A new ruthenium complex to study single-electron reduction of the pulsed O(H) state of detergent-solubilized cytochrome oxidase

The first step in the catalytic cycle of cytochrome oxidase, the one-electron reduction of the fully oxidized enzyme, was investigated using a new photoactive binuclear ruthenium complex, [Ru(bipyrazine)2]2(quaterpyridine), (Ru2Z). The aim of the work was to examine differences in the redox kinetics resulting from pulsing the oxidase (i.e., fully reducing the enzyme followed by reoxidation) just prior to photoreduction. Recent reports indicate transient changes in the redox behavior of the metal centers upon pulsing. The new photoreductant has a large quantum yield, allowing the kinetics data to be acquired in a single flash. The net charge of +4 on Ru2Z allows it to bind electrostatically near CuA in subunit II of cytochrome oxidase. The photoexcited state Ru(II*) of Ru2Z is reduced to Ru(I) by the sacrificial electron donor aniline, and Ru(I) then reduces CuA with yields up to 60%. A stopped-flow-flash technique was used to form the pulsed state of cytochrome oxidase (the "OH" state) from several sources (bovine heart mitochondria, Rhodobacter sphaeroides, and Paracoccus denitrificans). Upon mixing the fully reduced anaerobic enzyme with oxygenated buffer containing Ru2Z, the oxidized OH state was formed within 5 ms. Ru2Z was then excited with a laser flash to inject one electron into CuA. Electron transfer from CuA --> heme a --> heme a3/CuB was monitored by optical spectroscopy, and the results were compared with the enzyme that had not been pulsed to the OH state. Pulsing had a significant effect in the case of the bovine oxidase, but this was not observed with the bacterial oxidases. Electron transfer from CuA to heme a occurred with a rate constant of 20,000 s-1 with the bovine cytochrome oxidase, regardless of whether the enzyme had been pulsed. However, electron transfer from heme a to the heme a3/CuB center in the pulsed form was 63% complete and occurred with biphasic kinetics with rate constants of 750 s-1 and 110 s-1 and relative amplitudes of 25% and 75%. In contrast, one-electron injection into the nonpulsed O form of the bovine oxidase was only 30% complete and occurred with monophasic kinetics with a rate constant of 90 s-1. This is the first indication of a difference between the fast form of the bovine oxidase and the pulsed OH form. No reduction of heme a3 is observed, indicating that CuB is the initial electron acceptor in the one-electron reduced pulsed bovine oxidase.     

An electron nuclear double resonance investigation of redox-induced electronic structural change at CuA2+ in cytochrome c oxidase

We measured an electronic change at cysteine ligand(s) of the CuA2+ center brought on by reduction of other metal centers within cytochrome c oxidase, notably cytochrome a. This change specifically manifested itself as a modification in magnetic hyperfine coupling to the beta-protons of the beta-carbons adjacent to the cysteine sulfur in the CuA2+ coordination sphere. The electron nuclear double resonance ENDOR signals of these beta-protons had previously been assigned through study of selectively deuterated yeast oxidase. In the present study the ENDOR signals of the CuA2+ center were compared from the following forms of oxidase: resting (a3+.CuA2+.a3+3.CuB2+); mixed valence, 2-electron-reduced CO-ligated oxidase (a3+.CuA2+.a2+3CO.CuB+), and a more completely reduced mixed-valence CO-ligated oxidase. In agreement with previous studies on 3-electron-reduced oxidase, the latter more completely reduced oxidase showed cytochrome a preferentially reduced with respect to CuA, implying that the majority of paramagnetic CuA2+ centers had reduced cytochrome a partners. The ENDOR-resolved splitting of the beta-proton hyperfine features substantially decreased in going from the first two more oxidized forms to the more fully reduced latter form. Thus, the electronic structure of the CuA2+ center specifically monitored by hyperfine couplings to cysteine protons changed in response to a reductive event elsewhere in the protein. This structural change may correlate with the anticooperative redox interaction recently reported between cytochrome a and CuA.     

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.     

A re-examination of the reactions of cyanide with cytochrome c oxidase

Experiments were performed to examine the cyanide-binding properties of resting and pulsed cytochrome c oxidase in both their stable and transient turnover states. Inhibition of the oxidation of ferrocytochrome c was monitored as a function of cyanide concentration. Cyanide binding to partially reduced forms produced by mixing cytochrome c oxidase with sodium dithionite was also examined. A model is presented that accounts fully for cyanide inhibition of the enzyme, the essential feature of which is the rapid, tight, binding of cyanide to transient, partially reduced, forms of the enzyme populated during turnover. Computer fitting of the experimentally obtained data to the kinetic predictions given by this model indicate that the cyanide-sensitive form of the enzyme binds the ligand with combination constants in excess of 10(6) M-1 X s-1 and with KD values of 50 nM or less. Kinetic difference spectra indicate that cyanide binds to oxidized cytochrome a33+ and that this occurs rapidly only when cytochrome a and CuA are reduced.     

"Peroxidatic" form of cytochrome oxidase as studied by X-ray absorption spectroscopy

X-ray absorption spectroscopy shows pulsed oxidase to be similar to resting oxidase but to lack the sulfur bridge between iron and copper of active sites (Powers, L., Y. Ching, B. Chance, and B. Muhoberac, 1982, Biophys. J., 37[2, Pt. 2]: 403a. [Abstr.] ) The first shell ligands and bond lengths of the pulsed oxidase active site heme most clearly fit the ferric peroxidases from horseradish and yeast, and the pulsed oxidase cyanide compound resembles the low spin hemoprotein cyanide compounds. The structural results are consistent with an aquo or a peroxo form for pulsed oxidase as is also observed by optical studies. These structural and chemical data are consistent with a role for the pulsed forms in a cyclic peroxidatic side reaction in which the pulsed and pulsed peroxide compounds act as peroxide scavengers. The peroxidatic role of cytochrome oxidase in the nonsulfur bridged form suggests the renaming of the "oxygenated" or "pulsed" forms on a functional basis as "peroxidatic" forms of cytochrome oxidase.     

Characterisation of a near infra-red absorption band of the Escherichia coli quinol oxidase, cytochrome o, which is attributable to the high-spin ferrous haem of the binuclear site.

The bacterial quinol oxidase, cytochrome o, is an enzyme which is highly analogous to the better known cytochrome c oxidase, cytochrome aa3, but with the important difference that it lacks the near infra-red absorbing pigment CuA. In this article we report an absorption band in the near IR spectrum of cytochrome o with a maximal absorption at 758 nm, and which is attributable to the ferrous high-spin haem. The 758 nm band has an extinction coefficient of 0.2-0.3 mM-1.cm-1 at 758-800 nm. This region in cytochrome aa3 is dominated by the CuA absorption. The 758 nm absorption is lost on addition of CO or cyanide to the reduced enzyme. The carbon monoxide compound of cytochrome o also has absorbance bands in the near infra-red, and these may be attributable to a low-spin ferrous haem compound.     

Zinc cytochrome c fluorescence as a probe for conformational changes in cytochrome c oxidase.

Zinc cytochrome c forms tight 1:1 complexes with a variety of derivatives of cytochrome c oxidase. On complex-formation the fluorescence of zinc cytochrome c is diminished. Titrations of zinc cytochrome c with cytochrome c oxidase, followed through the fluorescence emission of the former, have yielded both binding constants (K approximately 7 x 10(6) M-1 for the fully oxidized and 2 x 10(7) M-1 for the fully reduced enzyme) and distance information. Comparison of steady-state measurements obtained by absorbance and fluorescence spectroscopy in the presence and in the absence of cyanide show that it is the reduction of cytochrome a and/or CuA that triggers a conformational change: this increases the zinc cytochrome c to acceptor (most probably cytochrome a itself) distance by some 0.5 nm. Ligand binding to the fully oxidized or fully reduced enzyme leaves the extent of fluorescence quenching unchanged, whereas binding of cyanide to the half-reduced enzyme (a2+CuA+CuB2+-CN(-)-a3(3+)) enhances fluorescence emission relative to that for the fully reduced enzyme, implying further relative movement of donor and acceptor.     

Electron transfer after flash photolysis of mixed-valence carboxycytochrome c oxidase

The light-induced difference spectra of the fully reduced (a2+ a23+-CO) complex and the mixed-valence carboxycytochrome c oxidase (a3+ a23+-CO) during steady-state illumination and after flash photolysis showed marked differences. The differences appear to be due to electron transfer between the redox centres in the enzyme. The product of the absorbance coefficient and the quantum yield was found to be equal in both enzyme species, both when determined from the rates of photolysis and from the values of the dissociation constants of the cytochrome a23+-CO complex. This would confirm that the spectral properties of cytochrome a3 are not affected by the redox state of cytochrome a and CuA. When the absorbance changes after photolysis of cytochrome a23+-CO with a laser flash were followed on a time scale from 1 mus to 1 s in the fully reduced carboxycytochrome c oxidase, only the CO recombination reaction was observed. However, in the mixed-valence enzyme an additional fast absorbance change (k = 7 X 10(3) s-1) was detected. The kinetic difference spectrum of this fast change showed a peak at 415 nm and a trough at 445 nm, corresponding to oxidation of cytochrome a3. Concomitantly, a decrease of the 830 nm band was observed due to reduction of CuA. This demonstrates that in the partially reduced enzyme a pathway is present between CuA and the cytochrome a3-CuB pair, via which electrons are transferred rapidly.     

The interactions of cytochrome c and porphyrin cytochrome c with cytochrome c oxidase. The resting, reduced and pulsed enzymes

Cytochrome c oxidase forms tight binding complexes with the cytochrome c analog, porphyrin cytochrome c. The behaviour of the reduced and pulsed forms of the oxidase with porphyrin cytochrome c have been followed as functions of ionic strength; this behaviour has been compared with that of the resting oxidase [Kornblatt, Hui Bon Hoa and English (1984) Biochemistry 23, 5906-5911]. All forms of the cytochrome oxidase studied bind one porphyrin cytochrome c per 'functional' cytochrome oxidase (two heme a); it appears as though porphyrin cytochrome c and cytochrome c compete for the same site on the oxidase. The resting enzyme binds cytochrome c 8 times more strongly than porphyrin cytochrome c; the reduced enzyme, in contrast, binds the two with almost equal affinity. In all three cases, resting, pulsed and reduced, the heme-to-porphyrin distance is estimated to be about 3 nm. The tight-binding complexes formed between cytochrome oxidase and porphyrin cytochrome c can be dissociated by salt. Debye-Hückel analysis of salt titrations indicate that the resting enzyme and the reduced enzyme are similar in that the product of the interaction charges on the two proteins is about -14. The product of the charges for the pulsed enzyme is -25, indicating that on average another positive and negative charge take part in the interaction of the two proteins. While there is one tight binding site for cytochrome c per two heme a, cytochrome c is able to 'communicate' with four heme a. In the absence of cytochrome c, electron transfer from tetramethylphenylenediamine to the oxidase to oxygen results in the conversion of the resting form to the 'oxygenated'; in the presence of cytochrome c, the same electron transfer results in the appearance of the 'pulsed' form. Cytochrome c titrations of the enzyme show that a ratio of only one cytochrome c to four heme a is sufficient to convert all the oxidase to the 'pulsed' form. Porphyrin cytochrome c, like cytochrome c, catalyzes the same conversion with the same stoichiometry. The binding data and salt effects indicate that major structural alterations occur in the oxidase as it is converted from the resting to the partially reduced and subsequently to the pulsed form.     

Resonance Raman spectroscopy and enhanced photoreducibility for the 420 nm pulsed form of cytochrome oxidase

Resonance Raman (RR) spectra, with 413.1 nm Kr+ laser excitation, are reported for cytochrome oxidase in resting, reduced, and 428 nm (oxygenated) forms, and for the first time, in the 420 nm (pulsed) forms [(1984) J. Biol. Chem. 259, 2073-2076]. The differences between the resting, 420 nm, and 428 nm forms' RR spectra are small. All these forms contain FeIII only, as indicated by single v4 bands at approximately 1371 cm-1, and the reoxidized forms show partial conversion from high- to intermediate- or low-spin heme a3 (intensity shift from 1575 to 1588 cm-1 for v2). The 420 nm form differs strikingly from both the 428 nm and resting forms, however, in being much more readily photoreduced by the laser illumination. This property is linked to the protein conformational change believed to be responsible for the greater accessibility to exogenous ligands of the heme a3 in the 420 nm form.     

Characterization of the low-temperature intermediates of the reaction of fully reduced soluble cytochrome oxidase with oxygen by electron-paramagnetic-resonance and optical spectroscopy.

The reaction of fully reduced soluble bovine heart cytochrome oxidase with O2 at 173K was investigated by low-temperature optical and e.p.r. spectroscopy, and the kinetics of the reaction were analysed by non-linear optimization techniques. The only e.p.r. signals seen during the course of the reaction are those attributable to low-spin cytochrome a3+ and CuA2+. Quantitative analysis of e.p.r. signals shows that, at the end point of the reaction at 173K, nearly 100% of CuA is in the cupric state but only about 40% of cytochrome a is in the ferric low-spin state. The optical spectra recorded at this stage of the reaction show incomplete oxidation of haem and the absence of a 655 nm absorption band. The only reaction scheme that accounts for both the e.p.r. and optical data is a four-intermediate mechanism involving a branching pathway. The reaction is initiated when fully reduced cytochrome oxidase reacts with O2 to form intermediate I. This is then converted into either intermediate IIA or intermediate IIB. Of these, intermediate IIB is a stable end product at 173 K, but intermediate IIA is converted into intermediate III, which is the stable state at 173 K in this branch of the mechanism. The kinetic analysis of the e.p.r. data allows the unambiguous assignments of the valence states of cytochrome a and CuA in the intermediates. Intermediate I contains cytochrome a2+ and CuA+, intermediate IIA contains low-spin cytochroma a3+ and CuA+, intermediate IIB contains cytochrome a2+ and CuA2+, and intermediate III contains low-spin cytochrome a3+ and CuA2+. The electronic state of the O2-binding CuBa3 couple during the reoxidation of cytochrome oxidase is discussed in terms of an integrated structure containing CuB, cytochrome a3 and O2.     

Evidence for a band III analogue in the near-infrared absorption spectra of cytochrome c oxidase.

Ground state near-infrared absorption spectra of fully reduced unliganded and fully reduced CO (a2+ CuA+ a3(2+)-CO CuB+) cytochrome c oxidase were investigated. Flash-photolysis time-resolved absorption difference spectra of the mixed-valence (a3+ CuA2+ a3(2+)-CO CuB+) and the fully reduced CO complexes were also studied. A band near 785 nm (epsilon approximately 50 M-1cm-1) was observed in the fully reduced unliganded enzyme and the CO photoproducts. The time-resolved 785 nm band disappeared on the same timescale (t1/2 approximately 7 ms) as CO recombined with cytochrome a3(2+). This band, which is attributed to the unliganded five coordinate ferrous cytochrome a3(2+), has some characteristics of band III in deoxy-hemoglobin and deoxy-myoglobin. A second band was observed at approximately 710 nm (epsilon approximately 80 M-1cm-1) in the fully reduced unliganded and the fully reduced CO complexes. This band, which we assign to the low spin ferrous cytochrome a, appears to be affected by the ligation state at the cytochrome a3(2+) site.     

Routes of electron transfer in beef heart cytochrome c oxidase: is there a unique pathway used by all reductants?

Cytochrome c oxidase oxidizes several hydrogen donors, including TMPD (N,N,N',N'-tetramethyl-p-phenyl-enediamine) and DMPT (2-amino-6,7-dimethyl-5,6,7,8-tetrahydropterine), in the absence of the physiological substrate cytochrome c. Maximal enzyme turnovers with TMPD and DMPT alone are rather less than with cytochrome c, but much greater than previously reported if extrapolated to high reductant levels and (or) to 100% reduction of cytochrome a in the steady state. The presence of cytochrome c is, therefore, not necessary for substantial intramolecular electron transfer to occur in the oxidase. A direct bimolecular reduction of cytochrome a by TMPD is sufficient to account for the turnover of the enzyme. CuA may not be an essential component of the TMPD oxidase pathway. DMPT oxidation seems to occur more rapidly than the DMPT--cytochrome a reduction rate and may therefore imply mediation of CuA. Both "resting" and "pulsed" oxidases contain rapid-turnover and slow-turnover species, as determined by aerobic steady-state reduction of cytochrome a by TMPD. Only the "rapid" fraction (approximately 70% of the total with resting and approximately 85% of the total with pulsed) is involved in turnover. We conclude that electron transfer to the a3CuB binuclear centre can occur either from cytochrome a or CuA, depending upon the redox state of the binuclear centre. Under steady-state conditions, cytochrome a and CuA may not always be in rapid equilibrium. Rapid enzyme turnover by either natural or artificial substrates may require reduction of both and two pathways of electron transfer to the a3CuB centre.     

Redox-cycled oxidase. One of the reaction products of reduced cytochrome c, cytochrome c oxidase, and dioxygen

Pulsed and oxygenated forms of cytochrome c oxidase are believed to be variants of the oxidized enzyme. They were produced as a consequence of one or more reduction-oxidation cycles of the resting form and are characterized by an increase of the alpha band intensity and a red-shift of the Soret absorption band to 428 nm. The rate of decay of these species back to the resting enzyme varies appreciably and appears to depend on the nature of the reductant and/or oxidant used in their preparation. Here we report that if resting oxidase is incubated with either reduced or oxidized cytochrome c and then exposed to dioxygen, an activated form is rapidly produced which appears to be more oxidized than the starting material. This finding suggest some degree of partial reduction of the resting enzyme, but this by itself cannot explain the extent of activation. Our results further question the significance of the optical spectral "signature" of the oxygenated (Okunuki, K., and Sekuzu, I. (1954) Seitaino Kagaka 5, 265-272), pulsed (Antonini, E., Brunori, M., Colosimo, A., Greenwood, C., and Wilson, M. T. (1977) Proc. Natl. Acad. Sci. U.S.A. 74, 3128-3132), and "420 nm" species (Kumar, C., Naqui, A., and Chance, B. (1984) J. Biol. Chem. 259, 2073-2076, 11668-11671), which are thought to be activated forms of oxidized cytochrome c oxidase.     

The reaction of the electrostatic cytochrome c-cytochrome oxidase complex with oxygen.

The reaction of the electrostatic cytochrome c-cytochrome oxidase complex with oxygen is measured by transient absorption spectroscopy. The oxygen reaction is initiated by photolytic removal of CO from cytochrome oxidase, using a flash-pumped dye laser. The subsequent reaction of the cytochrome c-cytochrome oxidase complex with oxygen is reported at 550, 605, 744, and 830 nm at different cytochrome c:cytochrome oxidase ratios and different oxygen concentrations. In the absence of cytochrome c the time course of the reaction of the oxidase is well described by a triple exponential process at any of the measured wavelengths. The three processes are well resolved at high O2 levels (i.e. greater than 200 microM), where they reach first-order rate limits of 2.4 x 10(4), 7.5 x 10(3), and 650 s-1. When cytochrome c is added the oxidation of cytochrome a and one of the redox active cooper centers (CuA) are interrupted. The maximal effect of cytochrome c on the oxidation of the oxidase occurs at a c:aa3 ratio of 1. Cytochrome c reacts in a biphasic process with rates of up to 7 x 10(3) and 550 s-1 at high oxygen. The fast phase takes up 60% of the process, and this is independent of the cytochrome c:cytochrome oxidase ratio. The results are discussed in the context of a model in which electron entry into cytochrome oxidase from cytochrome c is via CuA, and cytochrome a functions to mediate electron transfer from CuA to the oxygen binding site. The role of CuA as initial electron acceptor in cytochrome c oxidase is related to its physical proximity to cytochrome c is the cytochrome c-cytochrome oxidase complex.     

pH dependence of the tryptophan fluorescence in cytochrome c oxidase: further evidence for a redox-linked conformational change associated with CuA

When the low-potential metal centers of cytochrome c oxidase are reduced, the enzyme undergoes a conformational transition that shifts the fluorescence maximum of the emitting tryptophan residues from 329 to 345 nm. At pH 7.4, the change in this tryptophan fluorescence intensity is a nonlinear function of the electron equivalents added to the cyanide-inhibited enzyme. This nonlinear behavior is a result of the difference in redox potential between cytochrome a and CuA, which, at equilibrium, favors electron occupancy at cytochrome a. Studies on the cyanide-inhibited enzyme suggest that the conformational change is associated with reduction of CuA [Copeland, R. A., Smith, P. A., & Chan, S. I. (1987) Biochemistry 26, 7311-7316]. In this work we present tryptophan fluorescence data for the cyanide-inhibited enzyme at pH 8.9. Because of the pH dependence of the midpoint potential of cytochrome a in this form of the enzyme, the two low-potential centers become virtually isopotential at pH 8.9. The results obtained confirm our earlier conclusion that the observed conformational change is linked to the reduction of CuA only, rather than to the redox activity of both low-potential metal centers. We find that, in partially reduced cyanide-inhibited oxidase, raising the pH from 7.4 to 8.9 results in an intensification and red shift of the enzyme's tryptophan emission as the electron occupancy redistributes from cytochrome a to CuA. Moreover, when the fluorescence change is plotted as a function of the number of electrons added to the enzyme at pH 8.9, the data fit the nearly linear function expected for a conformational change triggered by reduction of CuA exclusively.     

Electron transfer rates and equilibrium within cytochrome c oxidase.

Intramolecular electron transfer (ET) between the CuA center and heme a in bovine cytochrome c oxidase was investigated by pulse radiolysis. CuA, the initial electron acceptor, was reduced by 1-methyl nicotinamide radicals in a diffusion-controlled reaction, as monitored by absorption changes at 830 nm. After the initial reduction phase, the 830 nm absorption was partially restored, corresponding to reoxidation of the CuA center. Concomitantly, the absorption at 445 nm and 605 nm increased, indicating reduction of heme a. The rate constants for heme a reduction and CuA reoxidation were identical within experimental error and independent of the enzyme concentration. This demonstrates that a fast intramolecular electron equilibration is taking place between CuA and heme a. The rate constants for CuA --> heme a ET and the reverse (heme a --> CuA) process were found to be 13 000 s-1 and 3700 s-1, respectively, at 25 degrees C and pH 7.4. This corresponds to an equilibrium constant of 3.4 under these conditions. Thermodynamic and activation parameters of the ET reactions were determined. The significance of these results, particularly the observed low activation barriers, are discussed within the framework of the known three-dimensional structure, ET pathways and reorganization energies.     

Cyanide inhibition of cytochrome c oxidase. A rapid-freeze e.p.r. investigation.

The inhibition of cytochrome c oxidase by cyanide, starting either with the resting or the pulsed enzyme, was studied by rapid-freeze quenching followed by quantitative e.p.r. It is found that a partial reduction of cytochrome oxidase by transfer of 2 electron equivalents from ferrocytochrome c to cytochrome a and CuA will induce a transition from a closed to an open enzyme conformation, rendering the cytochrome a3-CuB site accessible for cyanide binding, possibly as a bridging ligand. A heterogeneity in the enzyme is observed in that an e.p.r. signal from the cytochrome a3 3+-HCN complex is only found in 20% of the molecules, whereas the remaining cyanide-bound a3-CuB sites are e.p.r.-silent.     

Reaction of dioxygen with cytochrome c oxidase reduced to different degrees: indications of a transient dioxygen complex with copper-B.

The reactions of the fully reduced, three-electron-reduced, and mixed-valence cytochrome oxidase with molecular oxygen have been followed in flow-flash experiments, starting from the CO complexes, at 445 and 830 nm at pH 7.4 and 25 degrees C. With the fully reduced and the three-electron-reduced enzyme, four kinetic phases with rate constants in the range from 1 x 10(5) to 10(3) s-1 can be observed. The initial fast phase is associated with an absorbance increase at 830 nm. This is followed by an absorbance decrease (2.8 x 10(4) s-1), the amplitude of which increases with the degree of reduction of the oxidase. The third phase (6 x 10(3) s-1) displays the largest absorbance change at both wavelengths in the fully reduced enzyme and is not seen in the mixed-valence oxidase at 830 nm; a change with opposite sign but with a similar rate constant is found at 445 nm in this enzyme form. The slowest phase (10(3) s-1) is also largest in the fully reduced oxidase and not seen in the mixed-valence enzyme. It is suggested that O2 initially binds to reduced CuB and is then transferred to cytochrome a3 before electron transfer from cytochrome a/CuA takes place. The fast oxidation of cytochrome a seen with the fully reduced enzyme is suggested not to occur during natural turnover. A reaction cycle for the complete turnover of the enzyme is presented. In this cycle, the oxidase oscillates between electron input and output states of the proton pump, characterized by cytochrome a having a high and a low reduction potential, respectively.     

Some properties of Nitrosomonas europaea cytochrome c oxidase (aa3-type) which lacks CuA

From Nitrosomonas europaea which had been cultivated in a medium deficient in copper, cytochrome c oxidase (aa3-type) which did not have CuA was purified. The oxidase did not show the 830-nm peak and its ESR spectrum differed greatly from that of the normal enzyme, which has two copper atoms, CuA and CuB, per molecule. However, the oxidase which did not have CuA showed almost the same cytochrome c oxidizing activity as the normal oxidase.