15.25 +/- 3.18 mumol/g Hb/min, and those in plasma were 0.069 +/- 0.032, 0.081 +/- 0.023, and 0.080 +/- 0.028 mumol/ml/min. In group C, GSH-Px activity was lower in the RBC and higher in the plasma than those in group A, and it was observed that the Se concentration was higher in RBC, and that there was no remarkable change in the plasma. Catalase activity in group C was 3.58 +/- 0.81 mgH2O2/ml/30 min, which was significantly higher than that in group A (2.81 +/- 0.90 mgH2O2/ml/30 min). Further investigation is necessary in order to explain the above results. The regular indices used for evaluating lead exposure, showed significant correlations with Pb-B: r = -0.786 vs delta-Aminolevulinic acid (ALA) dehydratase activity in blood, r = 0.927 vs. inhibition rate, and r = 0.339 vs. ALA in urine.
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PMID:Indices of lead-exposure in blood and urine of lead-exposed workers and concentrations of major and trace elements and activities of SOD, GSH-Px and catalase in their blood. 884 89

Monoamine oxidases A/B (EC 1.4.3.4, MAO), flavoenzymes located on the outer mitochondrial membrane, catalyze the oxidative deamination of biogenic amines, such as dopamine, serotonin, and norepinephrine. In this study, we examined whether the H2O2 formed during the two-electron oxidation of tyramine [4-(2-aminoethyl)phenol] (a substrate for monoamine oxidases A/B) may contribute to the intramitochondrial steady-state concentration of H2O2 ([H2O2]ss) and, thus, be involved in the oxidative impairment of mitochondrial matrix components. Supplementation of intact, coupled rat brain mitochondria with benzylamine, beta-phenylethylamine, or tyramine showed initial rates of H2O2 production ranging from 0.4- to 1.6 nmol H2O2/min/mg protein. ESR analysis of the oxidative deamination of tyramine by intact rat brain mitochondria revealed the formation of hydroxyl (HO.) and carbon-centered radical adducts--the latter probably originating by the (HO.-)-mediated oxidation of mannitol. The signals were substantially enhanced upon addition of FeSO4 and were abolished by catalase. The intramitochondrial [H2O2]ss calculated in terms of glutathione peroxidase activity during the metabolism of tyramine was 48-fold higher (7.71 +/- 0.25 x 10(-7) M) than that obtained during the oxidation of succinate via complex II in the presence of antimycin A (1.64 +/- 0.2 x 10(-8) M). Oxidative damage to the brain mtDNA was assessed by single strand breakage. The ratio of nicked DNA for the preparations treated with tyramine and those without the amine was 1.5 +/- 0.29 (n = 4), 2.12 +/- 0.28 (n = 8, P < or = 0.05), and 3.12 +/- 0.69 (n = 3, P < or = 0.05) at 15, 30, and 60 min, respectively . Preincubation of mitochondria with tranylcypromine (trans-2-phenylcyclopropylamine), an inhibitor to MAO A/B, abolished mtDNA oxidative damage. Catalase inhibited mtDNA strand breakage by approximately 60%. Incubation of intact, coupled rat brain mitochondria with chlorodinitrobenzene (CDNB) depleted mitochondrial GSH by 72%. Tyramine-dependent damage of mtDNA was decreased by 68% in CDNB-treated mitochondria (with 28% remaining GSH). The [H2O2]ss was slightly increased in CDNB-treated mitochondria: 1.38- and 1.28-fold increase during the oxidation of succinate in the presence of antimycin A and during the oxidation of tyramine, respectively. These results suggest that the H2O2 generated during the MAO-catalyzed oxidation of biogenic amines and possibly certain neurotransmitters at the outer mitochondrial membrane contributes to the intramitochondrial [H2O2]ss and may cause oxidative damage to mtDNA. This is effected by the intramitochondrial concentration of GSH and might have potential implications for aging and neurodegenerative processes.
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PMID:The metabolism of tyramine by monoamine oxidase A/B causes oxidative damage to mitochondrial DNA. 891 26

The effect of copper sulfate (CuSO4) on both hepatic oxidative stress and heme oxygenase induction was studied. A strong increase in in vivo rat liver chemiluminescence was observed 1 h after Cu(II) administration. To evaluate liver antioxidant enzymatic defenses, superoxide dismutase, catalase, and glutathione peroxidase activities were determined. Catalase and glutathione peroxidase were found to be significantly decreased 5 h after CuSO4 injection. In contrast, superoxide dismutase activity was increased. Heme oxygenase activity appeared 5 h after treatment, reaching a maximum value 18 h after CuSO4 administration. This induction was preceded by a decrease in the intrahepatic GSH pool and an increase in the generation of thiobarbituric acid reactive substances, both effects taking place a number of hours before induction of heme oxygenase. Administration of bilirubin, the end product of heme catabolism in mammals, and alpha-tocopherol, a widely employed antioxidant, completely prevented heme oxygenase induction as well as the decrease in hepatic GSH and the increase in chemiluminescence when administered 2 h before CuSO4 treatment. Under the same experimental conditions, beta-carotene showed a moderate preventive effect on both heme oxygenase induction and oxidative stress parameters. These data obtained with Cu(II) treatment are in agreement with our previous reports suggesting a correlation between heme oxygenase induction and oxidative stress.
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PMID:Relationship between oxidative stress and heme oxygenase induction by copper sulfate. 901 30

Fenfluramine is an anorectic drug widely used for the regulation of food intake that presents some adverse effects at the central and peripheral levels. d-Fenfluramine, an isomer of dl-fenfluramine, is postulated to be more effective and to induce less side effects than the racemic compound. These drugs act preferentially on the serotonergic system. Some authors have suggested that fenfluramine causes a degeneration of serotonergic neurons. Alterations of the serotonergic system are also observed during the aging process, and in this case, a relationship with reactive oxygen species has been already established. In view of these data, the present study was conducted to investigate the relationship between fenfluramine and brain antioxidant defense system in mature and aged animals. Rats aged 4 and 17 months were chronically treated with dl-fenfluramine, d-fenfluramine, or saline. Brain activity of superoxide dismutase and glutathione peroxidase was significantly affected by aging. Catalase activity was altered by the treatment. Total glutathione content and chemiluminescence in the brains were also altered by aging. Glutathione levels were altered as a function of the interaction between age and treatment. These findings suggest that treatment with d- or dl-fenfluramine results in alteration of the anti-oxidant system that could be exacerbated when associated with the aging process.
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PMID:Chronic fenfluramine treatment of rats with different ages: effects on brain oxidative stress-related parameters. 906 50

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