UMLS:C0344329 - FACTA Search

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Query: UMLS:C0344329 (collapse)
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The present knowledge of glutathione (GSH) peroxidase is briefly reviewed: GSH peroxidase has a molecular weight of about 85,000, consists of four apparently-identical subunits and contains four g atom of selenium/mol. The enzyme-bound selenium can undergo a substrate-induced redox change and is obviously essential for activity. In accordance with the assumption that a selenol group is reversibly oxidized during catalysis, ping-pong kinetics are observed. Limiting maximum velocities and Michaelis constants, indicating the formation of an enzyme-substrate complex, are not detectable. The enzyme is highly specific for GSH but reacts with many hydroperoxides. It can be deduced from the kinetic analysis of GSH peroxidase that in physiological conditions removal of hydroperoxide is largely independent of fluctuations in the cellular concentration of GSH. However, the system will abruptly collapse if the rate of hydroperoxide formation exceeds that of regeneration of GSH. By these considerations, the pathophysiological manifestation of disorders in GSH metabolism and pentose-phosphate shunt may be explained. With regard to its low specificity for hydroperoxides, GSH peroxidase could be involved in various metabolic events such as H2O2 removal in compartments low in catalase, hydroperoxide-mediated mutagenesis, protection of unsaturated lipids in biomembranes, prostaglandin biosynthesis, and regulation of prostacyclin formation.
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PMID:Glutathione peroxidase: fact and fiction. 38 23

When exposed to CO, the aerobic respiratory system of the marine bacterium Pseudomonas nautica strain 617, previously reduced with dithionite, undergoes reoxidation. When dealing with the purified oxidase (dithionite reduced) exposure of the enzyme to CO induces its reoxidation (collapse of its alpha band). Under our experimental conditions, this form of the oxidase could not be reduced again by dithionite. Addition of formaldehyde to the native oxidized enzyme resulted in full inhibition of the oxidase reduction by dithionite, presumably due to complex formation. We hypothesized a reduction of CO into formaldehyde and a locking of the active site by the reaction product. By using flash photolysis, it was possible to turn over the enzyme, accumulate the reaction product and identify it as formaldehyde. When using the membrane-bound enzyme, formaldehyde accumulated without the help of flash photolysis. This unusual reduction of CO to formaldehyde could be related to the previously reported uncommon features of the P. nautica oxidase, in particular O2 reduction into H2O2 as end product [(1989) FEBS Lett. 247, 475-479].
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PMID:Reduction of carbon monoxide to formaldehyde by the terminal oxidase of the marine bacterium Pseudomonas nautica strain 617. 153 99

Reexpansion pulmonary edema parallels reperfusion (reoxygenation) injuries in other organs in that hypoxic and hypoperfused lung tissue develops increased vascular permeability and neutrophil infiltration after reexpansion. This study investigated endogenous lung catalase activity and H2O2 production during hypoxia (produced by lung collapse) and after reoxygenation (resulting from reexpansion), in addition to assessing the effects of exogenous catalase infusion on the development of unilateral pulmonary edema after reexpansion. Lung collapse resulted in a progressive increase in endogenous catalase activity after 3 (14%) and 7 days (23%), while activities in contralateral left lungs did not change (normal left lungs averaged 180 +/- 11 units/mg DNA). Tissue from control left lungs released H2O2 into the extracellular medium at a rate calculated to be 242 +/- 34 nmol.h-1.lung-1. No significant change in extracellular release of H2O2 occurred after 7 days of right lung collapse. However, after reexpansion of the previously collapsed right lungs for 2 h, H2O2 release from both reexpanded right and contralateral left lungs significantly increased (88 and 60%, respectively) compared with controls. Infusion of exogenous catalase significantly increased plasma and lung catalase activities. Exogenous catalase infusion prevented neither the increase in lung permeability nor the infiltration with neutrophils that typically occurs in reexpanded lungs. These data indicate that lung hypoxia/reoxygenation, induced by sequential collapse and reexpansion, has specific effects on endogenous lung catalase activity and H2O2 release. However, exogenous catalase does not prevent reexpansion pulmonary edema, eliminating extracellular (but not intracellular) H2O2 as an important mediator of unilateral lung injury in this model.
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PMID:Endogenous and exogenous catalase in reoxygenation lung injury. 156 81

The reaction of horseradish peroxidase with alkylhydrazines results in delta-meso-alkylation of the prosthetic heme group and enzyme inactivation (Ator, M. A., David, S. K., and Ortiz de Montellano, P. R. (1987) J. Biol. Chem. 262, 14954-14960). As reported here, enzyme inactivation is associated with the accumulation of intermediates that absorb at approximately 835 nm. The properties of these intermediates, including their collapse to give meso-alkylhemes, identify them as isoporphyrins. The t1/2 values for inactivation and formation of the isoporphyrin intermediate at 25 degrees C are, respectively, 11.6 and 12.5 min for methylhydrazine (2.0 mM), 8.7 and 7.2 min for ethylhydrazine (1.0 mM), and 30 and 25 s for phenylethylhydrazine (50 microM). The isoporphyrin intermediates are surprisingly long-lived, with half-lives (35 degrees C, pH 7.0) of 9, 28, 96, and 450 min for, respectively, the phenylethyl, methyl, n-butyl, and ethyl analogues. pH studies show that protonation of a group with pKa = 5.0-6.5 accelerates isoporphyrin decay and decreases steady state isoporphyrin accumulation. Horseradish peroxidase reconstituted with delta-meso-methylheme, unlike horseradish peroxidase with a heme that has a larger meso-substituent, is catalytically active but is more sensitive to H2O2-mediated degradation of the prosthetic group than is the native enzyme. The delta-meso-methylheme prosthetic group is converted in the reaction with H2O2 to a biliverdin-like product. The results implicate highly stabilized isoporphyrin intermediates in the inactivation of horseradish peroxidase by alkylhydrazines and indicate that inactivation by the meso-alkyl groups is due to steric interference with electron delivery to the heme edge rather than to intrinsic electronic consequences of meso-alkylation. The structural features that stabilize the cationic isoporphyrins may also be involved in stabilization of the Compound I porphyrin radical cation.
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PMID:Stabilized isoporphyrin intermediates in the inactivation of horseradish peroxidase by alkylhydrazines. 272 29

This study examined the effects of lung collapse, a condition that causes relative hypoxia in lung tissues, on superoxide dismutase (SOD), cytochrome oxidase (cyt ox), and pyruvate kinase (py ki) activities in rabbits. Cyanide-insensitive respiration measurements were done in collapsed and contralateral lungs, as an index of intracellular free radical production. Rabbits' right lungs were collapsed for 7 days after which the animals were killed. We found that control rabbit lungs contained approximately 25 SOD units/mg DNA measured with 10(-5) M KCN (total SOD) and approximately 11 SOD units/mg DNA measured with 10(-3) M KCN (mitochondrial or MnSOD). Right lung collapse caused a 25% decrease in mitochondrial SOD activity after 7 days (P less than 0.05), whereas no significant changes occurred in right or left lungs' total SOD activity. In control rabbits cyt ox activity averaged approximately 0.009 mumol ferrocytochrome c.min-1.mg DNA-1. Right lung collapse caused a greater than 40% decrease in cyt ox activity after 7 days of collapse (P less than 0.05), whereas cyt ox activity in contralateral left lungs did not change. Pyruvate kinase activity, a marker for anaerobic glycolysis resulting from tissue hypoxia, increased 49% in collapsed right lungs (P less than 0.01). Cyanide-insensitive respiration was 83% higher in 7 day-collapsed lungs (2.28 +/- 0.66 microliters O2.min-1.g-1) compared with contralateral lungs (1.24 +/- 0.34, P less than 0.05), indicating increased O2-. and H2O2 production in this tissue after homogenization at normoxic PO2 (approximately 150 Torr).(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Superoxide dismutase and cytochrome oxidase in collapsed lungs: possible role in reexpansion edema. 284 Dec 78

The generation of toxic oxygen products from activated phagocytic cells represents an important pathogenic mechanism in tissue damage associated with inflammatory reactions that are characterized by the involvement of neutrophils or other phagocytic cells. The production of these toxic products from activated phagocytic cells is related to receptor activation on the surface of the cells. Most emphasis has been placed on studies in the lung where the production of these toxic metabolites by phagocytic cells, either in the vasculature or in the airway compartment of the lungs, has been demonstrated to result in endothelial cell injury or damage and destruction of alveolar lining cells. In some cases these reactions are progressive, resulting in parenchymal collapse and fibrosis. Naturally occurring protective factors have been demonstrated both within cells and in the plasma and interstitial fluid compartments. Although there is increasing evidence that in the shock syndrome complement activation products and toxic oxygen metabolites from activated leukocytes play important roles, the most direct evidence for related mechanisms comes in detailed studies of immune complex induced injury where a role for both O-2 and H2O2 has been clearly demonstrated. These facts indicate that toxic oxygen metabolites from activated phagocytic cells play important roles in a variety of pathological situations, and have provided new insights into intervention therapy.
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PMID:Role of toxic oxygen products from phagocytic cells in tissue injury. 630 73

Alterations in the energy metabolism of cancer cells have been reported for many years. However, the deleterious mechanisms involved in these deficiencies have not yet been clearly proved. The main goal of this study was to decipher the harmful mechanisms responsible for the respiratory chain deficiencies in the course of diethylnitrosamine (DENA)-induced rat hepatocarcinogenesis, where mitochondrial DNA abnormalities had been previously reported. The respiratory activity of freshly isolated hepatoma mitochondria, assessed by oxygen consumption experiments and enzymatic assays, presented a severe complex I deficiency 19 months after DENA treatment, and later on, in addition, a defective complex III activity. Since respiratory complex subunits are encoded by both nuclear and mitochondrial genes, we checked whether the respiratory chain defects were due to impaired synthesis processes. The specific immunodetection of complex I failed to show any alterations in the steady-state levels of both nuclear and mitochondrial encoded subunits in the hepatomas. Moreover, in vitro protein synthesis experiments carried out on freshly isolated hepatoma mitochondria did not bring to light any modifications in the synthesis of the mitochondrial subunits of the respiratory complexes, whatever the degree of tumor progression. Finally, Southern blot analysis of mitochondrial DNA did not show any major mitochondrial DNA rearrangements in DENA-induced hepatomas. Because the synthetic processes of respiratory complexes did not seem to be implicated in the respiratory chain impairment, these deficiencies could be partly ascribed to a direct toxic impact of highly reactive molecules on these complexes, thus impairing their function. The mitochondrial respiratory chain is an important generator of noxious, reactive oxygen free radicals such as superoxide and H2O2, which are normally catabolized by powerful antioxidant scavengers. Nineteen months after DENA treatment, a general collapse of the antioxidant enzymatic system was demonstrated in the hepatomas, as recurrently observed in cancer cells. This oxidant versus antioxidant imbalance was characterized by the establishment of oxidative stress in the course of hepatocarcinogenesis, as partly shown by the important decrease of glutamine synthetase activity, an enzyme whose function is highly sensitive to oxidant reactions. This disequilibrium would result in a net increase of the steady-state concentration of superoxide generated between respiratory complexes I and III in the mitochondria. Once generated, superoxide would likely inactivate complexes I and III via oxidant reactions on their superoxide-sensitive [4Fe, 4S] clusters. The role of mitochondrial respiratory chain impairment in chemical carcinogenesis and/or the persistence of the cancerous state is further discussed.
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PMID:Impairment of the mitochondrial respiratory chain activity in diethylnitrosamine-induced rat hepatomas: possible involvement of oxygen free radicals. 760 23

Hydrogen peroxide is used to cleanse and irrigate wounds. As it decomposes immediately into water and oxygen on contact with organic tissue, it is usually regarded as a safe agent. We report a case of oxygen embolism associated with hydrogen peroxide irrigation of the surgical field during anterior fusion of the cervical vertebrae. It was accompanied by precipitous hypotension and decrease in pulse oximetry oxygen saturation and end-tidal CO2 tension. Semi-closed spaces formed under the apatite dowel and between the apatite dowel and vertebral bodies may have precipitated the absorption of oxygen bubbles into the vasculature. Although this case was associated with a rapid recovery and uneventful sequelae, it discourages the use of hydrogen peroxide in this procedure because of the potential hazards including cardiovascular collapse.
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PMID:Oxygen embolism due to hydrogen peroxide irrigation during cervical spinal surgery. 774 77

Ischemia/reperfusion mechanisms contribute to lung injury after transplantation, pulmonary embolism, and resolution of atelectasis. Alveolar tissue becomes hypoxic and deprived of substrate only when both ventilation and perfusion are interrupted, a situation modeled in vivo by complete, unilateral lung collapse. Because previously hypoxic mitochondria may be an important intracellular source of superoxide and hydrogen peroxide (H2O2) during reperfusion and re-oxygenation, the authors, in this study, investigated whether mitochondrial H2O2 release changed as a result of lung hypoxia/hypoperfusion resulting from collapse. Mitochondria were isolated from hypoxic (previously collapsed) right or contralateral left rabbits' lungs and from control rabbits' lungs. Mitochondrial H2O2 release, a marker of superoxide production, was measured fluorometrically after incubation with or without 1 mmol/L cyanide and 0.1 mmol/L nicotinamide adenine dinucleotide. Mitochondrial recovery was determined by assaying succinate dehydrogenase activity in mitochondrial preparations and lung homogenates. Lung succinate dehydrogenase activity and mitochondrial recovery were comparable among groups. Calculated lung mitochondrial content did not change (control subjects: left 7.9 +/- 0.5, right 13.8 +/- 1.7; hypoxic: left 10.3 +/- 1.3, right 10.5 +/- 2.4, all mg mitochondrial protein/lung). Mitochondria released hydrogen peroxide at approximately 5.6 nmol/h/mg pro in buffer alone and 14.8 nmol/h/mg pro in buffer with cyanide and nicotinamide adenine dinucleotide. However, lung collapse and resulting hypoxia caused no change in mitochondrial number or capacity to release H2O2 in vitro. Based on these findings, it is suggested that other sources of reactive oxygen metabolites, including xanthine oxidase and activated neutrophils, contribute to the oxidant injury observed in this model.
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PMID:Hydrogen peroxide release by mitochondria from normal and hypoxic lungs. 794 83

Hydrogen peroxide, a physiological metabolite, and a variety of other potentially toxic prooxidants, cause oxidation of the pyridine nucleotides NAD(P)H to NAD(P)+ in mitochondria. In Ca(2+)-loaded mitochondria NAD+ thus formed is hydrolyzed to ADP-ribose and nicotinamide. Subsequent to NAD+ hydrolysis, Ca2+ is released from the organelles via a specific pathway which is sensitive to several inhibitors, among them cyclosporine A and some of its derivatives. The release is probably regulated by peptidyl-prolyl cis-trans isomerase. Prolonged stimulation of the release pathway by certain prooxidants followed by re-uptake and release of Ca2+ (Ca2+ 'cycling') leads to collapse of the mitochondrial membrane potential, and is detrimental to the organelles. Excessive Ca2+ 'cycling' is likely to be a basis for the cell toxicity of some prooxidants. On the other hand, the toxicity of inhibitors of the prooxidant-induced Ca2+ release pathway may be due to long-term Ca2+ overloading of mitochondria.
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PMID:Mitochondrial calcium release induced by prooxidants. 845 54

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