Two different aa3-type cytochromes can be purified from the bacterium Bacillus cereus.

Two aa3-type cytochromes were purified from membranes of sporulating Bacillus cereus. One of them, an aa3 complex, was found to be composed of two subunits (51 and 31 kDa), two a hemes and three copper atoms, thus being similar to the cytochrome aa3 previously purified from vegetative B. cereus [García-Horsman, J. A., Barquera, B., González-Halphen, D. & Escamilla, J. E. (1991) Mol. Microbiol. 5, 197-205]. The second isoform, a caa3 complex, was expressed in sporulating cells only, and was found to be composed of two subunits (51 and 37 kDa). The 37-kDa subunit (subunit II) is a heme-c-containing polypeptide as shown by its peroxidase activity in SDS/PAGE gels and by its spectral features. Both subunits of the caa3 complex immunologically cross-reacted with antiserum raised against B. cereus cytochrome aa3, suggesting homology between the two enzymes. Also, the heme-c-containing subunit of the caa3 complex was reactive with anti-(bovine cytochrome c) antiserum, but not with anti-(bovine cytochrome c1) antiserum. In addition to one heme c and two hemes a, the caa3 complex contained three copper atoms. Kinetic comparison of aa3 and caa3 complexes revealed that the latter is slightly more active (k = 150 s-1) and has a lower affinity to yeast cytochrome c (Km = 76 microM) and to oxygen (Km = 2 microM) as compared with cytochrome aa3 (100 s-1, 10 microM, and 5 microM, respectively).     

Reduction of cytochrome oxidase by 5,10-dihydro-5-methylphenazine: kinetic parameters from rapid-scanning stopped-flow experiments

The kinetics of the reduction of resting cytochrome oxidase and of its cyanide complex by 5,10-dihydro-5- methylphenazine (MPH) have been characterized by rapid-scan and fixed-wavelength stopped-flow spectrophotometry in the Soret, visible, and near-IR spectral regions. In this study, we focused on a form of the resting enzyme that is characterized by a Soret absorption maximum at 424 nm. These experiments complement earlier work on the reduction of a 418 nm absorbing form of the resting enzyme [ Halaka , F.G., Babcock , G. T., & Dye, J. L. (1981) J. Biol. Chem. 256, 1084-1087]. The reduction of cytochrome a is accomplished in a second-order reaction with a rate constant of 3 X 10(5) M-1 s-1. The reduction of the 830-nm absorber, Cua, is closely coupled to but lags the reduction of cytochrome a; we have resolved a rate constant of about 20 s-1 for the copper reduction. The reduction of cytochrome a proceeds with a rate constant that is nearly independent of the spectral properties of the resting enzyme and of the ligation state of cytochrome a3. The reduction of cytochrome a3 occurs by slow, intramolecular electron transfer. We have resolved two phases for this process that have rate constants of approximately 0.2 s-1 and approximately 0.02 s-1 for both the 418- and 424-nm forms of the resting enzyme. It appears, therefore, that spectroscopic heterogeneity at the cytochrome a3 site in the resting enzyme exerts very little influence on the kinetics of the anaerobic reduction of the oxidase metal centers. From this we conclude that the rate of electron transfer to the a3 site is probably controlled by the protein conformation and not primarily by local factors within the a3 environment.     

Reactions of mercaptans with cytochrome c oxidase and cytochrome c

1. The steady-state oxidation of ferrocytochrome c by dioxygen catalyzed by cytochrome c oxidase, is inhibited non-competitively towards cytochrome c by methanethiol, ethanethiol, 1-propanethiol and 1-butanethiol with Ki values of 4.5, 91, 200 and 330 microM, respectively. 2. The inhibition constant Ki of ethanethiol is found to be constant between pH 5 and 8, which suggests that only the neutral form of the thiol inhibits the enzyme. 3. The absorption spectrum of oxidized cytochrome c oxidase in the Soret region shows rapid absorbance changes upon addition of ethanethiol to the enzyme. This process is followed by a very slow reduction of the enzyme. The fast reaction, which represents a binding reaction of ethanethiol to cytochrome c oxidase, has a k1 of 33 M-1 . s-1 and a dissociation constant Kd of 3.9 mM. 4. Ethanethiol induces fast spectral changes in the absorption spectrum of cytochrome c, which are followed by a very slow reduction of the heme. The rate constant for the fast ethanethiol reaction representing a bimolecular binding step is 50 M-1 . s-1 and the dissociation constant is about 2 mM. Addition of up to 25 mM ethanethiol to ferrocytochrome c does not cause spectral changes. 5. EPR (electron paramagnetic resonance) spectra of cytochrome c oxidase, incubated with methanethiol or ethanethiol in the presence of cytochrome c and ascorbate, show the formation of low-spin cytochrome alpha 3-mercaptide compounds with g values of 2.39, 2.23, 1.93 and of 2.43, 2.24, 1.91, respectively.     

Kinetic investigations of the reactions of cytochrome c oxidase with hydrogen peroxide

The reaction of H2O2 with reduced cytochrome c oxidase was investigated with rapid-scan/stopped-flow techniques. The results show that the oxidation rate of cytochrome a3 was dependent upon the peroxide concentration (k = 2 X 10(4) M-1 X s-1). Cytochrome a and CuA were oxidised with a maximal rate of approx. 20 s-1, indicating that the rate of internal electron transfer was much slower with H2O2 as the electron acceptor than with O2 (k greater than or equal to 700 s-1). Although other explanations are possible, this result strongly suggests that in the catalytic cycle with oxygen as a substrate the internal electron-transfer rate is enhanced by the formation of a peroxo-intermediate at the cytochrome a3-CuB site. It is shown that H2O2 took up two electrons per molecule. The reaction of H2O2 with oxidised cytochrome c oxidase was also studied. It is shown that pulsed oxidase readily reacted with H2O2 (k approximately 700 M-1 X s-1). Peroxide binding is followed by an H2O2-independent conformational change (k = 0.9 s-1). Resting oxidase partially bound H2O2 with a rate similar to that of pulsed oxidase; after H2O2 binding the resting enzyme was converted into the pulsed conformation in a peroxide-independent step (k = 0.2 s-1). Within 5 min, 55% of the resting enzyme reacted in a slower process. We conclude from the results that oxygenated cytochrome c oxidase probably is an enzyme-peroxide complex.     

Kinetic study on the successive four-step reduction of Cyt c3

A detailed kinetic study on the successive four-step reduction of cyt c3, which has four heme units in a single protein, III4 leads to III3II leads to III2II2 leads to III II3 leads to II4, was carried out by stopped-flow electronic spectroscopy (SF-UV) and stopped-flow circular dichroism spectroscopy (SF-CD). Based on the absorbance change vs. time and the ellipticity change vs. time at the characteristic CD, together with the electronic absorption of the enzyme, rate constants for the successive four electron transfer steps, k1-k4, were successfully estimated by computer simulation. The rate constants of the four steps (k1 = 19.8 s-1, k2 = 11.9 s-1, k3 = 8.9 s-1, and k4 = 1.6 s-1; 8.0 10(-4) M Na2S2O4) are quite different from the statistical values (4: 3: 2: 1), thus excluding the possibility of random reduction of hemes of equal reactivities. Instead, each heme has its own reactivity, probably dependent on its local environment. The value of k3 is somewhat higher than the statistical value, indicating the existence of an autoacceleration effect, although small. This autoacceleration is most probably due to a unique heme-heme and/or heme-environment interaction since unusual CD and electronic absorptions were observed at 350-400 nm at about the time corresponding.     

Adrenodoxin reductase and adrenodoxin. Mechanisms of reduction of ferricyanide and cytochrome c.

Adrenodoxin reductase, the flavoprotein moiety of the adrenal cortex mitochondrial steroid hydroxylating system, participates in adrenodoxin-dependent cytochrome c and adrenodoxin-independent ferricyanide reduction, with NADPH as electron donor for both of these 1-electron reductions. For ferricyanide reduction, adrenodoxin reductase cycles between oxidized and 2-electron-reduced forms, reoxidation proceeding via the neutral flavin (FAD) semiquinone form (Fig. 9). Addition of adrenodoxin has no effect upon the kinetic parameters of flavoprotein-catalyzed ferricyanide reduction. For cytochrome c reduction, the adrenodoxin reductase-adrenodoxin 1:1 complex has been shown to be the catalytically active species (Lambeth, J. D., McCaslin, D. R., and Kamin, H. (1976) J. Biol. Chem. 251, 7545-7550). Present studies, using stopped flow techniques, have shown that the 2-electron-reduced form of the complex (produced by reaction with 1 eq of NADPH) reacts rapidly with 1 eq of cytochrome c (k approximately or equal to 4.6 s-1), but only slowly with a second cytochrome c (k = 0.1 to 0.3 s-1). However, when a second NADPH is included, two more equivalents of cytochrome are reduced rapidly. Thus, the adrenodoxin reductase-adrenodoxin complex appears to cycle between 1- and 3-electron reduced states, via an intermediate 2-electron-containing form produced by reoxidation by cytochrome (Fig. 10). For ferricyanide reduction by adrenodoxin reductase, the fully reduced and semiquinone forms of flavin each transfer 1 electron at oxidation-reduction potentials which differ by approximately 130 mV. However, adrenodoxin in a complex with adrenodoxin reductase allows electrons of constant potential to be delivered from flavin to cytochrome c via the iron sulfur center...     

Redox interaction of cytochrome c3 with [NiFe] hydrogenase from Desulfovibrio vulgaris Miyazaki F

Cytochrome c3 isolated from a sulfate-reducing bacterium, Desulfovibrio vulgaris Miyazaki F, is a tetraheme protein. Its physiological partner, [NiFe] hydrogenase, catalyzes the reversible oxidoreduction of molecular hydrogen. To elucidate the mechanism of electron transfer between cytochrome c3 and [NiFe] hydrogenase, the transient complex formation by these proteins was investigated by means of NMR. All NH signals of uniformly 15N-labeled ferric cytochrome c3 except N-terminus, Pro, and Gly73 were assigned. 1H-15N HSQC spectra were recorded for 15N-labeled ferric and ferrous cytochrome c3, in the absence and presence of hydrogenase. Chemical shift perturbations were observed in the region around heme 4 in both oxidation states. Additionally, the region between hemes 1 and 3 in ferrous cytochrome c3 was affected in the presence of hydrogenase, suggesting that the mode of interaction is different in each redox state. Heme 3 is probably the electron gate for ferrous cytochrome c3. To investigate the transient complex of cytochrome c3 and hydrogenase in detail, modeling of the complex was performed for the oxidized proteins using a docking program, ZDOCK 2.3, and NMR data. Furthermore, the roles of lysine residues of cytochrome c3 in the interaction with hydrogenase were investigated by site-directed mutagenesis. When the lysine residues around heme 4 were replaced by an uncharged residue, methionine, one by one, the Km of the electron-transfer kinetics increased. The results showed that the positive charges of Lys60, Lys72, Lys95, and Lys101 around heme 4 are important for formation of the transient complex with [NiFe] hydrogenase in the initial stage of the cytochrome c3 reduction. This finding is consistent with the most possible structure of the transient complex obtained by modeling.     

Heme P460 of hydroxylamine oxidoreductase of Nitrosomonas. Reaction with CO and H2O2

Hydroxylamine oxidoreductase (HAO) of Nitrosomonas catalyzes the dehydrogenation of NH2OH and subsequent addition of oxygen to form nitrite. HAO contains c hemes and the CO-binding heme P460 in a 7:1 ratio; dehydrogenation of NH2OH involves passage of electrons to P460 and then c hemes. We now report that electrons rapidly pass from c hemes of HAO to the P460 center and then to H2O2. This conclusion is supported by (a) inhibition of c heme oxidation with CO and (b) loss of H2O2-oxidizability of ferrous c hemes following specific destruction of heme P460. Reaction of ferrous P460 with H2O2 is rate-limiting. Activation of dioxygen for N-oxidation by ferrous HAO may involve the two-electron reduction of O2 by P460. The reaction of ferrous HAO with H2O2 was studied as it may reveal aspects of the mechanism of activation of dioxygen. Reaction of ferrous heme P460 with CO is slow and with low affinity as compared with other hemoproteins. Values for reaction of CO with enzyme were: k1, 1.1 X 10(-3) M-1 s-1 and Kd, 12 microM.     

Electrochemical, kinetic, and circular dichroic consequences of mutations at position 82 of yeast iso-1-cytochrome c

Replacement of Phe-82 in yeast iso-1-cytochrome c with Tyr, Leu, Ile, Ser, Ala, and Gly produces a gradation of effects on (1) the reduction potential of the protein, (2) the rate of reaction with Fe(EDTA)2-, and (3) the CD spectra of the ferricytochromes in the Soret region under conditions where contributions from the alkaline forms of these proteins are absent. The reduction potential of cytochrome c is lowered by as little as 10 mV (Tyr-82) or by as much as 43 mV (Gly-82; pH 6.0) as the result of these substitutions. The second-order rate constants for reduction of these cytochromes range from a low of 6.20 (2) x 10(4) for the Tyr-82 variant to a high of 14.8 x 10(4) M-1 s-1 for the Ser-82 variant [pH 6.0, 25 degrees C, mu = 0.1 M (sodium phosphate)]. Analysis of these rates by use of relative Marcus theory produces values of k11corr that range from 10.9 M-1 s-1 for the wild-type protein to 190 M-1 s-1 for the Gly-82 mutant [25 degrees C, mu = 0.1 M, pH 6.0 (sodium phosphate)]. Reinvestigation of the effect of substituting Phe-82 by a Tyr residue on the CD spectrum of the protein now reveals little alteration of the intense, negative Cotton effect in the Soret CD spectrum of ferricytochrome c. On the other hand, substitution of nonaromatic residues of various sizes at this position results in loss of this spectroscopic feature, consistent with previous findings.(ABSTRACT TRUNCATED AT 250 WORDS)     

In vitro kinetics of reduction of cytochrome c554 isolated from the reaction center of the green phototrophic bacterium, Chloroflexus aurantiacus

The photochemical reaction center in the green bacterium Chloroflexus aurantiacus is similar to that found in purple phototrophic bacteria and interacts with a multiheme membrane-bound cytochrome. We have examined the kinetics of reduction of the pure solubilized reaction center cytochrome by laser flash photolysis of solutions containing lumiflavin or FMN. Reduction by lumiflavin semiquinone followed single exponential kinetics and the observed rate constant (kobs) was linearly dependent on protein concentration (k = 1.8 X 10(7) M-1s-1 heme-1). This result suggests either that the four hemes have similar reduction rate constants which cannot be resolved or that there are large differences in rate constant and only the most reactive heme (or hemes) was observed under these conditions. To determine the relative reactivities of the four hemes, we varied the extent of heme reduction at a single total protein concentration. As the hemes were progressively reduced by steady-state illumination prior to laser flash photolysis, kobs for the reaction with fully reduced lumiflavin decreased nonlinearly. Second-order rate constants for the four hemes were assigned by nonlinear least-squares analysis of kobs vs oxidized heme concentration data. The second-order rate constants obtained in this way for the highest and lowest potential hemes differed by a factor of about 20, which is larger than expected for c-type cytochromes based on redox potential alone (a factor of about 3 would be expected). This is interpreted as being due to differences in steric accessibility. Relative to the highest potential heme, which is as reactive as a typical c-type cytochrome, we estimated a steric effect of approximately twofold for heme 2, and steric effects of approximately fivefold for hemes 3 and 4. Using fully reduced FMN as reductant of oxidized cytochrome, ionic strength effects indicate a minus-minus interaction, with approximately a -2 charge near the site of reduction of the highest potential heme.     

Spectroscopic and rapid kinetic studies of reduction of cytochrome c554 by hydroxylamine oxidoreductase from Nitrosomonas europaea.

During oxidation of hydroxylamine, hydroxylamine oxidoreductase (HAO) transfers two electrons to tetraheme cytochrome c554 at rates sufficient to account for physiological rates of oxidation of ammonia to nitrite in Nitrosomonas europaea. Spectroscopic changes indicate that the two electrons are taken up by a high-potential pair of hemes (E degrees' = +47 mV) (one apparently high spin and one low spin). During single-turnover experiments, in which the reduction of oxidized cytochrome c554 by NH2OH-reduced HAO is monitored, one electron is taken up by the high-spin heme at a rate too fast to monitor directly (greater than 100 s-1) but which is inferred either by a loss of amplitude (relative to that observed under multiple-turnover conditions) or is slowed down by increasing ionic strength (greater than or equal to 300 mM KCl). The second electron is taken up by the low-spin heme at a 10-30-fold slower rate. The latter kinetics appear multiphasic and may be complicated by a transient oxidation of HAO due to the rapid transfer of the first electron into the high-spin heme of cytochrome c554. Under multiple-turnover conditions, a "slower" rate of reduction is observed for the high-spin heme of cytochrome c554 with a maximum rate constant of approximately 30 s-1, a value also obtained for the reduction, by NH2OH, of the cytochrome c554 high-spin heme within an oxidized HAO/c554 complex. Under these conditions, the maximum rate of reduction of the low-spin heme was approximately 11.0 s-1. Both rates decreased as the concentration of cytochrome c554 was increased above the concentration of HAO.(ABSTRACT TRUNCATED AT 250 WORDS)     

The hydrogenase cytochrome b heme ligands of Azotobacter vinelandii are required for full H(2) oxidation capability

The hydrogenase in Azotobacter vinelandii, like other membrane-bound [NiFe] hydrogenases, consists of a catalytic heterodimer and an integral membrane cytochrome b. The histidines ligating the hemes in this cytochrome b were identified by H(2) oxidation properties of altered proteins produced by site-directed mutagenesis. Four fully conserved and four partially conserved histidines in HoxZ were substituted with alanine or tyrosine. The roles of these histidines in HoxZ heme binding and hydrogenase were characterized by O(2)-dependent H(2) oxidation and H(2)-dependent methylene blue reduction in vivo. Mutants H33A/Y (H33 replaced by A or Y), H74A/Y, H194A, H208A/Y, and H194,208A lost O(2)-dependent H(2) oxidation activity, H194Y and H136A had partial activity, and H97Y,H98A and H191A had full activity. These results suggest that the fully conserved histidines 33, 74, 194, and 208 are ligands to the hemes, tyrosine can serve as an alternate ligand in position 194, and H136 plays a role in H(2) oxidation. In mutant H194A/Y, imidazole (Imd) rescued H(2) oxidation activity in intact cells, which suggests that Imd acts as an exogenous ligand. The heterodimer activity, quantitatively determined as H(2)-dependent methylene blue reduction, indicated that the heterodimers of all mutants were catalytically active. H33A/Y had wild-type levels of methylene blue reduction, but the other HoxZ ligand mutants had significantly less than wild-type levels. Imd reconstituted full methylene blue reduction activity in mutants H194A/Y and H208A/Y and partial activity in H194,208A. These results indicate that structural and functional integrity of HoxZ is required for physiologically relevant H(2) oxidation, and structural integrity of HoxZ is necessary for full heterodimer-catalyzed H(2) oxidation.     

Activation by reduction of the resting form of cytochrome c oxidase: tests of different models and evidence for the involvement of CuB

(1) The reaction of the resting form of oxidised cytochrome c oxidase from ox heart with dithionite has been studied in the presence and absence of cyanide. In both cases, cytochrome a reduction in 0.1 M phosphate (pH 7) occurs at a rate of 8.2.10(4) M-1.s-1. In the absence of cyanide, ferrocytochrome a3 appears at a rate (kobs) of 0.016 s-1. Ferricytochrome a3 maintains its 418 nm Soret maximum until reduced. The rate of a3 reduction is independent of dithionite concentration over a range 0.9 mM-131 mM. In the presence or cyanide, visible and EPR spectral changes indicate the formation of a ferric a3/cyanide complex occurs at the same rate as a3 reduction in the absence of cyanide. A g = 3.6 signal appears at the same time as the decay of a g = 6 signal. No EPR signals which could be attributed to copper in any significant amounts could be detected after dithionite addition, either in the presence or absence of cyanide. (2) Addition of dithionite to cytochrome oxidase at various times following induction of turnover with ascorbate/TMPD, results in a biphasic reduction of cytochrome a3 with an increasing proportion of the fast phase of reduction occurring after longer turnover times. At the same time, the predominant steady state species of ferri-cytochrome a3 shifts from high to low spin and the steady-state level of reduction of cytochrome a drops indicating a shift in population of the enzyme molecules to a species with fast turnover. In the final activated form, oxygen is not required for fast internal electron transfer to cytochrome a3. In addition, oxygen does not induce further electron uptake in samples of resting cytochrome oxidase reduced under anaerobic conditions in the presence of cyanide. Both findings are contrary to predictions of certain O-loop types of mechanism for proton translocation. (3) A measurement of electron entry into the resting form of cytochrome oxidase in the presence of cyanide, using TMPD or cytochrome c under anaerobic conditions, shows that three electrons per oxidase enter below a redox potential of around +200 mV. An initial fast entry of two electrons is followed by a slow (kobs approximately 0.02 s) entry of a third electron.(ABSTRACT TRUNCATED AT 400 WORDS)     

Role of configurational gating in intracomplex electron transfer from cytochrome c to the radical cation in cytochrome c peroxidase.

Electron transfer within complexes of cytochrome c (Cc) and cytochrome c peroxidase (CcP) was studied to determine whether the reactions are gated by fluctuations in configuration. Electron transfer in the physiological complex of yeast Cc (yCc) and CcP was studied using the Ru-39-Cc derivative, in which the H39C/C102T variant of yeast iso-1-cytochrome c is labeled at the single cysteine residue on the back surface with trisbipyridylruthenium(II). Laser excitation of the 1:1 Ru-39-Cc-CcP compound I complex at low ionic strength results in rapid electron transfer from RuII to heme c FeIII, followed by electron transfer from heme c FeII to the Trp-191 indolyl radical cation with a rate constant keta of 2 x 10(6) s-1 at 20 degrees C. keta is not changed by increasing the viscosity up to 40 cP with glycerol and is independent of temperature. These results suggest that this reaction is not gated by fluctuations in the configuration of the complex, but may represent the elementary electron transfer step. The value of keta is consistent with the efficient pathway for electron transfer in the crystalline yCc-CcP complex, which has a distance of 16 A between the edge of heme c and the Trp-191 indole [Pelletier, H., and Kraut, J. (1992) Science 258, 1748-1755]. Electron transfer in the complex of horse Cc (hCc) and CcP was examined using Ru-27-Cc, in which hCc is labeled with trisbipyridylruthenium(II) at Lys-27. Laser excitation of the Ru-27-Cc-CcP complex results in electron transfer from RuII to heme c FeII with a rate constant k1 of 2.3 x 10(7) s-1, followed by oxidation of the Trp-191 indole to a radical cation by RuIII with a rate constant k3 of 7 x 10(6) s-1. The cycle is completed by electron transfer from heme c FeII to the Trp-191 radical cation with a rate constant k4 of 6.1 x 10(4) s-1. The rate constant k4 decreases to 3.4 x 10(3) s-1 as the viscosity is increased to 84 cP, but the rate constants k1 and k3 remain the same. The results are consistent with a gating mechanism in which the Ru-27-Cc-CcP complex undergoes fluctuations between a major state A with the configuration of the hCc-CcP crystalline complex and a minor state B with the configuration of the yCc-CcP complex. The hCc-CcP complex, state A, has an inefficient pathway for electron transfer from heme c to the Trp-191 indolyl radical cation with a distance of 20.5 A and a predicted value of 5 x 10(2) s-1 for k4A. The observed rate constant k4 is thus gated by the rate constant ka for conversion of state A to state B, where the rate of electron transfer k4B is expected to be 2 x 10(6) s-1. The temperature dependence of k4 provides activation parameters that are consistent with the proposed gating mechanism. These studies provide evidence that configurational gating does not control electron transfer in the physiological yCc-CcP complex, but is required in the nonphysiological hCc-CcP complex.     

Reduction kinetics of the four hemes of cytochrome c3 from Desulfovibrio vulgaris by flash photolysis.

The reduction of the tetraheme cytochrome c3 (from Desulfovibrio vulgaris, strains Miyazaki F and Hildenbourough) by flavin semiquinone and reduced methyl viologen follows a monophasic kinetic profile, even though the four hemes do not have equivalent reduction potentials. Rate constants for reduction of the individual hemes are obtained subsequent to incrementally reducing the cytochrome by phototitration. The dependence of each rate constant on the reduction potential difference between the heme and the reductant can be described by outer sphere electron transfer theroy. Thus, the very low reduction potentials of the cytochrome c3 hemes compensate for the very large solvent accessibility of the hemes. The relative rate constants for electron transfer to the four hemes of cytochrome c3 are consistent with the assignments of reduction potential to hemes previously made by Park et al. (Park, J.-S., Kano, K., Niki, S. and Akutsu, H. (1991) FEBS Lett. 285, 149-151) using NMR techniques. The ionic strength dependence of the observed rate constant for reduction by the methyl viologen radical cation indicates that ionic strength substantially alters the structure and/or the heme reduction potentials of the cytochrome. This result is confirmed by reduction with a neutral flavin species (5-deazariboflavin semiquinone) in which the reactivity of the highest potential heme decreases and the reactivity of the lowest potential heme increases at high (500 mM) ionic strength, and by the sensitivity of heme methyl resonances to ionic strength as observed by 1H-NMR. These unusual ionic strength-dependent effects may be due to a combination of structural changes in the cytochrome and alterations of the electrostatic fields at elevated ionic strengths.     

The oxidation of cytochrome c oxidase by hydrogen peroxide

The reaction of H2O2 with mixed-valence and fully reduced cytochrome c oxidase was investigated by photolysis of fully reduced and mixed-valence carboxy-cytochrome c oxidase in the presence of H2O2 under anaerobic conditions. The results showed that H2O2 reacted rapidly (k = (2.5-3.1) X 10(4) M-1 X s-1) with both enzyme species. With the mixed-valence enzyme, the fully oxidised enzyme was reformed. On the time-scale of our experiments, no spectroscopically detectable intermediate was observed. This demonstrates that mixed-valence cytochrome c oxidase is able to use H2O2 as a two-electron acceptor, suggesting that cytochrome c oxidase may under suitable conditions act as a peroxidase. Upon reaction of H2O2 with the fully reduced enzyme, cytochrome a was oxidised before cytochrome a3. From this observation it was possible to estimate that the rate of electron transfer from cytochrome a to a3 is about 0.5-5 s-1.     

Assignment of individual heme EPR signals of Desulfovibrio baculatus (strain 9974) tetraheme cytochrome c3. A redox equilibria study

An EPR redox titration was performed on the tetraheme cytochrome c3 isolated from Desulfovibrio baculatus (strain 9974), a sulfate-reducer. Using spectral differences at different poised redox states of the protein, it was possible to individualize the EPR g-values of each of the four hemes and also to determine the mid-point redox potentials of each individual heme: heme 4 (-70 mV) at gmax = 2.93, gmed = 2.26 and gmin = 1.51; heme 3 (-280 mV) at gmax = 3.41; heme 2 (-300 mV) at gmax = 3.05, gmed = 2.24 and gmin = 1.34; and heme 1 (-355 mV) at gmx = 3.18. A previously described multi-redox equilibria model used for the interpretation of NMR data of D. gigas cytochrome c3 [Santos, H., Moura, J.J.G., Moura, I., LeGall, J. & Xavier, A. V. (1984) Eur. J. Biochem. 141, 283-296] is discussed in terms of the EPR results.     

Effect of heat treatment on oxidase activity and proton-pumping capability of proteoliposome-incorporated beef heart cytochrome aa3

By incubating beef heart cytochrome c oxidase at 43-45 degrees C, selective inactivation of the H+-pumping function is possible without affecting cytochrome c oxidase activity; proteoliposomes reconstituted with heated enzyme (43.5 degrees C for 60 min at pH 7.0) showed an apparent H+/e- ratio of only 0.3 and a turnover with cytochrome c plus ferrocyanide as substrate of 20 s-1, while those with the intact enzyme showed an apparent H+/e- ratio somewhat greater than 1.0 and a turnover of 19 s-1. This decrease in the H+/e- ratio could not be attributed to a stimulation of H+ permeability upon heating, since the respiratory control ratio and the magnitude of membrane potential formation remained almost the same in the two cases. A pH-dependent Em (midpoint redox potential) change of cytochrome a in the presence of cyanide was still observed after the heat treatment. Heating induced a small spectral shift in the Soret region of the oxidized (resting) enzyme; the peak of the heated enzyme was at 421 nm, while that of the intact enzyme was at 419 nm. The spectral shift obtained by pulsing the enzyme with oxygen under turnover conditions is also altered.     

Formation of electrostatically-stabilized complex at low ionic strength inhibits interprotein electron transfer between yeast cytochrome c and cytochrome c peroxidase

Electron transfer from yeast ferrous cytochrome c to H2O2-oxidized yeast cytochrome c peroxidase has been studied using flash photoreduction methods. At low ionic strength (mu less than 10 mM), where a strong complex is formed between cytochrome c and peroxidase, electron transfer occurs rather slowly (k approximately 200s-1). However, at high ionic strength where the electrostatic complex is largely dissociated, the observed first-order rate constant for peroxidase reduction increases significantly reaching a concentration independent limit of k approximately 1500 s-1. Thus, at least in some cases, formation of an electrostatically-stabilized complex can actually impede electron transfer between proteins.