Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:1.6.5.3 (complex I)
 8,901 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In Ascaris muscle mitochondria the major respiratory chain-linked phosphorylation activity is accomplished by a NADH-linked reduction of fumarate to succinate. Oxygen can also be employed as a terminal electron acceptor via a cyanide- and salicyl-hydroxamate-resistant terminal oxidase. As in fumarate-dependent electron transport this process appears to be coupled to energy conservation at phosphorylation site I. The branchpoint from which electrons are taken from the main respiratory chain to either the alternative oxidase or fumarate reductase is likely to be on the oxygen side of the NADH dehydrogenase segment. Malate and succinate are the only substrates which appreciably support respiration in the mitochondrion of the nematode. Regardless of the presence or absence of oxygen malate is utilized by an oxidation-reduction reaction resulting in the formation of pyruvate, acetate, succinate, propionate and CO2. In addition, aerobically, hydrogen peroxide is formed as the product of oxygen reduction. Succinate accumulation was found to be significantly higher in the anaerobic as compared to the aerobic incubation mixtures. This effect was accompanied by an increase in anaerobic malate consumption. ATP generation and the formation of pyruvate, acetate and propionate were found to be similar in the presence and absence of oxygen. In malate-supported respiration of intact Ascaris mitochondria reducing equivalents (NADH) are produced exclusively through pyruvate and acetate formation. These enzymatic reactions are functionally coupled to the electron transport-linked reductions of fumarate to succinate and oxygen to hydrogen peroxide, respectively. In accordance with the position of the redox potentials of the fumarate/succinate and O2/H2O2 couples, anaerobic and aerobic respiration was found to be associated with relatively low energy conservation efficiencies. Thus one molecule of ATP was conserved per 2e- transferred to fumarate or oxygen, respectively. No evidence could be obtained for a significant activity of energy conservation sites II and III and electron transfer through the alternative oxidase pathway was shown not to be coupled to phosphorylation.
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PMID:Mechanisms of respiration and phosphorylation in Ascaris muscle mitochondria. 744 10

Mitochondria are an important source of reactive oxygen intermediates because they are the major consumers of molecular oxygen in cells. Respiration is associated with toxicity, which is related to the activation of oxygen to reactive intermediates. The purpose of the present study was to examine the role of reduced glutathione (GSH) in the maintenance of mitochondrial functions during oxidative stress induced through selective inhibition of the complex III segment of the electron transport chain. Hydrogen peroxide monitored by the fluorescence of dichlorofluorescein increased in a time- and dose-dependent manner on incubation of mitochondria with antimycin A (AA), an inhibitor of complex III. However, blockade of complex I or II with rotenone or thenoyltrifluoroacetone, respectively, did not result in accumulation of hydrogen peroxide. Depletion of mitochondrial GSH to 10-20% of control by preincubation with diethylmaleate (0.8 mM) or ethacrynic acid (250 microM) also increased dichlorofluorescein and malondialdehyde levels and resulted in an additional (2-3-fold) increase after AA. Similar results were obtained when mitochondrial GSH depletion was produced by treatment with buthionine L-sulfoximine before mirochondria isolation. The endogenous oxidative stress induced by AA was accompanied by a moderate loss of activity of ATPase complex (77% of control) and complex IV of respiration (75% of control), which was accentuated after depletion of mitochondrial GSH (51% and 45% of control, respectively). Similar results were observed in isolated hepatocytes in which depletion of mitochondrial GSH and AA led to peroxidation and mitochondrial dysfunction. In addition, with electrophoretic mobility shift assay of the transcription factor nuclear factor-kappa B (NF-kappa B), we detected its activation in response to AA (2-3-fold). Depletion of mitochondrial GSH in hepatocytes (20% of control) led to further enhancement of NF-kappa B activation (2-4-fold), which correlated with generation of hydrogen peroxide. Thus, our results suggest that GSH protects mitochondria against the endogenous oxidative stress produced at the ubiquinone site of the electron transport chain. Mitochondrial GSH depletion potentiates oxidant-induced loss of mitochondrial functions. Oxidant stress in mitochondria can promote extramitochondrial activation of NF-kappa B and therefore may affect nuclear gene expression.
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PMID:Role of oxidative stress generated from the mitochondrial electron transport chain and mitochondrial glutathione status in loss of mitochondrial function and activation of transcription factor nuclear factor-kappa B: studies with isolated mitochondria and rat hepatocytes. 747 12

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

Electron transport and production of O2-/H2O2 by the NADH dehydrogenase flavin-semiquinone (FMNH.) and ubisemiquinone (UQH.) were studied in a model of in vivo ischemia-reperfusion in rat kidney. H2O2 production rates were assessed in isolated mitochondria using either succinate, with and without antimycin, or malate-glutamate, with and without rotenone. Respiratory activities of isolated mitochondria and activity of NADH- and succinate-cytochrome c reductase and of NADH- and succinate-dehydrogenase in submitochondrial particles were measured to evaluate the electron flux throughout respiratory carriers. The mitochondrial H2O2 production rate was approximately 1.5- and 4-times increased in ischemic and ischemic-reperfused kidneys, respectively. Ischemia caused a marked decrease in the electron transport throughout the NADH-UQ segment with no significant changes either in the NADH dehydrogenase activity or in the electron flux trough the succinate-cytochrome oxidase segment. Reperfusion did not further affect the NADH-ubiquinone segment but markedly inhibited the succinate-supported oxygen consumption, succinate-cytochrome c reductase and succinate dehydrogenase activity. Our results show a redistribution of the electron flux with an increased rate of superoxide anion/hydrogen peroxide production at NADH dehydrogenase in mitochondria subjected to ischemia only. After 10 min reperfusion an impairment of the electron flow at succinate-cytochrome c segment is established and hydrogen peroxide production by UQH. increases up to maximal values becoming the major source of superoxide anion/hydrogen peroxide.
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PMID:Mitochondrial sites of hydrogen peroxide production in reperfused rat kidney cortex. 772 10

Isolated mitochondria supplemented with succinate or NAD(+)-linked substrates generate hydrogen peroxide (H2O2) in State 4 and the generation is enhanced by antimycin A, an inhibitor of the respiratory chain. Superoxide is a stoichiometric precursor of mitochondrial H2O2 because the ratio of O2-/H2O2 generation rates is close to 2.0 and is generated by an autoxidizable component in the NADH dehydrogenase and the ubiquinone-cytochrome b site. Lipid peroxidation is a free radical-mediated degradation of polyunsaturated fatty acids. Lipid-peroxidation reactions by bovine submitochondrial particles are supported by NADH or NADPH in the presence of ADP-Fe3+ chelate. Electrons from NADH are supplied to the reactions from a component between the substrate site and the rotenone-sensitive site of the NADH dehydrogenase. The peroxidation is dependent on the rate of electron input into the respiratory chain and on the concentration of reduced ubiquinone. Alteration of inner-membrane components and damage to electron-transfer activities of submitochondrial particles are induced by lipid peroxidation. 1-Melhyl-4-phenylpyridinium (MPP+), a metabolite of a parkinsonism-inducing drug, induces NADH-dependent superoxide formation and enhances NADH-dependent lipid peroxidation in submitochondrial particles, indicating that the oxidative stress induced by MPP+ may potentiate its toxicity in dopamine neurons.
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PMID:[Superoxide formation and lipid peroxidation by the mitochondrial electron-transfer chain]. 777 32

Exposure of cells to hydrogen peroxide (H2O2) mediates adaptive responses or oxidative damage, depending on the magnitude of the challenge. Determining the threshold for peroxide-mediated oxidative stress thus requires quantitation of the changes in endogenous H2O2 production. The intracellular steady-state concentrations of H2O2 were measured in intact Escherichia coli under different conditions. Compounds that block electron transport at NADH dehydrogenase (rotenone) or between ubiquinone and cytochrome b (antimycin) showed that univalent reduction of O2 can occur at these sites in vivo to form superoxide anion (O2-), in agreement with reports for mammalian mitochondria. Mutational inactivation of different components of the respiratory chain showed that H2O2 production also depended on the energy status of the cell and on the arrangement of respiratory chain components corresponding to particular growth conditions. Production rates for O2- and H2O2 were linearly related to the number of active respiratory chains that reached maximal values during exponential growth. In the strains defective in respiratory chain components, catalase activity was regulated to compensate for changes in the H2O2 production rates, which maintained intracellular H2O2 at 0.1-0.2 microM during aerobic growth over a wide range of cell densities. The expression of a katG'::lacZ fusion (reporting transcriptional control of the catalase-hydroperoxidase I gene) was increased by H2O2 given either as a pulse or as a steady production. This response not only depended on the type and severity of the stimulus but was also strongly influenced by the growth phase of the cells.
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PMID:Metabolic sources of hydrogen peroxide in aerobically growing Escherichia coli. 777 20

The effects of 1-methyl-4-phenylpyridinium (MPP+) on the oxygen consumption, ATP production, H2O2 production, and mitochondrial NADH-CoQ1 reductase (complex I) activity of isolated rat brain mitochondria were investigated. Using glutamate and malate as substrates, concentrations of 10-100 microM MPP+ had no effect on state 4 (-ADP) respiration but decreased state 3 (+ADP) respiration and ATP production. Incubating mitochondria with ADP for 30 min after loading with varying concentrations of MPP+ produced a concentration-dependent decrease in H2O2 production. Incubation of mitochondria with ADP for 60 min after loading with 100 microM MPP+ caused no loss of complex I activity after washing of MPP+ from the mitochondrial membranes. These data are consistent with MPP+ initially binding specifically to complex I and inhibiting both the flow of reducing equivalents and the production of H2O2 by the mitochondrial respiratory chain, without irreversibly damaging complex I. However, mitochondria incubated with H2O2 in the presence of Cu2+ ions showed decreased complex I activity. This study provides additional evidence that cellular damage initiated by MPP+ is due primarily to energy depletion caused by specific binding to complex I, any increased damage due to free radical production by mitochondria being a secondary effect.
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PMID:Effects of 1-methyl-4-phenylpyridinium on isolated rat brain mitochondria: evidence for a primary involvement of energy depletion. 803 88

A continuation of our structure-activity study on flavonoids possessing varied hydroxyl ring configurations was conducted. We tested six additional flavonoids for their ability to inhibit beef heart mitochondrial succinoxidase and NADH-oxidase activities. In every case, the IC50 observed for the NADH-oxidase enzyme system was lower than for succinoxidase activity, demonstrating a primary site of inhibition in the complex I (NADH-coenzyme Q reductase) portion of the respiratory chain. The order of potency for inhibition of NADH-oxidase activity was robinetin, rhamnetin, eupatorin, baicalein, 7,8-dihydroxyflavone, and norwogonin with IC50 values of 19, 42, 43, 77, 277 and 340 nmol/mg protein, respectively. Flavonoids with adjacent tri-hydroxyl or para-dihydroxyl groups exhibited a substantial rate of auto-oxidation which was accelerated by the addition of cyanide (CN-). Flavonoids possessing a catechol configuration exhibited a slow rate of auto-oxidation in buffer that was stimulated by the addition of CN-. The addition of superoxide dismutase (SOD) and catalase in the auto-oxidation experiments each decreased the rate of oxygen consumption, indicating that O2- and H2O2 are generated during auto-oxidation. In the CN(-)-stimulated oxidation experiments, the addition of SOD also slowed the rate of oxygen consumption. These findings demonstrate that the CN-/flavonoid interaction generated O2- non-enzymatically, which could have biological implications.
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PMID:Inhibition of mitochondrial respiration and cyanide-stimulated generation of reactive oxygen species by selected flavonoids. 811 26

The objective of this study was to explore the possible cause(s) underlying the previously observed, age-related increase in the rate of mitochondrial H2O2 release in the housefly. The hypothesis that an imbalance between different respiratory complexes may be a causal factor was tested. Cytochrome c oxidase activity was found to sharply decline in the latter part of the life span of the flies. Effects of different substrates and respiratory inhibitors were determined in order to ascertain if a decrease in cytochrome c oxidase activity could be responsible for the increased H2O2 release. H2O2 was measured spectrofluorometrically using horseradish peroxidase and p-hydroxphenylacetate as an indicator. Neither NADH-linked substrates nor succinate caused a stimulation of H2O2 production. H2O2 release by mitochondria, inhibited with rotenone and antimycin A, was greatly increased upon supplementation with alpha-glycerophosphate; however, the further addition of KCN or myxothiazol, to such preparations, caused a depression of H2O2 generation. In contrast, relatively low concentrations of KCN or myxothiazol were found to stimulate H2O2 release in insect mitochondria supplemented with alpha-glycerophosphate and exposed to rotenone, but not antimycin A. Results are interpreted to suggest that partial inhibition of cytochrome c oxidase activity can lead to the stimulation of mitochondrial H2O2 production in the housefly at site(s) other than NADH dehydrogenase and ubisemiquinone/cytochrome b region; a possible source may be glycerophosphate dehydrogenase.
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PMID:Aging, cytochrome oxidase activity, and hydrogen peroxide release by mitochondria. 839 19

MPP+ has been reported to inhibit reduced nicotinamide adenine dinucleotide (NADH) dehydrogenase in mitochondria, which results in the formation of O2(.-). The current report demonstrates that H2O2 and HO. are also products of MPP+ interaction with NADH dehydrogenase. It is possible that MPP. formation precedes the formation of some of these active oxygen species. Reducing equivalents for radical formation come from NADH. MPP+ may be capable of interacting with submitochondrial particles at a site other than the rotenone site, which results in some formation of oxygen radicals. Plasma amine oxidase incubations with MPDP+ resulted in O2.- H2O2, and perhaps HO. formation. This is probably due to MPP. formation from the oxidation of MPDP+. This study presents new findings that indicate the potential importance of oxygen radical formation in mitochondria during MPTP toxicity.
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PMID:MPP+ and MPDP+ induced oxygen radical formation with mitochondrial enzymes. 839 43


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