METABOLISM OF GLUCOSE AND FREE AMINO ACIDS IN BRAIN, STUDIED WITH 14C-LABELLED GLUCOSE AND BUTYRATE IN RATS INTOXICATED WITH CARBON DISULPHIDE

Abstract— The effect of 15 h continuous exposure to CS₂ on the metaboliam of glucose and free amino acids in the brain of rats was studied. CS₂ caused a moderate hypoglycaemia. There were also changes in the amounts of some amino acids in the brain. Glutamate and γ-aminobutyrate were lower whereas glutamine was markedly increased. Comparative studies in vivo of the metabolism of [2-¹⁴C]glucose and [1-¹⁴C]butyrate indicated that CS₂ did not affect glycolysis or the incorporation of ¹⁴C from glucose into amino acids except into γ-aminobutyrate which was reduced. Contrary to the findings with [¹⁴C]glucose, CS₂ provoked distinct changes in the labelling of amino acids when [¹⁴C]butyrate was the precursor. The most notable change was a markedly increased incorporation of ¹⁴C into glutamine. Based on the two-compartment model of brain glutamate the experimental findings indicated that CS₂ affected metabolism associated with the 'small' pool of glutamate but had a minimal effect on metabolism associated with the 'large' glutamate pool. The possibility is suggested that the changes observed involved an increased rate of ammonia removal. The low incorporation of ¹⁴C into γ-aminobutyrate from either precursor is consistent with other evidence showing that CS₂ interferes with pyridoxal phosphate-dependent enzymes.     

c-Jun N-terminal kinase regulates mitochondrial bioenergetics by modulating pyruvate dehydrogenase activity in primary cortical neurons

This study examines the role of c- jun N-terminal kinase (JNK) in mitochondrial signaling and bioenergetics in primary cortical neurons and isolated rat brain mitochondria. Exposure of neurons to either anisomycin (an activator of JNK/p38 mitogen-activated protein kinases) or H₂O₂ resulted in activation (phosphorylation) of JNK (mostly p46^JNK1) and its translocation to mitochondria. Experiments with mitochondria isolated from either rat brain or primary cortical neurons and incubated with proteinase K revealed that phosphorylated JNK was associated with the outer mitochondrial membrane; this association resulted in the phosphorylation of the E_1α subunit of pyruvate dehydrogenase, a key enzyme that catalyzes the oxidative decarboxylation of pyruvate and that links two major metabolic pathways: glycolysis and the tricarboxylic acid cycle. JNK-mediated phosphorylation of pyruvate dehydrogenase was not observed in experiments carried out with mitoplasts, thus suggesting the requirement of intact, functional mitochondria for this effect. JNK-mediated phosphorylation of pyruvate dehydrogenase was associated with a decline in its activity and, consequently, a shift to anaerobic pyruvate metabolism: the latter was confirmed by increased accumulation of lactic acid and decreased overall energy production (ATP levels). Pyruvate dehydrogenase appears to be a specific phosphorylation target for JNK, for other kinases, such as protein kinase A and protein kinase C did not elicit pyruvate dehydrogenase phosphorylation and did not decrease the activity of the complex. These results suggest that JNK mediates a signaling pathway that regulates metabolic functions in mitochondria as part of a network that coordinates cytosolic and mitochondrial processes relevant for cell function.     

The plant mitochondrial proteome and the challenge of defining the posttranslational modifications responsible for signalling and stress effects on respiratory functions

The mitochondrion is the principle organelle in plant aerobic respiration, where the oxidation of organic acids to CO₂ and H₂O, combined with the coupling of electron transfer to O₂ via the respiratory electron transport chain to adenosine triphosphate synthesis, takes place. Plant mitochondria also have important secondary roles, such as the synthesis of nucleotides, amino acids, lipids, prosthetic groups and vitamins. They also interact with chloroplasts and peroxisomes through a series of primary metabolic pathways. By using proteomic tools such as polyacrylamide gel-based and mass spectrometry-based methods, over 400 proteins, including 30 proteins from the tricarboxylic acid cycle, 78 proteins from the electron transport chain and more than 20 proteins from amino acid metabolism pathways have been identified in mitochondria of the model plant, Arabidopsis thaliana . Beyond the mitochondrial proteome, there is growing evidence for reversible protein phosphorylation and oxidative posttranslational modifications (PTMs) that could affect functions of individual plant mitochondrial proteins or protein complexes. This review will discuss the progress in defining the PTMs that have the potential to regulate plant mitochondrial functions, with references to studies in plants, yeast and mammalian mitochondria and the development of various proteomic and affinity purification methods to study them.     

Stimulation of respiration by Pb2+ in detached leaves and mitochondria of C3 and C4 plants

The exposure of detached leaves of C₃ plants (pea, barley) and C₄ plant (maize) to 5 m M Pb (NO₃)₂ for 24 h caused a reduction of their photosynthetic activity by 40–60%, whereas the respiratory rate was stimulated by 20–50%. Mitochondria isolated from Pb²⁺-treated pea leaves oxidized substrates (glycine, succinate, malate) at higher rates than mitochondria from control leaves. The respiratory control (RCR) and the ADP/O ratio were not affected. Pb²⁺ caused an increase in ATP content and the ATP/ADP ratio in pea and maize leaves. Rapid fractionation of barley protoplasts incubated at low and high CO₂ conditions, indicated that the increased ATP/ADP ratio in Pb²⁺-treated leaves resulted mainly from the production of mitochondrial ATP. The measurements of membrane potential of mitochondria with a TPP⁺-sensitive electrode further showed that mitochondria isolated from Pb²⁺-treated leaves had at least as high membrane potential as mitochondria from control leaves. The activity of NAD-malate dehydrogenase in the protoplasts from barley leaves treated with Pb²⁺ was 3-fold higher than in protoplasts from control leaves. The activities of photorespiratory enzymes NADH-hydroxypyruvate reductase and glycolate oxidase as well as of NAD-malic enzyme were not affected. The presented data indicate that stimulation of respiration in leaves treated by lead is in a close relationship with activation of malate dehydrogenase and stimulation of the mitochondrial ATP production. Thus, respiration might fulfil a protective role during heavy metal exposure.     

Effects of mitochondrial complex III disruption in the respiratory chain of Neurospora crassa

In mitochondria from most organisms, including Neurospora crassa , dimeric complex III was found associated with complex I. Additional association of complex IV with this core structure leads to the formation of a respirasome. It was recently described for bacteria and mammals that complex III is needed for the assembly/stability of complex I. To elucidate the role of complex III in the organization of the respiratory chain of N. crassa , we analysed strains devoid of either the Rieske iron-sulphur or the COREII polypeptide subunits. The mutants display reduced growth, are female sterile and lack active complex III. The supramolecular organization of the oxidative phosphorylation system was characterized by electrophoretic analyses and the efficiency of the respiratory chain analysed by oxygen consumption measurements. The results obtained indicate that absence of complex III activity is not associated with the absence of complex I or complex IV, and leads to the induction of alternative oxidase. Complex III mutant mitochondria are devoid of respirasomes but contain significant amounts of dimeric complex I (I₂) and of the supercomplex I₁IV₁. Moreso, for the first time the alternative oxidase was found associated with dimeric complex IV and with supercomplex I₁IV₁.     

Inorganic Pi Increases Neuronal Survival in the Acute Early Phase Following Excitotoxic/Oxidative Insults

Abstract: Inorganic phosphate (P_i) plays a vital role in intracellular energy metabolism. Its many effects include stimulation of glucose use, enhancement of high-energy phosphate concentrations, and modulation of cytosolic free [Ca²⁺]. Cultured fetal rat cortical neurons constitutively import P_i, and cytosolic levels positively correlate with [ATP], [NADPH], and energy charge. In the present study, we demonstrate that the concentration of intracellular P_i is an important determinant of acute neuronal survival after an excitotoxic or oxidative insult to cultured fetal rat cortical neurons. Extracellular P_i dose-dependently enhanced survival of cortical neurons after exposure to NMDA at early (≤6 h) time points after termination of the insult. P_i similarly increased neuronal survival after exposure to kainic acid or H₂O₂. P_i-exposed neurons had higher basal intracellular [P_i], [ATP], and [GSH], and slightly lower cytosolic free [Ca²⁺], compared with P_i-deprived neurons. P_i-exposed neurons maintained increased [ATP] after exposure to NMDA and displayed reduced formation of reactive oxygen species after exposure to kainic acid or H₂O₂, compared with P_i-deprived neurons. These findings demonstrate that changes in extracellular and intracellular P_i can affect neuronal survival after excitotoxic or oxidative insults.     

THE EFFECT OF BILIRUBIN ON THE ENERGY METABOLISM OF BRAIN MITOCHONDRIA

Abstract— Unconjugated bilirubin caused uncoupling of oxidative phosphorylation in brain mitochondria prepared from mature or weanling rats. Human serum albumin in an amount sufficient to bind 100 per cent of the added bilirubin was able to protect the mitochondria from the inhibitory effects of bilirubin. Bilirubin inhibited both the endogenous and DNP-activated ATPase activities but had no effect upon the Mg²⁺-stimulated ATPase; albumin prevented the inhibition.     

Features of oxidative phosphorylation in brain mitochondria of rats with different sensitivity to oxygen insufficiency]

Oxidative phosphorylation parameters have been investigated in the isolated brain mitochondria of rats preliminary divided into non-resistant (NR) and high-resistant (HR) animals by their sensitivity to hypobaric hypoxia. During the NAD-dependent substrates oxidation it was shown that the identical effectiveness of the respiratory chain function in both groups of animals was reached at more tension of the oxidative processes. It has been established that at the identical effectiveness of the succinate oxidation by the brain mitochondria in both groups of animals compensatory potentialities of the succinate-oxidase pathway of oxidation is higher in the brain of the NR to hypoxia animals. It has been shown the regulated influence of the NAD-dependent pathway of oxidation activity on the succinate-oxidase site of respiratory chain. This influence is more expressed in the brain mitochondria of the NR animals that in the HR animals.     

Effects of 1-Methyl-4-Phenylpyridinium on Isolated Rat Brain Mitochondria: Evidence for a Primary Involvement of Energy Depletion

Abstract: 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 µ M 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 µ M 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.     

Manganese induces sustained Ser40 phosphorylation and activation of tyrosine hydroxylase in PC12 cells

Manganese (Mn²⁺) is an essential metal involved in normal functioning of a range of physiological processes. However, occupational overexposure to Mn²⁺ causes neurotoxicity. The dopaminergic system is a particular target for Mn²⁺ neurotoxicity. Tyrosine hydroxylase (TH) is the rate limiting enzyme for dopamine synthesis and is regulated acutely by phosphorylation at Ser40 and chronically by protein synthesis. In this study we used pheochromocytoma 12 cells to investigate the effects of Mn²⁺ exposure on the phosphorylation and activity of TH. Mn²⁺ treatment for 24 h caused a sustained increase in Ser40 phosphorylation and TH activity at a concentration of 100 μM, without altering the level of TH protein or PC12 cell viability. Inhibition of protein kinase A and protein kinase C and protein kinases known to be involved in sustained phosphorylation of TH in response to other stimuli did not block the effects of Mn²⁺ on Ser40 phosphorylation. A substantial increase in H₂O₂ production occurred in response to 100 μM Mn²⁺. The antioxidant Trolox^TM completely inhibited H₂O₂ production but did not block TH phosphorylation at Ser40, indicating that oxidative stress was not involved. Sustained TH phosphorylation at Ser40 and the consequent activation of TH both occurred at low concentrations of Mn²⁺ and this provides a potential new mechanism for Mn²⁺-induced neuronal action that does not involve H₂O₂-mediated cell death.     

Energy Metabolism in Rat Brain Synaptosomes from Nembutal-Anesthetized and Nonanesthetized Animals

Abstract: Cellular energetic parameters including the intramitochondrial and cytosolic [NAD⁺]/[NADH] ratios, the cellular [ATP]/[ADP][P_i and [creatine phosphate]/[creatine] ratios, the concentration of cytochrome c and its redox state and the respiratory rate were studied in suspensions of rat brain synapto-somes isolated from nembutal-anesthetized and nonanesthetized animals. The ratio of [3-hydroxybutyrate] to [acetoacetate] was 2.0 in synaptosomes isolated from nonanesthetized rats and 5.55 in those from anesthetized animals. The [lactate]/[pyruvate] ratio was 3.8 in the former and 10.9 in the latter preparation. The [ATP]/[ADP][P_i] was 3838 M⁻¹ in the synaptosomes from anesthetized rats and 840 M⁻¹ in those from nonanesthetized animals and the [creatine phosphate]/[creatine] ratios were 0.79 and 0.39, respectively. Cytochrome c was about 15% reduced in both preparations; however, the mitochon-drial cytochrome concentration was almost twofold higher in the synaptosomes from nonanesthetized animals. Calculations of the free energy relationships between the mitochondrial redox reactions and ATP synthesis showed that in synaptosomes isolated from the brains of nembutal-anesthetized rats the first two sites of oxidative phosphorylation were at near-equilibrium, in agreement with observations for intact cells and tissues. The energetic parameters for synaptosomes from anesthetized rats are very similar to the values for intact whole brain, whereas those for synaptosomes from nonanesthetized rats are lower and suggest that nembutal anesthesia protects against some irreversible damage to the synaptosome during isolation. It is concluded that synaptosomes isolated from brains of nembutal-anesthetized rats can be used as a convenient model system for studies of neuronal metabolism.     

Delta sleep inducing peptide (DSIP): effect on respiration activity in rat brain mitochondria and stress protective potency under experimental hypoxia

Neuromodulatory delta sleep inducing peptide (DSIP) seems to be implicated in the attenuation of stress-induced pathological metabolic disturbances in various animal species and human beings. Mitochondria, as cell organelles, are considered especially sensitive to stress conditions. In this work, the influence of DSIP and Deltaran((R))-a recently developed product based upon DSIP-on processes of oxidative phosphorylation and ATP production in rat brain mitochondria and rat brain homogenates was studied. A polarographic measurement of oxygen consumption was applied to evaluate the impact of DSIP on maximal rates of mitochondrial respiration and coupling of respiration to ATP production. We provide evidence that DSIP affected the efficiency of oxidative phosphorylation on isolated rat brain mitochondria. This peptide significantly increased the rate of phosphorylated respiration V3, while the rate of uncoupled respiration V(DNP) remaining unchanged. It enhanced the respiratory control ratio RCR and the rate of ADP phosphorylation. DSIP and Deltaran exhibited the same action in rat brain homogenates. We also examined the influence of DSIP under hypoxia when mitochondrial respiratory activity is altered. In rats subjected to hypoxia, we detected a significant stress-mediated reduction of V3 and ADP/t values. Pretreatment of rats with DSIP at the dose of 120 microgram/kg (i.p.) prior to their subjection to hypoxia completely inhibited hypoxia-induced reduction of mitochondrial respiratory activity. The revealed capacity of DSIP to enhance the efficiency of oxidative phosphorylation found in vitro experiments could contribute to understanding pronounced stress protective and antioxidant action of this peptide in vivo.     

Iron uncouples oxidative phosphorylation in brain mitochondria isolated from vitamin E-deficient rats

Few, if any, studies have examined the effect of vitamin E deficiency on brain mitochondrial oxidative phosphorylation. The latter was studied using brain mitochondria isolated from control and vitamin E-deficient rats (13 months of deficiency) after exposure to iron, an inducer of oxidative stress. Mitochondria were treated with iron (2 to 50 microM) added as ferrous ammonium sulfate. Rates of state 3 and state 4 respiration, respiratory control ratios, and ADP/O ratios were not affected by vitamin E deficiency alone. However, iron uncoupled oxidative phosphorylation in vitamin E-deficient mitochondria, but not in controls. In vitamin E-deficient mitochondria, iron decreased ADP/O ratios and markedly stimulated state 4 respiration; iron had only a modest effect on these parameters in control mitochondria. Thus, vitamin E may have an important role in sustaining oxidative phosphorylation. Low concentrations of iron (2 to 5 microM) oxidized mitochondrial tocopherol that exists in two pools. The release of iron in brain may impair oxidative phosphorylation, which would be exacerbated by vitamin E deficiency. The results are important for understanding the pathogenesis of human brain disorders known to be associated with abnormalities in mitochondrial function as well as iron homeostasis (e.g., Parkinson's disease).     

Carbon dioxide anaesthesia in rainbow trout: effects of hypercapnic level and stress on induction and recovery from anaesthetic treatment

The physiological and anaesthetic effects of three different levels of air-saturated and buffered CO₂ anaesthesia, P _w co ₂=31, 78, or 125 mmHg, were examined in cannulated rainbow trout Oncorhynchus mykiss . Complete anaesthesia (no opercular movements) was not achieved by these hypercapnic levels after 20 min of CO₂ exposure. Although increasing P _w co ₂ reduced the induction times to the early stages of anaesthesia, it also resulted in increasing hyperventilatory, hypoxaemic, and acid-base disturbances. After a 10-min recovery period, while the respiratory acidosis component of the acid-base disturbance was corrected, there was a significant metabolic acidosis. Recovery time was longest in the high P_w co₂ treatment where 33% of the fish died. Two additional groups ( P _w co ₂=37 and 78 mmHg) were exposed to an acute stress prior to the anaesthetic treatment. Stress reduced the hypoventilatory effects of the low P _w co₂ treatment, increased the recruitment of anaerobic metabolism, and prolonged recovery time. Although the increase in plasma catecholamines elicited by the stress was small relative to the response obtained with the anaesthetic, stress prior to CO₂ anaesthesia impaired the efficiency of the treatment. Overall, our results suggest that P _w co₂ levels above 37 mmHg and/or stress prior to the anaesthesia impair the efficiency of air-saturated and buffered CO₂ anaesthesia by exacerbating the hypoxaemic effects of the hypercapnic treatment.     

Effects of cucumber mosaic virus infection on electron transport and antioxidant system in chloroplasts and mitochondria of cucumber and tomato leaves

We examined the responses of the photosynthetic and respiratory electron transport and antioxidant systems in cell organelles of cucumber ( Cucumis sativus L.) and tomato ( Lycopersicon esculentum Mill.) leaves to infection of cucumber mosaic virus (CMV) by comparing the gas exchange, Chl fluorescence, respiratory electron transport, superoxide dismutase (SOD, EC 1.15.1.1) and ascorbate–glutathione (AsA–GSH) cycle enzymes and the production of H₂O₂ in chloroplasts, mitochondria and soluble fraction in virus-infected and non-infected leaves. Long-term CMV infection resulted in decreased photosynthesis and respiration rates. Photosynthetic electron flux to carbon reduction, respiratory electron transport via both complex I and complex II and also the Cyt respiration rate all significantly decreased, while photosynthetic alternative electron flux and alternative respiration significantly increased. These changes in electron transport were accompanied by a general increase in the activities of SOD/AsA–GSH cycle enzymes followed by an increased H₂O₂ accumulation in chloroplasts and mitochondria. These results demonstrated that disturbance of photosynthetic and respiratory electron transport by CMV also affected the antioxidative systems, thereby leading to oxidative stress in various organelles.     

Effect of mitochondrial genome rearrangement on respiratory activity, photosynthesis, photorespiration and energy status of MSC16 cucumber (Cucumis sativus) mutant

The effects of changes in mitochondrial DNA in cucumber ( Cucumis sativus L.) mosaic mutant (MSC16) on respiration, photosynthesis and photorespiration were analyzed under non-stressed conditions. Decreased respiratory capacity of complex I in MSC16 mitochondria was indicated by lower respiration rates of intact mitochondria with malate and by rotenone-inhibited NADH or malate oxidation in the presence of alamethicin. Moreover, blue native PAGE indicated decreased intensity of protein bands of respiratory chain complex I in MSC16 leaves. Concerning the redox state, complex I impairment could be compensated to some extent by increased external NADH dehydrogenases (ND_exNADH) and alternative oxidase (AOX) capacity, the latter presenting differential expression in the light and in the dark. Although MSC16 mitochondria have a higher AOX protein level and an increased capacity, the AOX activity measured in the dark conditions by oxygen discrimination technique is similar to that in wild-type (WT) plants. Photosynthesis induction by light followed different patterns in WT and MSC16, suggesting changes in feedback chloroplast ΔpH caused by different adenylate levels. At steady-state, net photosynthesis was only slightly impaired in MSC16 mutants, while photorespiration rate (PR) was significantly increased. This was the result of large decreases in both stomatal and mesophyll conductance to CO₂, which resulted in a lower CO₂ concentration in the chloroplasts. The observed changes on CO₂ diffusion caused by mitochondrial mutations open a whole new view of interaction between organelle metabolism and whole tissue physiology. The sum of all the described changes in photosynthetic and respiratory metabolism resulted in a lower ATP availability and a slower plant growth.     

RESPIRATORY ACTIVITY OF GUINEA PIG BRAIN NUCLEI

Abstract— Preparations of guinea pig brain nuclei, obtained by discontinuous gradient centrifugation in sucrose solutions of pH 6.7–6.8, containing 3 mM-MgCl₂ and phosphate exhibited steady and reproducible oxygen uptake. Oxygen uptake was stimulated 60–70 per cent by glucose, pyruvate, oxalacetate or α-ketoglutarate and 267 per cent by succinate. This respiratory activity was unaffected by the relative sodium or potassium ion content of the medium and by variations in the concentration of inorganic phosphate. Agents known to inhibit citric acid cycle oxidation, oxidative phosphorylation and glycolysis diminished oxygen uptake, but antibiotics inhibiting nucleic acid or protein synthesis did not. Treatment of the nuclear preparation with DNase decreased respiratory capacity, which was partially restored by the addition of polyacrylic acid.     

Kinetics of Regional Blood–Brain Barrier Transport and Brain Phosphorylation of Glucose and 2-Deoxyglucose in the Barbiturate–Anesthetized Rat

Abstract: Recent studies indicate the lumped constant (LC), which defines the relative rates of brain utilization of glucose and 2-deoxyglucose (2-DG), doubles to values > 1.0 under conditions of hypoglycemia. Since changes in the LC should be predictable given the kinetic parameters of blood-brain barrier (BBB) transport and brain phosphorylation of glucose and 2-DG, the present studies were designed to measure the necessary kinetic parameters. The carotid injection technique was used to determine cerebral blood flow and the K_m , V_max, and K _D of glucose and 2-DG transport through the BBB in seven brain regions in rats anesthetized with 50 mg/kg i.p. pentobarbital. Regional glucose transport through the BBB was characterized by an average K_m = 6.3 m m , average V_max = 0.53 μmol min⁻¹g⁻¹, and average K _D= 0.022 ml min⁻¹g⁻¹. The nonsaturable route of transport of glucose represented on the average 40% of the total glucose influx into brain regions at an arterial glucose concentration of 10 m m . In addition, the rate constants of phosphorylation of glucose and 2-DG were measured for each region. Substitutions of the measured kinetic parameters for sugar transport and phosphorylation into equations defining the LC confirm the observation that the LC would be expected to vary under extreme conditions such as hypoglycemia and to exceed values of 1.0 under these conditions.     

Inhibition of Dopamine Release by Prostaglandin EP3 Receptor via Pertussis Toxin-Sensitive and -Insensitive Pathways in PC12 Cells

Abstract: Hydrogen peroxide (H₂O₂) is produced from several sources in brain and may be involved in neurodegeneration and second messenger signaling. Little is known about the effects of H₂O₂ on transmitter storage in brain synaptic vesicles. Neurotransmitter uptake into synaptic vesicles is driven by an electrochemical proton gradient generated by the vacuolar H⁺-ATPase (V-ATPase) in the vesicle membrane. We report here that the V-ATPase in bovine brain synaptic vesicles is highly sensitive to inhibition by micromolar concentrations of H₂O₂. Glutamate uptake by the vesicles is also inhibited, very likely as a secondary consequence of ATPase inactivation. Dithiothreitol or reduced glutathione reverse H₂O₂-induced inhibition of the V-ATPase, and ATP or GTP partially protect the ATPase from inhibition by H₂O₂. These and other results suggest that the mechanism of inhibition of the V-ATPase by H₂O₂ involves oxidation of a reactive cysteine sulfhydryl group in the ATP binding site. Inhibition of V-ATPase activity would decrease the amount of transmitter stored in synaptic vesicles and thus down-regulate transmitter release during episodes of oxidative stress or in response to second messenger signaling.     

Interaction of α-Phenyl-N-tert-Butyl Nitrone and Alternative Electron Acceptors with Complex I Indicates a Substrate Reduction Site Upstream from the Rotenone Binding Site

Abstract: Mitochondrial complexes I, II, and III were studied in isolated brain mitochondrial preparations with the goal of determining their relative abilities to reduce O₂ to hydrogen peroxide (H₂O₂) or to reduce the alternative electron acceptors nitroblue tetrazolium (NBT) and diphenyliodonium (DPI). Complex I and II stimulation caused H₂O₂ formation and reduced NBT and DPI as indicated by dichlorodihydrofluorescein oxidation, nitroformazan precipitation, and DPI-mediated enzyme inactivation. The O₂ consumption rate was more rapid under complex II (succinate) stimulation than under complex I (NADH) stimulation. In contrast, H₂O₂ generation and NBT and DPI reduction kinetics were favored by NADH addition but were virtually unobservable during succinate-linked respiration. NADH oxidation was strongly suppressed by rotenone, but NADH-coupled H₂O₂ flux was accelerated by rotenone. α-Phenyl- N-tert -butyl nitrone (PBN), a compound documented to inhibit oxidative stress in models of stroke, sepsis, and parkinsonism, partially inhibited complex I-stimulated H₂O₂ flux and NBT reduction and also protected complex I from DPI-mediated inactivation while trapping the phenyl radical product of DPI reduction. The results suggest that complex I may be the principal source of brain mitochondrial H₂O₂ synthesis, possessing an "electron leak" site upstream from the rotenone binding site (i.e., on the NADH side of the enzyme). The inhibition of H₂O₂ production by PBN suggests a novel explanation for the broad-spectrum antioxidant and antiinflammatory activity of this nitrone spin trap.