The cytochrome c peroxidase-catalyzed oxidation of ferrocytochrome c by hydrogen peroxide. Steady state kinetic mechanism

Initial velocities for the cytochrome c peroxidase-catalyzed oxidation of ferrocytochrome c by hydrogen peroxide have been measured as functions of both the ferrocytochrome c (0.27-104 microM) and hydrogen peroxide (0.25-200 microM) concentrations at 25 degrees C, 0.01 M ionic strength, and pH 7 in a cacodylate/KNO3 buffer system Eadie-Hofstee plots of the initial velocity as a function of ferrocytochrome c concentration at constant hydrogen peroxide are nonlinear. A mechanism is proposed which includes random addition of the two substrates to the enzyme and a single catalytically active cytochrome c binding site. The mechanism is consistent with prior studies on cytochrome c peroxidase and fits the steady state kinetic data well.     

Cytochrome c peroxidase activity of bovine heart cytochrome oxidase incorporated in liposomes and generation of membrane potential

Cytochrome oxidase vesicles catalyzed the peroxidatic oxidation of ferrocytochrome c. The maximal peroxidase activity in the absence of an uncoupling agent was 9.8 mol ferrocytochrome c oxidized/(s X mol heme a), indicating a 5-fold activation compared with the soluble enzyme system. The peroxidase activity was further enhanced 1.2 to 2.1 times upon addition of an uncoupler, carbonyl cyanide p-trifluoromethoxyphenyl hydrazone. The stoichiometry of the reduction of hydrogen peroxide by ferrocytochrome c was established to be 1 : 2, indicating water formation. Potassium cyanide (0.14 mM) completely inhibited the peroxidase activity. The inhibition by 1 mM CO was 40-77% depending on the energized state of cytochrome oxidase vesicles, but in contrast, 85% inhibition was observed with the soluble enzyme. In the energized state the enzyme showed a slightly lower affinity for CO than in the deenergized state. Coupled with the peroxidase activity, a membrane potential of 72 mV was registered transiently; this may be physiologically significant in relation to the energy transduction mechanism.     

Cytochrome c peroxidase catalyzed oxidation of ferrocytochrome c by hydrogen peroxide: ionic strength dependence of the steady-state rate parameters

The steady-state kinetics of the cytochrome c peroxidase catalyzed oxidation of horse heart ferrocytochrome c by hydrogen peroxide have been studied at both pH 7.0 and pH 7.5 as a function of ionic strength. Plots of the initial velocity versus hydrogen peroxide concentration at fixed cytochrome c are hyperbolic. The limiting slope at low hydrogen peroxide give apparent bimolecular rate constants for the cytochrome c peroxidase-hydrogen peroxide reaction identical with those determined directly by stopped-flow techniques. Plots of the initial velocity versus cytochrome c concentration at saturating hydrogen peroxide (200 microM) are nonhyperbolic. The rate expression requires squared terms in cytochrome c concentration. The maximum turnover rate of the enzyme is independent of ionic strength, with values of 470 +/- 50 s-1 and 290 +/- 30 s-1 at pH 7.0 and 7.5, respectively. The limiting slope of velocity versus cytochrome c concentration plots provides a lower limit for the association rate constant between cytochrome c and the oxidized intermediates of cytochrome c peroxidase. The limiting slope varies from 10(6) M-1 s-1 at 300 mM ionic strength to 10(8) M-1 s-1 at 20 mM ionic strength and extrapolates to 5 x 10(8) M-1 s-1 at zero ionic strength. The data are discussed in terms of both a two-binding-site mechanism and a single-binding-site, multiple-pathway mechanism.     

Yeast cytochrome c peroxidase: mechanistic studies via protein engineering

Cytochrome c peroxidase (CcP) is a yeast mitochondrial enzyme that catalyzes the reduction of hydrogen peroxide to water by ferrocytochrome c. It was the first heme enzyme to have its crystallographic structure determined and, as a consequence, has played a pivotal role in developing ideas about structural control of heme protein reactivity. Genetic engineering of the active site of CcP, along with structural, spectroscopic, and kinetic characterization of the mutant proteins has provided considerable insight into the mechanism of hydrogen peroxide activation, oxygen-oxygen bond cleavage, and formation of the higher-oxidation state intermediates in heme enzymes. The catalytic mechanism involves complex formation between cytochrome c and CcP. The cytochrome c/CcP system has been very useful in elucidating the complexities of long-range electron transfer in biological systems, including protein-protein recognition, complex formation, and intracomplex electron transfer processes.     

Complex-formation between cytochrome c and cytochrome c peroxidase. Equilibrium and titration studies

1. Physical studies of complex-formation between cytochrome c and yeast peroxidase are consistent with kinetic predictions that these complexes participate in the catalytic activity of yeast peroxidase towards ferrocytochrome c. Enzyme-ferricytochrome c complexes have been detected both by the analytical ultracentrifuge and by column chromatography, whereas an enzyme-ferrocytochrome c complex was demonstrated by column chromatography. Estimated binding constants obtained from chromatographic experiments were similar to the measured kinetic values. 2. The physicochemical study of the enzyme-ferricytochrome c complex, and an analysis of its spectrum and reactivity, suggest that the conformation and reactivity of neither cytochrome c nor yeast peroxidase are grossly modified in the complex. 3. The peroxide compound of yeast cytochrome c peroxidase was found to have two oxidizing equivalents accessible to cytochrome c but only one readily accessible to ferrocyanide. Several types of peroxide compound, differing in available oxidizing equivalents and in reactivity with cytochrome c, seem to be formed by stoicheiometric amounts of hydrogen peroxide. 4. Fluoride combines not only with free yeast peroxidase but also with peroxidase-peroxide and accelerates the decomposition of the latter compound. The ligand-catalysed decomposition provides evidence for one-electron reduction pathways in yeast peroxidase, and the reversible binding of fluoride casts doubt upon the concept that the peroxidase-peroxide intermediate is any form of peroxide complex. 5. A mechanism for cytochrome c oxidation is proposed involving the successive reaction of two reversibly bound molecules of cytochrome c with oxidizing equivalents associated with the enzyme protein.     

A covalent complex between horse heart cytochrome c and yeast cytochrome c peroxidase: kinetic properties

The kinetic properties of a 1:1 covalent complex between horse-heart cytochrome c and yeast cytochrome c peroxidase (ferrocytochrome-c:hydrogen-peroxide oxidoreductase, EC 1.11.1.5) have been investigated by transient-state and steady-state kinetic techniques. Evidence for heterogeneity in the complex is presented. About 50% of the complex reacts with hydrogen peroxide with a rate 20–40% faster than that of native enzyme; 20% of the complex exists in a conformation which does not react with hydrogen peroxide but converts to the reactive form at a rate of 20 ± 5 s⁻¹; 30% of the complex does not react with hydrogen peroxide to form the oxidized enzyme intermediate, cytochrome c peroxidase Compound I. Intramolecular electron transfer between covalently bound ferrocytochrome c and an oxidized site in cytochrome c peroxidase Compound I is too fast to measure, but a lower limit of 600 s⁻¹ can be estimated at 5°C in a 10 mM potassium phosphate buffer at pH 7.5. Free ferrocytochrome c reduces cytochrome c peroxidase Compound I covalently bound to ferricytochrome c at a rate 10⁻⁴ to 10⁻⁵-times slower than for free Compound I. The transient-state ferrocytochrome c reduction rates of Compound I covalently linked to ferricytochrome c are about 70-times too slow to account for the steady-state catalytic properties of the 1:! covalent complex. This indicates that hydrogen peroxide can interact with the 1:1 complex at sites other than the heme of cytochrome c peroxidase, generating additional species capable of oxidizing free ferrocytochrome c.     

A kinetic analysis of the catalase activity of myeloperoxidase

The predominant physiological activity of myeloperoxidase is to convert hydrogen peroxide and chloride to hypochlorous acid. However, this neutrophil enzyme also degrades hydrogen peroxide to oxygen and water. We have undertaken a kinetic analysis of this reaction to clarify its mechanism. When myeloperoxidase was added to hydrogen peroxide in the absence of reducing substrates, there was an initial burst phase of hydrogen peroxide consumption followed by a slow steady state loss. The kinetics of hydrogen peroxide loss were precisely mirrored by the kinetics of oxygen production. Two mols of hydrogen peroxide gave rise to 1 mol of oxygen. With 100 microM hydrogen peroxide and 6 mM chloride, half of the hydrogen peroxide was converted to hypochlorous acid and the remainder to oxygen. Superoxide and tyrosine enhanced the steady-state loss of hydrogen peroxide in the absence of chloride. We propose that hydrogen peroxide reacts with the ferric enzyme to form compound I, which in turn reacts with another molecule of hydrogen peroxide to regenerate the native enzyme and liberate oxygen. The rate constant for the two-electron reduction of compound I by hydrogen peroxide was determined to be 2 x 10(6) M(-1) s(-1). The burst phase occurs because hydrogen peroxide and endogenous donors are able to slowly reduce compound I to compound II, which accumulates and retards the loss of hydrogen peroxide. Superoxide and tyrosine drive the catalase activity because they reduce compound II back to the native enzyme. The two-electron oxidation of hydrogen peroxide by compound I should be considered when interpreting mechanistic studies of myeloperoxidase and may influence the physiological activity of the enzyme.     

Steady-state kinetics of yeast cytochrome c peroxidase catalyzed oxidation of inorganic reductants by hydrogen peroxide

Rates of yeast cytochrome c peroxidase (ferrocytochrome c:hydrogen-peroxide oxidoreductase, EC 1.11.1.5) catalyzed oxidation of bis(tripyridine)cobalt(II) ion, penta(amine)pyridineruthenium(II) ion and ferrocyanide ion by hydrogen peroxide have been found to obey the empirical equation: (formula; see text) in the pH range 5 to 8, and at saturating H2O2 concentrations. [( S] and [CcP] are the concentrations of the reductant and the enzyme, respectively.) Values of k2 were found to be independent of the reductant. The term k0[S] is only significant with the cobalt and ruthenium complexes at high pH. The mechanism proposed to account for this rate equation differs significantly from previous mechanistic proposals. In particular, the rate data require the assignment of the rate-limiting step at high substrate concentrations to a slow electron-transfer within the enzyme, and not, as previously suggested, to saturation of substrate binding to the enzyme. Also, the term k0[S] implies that the reactive substrates, including the natural substrate (yeast cytochrome c), react with the hydrogen peroxide-heme complex and not with the radical species formed by reaction with hydrogen peroxide in the absence of reductants.     

Implications of the integrated rate law for the reactions of Paracoccus denitrificans nitrite reductase.

The integrated rate law for the reaction of the nitrite reductase of Paracoccus denitrificans, a cytochrome cd, has been established for turnover assays using donor ferrocytochromes c and either nitrite or molecular oxygen as the ultimate acceptor. The time course for the concentration of ferrocytochrome follows the law: formula: (see text), where S is the concentration of donor ferrocytochrome c, So is the initial concentration, t is time, and u1, u2, and u3 are empirical parameters that are constant for a given experiment but depend upon the initial substrate concentration. In particular, all the u1 increase with decreasing initial ferrocytochrome concentration. Saturation of reaction rates at high donor ferrocytochrome concentrations was not observed. The parameter u1 was proportional to the enzyme concentration while u2 and u3 were not. The form of the integrated rate law and the behavior of the u1 impose severe restrictions on possible kinetic schemes for the activity of the enzyme. Contemporary mechanisms that have been proposed for mitochondrial oxidase aa3 are examined and found to be inadequate to explain the reactivity of cytochrome cd. The simplest interpretations of the cytochrome cd data suggest that the enzyme does not bind the ferri and ferro forms of donor cytochromes c with equal affinity and that the enzyme is subject to inhibition by a product of reaction. Eucaryotic horse cytochrome c reacts with the Paracoccus cytochrome cd with 77% of the activity when Paracoccus cytochrome c550 is used as the electron donor.     

Model development for horseradish peroxidase catalyzed removal of aqueous phenol

Once activated by hydrogen peroxide, horseradish peroxidase (HRP) catalyzes the oxidation of aqueous aromatic compounds to produce high molecular weight polymers of low solubility. A pseudo steady-state kinetic model of the HRP-hydrogen peroxide-aromatic compound system was modified to incorporate enzyme inactivation mechanisms in order to improve its predictive ability. The kinetic constants of the model were calibrated using a series of experimental data sets. The model's ability to predict the time-dependent removal of phenol within the range of 0.5-6 mM from a batch reactor was validated. The model accounts for permanent losses of enzyme activity through inactivation by free radicals as well as interaction with end-product polymers as they form. (c) 1997 John Wiley & Sons, Inc. Biotechnol Bioeng 54: 251-261, 1997.     

Reduction of cytochrome c peroxidase compounds I and II by ferrocytochrome c. A stopped-flow kinetic investigation

The oxidation of yeast cytochrome c peroxidase by hydrogen peroxide produces a unique enzyme intermediate, cytochrome c peroxidase Compound I, in which the ferric heme iron has been oxidized to an oxyferryl state, Fe(IV), and an amino acid residue has been oxidized to a radical state. The reduction of cytochrome c peroxidase Compound I by horse heart ferrocytochrome c is biphasic in the presence of excess ferrocytochrome c as cytochrome c peroxidase Compound I is reduced to the native enzyme via a second enzyme intermediate, cytochrome c peroxidase Compound II. In the first phase of the reaction, the oxyferryl heme iron in Compound I is reduced to the ferric state producing Compound II which retains the amino acid free radical. The pseudo-first order rate constant for reduction of Compound I to Compound II increases with increasing cytochrome c concentration in a hyperbolic fashion. The limiting value at infinite cytochrome c concentration, which is attributed to the intracomplex electron transfer rate from ferrocytochrome c to the heme site in Compound I, is 450 +/- 20 s-1 at pH 7.5 and 25 degrees C. Ferricytochrome c inhibits the reaction in a competitive manner. The reduction of the free radical in Compound II is complex. At low cytochrome c peroxidase concentrations, the reduction rate is 5 +/- 3 s-1, independent of the ferrocytochrome c concentration. At higher peroxidase concentrations, a term proportional to the square of the Compound II concentration is involved in the reduction of the free radical. Reduction of Compound II is not inhibited by ferricytochrome c. The rates and equilibrium constant for the interconversion of the free radical and oxyferryl forms of Compound II have also been determined.     

Change in the ratio of cytochrome oxidase activity to nitrite reductase activity of Pseudomonas aeruginosa nitrite reductase with the kind of C-type cytochrome used as an electron donor.

The ratio between the nitrite reductase and cytochrome oxidase activities of Pseudomonas aeruginosa nitrite reductase [EC 1.9.3.2.] varies with kind of C-type cytochrome used as the electron donor. Withe cytochrome c-548, 554 (Micrococcus sp.), the nitrite reductase activity is greater than the cytochrome oxidase activity, while the former is smaller than the latter with cytochrome c-554 (Navicula pelliculosa). The aerobic oxidation catalyzed by this enzyme of denitrifying bacterial ferrocytochrome c is greatly accelerated on addition of nitrite, while that of the algal ferrocytochrome c is not affected or is even depressed by the salt. An accelerative effect of nitrite is generally observed with many kinds of C-type cytochromes which react with the enzyme very or fairly rapidly. The difference in the ratio of the two activities of the enzyme seems to arise according to whether or not nitrite affects the interaction of C-type cytochrome with the enzyme.     

Redox control of calcineurin by targeting the binuclear Fe(2+)-Zn(2+) center at the enzyme active site.

The interaction of protein serine/threonine phosphatase calcineurin (CaN) with superoxide and hydrogen peroxide was investigated. Superoxide specifically inhibited phosphatase activity of CaN toward RII (DLDVPIPGRFDRRVSVAAE) phosphopeptide in tissue and cell homogenates as well as the activity of the enzyme purified under reducing conditions. Hydrogen peroxide was an effective inhibitor of CaN at concentrations several orders of magnitude higher than superoxide. Inhibition by superoxide was calcium/calmodulin-dependent. Nitric oxide (NO) antagonized superoxide action on CaN. We provide kinetic and spectroscopic evidence that native, catalytically active CaN has a Fe(2+)-Zn(2+) binuclear center in its active site that is oxidized to Fe(3+)-Zn(2+) by superoxide and hydrogen peroxide. This oxidation is accompanied by a gain of manganese dependence of enzyme activity. CaN isolated by a conventional purification procedure was found in the oxidized, ferric enzyme form, and it became increasingly dependent on divalent cations. These results point to a complex redox regulation of CaN phosphatase activity by superoxide, which is modified by calcium, NO, and superoxide dismutase.     

Estimation of the overall kinetic parameters of enzyme inactivation using an isoconversional method

An isoconversional method is proposed in order to calculate the kinetic parameters of enzyme inactivation. The method provides an efficient and low-cost procedure to describe both operational and thermal inactivation. Unlike the ordinary kinetic assays performed at constant enzyme concentration and at various substrate concentrations, the isoconversional method requires several extended kinetic curves for constant initial substrate concentration and different enzyme concentrations. The procedure was tested and validated using simulated data obtained for several kinetic models frequently discussed in the literature. After the validation, the isoconversional method was used for the investigation of the thermoinactivation of urease during urea hydrolysis in self buffered medium and the operational inactivation (destructive oxidation by excess peroxide) of catalase at high concentration of hydrogen peroxide. The results showed that the isoconversional method gives good results of global inactivation constant for both simple and more complex models.     

Activation of Pseudomonas cytochrome oxidase by limited proteolysis with subtilisin

Oxidized Pseudomonas cytochrome oxidase (ferrocytochrome c2: oxygen oxidoreductase; E.C.1.9.3.2) can be digested with subtilisin under controlled conditions that convert the original parent polypeptide chain (Mr on SDS gels approximately equal to 60,000) to a slightly smaller species (Mr on SDS gels approximately equal to 58,000). Under the conditions used (0.33% subtilisin, w/w, pH 7.4), the product formed from the oxidase was relatively stable to further digestion. Cytochrome oxidase activity was assayed at intervals during proteolysis by following the rate of oxidation of Pseudomonas ferrocytochrome c-551 by the enzyme in the presence of oxygen. The activity increased to a plateau that was more than two times the value for an untreated control. These observations suggest that clipping a small peptide from Pseudomonas cytochrome oxidase either facilitates the rate-limiting electron transfer between the intraprotein heme c and heme d1, enhances the interaction of the enzyme with ferrocytochrome c-551, or both.     

Effect of Physical Factors on Reactions of Horse-Radish Peroxidase Complexes with Reduced Cytochrome c

This investigation concerns the effect of certain physical factors—viscosity, dielectric constant, ionic strength, and temperature of the medium—on the reaction of hydrogen peroxide and ferrocytochrome c in the presence of the enzyme horse-radish peroxidase. From study of the effects of viscosity and dielectric constant, it was concluded that the reaction between the secondary complex of hydrogen peroxide and enzyme on the one hand and ferrocytochrome c on the other is controlled by diffusion in media of high viscosity and by electrostatic effects at low viscosities. With respect to ionic strength, the data at pH 4.7 indicated a dipole-dipole interreaction. The temperature dependence of the over-all reaction had a Q₁₀ of 1.25.     

Tryptophan-191----phenylalanine, a proximal-side mutation in yeast cytochrome c peroxidase that strongly affects the kinetics of ferrocytochrome c oxidation

On the basis of X-ray structural information, it was previously proposed that tryptophan-191 of yeast cytochrome c peroxidase (CCP) may be important in determining the spectroscopic and catalytic properties of the enzyme [Edwards, S. L., Xuong, Ng. H., Hamlin, R. C., & Kraut, J. (1987) Biochemistry 26, 1503-1511]. By use of site-directed mutagenesis and an Escherichia coli expression system, a mutant phenylalanine-191 (F191) CCP was prepared in order to examine the effects of altering the H-bonding and pi-pi interactions that occur between Trp-191 and the iron-coordinated proximal His-175 in the parent enzyme. The F191 mutant enzyme exhibits a dramatic decrease (approximately 3000-fold at pH 7) in V0/e for catalysis of peroxide-dependent ferrocytochrome c oxidation, while V0/e for oxidation of ferrocyanide is decreased only 4.6-fold compared to that of the parent. The Fe3+/Fe2+ Em,7 and the stability of the oxyferryl center in the H2O2-oxidized mutant enzyme are relatively unaffected by the mutation, but the species responsible for a radical-like signal centered at g = 2.00 has been destabilized approximately 100-fold with respect to spontaneous decay. Steady-state kinetic assays as well as transient-state laser flash photolysis experiments utilizing flavin semiquinones as reductants indicate that the mutant CCP forms a complex with cytochrome c but the oxyferryl center in the oxidized enzyme is no longer able to be rapidly reduced by ferrocytochrome c. The most likely reasons for this kinetic behavior are either that new steric constraints exist in the mutant which impede relaxation of the iron center to the resting ferric state or that the indole ring of Trp-191 is important in a specific interprotein electron-transfer pathway that exists between the heme centers of CCP and cytochrome c.     

Kinetic mechanism and nucleotide specificity of NADH peroxidase

NADH peroxidase is a flavoprotein isolated from Streptococcus faecalis which catalyzes the pyridine nucleotide-dependent reduction of hydrogen peroxide to water. Initial velocity, product, and dead-end inhibition studies have been performed at pH 7.5 and support a ping-pong kinetic mechanism. In the absence of hydrogen peroxide, both transhydrogenation between NADH and thioNAD, and isotope exchange between [14C]NADH and NAD, have been demonstrated, although in both these experiments, the maximal velocity of nucleotide exchange was less than 1.5% the maximal velocity of the peroxidatic reaction. We propose that NADH binds tightly to both oxidized and two-electron reduced enzyme. NADH oxidation proceeds stereospecifically with the transfer of the 4S hydrogen to enzyme, and then, via exchange, to water. No primary tritium kinetic isotope effect was observed, and no statistically significant primary deuterium kinetic isotope effects on V/K were determined, although primary deuterium kinetic isotope effects on V were observed in the presence and absence of sodium acetate. NADH peroxidase thus shares with other flavoprotein reductases striking kinetic, spectroscopic, and stereochemical similarities. On this basis, we propose a chemical mechanism for the peroxide cleaving reaction catalyzed by NADH peroxidase which involves the obligate formation of a flavinperoxide, and peroxo bond cleavage by nucleophilic attack by enzymatic dithiols.     

Coupling of dihydroriboflavin oxidation to the formation of the higher valence states of hemeproteins.

The reactions between hydrogen peroxide and hemeproteins have been coupled to the oxidation of dihydroriboflavin so as to provide a simple method for measuring the rate constant of hemeprotein peroxidation. Dihydroriboflavin rapidly reduces the higher oxidation states of iron and the hydroxy radicals which are the products of the hemeprotein/hydrogen peroxide reaction. The rapid reduction of these highly reactive compounds prevents the hemeproteins from undergoing irreversible chemical modifications and thus allows the kinetics of peroxidation to be studied. The rate constants at pH 7.2 and 23 degrees C for the peroxidation of horseradish peroxidase, myoglobin, and ferrocytochrome c are found to be 6.2 x 10(6), 7.5 x 10(4), and 8 x 10(3)M-1s-1, respectively. These studies suggest that reduced riboflavin might efficiently protect cells from oxidative damage such as that occurring in inflammation and reperfusion injury.     

Immuno-spin trapping of hemoglobin and myoglobin radicals derived from nitrite-mediated oxidation

The reaction of nitrite with hemoglobin has become of increasing interest due to the realization that plasma nitrite may act as an NO congener that is activated by interaction with red blood cells. Using a combination of spectrophotometry, immuno-spin trapping, and EPR, we have examined the formation of radicals during the oxidation of oxyhemoglobin (oxyHb) and oxymyoglobin (oxyMb) by inorganic nitrite. The proposed intermediacy of ferryl species during this oxidation was confirmed by spectrophotometry using multiple linear regression analysis of kinetic data. Using EPR/spin trapping, a protein radical was observed in the case of oxyMb, but not oxyHb, and was inhibited by catalase. When DMPO spin trapping was combined with Western blot analysis using an anti-DMPO-nitrone antibody, globin/DMPO adducts of both oxyHb and oxyMb were detected, and their formation was inhibited by catalase. Catalase effects confirm the intermediacy of hydrogen peroxide as a heme oxidant in this system. Spectrophotometric kinetic studies revealed that the presence of DMPO elongated the lag phase and decreased the maximal rate of oxidation of both oxyHb and oxyMb, which suggests that the globin radical plays an active role in the mechanism of autocatalysis. Interestingly, the oxidation of oxyHb or oxyMb by nitrite, but not by hydrogen peroxide, produced a diffusible radical that was able to generate spin adducts on a bystander protein. This indicates that the oxidation of oxyhemeproteins by nitrite may cause more widespread oxidative damage than the corresponding oxidation by hydrogen peroxide. The immuno-spin trapping technique represents an important new development for the study of the range and extent of protein oxidation by free radicals and oxidants.