Effects of hydrogen peroxide on cytochrome P-450 inactivation

Inactivation rate of purified oligomeric cytochrome P-450 LM2 has been investigated in glucose oxidase system and under the action of exogenous hydrogen peroxide (400 microM). It has been found that hydrogen peroxide has a distinct inactivating effect on cytochrome P-450. The enzyme inactivation is accompanied by the loss of heme and the decrease in SH-group content in the protein molecule. Benzphetamine, a substrate specific for this enzyme isoform, exerts a protective effect by decreasing the rate of cytochrome P-450 inactivation and SH-group oxidation. Similar results have been obtained during the investigation of cytochrome P-450 inactivation in the monomerized system. It has been found that the inactivation process is accompanied by the formation of the enzyme aggregates. The changes in the aggregate state are due to the formation of intermolecular covalent bonds.     

Participation of superoxide, hydrogen peroxide and hydroxyl radicals in NADPH-cytochrome P-450 reductase-catalyzed peroxidation of methyl linolenate.

1. NADPH-cytochrome P-450 reductase-catalyzed peroxidation of methyl linolenate is inhibited by superoxide dismutase, catalase, ethanol, and mannitol, and is potentiated by H2O2. 2. H2O2 is shown to be generated in the incubation mixture in the presence of NADPH and NADPH-cytochrome P-450 reductase. If the system contains Fe-EDTA complex, H2O2 is not formed. In the presence of the enzyme and Fe-EDTA complex, added H2O2 is consumed. 3. In the presence of Fe-EDTA complex, NADPH-cytochrome P-450 reductase is shown to generate O-2 at a slow rate. These results suggest that H2O2 produced from O-2 is decomposed to form OH . by the action of Fe-EDTA complex in the lipid peroxidation system, and that OH . is a trigger of lipid peroxidation.     

Neutrophil-mediated methemoglobin formation in the erythrocyte. The role of superoxide and hydrogen peroxide

Human neutrophils incubated with phorbol myristate acetate oxidized hemoglobin within the intact erythrocyte by a mechanism dependent on cell-cell contact but independent of phagocytosis. Spectrophotometric examination of the erythrocyte lysates revealed that the major component formed was methemoglobin along with small amounts of a species with spectral characteristics similar to choleglobin. Methemoglobin formation was directly related to the neutrophil concentration and the time of incubation. The addition of superoxide dismutase or catalase modestly inhibited the formation of methemoglobin, while a combination of the enzymes provided the most dramatic protection. Methemoglobin of hydroxyl radical or hypochlorous acid scavengers. Apparently, either O2.- or H2O2 alone was capable of mediating methemoglobin formation in the intact erythrocyte. Maintenance of the intraerythrocytic hemoglobin in its oxygenated state or its derivatization to carbon monoxyhemoglobin markedly inhibited methemoglobin formation. Blockade of the anion channels in the intact erythrocyte with sulfonated stilbenes inhibited O2.- but not H2O2 from oxidizing intracellular hemoglobin. It appears that neutrophil-derived O2.- and H2O2 can cross the erythrocyte membrane through the anion channel or diffuse directly into the intracellular space and react with oxyhemoglobin or deoxyhemoglobin to form a mixture of hemoglobin oxidation products within the intact cell.     

Demethylation of tertiary amines by a reconstituted cytochrome P-450 enzyme system: kinetics of oxygen consumption and hydrogen peroxide formation

Initial reaction rates of oxygen consumption and hydrogen peroxide formation in a cytochrome P-450 catalyzed reaction are practically independent of the nature of tertiary amines that were used as substrates. From the kinetic studies and the substrate conversion results that the amount of water formed in a side reaction is determined by the substrate specificity. Both hydrogen peroxide and water formation lower the efficiency of the monooxygenatic activity of cytochrome P-450.     

Cytochrome oxidase-catalyzed superoxide generation from hydrogen peroxide.

Superoxide dismutase is shown to affect spectral changes observed upon cytochrome c oxidase reaction with H2O2, which indicates a possibility of O2- radicals being formed in the reaction. Using DMPO as a spin trap, generation of superoxide radicals from H2O2 in the presence of cytochrome oxidase is directly demonstrated. The process is inhibited by cyanide and is not observed with a heat-denatured enzyme pointing to a specific reaction in the oxygen-reducing centre of cytochrome c oxidase. The data support a hypothesis on a catalase cycle catalyzed by cytochrome c oxidase in the presence of excess H2O2 (Vygodina and Konstantinov (1988) Ann. NY Acad. Sci., 550, 124-138): (formula: see text)     

Inactivation of cytochrome P-450 by hydrogen peroxide formed in the catalytic cycle during peroxy-complex degradation

It was shown that the crucial role in the inactivation of microsomal cytochrome P-450 in reactions of hydroxylation of type I (DMA, AP, BPh, p-NA) and type II (AN) substrates belongs to H2O2 directly formed in the enzyme active center during the decomposition of the peroxy complex. Hydrogen peroxide formed via an indirect pathway during the dismutation of superoxide radicals does not play a role in the hemoprotein inactivation.     

Spin traps inhibit formation of hydrogen peroxide via the dismutation of superoxide: implications for spin trapping the hydroxyl free radical.

To enhance the sensitivity of EPR spin trapping for radicals of limited reactivity, high concentrations (10-100 mM) of spin traps are routinely used. We noted that in contrast to results with other hydroxyl radical detection systems, superoxide dismutase (SOD) often increased the amount of hydroxyl radical-derived spin adducts of 5,5-dimethyl-1-pyrroline N-oxide (DMPO) produced by the reaction of hypoxanthine, xanthine oxidase and iron. One possible explanation for these results is that high DMPO concentrations (approximately 100 mM) inhibit dismutation of superoxide (O2.-) to hydrogen peroxide (H2O2). Therefore, we examined the effect of DMPO on O2.- dismutation to H2O2. Lumazine +/- 100 mM DMPO was placed in a Clark oxygen electrode following which xanthine oxidase was added. The amount of H2O2 formed in this reaction was determined by introducing catalase and measuring the amount of generated via O2.- dismutation as compared to direct divalent O2 reduction. In the presence of 100 mM DMPO, H2O2 generation decreased 43%. DMPO did not scavenge H2O2 nor alter the rate of O2.- production. The effect of DMPO was concentration-dependent with inhibition of H2O2 production observed at [DMPO] greater than 10 mM. Inhibition of H2O2 production by DMPO was not observed if SOD was present or if the rate of O2.- formation increased. The spin trap 2-methyl-2-nitroso-propane (MNP, 10 mM) also inhibited H2O2 formation (81%). However, alpha-phenyl-N-tert-butylnitrone (PBN, 10 mM), 3,3,5,5 tetramethyl-1-pyrroline N-oxide (M4PO, 100 mM), alpha-(4-pyridyl-1-oxide)-N-tert-butylnitrone (4-POBN, 100 mM) had no effect. These data suggest that in experimental systems in which the rate of O2.- generation is low, formation of H2O2 and thus other H2O2-derived species (e.g., OH) may be inhibited by commonly used concentrations of some spin traps. Thus, under some experimental conditions spin traps may potentially prevent production of the very free radical species they are being used to detect.     

Hydrogen peroxide formation and stoichiometry of hydroxylation reactions catalyzed by highly purified liver microsomal cytochrome P-450.

The stoichiometry of hydroxylation reactions catalyzed by cytochrome P-450 was studied in a reconstituted enzyme system containing the highly purified cytochrome from phenobarbital-induced rabbit liver microsomes. Hydrogen peroxide was shown to be formed in the reconstituted system in the presence of NADPH and oxygen; the amount of peroxide produced varied with the substrated added. NADPH oxidation, oxygen consumption, and total product formation (sum of hydroxylated compound and hydrogen peroxide) were shown to be equimolar when cyclohexane, benzphetamine, or dimethylaniline served as the substrate. The stoichiometry observed represents the sum of two activities associated with cytochrome P-450. These are (1) hydroxylase activity: NADPH + H⁺ + O₂ + RH → NADP⁺ + H₂O + ROH; and (2) oxidase activity: NADPH + H⁺ + O₂ → NADP⁺ + H₂O₂. Benzylamphetamine (desmethylbenzphetamine) acts as a pseudosubstrate in that it stimulates peroxide formation to the same extent as the parent compound (benzphetamine), but does not undergo hydroxylation. Accordingly, when benzylamphetamine alone is added in control experiments to correct for the NADPH and O₂ consumption not associated with benzphetamine hydroxylation, the expected 1:1:1 stoichiometry for NADPH oxidation, O₂ consumption, and formaldehyde formation in the hydroxylation reaction is observed.     

Oxidation of reduced cytochrome c by hydrogen peroxide. Implications for superoxide assays

Hydrogen peroxide, formed directly or as a product of superoxide dismutation, can oxidize ferrocytochrome c at rates comparable to those at which ferricytochrome c is reduced by superoxide. This reoxidation can significantly affect estimates of rates and amounts of superoxide production using absorbance changes for cytochrome c at 550 nm as the assay. The oxidation can be inhibited by catalase.     

Cell culture models for oxidative stress: superoxide and hydrogen peroxide versus normobaric hyperoxia.

According to the free radical theory of aging, loss of cellular function during aging is a consequence of accumulating subcellular damage inflicted by activated oxygen species. In cells, the deleterious effects of activated oxygen species may become manifest when the balance between radical formation and destruction (removal) is disturbed creating a situation denoted as 'oxidative stress'. Cell culture systems are especially useful to study the effects of oxidative stress, in terms of both toxicity and cellular adaptive responses. A better understanding of such processes may be pertinent to fully comprehend the cellular aging process. This article reviews three model systems for oxidative stress: extracellular sources of O2-. and H2O2, and normobaric hyperoxia (elevated ambient oxygen). Methodological and practical aspects of these exposure models are discussed, as well as their prominent effects as observed in cultures of Chinese hamster cell lines. Since chronic exposure models are to be preferred, it is argued that normobaric hyperoxia is a particularly relevant oxidative stress model for in vitro cellular aging studies.     

Different contribution of rat liver microsomal pigments in the formation of superoxide anions and hydrogen peroxide during development.

Liver microsomes of adult rats produce, by an NADPH-dependent pathway, O₂^? radicals, as detected by the epinephrine cooxidation to adrenochrome (24.8 nmol/min/mg of protein). This production has also been measured during liver development (from 1 to 20 days after birth) and correlated to the enzyme content (NADPH-cytochrome c reductase, cytochrome b₅, and cytochrome P-450), with the aim of establishing the level at which Superoxide radicals are formed in the electron transport system. At 1 day the adrenochrome formation and the activity of NADPH-cytochrome c reductase are about 50 and 40% of those of the adult, respectively, whereas those of cytochromes b₅ and P-450 are approximately 10%. After 20 days of development cytochrome b₅ and the dehydrogenase reach the adult level, while cytochrome P-450 is about 80%. At this age O₂^? radicals have a 30% increment and reach only 60% of those of the adult; H₂O₂ production is also 60% and the N-demethylation of aminopyrine is only 30%. Thus, at birth the formation of O₂^? radicals is almost entirely dependent on the activity of the flavoprotein. The close correlation between the slight increase in the demethylase activity and adrenochrome formation from 1 to 20 days suggests that a portion of O₂^? radicals produced by the NADPH-dependent electron transfer is directly involved in the mixed function oxidation. Since about 50% of the radicals are formed at the flavoprotein level, these results indicate that in the adult liver the remaining amount may be generated at the level of cytochrome P-450.     

Influence of flavin addition and removal on the formation of superoxide by NADPH-Cytochrome P-450 reductase: a spin-trap study

Several structural derivatives of the dipeptide, l (and d)-cysteinyl-l-proline were synthesized and shown to be very potent competitive and noncompetitive inhibitors of human serum angiotensin I-converting enzyme. Only if the sulfhydryl group of the cysteine was blocked with benzyl, trityl, or benzyloxycarbonyl protecting groups, was the dipeptide a noncompetitive inhibitor. Compounds with free sulfhydryl groups were competitive inhibitors with K_i values in the 10^?8m range. d-Cys-l-Pro, our most potent inhibitor (k₁ = 0.0055 μM), was an order of magnitude more potent than l-Cys-l-Pro consistent with findings of Cushman et al. (1977, Biochemistry16, 5484) that -CH₃ group substitution improves binding if the configuration is d but diminishes binding if the configuration is l. Zinc and calcium ions released inhibition by some of the noncompetitive, but only one, of the competitive inhibitors. The noncompetitive inhibitor, l-cysteinyl(benzyl)-l-proline, and the competitive inhibitor, l-cysteinyl-l-proline, were used as affinity ligands to obtain near homogenous (25 units/mg) enzyme from human plasma. The observation that compounds with a free sulfhydryl group are competitive inhibitors and those in which the sulfhydryl groups are blocked are noncompetitive inhibitors can be rationalized if the active site of the converting enzyme is an extended linear trench.     

Enhanced mitochondrial superoxide in hyperglycemic endothelial cells: direct measurements and formation of hydrogen peroxide and peroxynitrite

Hyperglycemic challenge to bovine aortic endothelial cells (BAECs) increases oxidant formation and cell damage that are abolished by MnSOD overexpression, implying mitochondrial superoxide (O(2)(.-)) as a central mediator. However, mitochondrial O(2)(.-) and its steady-state concentrations have not been measured directly yet. Therefore, we aimed to detect and quantify O(2)(.-) through different techniques, along with the oxidants derived from it. Mitochondrial aconitase, a sensitive target of O(2)(.-), was inactivated 60% in BAECs incubated in 30 mM glucose (hyperglycemic condition) with respect to cells incubated in 5 mM glucose (normoglycemic condition). Under hyperglycemic conditions, increased oxidation of the mitochondrially targeted hydroethidine derivative (MitoSOX) to hydroxyethidium, the product of the reaction with O(2)(.-), could be specifically detected. An 8.8-fold increase in mitochondrial O(2)(.-) steady-state concentration (to 250 pM) and formation rate (to 6 microM/s) was estimated. Superoxide formation increased the intracellular concentration of both hydrogen peroxide, measured as 3-amino-2,4,5-triazole-mediated inactivation of catalase, and nitric oxide-derived oxidants (i.e., peroxynitrite), evidenced by immunochemical detection of 3-nitrotyrosine. Oxidant formation was further evaluated by chloromethyl dichlorodihydrofluorescein (CM-H(2)DCF) oxidation. Exposure to hyperglycemic conditions triggered the oxidation of CM-H(2)DCF and was significantly reduced by pharmacological agents that lower the mitochondrial membrane potential, inhibit electron transport (i.e., myxothiazol), and scavenge mitochondrial oxidants (i.e., MitoQ). In BAECs devoid of mitochondria (rho(0) cells), hyperglycemic conditions did not increase CM-H(2)DCF oxidation. Mitochondrial O(2)(.-) formation in hyperglycemic conditions was associated with increased glucose metabolization in the Krebs cycle and hyperpolarization of the mitochondrial membrane.     

Effect of amidopyrine on the rate of cytochrome P-450 isoform breakdown

The effect of liver monooxygenase system substrates upon the rate of cytochrome P-450 isoform degradation was investigated by measuring the half-life of liver microsomal proteins in C57BL/6 mice injected with phenobarbital and then 24 hours later with aminopyrine every 6 hours. The rate of phenobarbital-induced degradation of cytochrome P-450 isoform (mol weight 56000 daltons) was shown to be increased two-fold.     

Anoxic stress leads to hydrogen peroxide formation in plant cells.

Hydrogen peroxide (H2O2) was detected cytochemically in plant tissues during anoxia and re-oxygenation by transmission electron microscopy using its reaction with cerium chloride to produce electron dense precipitates of cerium perhydroxides. Anoxia-tolerant yellow flag iris (Iris pseudacorus) and rice (Oryza sativa), and anoxia-intolerant wheat (Triticum aestivum) and garden iris (Iris germanica) were used in the experiments. In all plants tested, anoxia and re-oxygenation increased H2O2 in plasma membranes and the apoplast. In the anoxia-tolerant species the response was delayed in time, and in highly tolerant I. pseudacorus plasma membrane associated H2O2 was detected only after 45 d of oxygen deprivation. Quantification of cerium precipitates showed a statistically significant increase in the amount of H2O2 caused by anoxia in wheat root meristematic tissue, but not in the anoxia-tolerant I. pseudacorus rhizome parenchyma. Formation of H2O2 under anoxia is considered mainly an enzymatic process (confirmed by an enzyme inhibition analysis) and is due to the trace amount of dissolved oxygen (below 10(-5) M) present in the experimental system. The data suggest oxidative stress is an integral part of oxygen deprivation stress, and emphasize the importance of the apoplast and plasma membrane in the development of the anoxic stress response.     

The oxygen-evolving complex requires chloride to prevent hydrogen peroxide formation.

Illumination of PSII core preparations can cause the production of H2O2 at rates which approach 60 mumol of H2O2 (mg of Chl.h)-1. The rate of peroxide production is maximal at pH 7.2 at low sucrose concentrations and at concentrations of Cl- (1.5-3.0 mM) that limit the rate of the oxidation of water to O2. The rate of H2O2 production increased with pH from pH 6.8 to 7.2 and was inversely proportional to the oxidation of water to O2 from pH 6.8 to 7.5. While EDTA does not inhibit H2O2 production, this reaction is abolished by 5 mM NH2OH and inhibited by the same concentrations of NH3 that affect water oxidation which indicates that the oxygen-evolving complex is responsible for the production of peroxide generated upon illumination of PSII core preparations. These results support a mechanism in which bound Cl- in the S2 state is displaced by OH- ions which are then oxidized by the OEC to form H2O2. Thus, the OEC requires Cl- to prevent access to the active site of the OEC until four oxidizing equivalents can be generated to allow the oxidation of water to O2.     

The interaction of oxymyoglobin with hydrogen peroxide: the formation of ferrylmyoglobin at moderate excesses of hydrogen peroxide

The reaction of oxymyoglobin with H2O2 has been examined at pH 7.2 and 20(+/-2) degrees over a range of [H2O2] up to an initial excess of 25:1. The reaction is characterized by a direct conversion of oxymyoglobin to ferrylmyoglobin without the intermediacy of the ferri derivative. The initial rate of loss of oxymyoglobin is first-order with respect to [oxymyoglobin], and exhibits saturation kinetics with increasing [H2O2]. In addition, the stoichiometric relationship between the reactants varies as [H2O2] increases. A complex non-Michaelis-Menten mechanism is proposed in which an intermediate, produced upon the initial interaction of the reactants, regenerates oxymyoglobin by reaction with further H2O2, in competition with the formation of the ferryl derivative. In this way, oxymyoglobin catalytically decomposes excess H2O2. Deoxygenated ferromyoglobin is substantially more reactive with H2O2 in producing the transient intermediate than the oxy analog. Some fundamental similarity is noted between the catalytic mechanism and that of catalase activity. From a detailed examination of the probable nature of the intermediate, conventional Fenton reactivity is rejected for the reaction of H2O2 with oxymyoglobin.