Glycerophosphate-dependent hydrogen peroxide production by brown adipose tissue mitochondria and its activation by ferricyanide

Oxidation of glycerophosphate (GP) by brown adipose tissue mitochondria in the presence of antimycin A was found to be accompanied by significant production of hydrogen peroxide. GP-dependent hydrogen peroxide production could be detected by p-hydroxyphenylacetate fluorescence changes or as an antimycin A-insensitive oxygen consumption. One-electron acceptor, potassium ferricyanide, highly stimulated the rate of GP-dependent antimycin A-insensitive oxygen uptake, which was prevented by inhibitors of mitochondrial GP dehydrogenase (mGPDH) or by coenzyme Q(CoQ). GP-dependent ferricyanide-induced peroxide production was also determined luminometrically, using mitochondria or partially purified mGPDH. Ferricyanide-induced peroxide production was negligible, when succinate or NADH was used as a substrate. These results indicate that hydrogen peroxide is produced directly by mGPDH and reflect the differences in the transport of reducing equivalents from mGPDH and succinate dehydrogenase to the CoQ pool. The data suggest that more intensive production of reactive oxygen species may be present in mammalian cells with active mGPDH.     

Evidence for water as the product for oxygen reduction by cytochrome cd.

Evidence is presented that water is the final product of electron donation to molecular oxygen by cytochrome $\text{cd}$ from $\text{Paracoccus}\text{denitrificans}$ when ferrocytochrome $\text{c}$ acts as donor to $\text{cd}$. Negative evidence for the accumulation of superoxide and peroxide was obtained by rate effect experiments in the presence of superoxide dismutase, catalase, and peroxidase. Positive evidence for water was obtained by showing a 4 to 1 stoichiometric balance for rates of electron acceptance from ferrocytochrome $\text{c}$ to rates of donation to molecular oxygen.     

Mitochondrial catalase and oxidative injury

Mitochondria dysfunction induced by reactive oxygen species (ROS) is related to many human diseases and aging. In physiological conditions, the mitochondrial respiratory chain is the major source of ROS. ROS could be reduced by intracellular antioxidant enzymes including superoxide dismutase, glutathione peroxidase and catalase as well as some antioxidant molecules like glutathione and vitamin E. However, in pathological conditions, these antioxidants are often unable to deal with the large amount of ROS produced. This inefficiency of antioxidants is even more serious in mitochondria, because mitochondria in most cells lack catalase. Therefore, the excessive production of hydrogen peroxide in mitochondria will damage lipid, proteins and mDNA, which can then cause cells to die of necrosis or apoptosis. In order to study the important role of mitochondrial catalase in protecting cells from oxidative injury, a HepG2 cell line overexpressing catalase in mitochondria was developed by stable transfection of a plasmid containing catalase cDNA linked with a mitochondria leader sequence which would encode a signal peptide to lead catalase into the mitochondria. Mitochondria catalase was shown to protect cells from oxidative injury induced by hydrogen peroxide and antimycin A. However, it increased the sensitivity of cells to tumor necrosis factor-alpha-induced apoptosis by changing the redox-oxidative status in the mitochondria. Therefore, the antioxidative effectiveness of catalase when expressed in the mitochondrial compartment is dependent upon the oxidant and the locus of ROS production.     

Superoxide and hydrogen peroxide production and NADPH oxidation stimulated by nitrofurantoin in lung microsomes: possible implications for toxicity.

The addition of nitrofurantoin to aerobic incubation mixtures containing rat lung microsomes strongly enhanced the generation of adrenochrome from epinephrine. Adrenochrome formation in this system was blocked by superoxide dismutase, but not by catalase. Hydrogen peroxide production was also strongly enhanced by nitrofurantoin in these preparations; superoxide dismutase did not significantly alter the amount of H₂O₂ measured, but no H₂O₂ was detected in incubation mixtures in the presence of catalase. Nitrofurantoin enhanced the oxidation of NADPH in lung microsomal suspensions under aerobic conditions; the enhancement was unaffected by catalase but was partially prevented by superoxide dismutase. Neither adrenochrome formation nor H₂O₂ production were enhanced by nitrofurantoin under anaerobic (N₂) conditions, but NADPH oxidation in the presence of nitrofurantoin was greater under anaerobic conditions than under aerobic conditions. These results are consistent with the view that the redox cycling of nitrofurantoin in lung microsomes in the presence of oxygen results in the consumption of NADPH and the production of activated oxygen species, emphasizing some $\text{in vitro}$ metabolic similarities with the lung-toxic herbicide, paraquat.     

The intramitochondrial location of cytochrome c peroxidase in wild-type and petite Saccharomyces cerevisiae

Cytochemical and ultrastructural analysis of wild-type cells of Saccharomyces cerevisiac, grown aerobically in a glucose-limited chemostat, shows that cytochrome c peroxidase is localized between the membranes of the cristae, that is, in the intracristal space. This enzyme is thus positioned appropriately within the organelle to act as an alternate terminal oxidase for the respiratory chain. The proximity of the peroxidase to major sites of generation of its two substrates may account for the small leakage of hydrogen peroxide from yeast mitochondria, as compared with the larger outflow from mammalian mitochondria.In the cytoplasmic petite mutant, gross distortion of promitochondrial membrane arrangement is evident. Nevertheless, cytochrome c peroxidase activity is present in the same amounts as is found in wildtype cell, and is localized predominantly within annuli of membrane which constitute the promitochondria in these cells.No unequivocal evidence was obtained for the localization of catalase in microbodies or other organelles in either wild-type or petite cells.     

The contribution of thioredoxin-2 reductase and glutathione peroxidase to H2O2 detoxification of rat brain mitochondria

Brain mitochondria are not only major producers of reactive oxygen species but they also considerably contribute to the removal of toxic hydrogen peroxide by the glutathione (GSH) and thioredoxin-2 (Trx2) antioxidant systems. In this work we estimated the relative contribution of both systems and catalase to the removal of intrinsically produced hydrogen peroxide (H₂O₂) by rat brain mitochondria. By using the specific inhibitors auranofin and 1-chloro-2,4-dinitrobenzene (DNCB), the contribution of Trx2- and GSH-systems to reactive oxygen species (ROS) detoxification in rat brain mitochondria was determined to be 60 ± 20% and 20 ± 15%, respectively. Catalase contributed to a non-significant extent only, as revealed by aminotriazole inhibition. In digitonin-treated rat hippocampal homogenates inhibition of Trx2- and GSH-systems affected mitochondrial hydrogen peroxide production rates to a much higher extent than the endogenous extramitochondrial hydrogen peroxide production, pointing to a strong compartmentation of ROS metabolism. Imaging experiments of hippocampal slice cultures showed on single cell level substantial heterogeneity of hydrogen peroxide detoxification reactions. The strongest effects of inhibition of hydrogen peroxide removal by auranofin or DNCB were detected in putative interneurons and microglial cells, while pyramidal cells and astrocytes showed lower effects. Thus, our data underline the important contribution of the Trx2-system to hydrogen peroxide detoxification in rat hippocampus. This article is part of a Special Issue entitled: 17th European Bioenergetics Conference (EBEC 2012).     

The use of 3-amino-1,2,4-triazole to investigate the short-term effects of oxygen toxicity on carbon assimilation by Pisum sativum seedlings

To study the in vivo short-term effect of hydrogen peroxide on plant metabolism, 2 mol m^?3 3-amino-1,2,4-triazole, a catalase inhibitor, was applied through the transpiration stream to Pisum sativum seedlings, and gas exchange characteristics, ascorbate peroxidase, glutathione reductase and catalase activities, and levels of hydrogen peroxide and formate were determined. Carbon dioxide assimilation rates were inhibited after the addition of aminotriazole: photorespiratory conditions exacerbated this inhibition. Carbon dioxide response curves showed that aminotriazole reduced both the RuBP regeneration rate and the efficiency of the carboxylation reaction of Rubisco. Catalase activity was completely inhibited 200 min after the application of this inhibitor, but no concomitant increase in H₂O₂ concentration was found. Under enhanced photorespiratory conditions, H₂O₂ concentrations increased. This suggests that under normal environmental conditions hydrogen peroxide is metabolized via alternative mechanisms. The aminotriazole treatment had no effect on the ascotbate peroxidase and glutathione reductase activities, but caused a substantial increase in the formate pool size. These results suggest that hydrogen peroxide is metabolized by reacting with glyoxylate to produce formate and CO₂. The increased production of formate may reduce the flow of carbon through the normal photorespiratory pathway and may also be used anaplerotically as a precursor of products of 1-C metabolism other than serine. This would prevent the return of photorespiratory carbon to the RPP pathway, leading to a smaller RuBP pool size which would in turn result in a decrease in carboxylation conductance (carboxylation efficiency) and regeneration rate of RuBP.     

Effect of electron-transport inhibitors on the generation of reactive oxygen species by pea mitochondria during succinate oxidation

The effect of inhibitors of the cytochrome pathway and alternative oxidase on the rate of respiration and generation of reactive oxygen species by pea mitochondria was studied. Respiration of mitochondria from pea cotyledons was inhibited by 70-80% by salicylhydroxamate (SHAM). The rate of hydrogen peroxide production by pea cotyledon mitochondria during succinate oxidation was 0.15 nmol/min per mg protein. SHAM considerably accelerated the hydrogen peroxide production. The SHAM-dependent H₂O₂ production was stimulated by 2 M antimycin A and inhibited by 5 mM KCN and 1 M myxothiazol. The study of the rate of generation by pea mitochondria using EPR spin traps and epinephrine oxidation showed that H₂O₂ accumulation can be accounted for by a significant increase in the rate of production.     

Ethanol metabolism in guinea pig: Ethanol oxidation and its effect on NADNADH ratios,oxygen consumption,and ketogenesis in isolated hepatocytes of fed and fasted animals

Ethanol metabolism was studied in isolated hepatocytes of fed and fasted guinea pigs. Alcohol dehydrogenase (EC 1.1.1.1) activities of fed or fasted liver cells were 2.04 and 1.88 μmol/g cells/min, respectively. Under a variety of in vitro conditions, alcohol dehydrogenase operates in fed hepatocytes at 34–74% and in fasted liver cells at 23–61% of its maximum velocity, respectively. Hepatocytes of fed animals, incubated in Krebs-Ringer bicarbonate buffer, oxidized ethanol at an average rate of 0.69 μmol/g wet weight cells/min, whereas cells of 48-h fasted animals consumed only 0.44 μmol/g/min under identical conditions. Various substrates and metabolites of intermediary metabolism significantly enhanced ethanol oxidation in fed liver cells. Maximum stimulatory effects were achieved with alanine (+138%) and pyruvate (+102%), followed in decreasing order by propionate, lactate, fructose, dihydroxyacetone, and galactose. In contrast to substrate couples such as lactate/pyruvate and glycerol/dihydroxyacetone, sorbitol with or without fructose significantly inhibited ethanol oxidation. The addition of hydrogen shuttle components such as malate, aspartate, or glutamate to fasted hepatocytes resulted in significantly higher stimulation of ethanol uptake than in fed hepatocytes. Also, the degree of inhibition of shuttle activity by n-butylmalonate was more pronounced in fasted liver cells (77% inhibition) than in fed cells (59% inhibition). These data as well as oxygen kinetic studies in intact guinea pig hepatocytes utilizing uncouplers (carbonyl cyanide-p-trifluoromethoxyphenylhydrazone, dinitrophenol), electron-transport inhibitors (rotenone, antimycin), and malate-aspartate shuttle inhibitors (aminooxyacetate, n-butylmalonate) strongly suggested that the malate-aspartate shuttle is the predominant hydrogen transport system during ethanol oxidation in guinea pig liver.Comparison of the alcohol dehydrogenase-inhibitors 4-methylpyrazole and pyrazole on ethanol oxidation demonstrated that the alcohol dehydrogenase system is quantitatively the most important alcohol-metabolizing pathway in guinea pig liver. Supporting this conclusion, it was found that the H₂O₂-forming substrate glycolate slightly increased ethanol oxidation in liver cells of control animals (+26%), but prior inhibition of catalase by 3-amino-1,2,4-triazole resulted in a significant increase (+25%) instead of a decrease in alcohol oxidation. This finding does not support a quantitatively important role of peroxidatic oxidation of ethanol by catalase in liver.Cytosolic $\text{NAD}\text{NADH}$ ratios were greatly shifted toward reduction during ethanol oxidation. These reductive shifts were even more pronounced when cells were incubated in the presence of fatty acids (octanoate, oleate) plus ethanol. Inhibitor studies with 4-methylpyrazole demonstrated that the decrease of the cytosolic $\text{NAD}\text{NADH}$ ratio during fatty acid oxidation was due to an inhibition of hydrogen transport from cytosol to mitochondria and not the result of transfer of hydrogen, generated by fatty acid oxidation, from mitochondria to cytosol. Lactate plus pyruvate formation was slightly inhibited by ethanol in fed hepatocytes but greatly accelerated in fasted cells; this latter effect was mostly the result of increased lactate formation. Such regulation may represent a hepatic mechanism of alcoholic lactic acidosis as observed in human alcoholics. The ethanol-induced decrease of the mitochondrial $\text{NAD}\text{NADH}$ ratio was prevented by addition of 4-methylpyrazole. Endogenous ketogenesis was greatly increased (+80%) by ethanol in fed liver cells. This effect of ethanol was blunted in the presence of glucose. Propionate, by competing with fatty acid oxidation, was strongly antiketogenic. This effect was alleviated by ethanol. In 48-h fasted hepatocytes, endogenous ketogenesis was enhanced by 84%. Although ethanol did not further stimulate endogenous ketogenesis under these conditions, alcohol significantly increased ketogenesis in the presence of octanoate or oleate. This stimulatory effect of ethanol was almost completely prevented by 4-methylpyrazole. These findings demonstrate that the syndrome of alcoholic ketoacidosis may be due, at least partially, to the additional stimulation of ketogenesis by or from ethanol during fatty acid oxidation in the fasting state.     

Mechanism of the enzyme-catalyzed bioluminescent oxidation of coelenterate-type luciferin.

The use of a fully active, synthetic analogue of coelenterate-type luciferin labeled in the carbonyl position with ¹⁴C and ¹⁸O was used to probe the mechanism of the $\text{Renilla}$ luciferase catalyzed oxidative decarboxylation of this compound. In the presence of ¹⁷O₂, the CO₂ produced in this oxidation can be shown to contain approximately one ¹⁷O atom per CO₂ molecule. This result is consistent with a cyclic peroxide or dioxetanone-type mechanism. In the presence of luciferase, the oxygen in the luciferin carbonyl group is rapidly exchanged with solvent water prior to the production of CO₂. Thus, the $\text{reaction}$ CO₂ contains considerable oxygen derived from water, via exchange with the carbonyl group, and about one oxygen from O₂ via a cyclic peroxide.     

Tetrahydropterin: Reduction of cytochrome c and coupled phosphorylation at mitochondrial site 3

Incubation of rat liver mitochondria with tetrahydropterin results in ATP production with a P:O ratio of 0.85, consistent with the entry of reducing equivalents into the mitochondrial electron transport chain at cytochrome $\text{c}$. No evidence for an enzymatic reduction of cytochrome $\text{c}$ was found. The reduction of either soluble or mitochondrial cytochrome $\text{c}$ was not diminished by superoxide dismutase or anaerobic conditions, indicating that the reaction is not dependent on the autoxidation of the reduced pterin and the formation of an active species of oxygen. The experiments indicate a potential pathway for the production of ATP coupled to the oxidation of NADPH through the activity of NADPH-dependent pteridine reductases.     

Evaluation of relative contributions of two enzymes supposed to metabolise hydrogen peroxide in Paracoccus denitrificans

A biosensor exploiting an electrochemically mediated enzyme-catalysed reaction was used to quantify relative contributions of cytoplasmic catalase and periplasmic cytochrome c peroxidase to the overall rate of hydrogen peroxide breakdown in cells of Paracoccus denitrificans. The effects of antimycin (an inhibitor of electron flow to cytochrome c peroxidase), the reaction rate versus substrate concentration profiles for the whole cells and subcellular fractions, and the time courses of oxygen concentration demonstrated a profound decrease in the capacity of cytochrome c peroxidase to reduce H2O2 under in vivo conditions. The reason is suggested to be a competition for available electrons between the enzyme and terminal oxidases metabolising oxygen produced by catalase.     

Effect of 24-Epibrassinolide on Antioxidative Defence System Against Lead-Induced Oxidative Stress in The Roots of <Emphasis Type="Italic">Brassica juncea</Emphasis> L. Seedlings

Lead (Pb) toxicity causes oxidative stress by increasing the production of reactive oxygen species. The aim of the present study was to investigate the role of 24-epibrassinolide (24-EBL) on the antioxidant defence system as a response to Pb stress in Brassica juncea L. Surface-sterilized seeds were exposed to Pb ion (0 and 2 mM) toxicity in Petri dishes and subsequently, the seeds were sprayed with either (i) deionized water or (ii) different concentrations (10^–12, 10^–10, and 10^–8 M) of 24-EBL on alternate days. After nine days, the roots of the B. juncea seedlings were harvested to analyze the heavy metal content, root length, hydrogen peroxide level, lipid peroxidation, total protein content and activities of the antioxidant enzymes (superoxide dismutase, catalase, ascorbate peroxidase, peroxidase, glutathione reductase and glutathione-S-transferase). According to our results, the Pb ions accumulated by the B. juncea roots led to oxidative stress by increasing the level of H₂O₂ and malondialdehyde, and thus, increased the activity of the antioxidative enzymes (except for catalase) and the growth and total protein content decreased. Whereas, the 24-EBL treatment to the roots of Pb stressed seedlings was able to alleviate the Pb-induced oxidative stress. Upon the application of 24-EBL, a reduction in Pb accumulation, H₂O₂ and malondialdehyde levels as well as an increased total protein content and activity of antioxidative enzymes detoxifying hydrogen peroxide (catalase, ascorbate peroxidase and peroxidase) were observed. As a result, the stress protective properties of 24-EBL depending on concentration in B. juncea roots were revealed in this study.     

Electron acceptor function of O2 in radical N-demethylation reactions catalyzed by hemeproteins

In aerobic solutions, O₂ consumption correlated well with N-demethylation of N,N-dimethyl-$\text{p}$-toluidine catalyzed by horseradish peroxidase, in the presence or absence of H₂O₂. In the absence of added H₂O₂, superoxide dismutase stimulated, and catalase inhibited, both reactions; in the presence of H₂O₂, argon inhibition of formaldehyde production increased with increasing concentration of horseradish peroxidase. These results provide evidence for competing reactions of the enzymatically-generated substrate radical: oxidation by O₂ increases formaldehyde production, while radical dimerization decreases the yield of this product. Implications of these findings for similar reactions catalyzed by microsomal cytochrome P-450 are suggested.     

Adenine nucleotide control of the rate of oxygen uptake by rat heart mitochondria over a 15- to 20-fold range

Rat heart mitochondria oxidizing pyruvate (in the presence of 20% as much malate) took up nearly the amount of oxygen required for complete oxidation to CO₂. Thus pyruvate, a physiological substrate of the citrate cycle, is oxidized through the entire cycle in these mitochondria, and they seem suitable for study of regulation of integrated mitochondrial energy transduction. By addition of graded amounts of hexokinase or pyruvate kinase to the suspending medium (in the presence of excess glucose or phosphoenolpyruvate), a wide range of steady-state values of the $\text{ATP}\text{ADP}$ concentration ratio was obtained. At a constant concentration of phosphate, the steady-state rate of oxygen uptake by rat heart mitochondria oxidizing pyruvate was a function of the adenylate energy charge or of the $\text{ATP}\text{ADP}$ ratio, and relatively independent of the absolute concentrations of these nucleotides. The oxygen uptake rates typically spanned a range of about 20-fold. At very high values of the $\text{ATP}\text{ADP}$ ratio, the rate of oxygen uptake is much lower than the “state 4” rate seen after added ADP has been phosphorylated. This result suggests that “state 4” respiration, at least in these freshly prepared mitochondria, measures the rate at which ADP is made available by ATPase activity, rather than indicating uncoupling of electron transport from phosphorylation. The concentration of orthophosphate affected the rate of oxygen uptake and the pattern of response to the $\text{ATP}\text{ADP}$ ratio or the energy charge, but the effects did not seem interpretable in terms of the mass-action expression for hydrolysis of ATP, $\text{(ATP}\text{ADP)}$ (P_i.     

ESR characterization of chitins and chitosans.

Chitins and chitosans from crabs and shrimps as well as the chitosan-glucan complex from $\text{Aspergillus niger}$ show an ESR singlet at 3387–3391 G and $\text{g}$ values 2.00117-200354; this signal is altered by the action of oxygen from the atmosphere and from hydrogen peroxide, and by hot water.     

Oxidative stress in myelin sheath: The other face of the extramitochondrial oxidative phosphorylation ability

Abstract

Oxidative phosphorylation (OXPHOS) is not only the main source of ATP for the cell, but also a major source of reactive oxygen species (ROS), which lead to oxidative stress. At present, mitochondria are considered the organelles responsible for the OXPHOS, but in the last years we have demonstrated that it can also occur outside the mitochondrion. Myelin sheath is able to conduct an aerobic metabolism, producing ATP that we have hypothesized is transferred to the axon, to support its energetic demand.

In this work, spectrophotometric, cytofluorimetric, and luminometric analyses were employed to investigate the oxidative stress production in isolated myelin, as far as its respiratory activity is concerned. We have evaluated the levels of malondialdehyde (MDA) and 4-hydroxynonenal (4-HNE), markers of lipid peroxidation, as well as of hydrogen peroxide (H₂O₂), marker of ROS production. To assess the presence of endogenous antioxidant systems, superoxide dismutase, catalase, and glutathione peroxidase activities were assayed. The effect of certain uncoupling or antioxidant molecules on oxidative stress in myelin was also investigated.

We report that isolated myelin produces high levels of MDA, 4-HNE, and H₂O₂, likely through the pathway composed by Complex I–III–IV, but it also contains active superoxide dismutase, catalase, and glutathione peroxidase, as antioxidant defense. Uncoupling compounds or Complex I inhibitors increase oxidative stress, while antioxidant compounds limit ROS generation.

Data may shed new light on the role of myelin sheath in physiology and pathology. In particular, it can be presumed that the axonal degeneration associated with myelin loss in demyelinating diseases is related to oxidative stress caused by impaired OXPHOS.     

DNA strand scission in E.coli by electronically excited state molecules generated by enzymatic systems

$\text{E.}\text{coli}$ containing pAT 153 plasmid undergoes strand scission when exposed to the indole-3-acetic acid/peroxidase/D₂ system. Neither the initial components of this reaction nor the final stable products are responsible for this effect. Indole-3-aldehyde in its triplet state and singlet oxygen have been recently identified in this system. That singlet oxygen is one of the species acting on the plasmid in $\text{E.}\text{coli}$ cells was suggested by protective effect of histidine and guanosine which are singlet oxygen quenchers. Similar effect on plasmid with malonaldehyde/peroxidase/O₂ system was observed, which is an excellent singlet oxygen generator. This is the first report of a biological system where it is possible to detect a DNA scission in the intact cell by a bioenergized process. This presumably is related to spontaneous mutagenesis.     

Interdependence between mitochondrial matrix volume and the extramitochondrial ratio of [ATP]/[ADP] [inorganic phosphate].

ATP or combinations of ATP with EDTA and EGTA can act as chelators to support succinate-driven, phosphate-requiring expansion of mitochondrial inner membrane-matrices. Contraction of these swollen mitochondria can be induced with antimycin, MgCl₂ and ADP. The magnitude of ADP-induced contraction of mitochondria, swollen in the presence of ATP, is dependent on [ADP] and may be altered by the extramitochondrial concentrations of both P_i and ATP. In fact, the extent of contraction (+ΔA₅₂₀) is a linear function of the thermodynamic parameter, ?ΔGp (free energy of hydrolysis of ATP), provided excessive concentrations of reactants are not present and the extents of matrix swelling are similar ($\text{e.g.}\text{ΔA}{}_{520}$ is about 0.250) before starting contraction with ADP.