Cyanide stimulated dissociation of chloride from the catalytic center of oxidized cytochrome c oxidase

A comparison of bovine cytochrome c oxidase isolated in the presence and the absence of chloride salts reveals that only enzyme isolated in the presence of chloride salts is a mixture of a complex of oxidized enzyme with chloride (CcO.Cl) and chloride-free enzyme (CcO). Using a spectrophotometric method for chloride determination, it was shown that CcO.Cl contains one chloride ion that is released into the medium by a single turnover or by cyanide binding. Chloride is bound slowly within the heme a(3)-Cu(B) binuclear center of oxidized enzyme in a manner similar to the binding of azide. The pH dependence of the dissociation constant for the formation of the CcO.Cl complex reveals that chloride binding proceeds with the uptake of one proton. With both forms of the enzyme the dependence of the rate of reaction for cyanide binding upon cyanide concentration asymptotes a limiting value indicating the existence of an intermediate. With CcO.Cl this limiting rate is 10(3) higher than the rate of the spontaneous dissociation of chloride from the binuclear center and we propose that the initial step is the coordination of cyanide to Cu(B) and in this intermediate state the rate of dissociation of chloride is substantially enhanced.     

A role for the protein in internal electron transfer to the catalytic center of cytochrome c oxidase

Internal electron transfer (ET) to heme a(3) during anaerobic reduction of oxidized bovine heart cytochrome c oxidase (CcO) was studied under conditions where heme a and Cu(A) were fully reduced by excess hexaamineruthenium. The data show that ET to heme a(3) is controlled by the state of ionization of a single protolytic residue with a pK(a) of 6.5 +/- 0.2. On the basis of the view that ET to the catalytic site is limited by coupled proton transfer, this pK(a) was attributed to Glu60 which is located at the entrance of the proton-conducting K channel on the matrix side of CcO. It is proposed that Glu60 controls proton entry into the channel. However, even with this channel open, there is the second factor that regulates ET, and this is ascribed to the rate of proton diffusion in the channel. In addition, it is concluded that proton transfer in the K channel is reversibly inhibited by the detergent Triton X-100. It is also found that the rate of ET to heme a(3) in the as-isolated resting enzyme and in CcO "activated" by reaction of fully reduced enzyme with O(2) is the same, implying that the catalytic sites of these two forms of oxidized enzyme are essentially identical.     

Proton interactions with hemes a and a3 in bovine heart cytochrome c oxidase

Three forms of cytochrome c oxidase, fully oxidized CcO (CcO-O), oxidized CcO complexed with cyanide (CcO.CN), and mixed valence CcO, in which both heme a(3) and Cu(B) are reduced and stabilized by carbon monoxide (MV.CO), were investigated by optical spectroscopy, MCD, and stopped-flow for the pH sensitivity of spectral features. In the pH range between pH 5.7 and 9.0, both heme a and heme a(3) in CcO-O interact with a single protolytic group. From the variation of the position of the Soret peak with changes in pH, a pK(a) of 6.6 +/- 0.2 was determined for this group. The pH sensitivity of heme a(3) is lost in the CcO.CN complex, and only heme a responds to pH changes. In MV.CO the spectra of both hemes are almost independent of pH between 5.7 and 11.0. The stoichiometry of proton uptake in the conversion of CcO-O both to MV.CO and to fully reduced CcO was determined between pH 5.8 and pH 8.2. Formation of MV.CO from CcO-O was accompanied by the uptake of approximately two protons, and this value was almost independent of pH. Full reduction of oxidized CcO was associated with the uptake of approximately 2 H(+) at basic pH, and this value increases with decreasing pH. On the basis of these proton uptake measurements, it is concluded that the pK(a) of the group is independent of the redox state of CcO. It is suggested that Glu60 of subunit II, located at the entrance of the proton conducting K-channel, is the protolytic residue that interacts with both hemes through a hydrogen-bonding network.     

Involvement of phospholipid, biomembrane integrity, and NO peroxidase activity in the NO catabolism by cytochrome c oxidase

The physiological regulation of mitochondrial respiration by NO has been reported to result from the reversible binding of NO to the two-electron reduced binuclear center (Fe(2+)(a3)-Cu(1+)(B)) of cytochrome c oxidase (CcO). Although the role of CcO and its derived catalytic intermediates in the catabolism of NO has been documented, little has been established for the enzyme in its fully oxidized state (Fe(3+)(a3)-Cu(2+)(B)). We report: (1) CcO, in its fully oxidized state, represents the major component of the mitochondrial electron transport chain for NO consumption as controlled by the binding of NO to its binuclear center. Phospholipid enhances NO consumption by fully oxidized CcO, whereas the consumption of NO is slowed down by membrane structure and membrane potential when CcO is embedded in the phospholipid bilayer. (2) In the presence of H(2)O(2), CcO was shown to serve as a mitochondria-derived NO peroxidase. A CcO-derived protein radical intermediate was induced and involved in the modulation of NO catabolism.     

Electron spin resonance investigation of the cyanyl and azidyl radical formation by cytochrome c oxidase.

Cyanide (CN(-)) is a frequently used inhibitor of mitochondrial respiration due to its binding to the ferric heme a(3) of cytochrome c oxidase (CcO). As-isolated CcO oxidized cyanide to the cyanyl radical ((.)CN) that was detected, using the ESR spin-trapping technique, as the 5,5-dimethyl-1-pyrroline N-oxide (DMPO)/(.)CN radical adduct. The enzymatic conversion of cyanide to the cyanyl radical by CcO was time-dependent but not affected by azide (N(3)(-)). The small but variable amounts of compound P present in the as-isolated CcO accounted for this one-electron oxidation of cyanide to the cyanyl radical. In contrast, as-isolated CcO exhibited little ability to catalyze the oxidation of azide, presumably because of azide's lower affinity for the CcO. However, the DMPO/(.)N(3) radical adduct was readily detected when H(2)O(2) was included in the system. The results presented here indicate the need to re-evaluate oxidative stress in mitochondria "chemical hypoxia" induced by cyanide or azide to account for the presence of highly reactive free radicals.     

Mutants of the CuA site in cytochrome c oxidase of Rhodobacter sphaeroides: II. Rapid kinetic analysis of electron transfer

The function of the binuclear Cu(A) center in cytochrome c oxidase (CcO) was studied using two Rhodobacter sphaeroides CcO mutants involving direct ligands of the Cu(A) center, H260N and M263L. The rapid electron-transfer kinetics of the mutants were studied by flash photolysis of a cytochrome c derivative labeled with ruthenium trisbipyridine at lysine-55. The rate constant for intracomplex electron transfer from heme c to Cu(A) was decreased from 40000 s(-1) for wild-type CcO to 16000 s(-1) and 11000 s(-1) for the M263L and H260N mutants, respectively. The rate constant for electron transfer from Cu(A) to heme a was decreased from 90000 s(-1) for wild-type CcO to 4000 s(-1) for the M263L mutant and only 45 s(-1) for the H260N mutant. The rate constant for the reverse reaction, heme a to Cu(A), was calculated to be 66000 s(-1) for M263L and 180 s(-1) for H260N, compared to 17000 s(-1) for wild-type CcO. It was estimated that the redox potential of Cu(A) was increased by 120 mV for the M263L mutant and 90 mV for the H260N mutant, relative to the potential of heme a. Neither mutation significantly affected the binding interaction with cytochrome c. These results indicate that His-260, but not Met-263, plays a significant role in electron transfer between Cu(A) and heme a.     

Filling the catalytic site of cytochrome c oxidase with electrons. Reduced CuB facilitates internal electron transfer to heme a3

In the reductive phase of its catalytic cycle, cytochrome c oxidase receives electrons from external electron donors. Two electrons have to be transferred into the catalytic center, composed of heme a(3) and Cu(B), before reaction with oxygen takes place. In addition, this phase of catalysis appears to be involved in proton translocation. Here, we report for the first time the kinetics of electron transfer to both heme a(3) and Cu(B) during the transition from the oxidized to the fully reduced state. The state of reduction of both heme a(3) and Cu(B) was monitored by a combination of EPR spectroscopy, the rapid freeze procedure, and the stopped-flow method. The kinetics of cytochrome c oxidase reduction by hexaamineruthenium under anaerobic conditions revealed that the rate-limiting step is the initial electron transfer to the catalytic site that proceeds with apparently identical rates to both heme a(3) and Cu(B). After Cu(B) is reduced, electron transfer to oxidized heme a(3) is enhanced relative to the rate of entry of the first electron.     

Modulation of the electron-proton coupling at cytochrome a by the ligation of the oxidized catalytic center in bovine cytochrome c oxidase

Cytochrome a was suggested as the key redox center in the proton pumping process of bovine cytochrome c oxidase (CcO). Recent studies showed that both the structure of heme a and its immediate vicinity are sensitive to the ligation and the redox state of the distant catalytic center composed of iron of cytochrome a₃ (Fe_a3) and copper (Cu_B). Here, the influence of the ligation at the oxidized Fe_a3³⁺–Cu_B²⁺ center on the electron–proton coupling at heme a was examined in the wide pH range (6.5-11). The strength of the coupling was evaluated by the determination of pH dependence of the midpoint potential of heme a (E_m(a)) for the cyanide (the low-spin Fe_a3³⁺) and the formate-ligated CcO (the high-spin Fe_a3³⁺). The measurements were performed under experimental conditions when other three redox centers of CcO are oxidized. Two slightly differing linear pH dependencies of E_m(a) were found for the CN– and the formate–ligated CcO with slopes of −13 mV/pH unit and −23 mV/pH unit, respectively. These linear dependencies indicate only a weak and unspecific electron–proton coupling at cytochrome a in both forms of CcO. The lack of the strong electron–proton coupling at the physiological pH values is also substantiated by the UV–Vis absorption and electron–paramagnetic resonance spectroscopy investigations of the cyanide–ligated oxidized CcO. It is shown that the ligand exchange at Fe_a³⁺ between His–Fe_a³⁺–His and His–Fe_a³⁺–OH⁻ occurs only at pH above 9.5 with the estimated pK >11.0.     

Infrared evidence of azide binding to iron, copper, and non-metal sites in heart cytochrome c oxidase.

Interactions of azide ion with bovine heart cytochrome c oxidase (CcO) at five redox levels (IV) to (0), obtained by zero to four electron reduction of fully oxidized enzyme CcO(IV), were monitored by infrared and visible/Soret spectra. Partially reduced CcO gave three azide asymmetric stretch band at 2040, 2016, and 2004 cm-1 for CcO(III)N3 and two at 2040 and 2016 cm-1 for CcO(II)N3 and CcO(I)N3. Resting CcO(IV) reacts with N3- to give one band at 2041 cm-1 assigned to CuB2+N3 and another at 2051 cm-1 to N3- that is associated with protein but is not bound to a metal ion. At high azide concentrations the weak association of many azide molecules with non-metal protein sites was observed at all redox levels. These findings provide direct evidence for 1) N3- binding to CuB as well as Fea3 in partially reduced enzyme, but no binding to Fea3 in fully oxidized enzyme and no binding to either metal in fully reduced enzyme; 2) a long range effect of the oxidation state of Fea or CuA on ligand binding at heme a3, but not at CuB; and 3) an insensitivity of either Fea3 or CuB ligand site to changes in ligand or oxidation state at the other site. The observed independence of the Fea3 and CuB sites provides further support for Fea3(3)+ OOH, rather than Fea3(3)+ OOCuB2+, as an intermediate in the reduction of O2 to water by the oxidase.     

Spectral and kinetic equivalence of oxidized cytochrome C oxidase as isolated and "activated" by reoxidation

The spectral and kinetic characteristics of two oxidized states of bovine heart cytochrome c oxidase (CcO) have been compared. The first is the oxidized state of enzyme isolated in the fast form (O) and the second is the form that is obtained immediately after oxidation of fully reduced CcO with O2 (OH). No observable differences were found between O and OH states in: (i) the rate of anaerobic reduction of heme a3 for both the detergent-solubilized enzyme and for enzyme embedded in its natural membraneous environment, (ii) the one-electron distribution between heme a3 and CuB in the course of the full anaerobic reduction, (iii) the optical and (iv) EPR spectra. Within experimental error of these characteristics both forms are identical. Based on these observations it is concluded that the reduction potentials and the ligation states of heme a3 and CuB are the same for CcO in the O and OH states.     

The protonation state of a heme propionate controls electron transfer in cytochrome c oxidase

In cytochrome c oxidase (CcO), exergonic electron transfer reactions from cytochrome c to oxygen drive proton pumping across the membrane. Elucidation of the proton pumping mechanism requires identification of the molecular components involved in the proton transfer reactions and investigation of the coupling between internal electron and proton transfer reactions in CcO. While the proton-input trajectory in CcO is relatively well characterized, the components of the output pathway have not been identified in detail. In this study, we have investigated the pH dependence of electron transfer reactions that are linked to proton translocation in a structural variant of CcO in which Arg481, which interacts with the heme D-ring propionates in a proposed proton output pathway, was replaced with Lys (RK481 CcO). The results show that in RK481 CcO the midpoint potentials of hemes a and a(3) were lowered by approximately 40 and approximately 15 mV, respectively, which stabilizes the reduced state of Cu(A) during reaction of the reduced CcO with O(2). In addition, while the pH dependence of the F --> O rate in wild-type CcO is determined by the protonation state of two protonatable groups with pK(a) values of 6.3 and 9.4, only the high-pK(a) group influences this rate in RK481 CcO. The results indicate that the protonation state of the Arg481 heme a(3) D-ring propionate cluster having a pK(a) of approximately 6.3 modulates the rate of internal electron transfer and may act as an acceptor of pumped protons.     

Implications of ligand binding studies for the catalytic mechanism of cytochrome c oxidase

The reaction of oxidized bovine heart cytochrome c oxidase (CcO) with one equivalent of hydrogen peroxide results in the formation of two spectrally distinct species. The yield of these two forms is controlled by the ionization of a group with a pK(a) of 6.6. At basic pH, where this group is deprotonated, an intermediate called P dominates (P, because it was initially believed to be a peroxy compound). At acidic pH where the group is protonated, a different species, called F (ferryl intermediate) is obtained. We previously proposed that the only difference between these two species is the presence of one proton in the catalytic center of F that is absent in P. It is now suggested that the catalytic center of this F form has the same redox and protonation state as a second ferryl intermediate produced at basic pH by two equivalents of hydrogen peroxide; the role of the second equivalent of H(2)O(2) is that of a proton donor in the conversion of P to F. Two chloride-binding sites have been detected in oxidized CcO. One site is located at the binuclear center; the second site was identified from the sensitivity of g=3 signal of cytochrome a to chloride in the EPR spectra of oxidized CcO. Turnover of CcO releases chloride from the catalytic center into the medium probably by one of the hydrophobic channels, proposed for oxygen access, with an orientation parallel to the membrane plane. Chloride in the binuclear center is most likely not involved in CcO catalysis. The influence of the second chloride site upon several reactions of CcO has been assessed. No correlation was found between chloride binding to the second site and the reactions that were examined.     

Proton NMR study of the heme environment in bacterial quinol oxidases

The heme environment and ligand binding properties of two relatively large membrane proteins containing multiple paramagnetic metal centers, cytochrome bo3 and bd quinol oxidases, have been studied by high field proton nuclear magnetic resonance (NMR) spectroscopy. The oxidized bo3 enzyme displays well-resolved hyperfine-shifted 1H NMR resonance assignable to the low-spin heme b center. The observed spectral changes induced by addition of cyanide to the protein were attributed to the structural perturbations on the low-spin heme (heme b) center by cyanide ligation to the nearby high-spin heme (heme o) of the protein. The oxidized hd oxidase shows extremely broad signals in the spectral region where protons near high-spin heme centers resonate. Addition of cyanide to the oxidized bd enzyme induced no detectable perturbations on the observed hyperfine signals, indicating the insensitive nature of this heme center toward cyanide. The proton signals near the low-spin heme b558 center are only observed in the presence of 20% formamide, consistent with a critical role of viscosity in detecting NMR signals of large membrane proteins. The reduced bd protein also displays hyperfine-shifted 1H NMR signals, indicating that the high-spin heme centers (hemes b595 and d) remain high-spin upon chemical reduction. The results presented here demonstrate that structural changes of one metal center can significantly influence the structural properties of other nearby metal center(s) in large membrane paramagnetic metalloproteins.     

Effect of cyanide binding on the copper sites of cytochrome c oxidase: an X-ray absorption spectroscopic study

Cu x-ray absorption spectroscopy (XAS) has been used to investigate the effect of cyanide treatment on the structures of the copper sites in beef heart cytochrome c oxidase. The Cu K-edge spectrum changes significantly upon cyanide binding to resting state enzyme, as does the Cu extended x-ray absorption fine structure (EXAFS) spectrum. The Cu EXAFS Fourier transfer (FT) exhibits an enhanced peak for the cyanide-treated enzyme in the region containing the Cu...Fe peak in the resting state FT (at R' approximately equal to 2.6-2.7 A). This peak in the cyanide-treated sample is hypothesized to arise from "outer shell" scattering from a linear Cu-cyanide moiety, suggesting cyanide binding to CuB only (CuB 2+-CN-) or cyanide bridging between the Fe of heme a3 and CuB (Fe3+-(CN-)-CuB 2+).     

The rate-limiting step in O(2) reduction by cytochrome ba(3) from Thermus thermophilus

Cytochrome ba(3) (ba(3)) of Thermus thermophilus (T. thermophilus) is a member of the heme-copper oxidase family, which has a binuclear catalytic center comprised of a heme (heme a(3)) and a copper (Cu(B)). The heme-copper oxidases generally catalyze the four electron reduction of molecular oxygen in a sequence involving several intermediates. We have investigated the reaction of the fully reduced ba(3) with O(2) using stopped-flow techniques. Transient visible absorption spectra indicated that a fraction of the enzyme decayed to the oxidized state within the dead time (~1ms) of the stopped-flow instrument, while the remaining amount was in a reduced state that decayed slowly (k=400s(-1)) to the oxidized state without accumulation of detectable intermediates. Furthermore, no accumulation of intermediate species at 1ms was detected in time resolved resonance Raman measurements of the reaction. These findings suggest that O(2) binds rapidly to heme a(3) in one fraction of the enzyme and progresses to the oxidized state. In the other fraction of the enzyme, O(2) binds transiently to a trap, likely Cu(B), prior to its migration to heme a(3) for the oxidative reaction, highlighting the critical role of Cu(B) in regulating the oxygen reaction kinetics in the oxidase superfamily.     

Redox-linked conformational changes in bovine heart cytochrome c oxidase: picosecond time-resolved fluorescence studies of cyanide complex

Picosecond time-resolved fluorescence studies are carried out on cyanide-inhibited and heat-modified cytochrome c oxidase in aqueous lauryl maltoside surfactant solution, as well as in an aqueous vesicle, to understand the conformational changes associated with electron transfer and proton pumping activity of the enzyme. The tryptophan fluorescence decay profiles follow a four exponential model, which also matches the lifetime maxima obtained in a maximum entropy method analysis. The fast lifetime components are highly affected by the reduction and chemical modification of the enzyme. Changes in these lifetime components are related to the conformational changes in the vicinity of the heme centers of the enzyme. The cyanide-inhibited enzyme in the oxidized form shows a fluorescence decay profile similar to that of the native oxidized form, indicating that the conformational changes due to cyanide binding are very small. However, reduction of the cyanide-inhibited enzyme that leaves cyanide bound heme alpha3 oxidized causes a large increase in the fluorescence lifetimes, which indicates very significant conformational changes due to electron transfer to the dinuclear Cu(A) and heme alpha centers. A comparison of the tryptophan fluorescence decay of various other modified forms of the enzyme leads us to propose that the possible site of conformational coupling is located near heme alpha instead of the binuclear heme alpha3-Cu(B) center.     

Cytochrome c oxidase dysfunction in oxidative stress

Cytochrome c oxidase (CcO) is the terminal oxidase of the mitochondrial electron transport chain. This bigenomic enzyme in mammals contains 13 subunits of which the 3 catalytic subunits are encoded by the mitochondrial genes. The remaining 10 subunits with suspected roles in the regulation, and/or assembly, are coded by the nuclear genome. The enzyme contains two heme groups (heme a and a3) and two Cu(2+) centers (Cu(2+) A and Cu(2+) B) as catalytic centers and handles more than 90% of molecular O(2) respired by the mammalian cells and tissues. CcO is a highly regulated enzyme which is believed to be the pacesetter for mitochondrial oxidative metabolism and ATP synthesis. The structure and function of the enzyme are affected in a wide variety of diseases including cancer, neurodegenerative diseases, myocardial ischemia/reperfusion, bone and skeletal diseases, and diabetes. Despite handling a high O(2) load the role of CcO in the production of reactive oxygen species still remains a subject of debate. However, a volume of evidence suggests that CcO dysfunction is invariably associated with increased mitochondrial reactive oxygen species production and cellular toxicity. In this paper we review the literature on mechanisms of multimodal regulation of CcO activity by a wide spectrum of physiological and pathological factors. We also review an array of literature on the direct or indirect roles of CcO in reactive oxygen species production.     

Electron transfer at the low-spin heme b of cytochrome bo(3) induces an environmental change of the catalytic enhancer glutamic acid-286

Intramolecular proton transfer of heme-copper oxidases is performed via the K- and the transmembrane D-channels. A carboxyl group conserved in a subgroup of heme-copper oxidases, located within the D-channel close to the binuclear center (=glutamic acid-286 in cytochrome bo(3) from Escherichia coli) is essential for proton pumping. Upon electron transfer to the fully oxidized (FO) enzyme, this amino acid has been shown to undergo a cyanide-independent environmental change. The redox-induced environmental transition of glutamic acid-286 is preserved in the site-directed mutant Y288F, which has lost its Cu(B) binding capacity. Furthermore, the mixed-valence (MV) redox state of cytochrome bo(3) (in which Cu(B) and high-spin heme are reduced, whereas the low-spin heme stays oxidized) was prepared by anaerobic exposure of the protein to carbon monoxide. This complex was converted (i) to the FO state by reaction with the caged dioxygen donor mu-peroxo) (mu-hydroxo) bis [bis (bipyridyl) cobalt (III)] and (ii) to the fully reduced (FR) state via caged electron donors; the environmental change of glutamic acid-286 could be observed only upon reduction. Taken together, these results from two different lines of evidence clearly show that the redox transition of the low-spin heme b center alone triggers the change in the chemical environment of this acidic side chain. It is suggested that glutamic acid-286 is a kinetic enhancer of proton translocation, which is energetically favoured in mesophilic oxidases.     

Examination of the reaction of fully reduced cytochrome oxidase with hydrogen peroxide by flow-flash spectroscopy

The reaction of cytochrome c oxidase with hydrogen peroxide has been of great value in generating and characterizing oxygenated species of the enzyme that are identical or similar to those formed during turnover of the enzyme with dioxygen. Most previous studies have utilized relatively low peroxide concentrations (millimolar range). In the current work, these studies have been extended to the examination of the kinetics of the single turnover of the fully reduced enzyme using much higher concentrations of peroxide to avoid limitations by the bimolecular reaction. The flow-flash method is used, in which laser photolysis of the CO adduct of the fully reduced enzyme initiates the reaction following rapid mixing of the enzyme with peroxide, and the reaction is monitored by observing the absorbance changes due to the heme components of the enzyme. The following reaction sequence is deduced from the data. (1) The initial product of the reaction appears to be heme a(3) oxoferryl (Fe(4+)=O(2)(-) + H(2)O). Since the conversion of ferrous to ferryl heme a(3) (Fe(2+) to Fe(4+)) is sufficient for this reaction, presumably Cu(B) remains reduced in the product, along with Cu(A) and heme a. (2) The second phase of the reaction is an internal rearrangement of electrons and protons in which the heme a(3) oxoferryl is reduced to ferric hydroxide (Fe(3+)OH(-)). In about 40% of the population, the electron comes from heme a, and in the remaining 60% of the population, Cu(B) is oxidized. This step has a time constant of about 65 micros. (3) The third apparent phase of the reaction includes two parallel reactions. The population of the enzyme with an electron in the binuclear center reacts with a second molecule of peroxide, forming compound F. The population of the enzyme with the two electrons on heme a and Cu(A) must first transfer an electron to the binuclear center, followed by reaction with a second molecule of peroxide, also yielding compound F. In each of these reaction pathways, the reaction time is 100-200 micros, i.e., much faster than the rate of reaction of peroxide with the fully oxidized enzyme. Thus, hydrogen peroxide is an efficient trap for a single electron in the binuclear center. (4) Compound F is then reduced by the final available electron, again from heme a, at the same rate as observed for the reduction of compound F formed during the reaction of the fully reduced oxidase with dioxygen. The product is the fully oxidized enzyme (heme a(3) Fe(3+)OH(-)), which reacts with a third molecule of hydrogen peroxide, forming compound P. The rate of this final reaction step saturates at high concentrations of peroxide (V(max) = 250 s(-)(1), K(m) = 350 mM). The data indicate a reaction mechanism for the steady-state peroxidase activity of the enzyme which, at pH 7.5, proceeds via the single-electron reduction of the binuclear center followed by reaction with peroxide to form compound F directly, without forming compound P. Peroxide is an efficient trap for the one-electron-reduced state of the binuclear center. The results also suggest that the reaction of hydrogen peroxide to the fully oxidized enzyme may be limited by the presence of hydroxide associated with the heme a(3) ferric species. The reaction of hydrogen peroxide with heme a(3) is very substantially accelerated by the availability of an electron on heme a, which is presumably transferred to the binuclear center concomitant with a proton that can convert the hydroxide to water, which is readily displaced.     

Structural studies on bovine heart cytochrome c oxidase

Among the X-ray structures of bovine heart cytochrome c oxidase (CcO), reported thus far, the highest resolution is 1.8?. CcO includes 13 different protein subunits, 7 species of phospholipids, 7 species of triglycerides, 4 redox-active metal sites (Cu(A), heme a (Fe(a)), Cu(B), heme a(3) (Fe(a3))) and 3 redox-inactive metal sites (Mg(2+), Zn(2+) and Na(+)). The effects of various O(2) analogs on the X-ray structure suggest that O(2) molecules are transiently trapped at the Cu(B) site before binding to Fe(a3)(2+) to provide O(2)(-). This provides three possible electron transfer pathways from Cu(B), Fe(a3) and Tyr244 via a water molecule. These pathways facilitate non-sequential 3 electron reduction of the bound O(2)(-) to break the OO bond without releasing active oxygen species. Bovine heart CcO has a proton conducting pathway that includes a hydrogen-bond network and a water-channel which, in tandem, connect the positive side phase with the negative side phase. The hydrogen-bond network forms two additional hydrogen-bonds with the formyl and propionate groups of heme a. Thus, upon oxidation of heme a, the positive charge created on Fe(a) is readily delocalized to the heme peripheral groups to drive proton-transport through the hydrogen-bond network. A peptide bond in the hydrogen-bond network and a redox-coupled conformational change in the water channel are expected to effectively block reverse proton transfer through the H-pathway. These functions of the pathway have been confirmed by site-directed mutagenesis of bovine CcO expressed in HeLa cells.