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)

We searched for possible sites of superoxide generation in the complex I segment of the respiratory chain by studying both forward and reverse electron transfer reactions in isolated rat heart mitochondria. Superoxide production was monitored by measuring the release of hydrogen peroxide from mitochondria with a fluorescence spectrophotometer using the Amplex red/horseradish peroxidase system. In the forward electron transfer, a slow superoxide production in the presence of glutamate and malate was enhanced by both rotenone and piericidin A (specific inhibitors at the end of the complex I respiratory chain). Both diphenileneiodonium and ethoxyformic anhydride (inhibitors for respiratory components located upstream of the respiratory chain) inhibited the enhancement by rotenone and piericidin A. In contrast, in reverse electron transfer driven by ATP, both diphenileneiodonium and ethoxyformic anhydride enhanced the superoxide production. Piericidin A also increased superoxide production. Rotenone increased it only in the presence of piericidin A. Our results suggest that the major site of superoxide generation is not flavin, but protein-associated ubisemiquinones which are spin-coupled with iron-sulfur cluster N2.
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PMID:A possible site of superoxide generation in the complex I segment of rat heart mitochondria. 1590 44

Generation of reactive oxygen species (ROS) is increasingly recognized as an important cellular process involved in numerous physiological and pathophysiological processes. Complex I (NADH:ubiquinone oxidoreductase) is considered as one of the major sources of ROS within mitochondria. Yet, the exact site and mechanism of superoxide production by this large membrane-bound multiprotein complex has remained controversial. Here we show that isolated complex I from Yarrowia lipolytica forms superoxide at a rate of 0.15% of the rate measured for catalytic turnover. Superoxide production is not inhibited by ubiquinone analogous inhibitors. Because mutant complex I lacking a detectable iron-sulfur cluster N2 exhibited the same rate of ROS production, this terminal redox center could be excluded as a source of electrons. From the effect of different ubiquinone derivatives and pH on this side reaction of complex I we concluded that oxygen accepts electrons from FMNH2 or FMN semiquinone either directly or via more hydrophilic ubiquinone derivatives.
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PMID:Superoxide radical formation by pure complex I (NADH:ubiquinone oxidoreductase) from Yarrowia lipolytica. 1598 26

Oxidative stress evoked by excitotoxicity is considered an important factor for the loss of dopaminergic neurons in Parkinson's disease. In vitro, protective effects of the dopamine agonist lisuride on complex I inhibition in primary dopaminergic cell culture have been reported. However, little is known about the effects of lisuride on glutamate-induced radical formation. Here, effects of lisuride on the formation of nitric oxide (NO) and superoxide radicals following glutamate exposure were studied on primary cell cultures prepared from mouse mesencephala. Glutamate treatment resulted in doubling of NO and superoxide radical formation, increased dopaminergic cell degeneration and extensively altered neuronal appearance. Pretreatment with lisuride significantly lowered the levels of either reactive species and increased the survival of dopaminergic neurons compared to glutamate-treated cultures. Moreover, the beneficial effect of lisuride could be completely inhibited by the D2/D3 receptor antagonist sulpiride when co-treated in cultures.
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PMID:Glutamate-induced cell death and formation of radicals can be reduced by lisuride in mesencephalic primary cell culture. 1646 21

The effect of the duration of hypoxia on superoxide radical production in isolated rat heart mitochondria was studied by the spin trapping technique. 4,5-Dioxybenzene was used as a spin trap. Samples were placed into the cavity of an EPR spectrometer in thin-wall gas-permeable capillary tubes, which allowed keeping the suspension of mitochondria in aerobic or hypoxic conditions. Previously we have demonstrated that the rate of superoxide generation by mitochondria isolated from postischemic hearts depends radically on the duration of myocardial ischemia. By contrast, in mitochondria isolated from intact hearts, the effect did not depend on the duration of hypoxia. The rate of superoxide production by isolated mitochondria in the presence of antimycin A (a complex III Q-cycle inhibitor) and complex I or complex II substrates was 0.9 +/- 0.1 nmole O2*- /min/mg protein at 25 degrees C. Under reoxygenation conditions, after 10 min of hypoxia, the rate of superoxide production was considerably higher than before hypoxia. At the same time, after prolonged hypoxia, its value was practically the same as after 10-min hypoxia. The results enable the conclusion that isolated mitochondria are less sensitive to hypoxic conditions than mitochondria in ischemic heart.
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PMID:[Production of oxygen free radicals by cardiac mitochondria: effect of hypoxia-reoxygenation]. 1680 47

We used fluorescent probes and EPR to study the mechanism(s) underlying reactive oxygen species (ROS) production by endothelial cell mitochondria and the action of mitoquinol, a mitochondria-targeted antioxidant. ROS measured by fluorescence resulted from complex I superoxide released to the matrix and converted to H(2)O(2). In contrast, EPR largely detected superoxide generated at complex III and effluxed outward. ROS fluorescence by mitochondria fueled by the complex II substrate, succinate, was substantial but markedly inhibited by rotenone. Superoxide, detected by EPR, in succinate-fueled mitochondria was not inhibited by rotenone and likely derived from semiquinone formation at complex III. Mitoquinol decreased H(2)O(2) fluorescence by succinate-fueled mitochondria but had little effect on the EPR signal for superoxide. This was not associated with a detectable decrease in membrane potential. Mitoquinol markedly enhanced ROS fluorescence in mitochondria fueled by the complex I substrates, glutamate and malate. Inhibitor studies suggested that this occurred in complex I, at one or more Q binding pockets. The above effects of mitoquinol were determined in mitochondria isolated and subsequently exposed to the targeted antioxidant. However, similar effects were observed in mitochondria after antecedent exposure to mitoquinol/mitoquinone in culture, suggesting that the agent is retained after isolation of the organelles. In conclusion, ROS production in bovine aortic endothelial cell mitochondria results largely from reverse transport to complex I and through the Q cycle in complex III. Mitoquinol blocks ROS from reverse electron transport but increases superoxide production derived from forward transport. These effects likely occur at one or more Q binding sites in complex I.
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PMID:Reactive oxygen and targeted antioxidant administration in endothelial cell mitochondria. 1706 Mar 16

NADH dehydrogenase subunit 2, encoded by the mtDNA, has been associated with resistance to autoimmune type I diabetes (T1D) in a case control study. Recently, we confirmed a role for the mouse ortholog of the protective allele (mt-Nd2(a)) in resistance to T1D using genetic analysis of outcrosses between T1D-resistant ALR and T1D-susceptible NOD mice. We sought to determine the mechanism of disease protection by elucidating whether mt-Nd2(a) affects basal mitochondrial function or mitochondrial function in the presence of oxidative stress. Two lines of reciprocal conplastic mouse strains were generated: one with ALR nuclear DNA and NOD mtDNA (ALR.mt(NOD)) and the reciprocal with NOD nuclear DNA and ALR mtDNA (NOD.mt(ALR)). Basal mitochondrial respiration, transmembrane potential, and electron transport system enzymatic activities showed no difference among the strains. However, ALR.mt(NOD) mitochondria supported by either complex I or complex II substrates produced significantly more reactive oxygen species when compared with both parental strains, NOD.mt(ALR) or C57BL/6 controls. Nitric oxide inhibited respiration to a similar extent for mitochondria from the five strains due to competitive antagonism with molecular oxygen at complex IV. Superoxide and hydrogen peroxide generated by xanthine oxidase did not significantly decrease complex I function. The protein nitrating agents peroxynitrite or nitrogen dioxide radicals significantly decreased complex I function but with no significant difference among the five strains. In summary, mt-Nd2(a) does not confer elevated resistance to oxidative stress; however, it plays a critical role in the control of the mitochondrial reactive oxygen species production.
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PMID:Nuclear and mitochondrial interaction involving mt-Nd2 leads to increased mitochondrial reactive oxygen species production. 1718 52

Deficiency of NADH:ubiquinone oxidoreductase or complex I (CI) is the most common cause of disorders of the oxidative phosphorylation system in humans. Using life cell imaging and blue-native electrophoresis we quantitatively compared superoxide production and CI amount and activity in cultured skin fibroblasts of 7 healthy control subjects and 21 children with inherited isolated CI deficiency. Thirteen children had a disease causing mutation in one of the nuclear-encoded CI subunits, whereas in the remainder the genetic cause of the disease is not yet established. Superoxide production was significantly increased in all but two of the patient cell lines. An inverse relationship with the amount and residual activity of CI was observed. In agreement with this finding, rotenone, a potent inhibitor of CI activity, dose-dependently increased superoxide production in healthy control cells. Also in this case an inverse relationship with the residual activity of CI was observed. In sharp contrast, however, rotenone did not decrease the amount of CI. The data presented show that superoxide production is increased in inherited CI deficiency and that this increase is primarily a consequence of the reduction in cellular CI activity and not of a further leakage of electrons from mutationally malformed complexes.
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PMID:Superoxide production is inversely related to complex I activity in inherited complex I deficiency. 3330 40

In intact U937 cells, peroxynitrite promotes the mitochondrial formation of superoxide via a Ca2+-dependent mechanism involving inhibition of complex III. Superoxide then readily dismutates to H2O2 causing lesions on different biomolecules, including DNA. Here we show that formation of H2O2 and DNA damage are suppressed by inhibition of complex I (by rotenone) or ubisemiquinone formation (by myxothiazol), as well as by a variety of manipulations preventing either the mobilization of Ca2+ or its mitochondrial accumulation. In addition, complex III inhibitors promoted rotenone- or myxothiazol-sensitive formation of H2O2 and DNA strand scission in cells exposed to otherwise inactive concentrations of peroxynitrite. However, under these conditions, the intra-mitochondrial concentration of Ca2+ remained unchanged and the effects of peroxynitrite therefore take place via Ca2+-independent mechanisms. H2O2 formation was paralleled by, and causally linked to, the loss of mitochondrial membrane potential associated with the mitochondrial release of cytochrome c and AIF, and with the mitochondrial accumulation of Bax. These events, although Ca2+ independent, were rapidly followed by death mediated by mitochondrial permeability transition, generally considered a typical Ca2+-dependent event. Thus, enforced inhibition of complex III promotes the loss of Ca2+ dependence of those mitochondrial mechanisms regulating superoxide formation and mitochondrial permeability transition evoked by peroxynitrite.
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PMID:Inhibition of complex III promotes loss of Ca2+ dependence for mitochondrial superoxide formation and permeability transition evoked by peroxynitrite. 1750 11

NO (nitric oxide) can affect mitochondrial function by interacting with the cytochrome c oxidase (complex IV) of the electron transport chain in a manner that is reversible and in competition with oxygen. Concentrations of NO too low to inhibit respiration can trigger cell defence response mechanisms involving reactive oxygen species and various signalling molecules such as nuclear factor kappaB and AMP kinase. Inhibition of mitochondrial respiration by NO at low oxygen concentrations can cause so-called metabolic hypoxia and divert oxygen towards other oxygen-dependent systems. Such a diversion reactivates prolyl hydroxylases and thus accounts for the prevention by NO of the stabilization of hypoxia-inducible transcription factor. In certain circumstances NO interacts with superoxide radical to form peroxynitrite, which can affect the action of key enzymes, such as mitochondrial complex I, by S-nitrosation. This chapter discusses the physiological and pathophysiological implications of the interactions of NO with the cytochrome c oxidase.
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PMID:Nitric oxide and hypoxia. 1770 91

Despite the considerable interest in superoxide as a potential cause of pathology, the mechanisms of its deleterious production by mitochondria remain poorly understood. Previous studies in purified mitochondria have found that the highest rates of superoxide production are observed with succinate-driven reverse-electron transfer through complex I, although the physiological importance of this pathway is disputed because it necessitates high concentrations of succinate and is thought not to occur when NAD is in the reduced state. However, very few studies have examined the rates of superoxide production with mitochondria respiring on both NADH-linked (e.g. glutamate) and complex II-linked substrates. In the present study, we find that the rates of superoxide production (measured indirectly as H2O2) with glutamate+succinate (approximately 1100 pmol of H2O2 x min(-1) x mg(-1)) were unexpectedly much higher than with succinate (approximately 400 pmol of H2O2 x min(-1) x mg(-1)) or glutamate (approximately 80 pmol of H2O2 x min(-1) x mg(-1)) alone. Superoxide production with glutamate+succinate remained high even at low substrate concentrations (<1 mM), was decreased by rotenone and was completely eliminated by FCCP (carbonyl cyanide p-trifluoromethoxyphenylhydrazone), indicating that it must in large part originate from reverse-electron transfer through complex I. Similar results were obtained when glutamate was replaced with pyruvate, alpha-ketoglutarate or palmitoyl carnitine. In contrast, superoxide production was consistently lowered by the addition of malate (malate+succinate approximately 30 pmol of H2O2 x min(-1) x mg(-1)). We propose that the inhibitory action of malate on superoxide production can be explained by oxaloacetate inhibition of complex II. In summary, the present results indicate that reverse-electron transfer-mediated superoxide production can occur under physiologically realistic substrate conditions and suggest that oxaloacetate inhibition of complex II may be an adaptive mechanism to minimize this.
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PMID:High rates of superoxide production in skeletal-muscle mitochondria respiring on both complex I- and complex II-linked substrates. 1791 65


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