Electron transfer between cytochrome a and copper A in cytochrome c oxidase: a perturbed equilibrium study

Intramolecular electron transfer in partially reduced cytochrome c oxidase has been studied by the perturbed equilibrium method. We have prepared a three-electron-reduced, CO-inhibited form of the enzyme in which cytochrome a and copper A are partially reduced and in an intramolecular redox equilibrium. When these samples were irradiated with a nitrogen laser (0.6-ns, 1.0-mJ pulses) to photodissociate the bound CO, changes in absorbance at 598 and 830 nm were observed which were consistent with a fast electron transfer from cytochrome a to copper A. The absorbance changes at 598 nm gave an apparent rate of 17,000 +/- 2000 s-1 (1 sigma), at pH 7.0 and 25.5 degrees C. These changes were not observed in either the CO mixed-valence or the CO-inhibited fully reduced forms of the enzyme. The rate was fastest at about pH 8.0, falling off toward both lower and higher pHs. There was a small but clear temperature dependence. The process was also observed in the cytochrome c-cytochrome c oxidase high-affinity complex. The electron equilibration measured between cytochrome a and copper A is far faster than any rate measured or inferred previously for this process.     

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 effect of pH and temperature on the reaction of fully reduced and mixed-valence cytochrome c oxidase with dioxygen

The reaction of fully reduced and mixed-valence cytochrome oxidase with O2 has been followed in flow-flash experiments, starting from the CO complexes, at 428, 445, 605 and 830 nm between pH 5.8b and 9.0 in the temperature range of 2-40 degrees C. With the fully reduced enzyme, four kinetic phase with rate constants at pH 7.4 and 25 degrees C of 9 x 10(4), 2.5 x 10(4), 1.0 x 10(4) and 800 s(-1), respectively, are observed. The rates of the three last phases display a very small temperature dependence, corresponding to activation energies in the range 13-54 kJ x mol(-1). The rates of the third and fourth phases decrease at high pH due to the deprotonation of groups with pKa values of 8.3 and 8.8, respectively, but also the second phase appears to have a small pH dependence. In the reaction of the mixed-valence enzyme, three kinetic phases with rate constants at pH 7.4 and 25 degrees C of 9 x 10(4), 6000 and 150 s(-1), respectively, are observed. The third phase only has a small temperature dependence, corresponding to an activation energy of 20 kJ x mol(-1). No pH dependence could be detected for any phase. Reaction schemes consistent with the experimental observations are presented. The pH dependencies of the rates of the two final phase in the reaction of the fully reduced enzyme are proposed to be related to the involvement of protons in the reduction of a peroxide intermediate. The temperature dependence data suggest that the reorganization energies and driving forces are closely matched in all electron transfer steps with both enzyme forms. It is suggested that the slowest step in the reaction of the mixed-valence enzyme is a conformation change involved in the reaction cycle of cytochrome oxidase as a proton pump.     

Internal electron transfer in cytochrome c oxidase: evidence for a rapid equilibrium between cytochrome a and the bimetallic site.

Internal electron-transfer reactions in cytochrome oxidase following flash photolysis of the CO compounds of the enzyme reduced to different degrees (2-4 electron equiv) have been followed at 445, 605, and 830 nm. Apart from CO dissociation and recombination, two kinetic phases are seen both at 445 and at 605 nm with rate constants of 2 x 10(5) and 1.3 x 10(4) s-1, respectively; at 605 nm, an additional phase with a rate constant of 400 s-1 is resolved. At 830 nm, only the second reaction phase (rate constant of 1.3 x 10(4) s-1) is observed. The amplitude of the first phase is largest with the two-electron-reduced enzyme, whereas that of the second phase is maximal at the three-electron-reduction level. Neither phase shows any marked pH dependence. The reaction in the first phase has a free energy of activation of 41 kJ mol-1 and an entropy of activation of -14 JK-1 mol-1. Analysis suggests that the two rapid reaction phases represent internal electron redistributions between the bimetallic site and cytochrome a, and between cytochrome a and CuA, respectively. The slow phase (400 s-1) probably involves a structural rearrangement.     

A flash-photolysis study of the reactions of acaa 3-ttype cytochrome oxidase with dioxygen and carbon monoxide

The time course of absorbance changes following flash photolysis of the fully-reduced carboxycytochrome oxidase fromBacillus PS3 in the presence of O₂ has been followed at 445, 550, 605, and 830 nm, and the results have been compared with the corresponding changes in bovine cytochrome oxidase. The PS3 enzyme has a covalently bound cytochromec subunit and the fully-reduced species therefore accommodates five electrons instead of four as in the bovine enzyme. In the bovine enzyme, following CO dissociation, four phases were observed with time constants of about 10 s, 30 s, 100 s, and 1 ms at 445 nm. The initial, 10-s absorbance change at 445 nm is similar in the two enzymes. The subsequent phases involving hemea and Cu_A are not seen in the PS3 enzyme at 445 nm, because these redox centers are re-reduced by the covalently bound cytochromec, as indicated by absorbance changes at 550 nm. A reaction scheme consistent with the experimental observations is presented. In addition, internal electron-transfer reactions in the absence of O₂ were studied following flash-induced CO dissociation from the mixed-valence enzyme. Comparisons of the CO recombination rates in the mixed-valence and fully-reduced oxidases indicate that more electrons were transferred from hemea ₃ toa in PS3 oxidase compared to the bovine enzyme.     

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.     

Electron transfer process in cytochrome oxidase after pulse radiolysis

The reduction of bovine heart cytochrome oxidase by the 1-methylnicotinamide (MNA) radical was investigated by the use of pulse radiolysis. With the decay of the MNA radical, the absorption at 445 and 605 nm, a characteristic to ferrous heme a of the oxidase, increased. The kinetic difference spectrum obtained was similar to that of the fully reduced minus the fully oxidized form of the oxidase, and was not different from that obtained in the reaction of the MNA radical with the mixed valence CO complex of the oxidase, where heme a3 is the CO-bound reduced form with heme a oxidized. This suggests that the absorption changes at 445 and 605 nm arise from the reduction of heme a, not heme a3. In order to elucidate the contribution of "visible" copper in this reaction, the absorption of the oxidase in the near-infrared region was measured. A decrease of the 830 nm band due to the reduction of visible copper was detected with a half-life of 5 microseconds. This absorption change obeyed pseudo-first order kinetics and its rate constant increased with the concentration of the oxidase. This suggests that the absorption change at 830 nm is followed by a bimolecular reaction of the MNA radical with visible copper of the oxidase. After the first phase of the reduction, the return of the 830 nm band corresponding to oxidation of the copper was observed with a half-life of 100 microseconds. Concomitantly, the absorption at 605 and 445 nm due to the reduction of heme a increased. The rates of oxidation of the copper were identical to those of the reduction of heme a and independent of the oxidase concentration. This suggests that the MNA radical reacts with visible copper of the oxidase with a second order rate constant of 1.5 X 10(9) m-1 s-1 and subsequently the electron flows to heme a by intramolecular electron migration with a first order rate constant of 1.8 X 10(4) s-1. An activation energy of the intramolecular electron transfer was calculated to be 2.8 kcal/mol in the range 4-33 degrees C.     

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

The light-induced difference spectra of the fully reduced (a³⁺a²⁺₃-CO) complex and the mixed-valence carboxycytochrome c oxidase (a³⁺a²⁺₃-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 a²⁺₃-CO complex. This would confirm that the spectral properties of cytochrome a₃ are not affected by the redox state of cytochrome a and Cu_A. When the absorbance changes after photolysis of cytochrome a²⁺₃-CO with a laser flash were followed on a time scale from 1 μs 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 = 7·10³s^?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 Cu_A. This demonstrates that in the partially reduced enzyme a pathway is present between Cu_A and the cytochrome a₃-Cu_B pair, via which electrons are transferred rapidly.     

Compound C2, a product of the reaction of oxygen and the mixed-valence state of cytochrome oxidase. Optical evidence for a type-I copper.

Compound C2 is a product of the reaction of O2 and the mixed-valence state of cytochrome oxidase. The mixed-valence state of membrane-bound cytochrome oxidase is obtained at -24 degrees C, by using either ferricyanide or yeast peroxidase complex ES as oxidants, and the configurations of oxidized haem a and its associated copper (a3+Cua2+) and of reduced haem a3 and its associated copper (ac3+.CO.Cua3+) are obtained. The mixed-valence-state cytochrome oxidase mixed with O2 at -24 degrees C and flash-photolysed at -60 to -100 degrees C reacts with O2 and initially forms an oxy compound (A2) similar to that formed from the fully reduced state (A1). Thereafter the course of the reaction differs from that obtained in the fully reduced state, and absorbance increases are observed at 740--750 nm and 609 nm and a decrease at 444 nm, with no increase in absorbance at 655 nm. One possible attribution of the absorbance increases is to charge-transfer interaction between the iron of haem a3 and the copper associated with haem a3, Cua3(2+), having properties of a type-I 'blue' copper. A possible attribution of the decrease in absorbance at 444 nm is to liganding of a3(2+). A related explanation is that the 609 nm absorbance involves a charge-transfer interaction of both iron and copper as a mixed-valence binuclear complex, Cua3, having properties of a non-blue copper. Intermediates in addition to Compound C2 are not yet identifiable by chemical or spectroscopic tests. The kinetic and equilibrium properties of Compound C2 are described.     

Studies on partially reduced mammalian cytochrome oxidase. Reactions with carbon monoxide and oxygen

A number of methods were used to prepare a species of mammalian cytochrome oxidase (EC 1.9.3.1, ferrocytochrome c-oxygen oxidoreductase) in which only cytochrome a(3) is reduced and in combination with CO. The kinetics of CO binding by cytochrome a(3) (2+) in this species is significantly different from that exhibited by cytochrome a(3) (2+) in the fully reduced enzyme. The second-order rate constant for combination was 5x10(4)m(-1).s(-1) and the ;off' constant was 3x10(-2)s(-1). The kinetic difference spectra cytochrome a(3) (2+)-cytochrome a(3) (2+)-CO reveal further differences between the mixed-valence and the fully reduced enzyme. The reaction between cytochrome a(3) (2+) and oxygen in the mixed-valence species was followed in flow-flash experiments and reveals a fast, oxygen-dependent (8x10(7)m(-1).s(-1) at low oxygen) rate followed by a slow process, whose rate is independent of oxygen but whose amplitude is dependent on [O(2)]. The fast oxygen-dependent reaction yields as the first product the so-called ;oxygenated' enzyme. We conclude from these experiments that the ligand-binding behaviour of cytochrome a(3) depends on the redox state of its partners, a fact which represents clear evidence for site-site interaction in this enzyme. The fact that oxygen reacts rapidly with this enzyme species in which only one component, namely cytochrome a(3), is reduced represents clear and unequivocal evidence that this is indeed the O(2)-binding site in cytochrome oxidase and may indicate that reduction of oxygen can proceed via single electron steps.     

EPR studies of the photodissociation reactions of cytochrome c oxidase-nitric oxide complexes

Three complexes of NO with cytochrome c oxidase are described which are all photodissociable at low temperatures as measured by EPR. The EPR parameters of the cytochrome a2+(3)-NO complex are the same both in the fully reduced enzyme and in the mixed-valence enzyme. The kinetics of photodissociation of cytochrome a2+(3)-NO and recombination of NO with cytochrome a2+(3) (in the 30-70 K region) revealed no differences in structure between cytochrome a2+(3) in the fully reduced and the mixed-valence states. The action spectrum of the photodissociation of cytochrome a2+(3)-NO as measured by EPR has maxima at 595, 560 and 430 nm, and corresponds to the absorbance spectrum of cytochrome a2+(3)-NO. Photodissociation of cytochrome a2+(3)-NO in the mixed-valence enzyme changes the EPR intensity at g 3.03, due to electron transfer from cytochrome a2+(3) to cytochrome a3+. The extent of electron transfer was found to be temperature dependent. This suggests that a conformational change is coupled to this electron transfer. The complex of NO with oxidized cytochrome c oxidase shows a photodissociation reaction and recombination of NO (in the 20-40 K region) which differ completely from those observed in cytochrome a2+(3)-NO. The observed recombination occurs at a temperature 15 K lower than that found for the cytochrome a2+(3)-NO complex. The action spectrum of the oxidized complex shows a novel spectrum with maxima at 640 and below 400 nm; it is assigned to a Cu2+B-NO compound. The triplet species with delta ms = 2 EPR signals at g 4 and delta ms = 1 signals at g 2.69 and 1.67, that is observed in partially reduced cytochrome c oxidase treated with azide and NO, can also be photodissociated.     

The mechanism of electron gating in proton pumping cytochrome c oxidase: the effect of pH and temperature on internal electron transfer

Electron-transfer reactions following flash photolysis of the mixed-valence cytochrome oxidase-CO complex have been measured at 445, 598 and 830 nm between pH 5.2 and 9.0 in the temperature range of 0-25 degrees C. There is a rapid electron transfer from the cytochrome a3-CuB pair to CuA (time constant: 14200 s-1), which is followed by a slower electron transfer to cytochrome a. Both the rate and the amplitude of the rapid phase are independent of pH, and the rate in the direction from CuA to cytochrome a3-CuB is practically independent of temperature. The second phase depends strongly on pH due to the titration of an acid-base group with pKa = 7.6. The equilibrium at pH 7.4 corresponds to reduction potentials of 225 and 345 mV for cytochrome a and a3, respectively, from which it is concluded that the enzyme is in a different conformation compared to the fully oxidized form. The results have been used to suggest a series of reaction steps in a cycle of the oxidase as a proton pump. Application of the electron-transfer theory to the temperature-dependence data suggests a mechanism for electron gating in the pump. Reduction of both cytochrome a and CuA leads to a conformational change, which changes the structure of cytochrome a3-CuB in such a way that the reorganizational barrier for electron transfer is removed and the driving force is increased.     

The kinetics of electron transfer between pseudomonas aeruginosa cytochrome c-551 and its oxidase.

The redox reaction between cytochrome c-551 and its oxidase from the respiratory chain of pseudomonas aeruginosa was studied by rapid-mixing techniques at both pH7 and 9.1. The electron transfer in the direction of cytochrome c-551 reduction, starting with the oxidase in the reduced and CO-bound form, is monophasic, and the governing bimolecular rate constants are 1.3(+/- 0.2) x 10(7) M-1 . s-1 at pH 9.1 and 4 (+/- 1) x 10(6) M-1 . s-1 at pH 7.0. In the opposite direction, i.e. mixing the oxidized oxidase with the reduced cytochrome c-551 in the absence of O2, both a lower absorbance change and a more complex kinetic pattern were observed. With oxidized azurin instead of oxidized cytochrome c-551 the oxidation of the c haem in the CO-bound oxidase is also monophasic, and the second-order rate constant is 2 (+/- 0.7) x 10(6) M-1 . s-1 at pH 9.1. The redox potential of the c haem in the oxidase, as obtained from kinetic titrations of the completely oxidized enzyme with reduced azurin as the variable substrate, is 288 mV at pH 7.0 and 255 mV at pH 9.1. This is in contrast with the very high affinity observed in similar titrations performed with both oxidized azurin and oxidized cytochrome c-551 starting from the CO derivative of the reduced oxidase. It is concluded that: (i) azurin and cytochrome c-551 are not equally efficient in vitro as reducing substrates of the oxidase in the respiratory chain of Pseudomonas aeruginosa; (ii) CO ligation to the d1 haem in the oxidase induces a large decrease (at least 80 mV) in the redox potential of the c-haem moiety.     

Amplitude analysis of single-wavelength time-dependent absorption data does not support the conventional sequential mechanism for the reduction of dioxygen to water catalyzed by bovine heart cytochrome c oxidase

The reactions of fully reduced and mixed-valence bovine heart cytochrome c oxidase with dioxygen have been reinvestigated in the absence and presence of metal ions (Zn(2+), Ni(2+), and Cd(2+)) by time-resolved optical absorption spectroscopy using the CO flow-flash technique. The time-resolved data were recorded on a microsecond to millisecond time scale at 442, 610, and 820 nm and subjected to quantitative amplitude analysis based on a conventional unidirectional sequential mechanism. The amplitudes of the sequential intermediates are derived from the absorbance changes associated with the different exponentials and from the kinetic equations of the sequential scheme. The general relationship between the pre-exponential factors and the absorbance of the successive intermediates in the sequential scheme is presented. A comparison of the experimental amplitudes of the individual intermediates with the model amplitudes at the three wavelengths indicates that the low spin heme a is incompletely oxidized during the formation of the sequential P(R) intermediate (P(R,s)). The conversion of the sequential F intermediate to the oxidized enzyme occurs on two millisecond time scales. The amplitude analysis of the single-wavelength data does not support the conventional sequential mechanism for the reduction of dioxygen to water catalyzed by 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.     

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.     

Observation of a novel transient ferryl complex with reduced CuB in cytochrome c oxidase

The reaction between mixed-valence (MV) cytochrome c oxidase from beef heart with H2O2 was investigated using the flow-flash technique with a high concentration of H2O2 (1 M) to ensure a fast bimolecular interaction with the enzyme. Under anaerobic conditions the reaction exhibits 3 apparent phases. The first phase (tau congruent with 25 micros) results from the binding of one molecule of H2O2 to reduced heme a3 and the formation of an intermediate which is heme a3 oxoferryl (Fe4+=O2-) with reduced CuB (plus water). During the second phase (tau congruent with 90 micros), the electron transfer from CuB+ to the heme oxoferryl takes place, yielding the oxidized form of cytochrome oxidase (heme a3 Fe3+ and CuB2+, plus hydroxide). During the third phase (tau congruent with 4 ms), an additional molecule of H2O2 binds to the oxidized form of the enzyme and forms compound P, similar to the product observed upon the reaction of the mixed-valence (i.e., two-electron reduced) form of the enzyme with dioxygen. Thus, within about 30 ms the reaction of the mixed-valence form of the enzyme with H2O2 yields the same compound P as does the reaction with dioxygen, as indicated by the final absorbance at 436 nm, which is the same in both cases. This experimental approach allows the investigation of the form of cytochrome c oxidase which has the heme a3 oxoferryl intermediate but with reduced CuB. This state of the enzyme cannot be obtained from the reaction with dioxygen and is potentially useful to address questions concerning the role of the redox state in CuB in the proton pumping mechanism.     

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.     

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.     

Reaction of oxygen with cytochrome c oxidase from Paracoccus denitrificans

The reaction of reduced cytochrome c oxidase (EC 1.9.3.1) from Paracoccus denitrificans (American Type Culture Collection 13543) with dioxygen has been followed by laser flash photolysis of the CO derivative. In detergent-stabilized solutions the reaction showed at least two distinct kinetic components, the faster of which was oxygen concentration dependent and had a rate of approximately 60 X 10(6) M-1 s-1. The slower reaction was independent of oxygen concentration and had a rate of 9 X 10(2) s-1. These rates are about 1.5 times greater than comparable rates for ox heart oxidase reported by C. Greenwood and Q. H. Gibson (J. Biol. Chem. (1967) 242, 1782-1787). The kinetic components have markedly different optical spectra which agree precisely in form with those for ox heart enzyme (Greenwood, C., and Gibson, Q. H. (1967) J. Biol. Chem. 242, 1782-1787) but are shifted by 2 nm toward the red. In phospholipid vesicles, the spectral contribution of the faster component was augmented. The dissociation constant for CO at 20 degrees C is 1.6 microM, 6 times greater than for the ox heart enzyme. The bacterial enzyme binds one CO per 2 heme a. The enzyme has an absorption band at 830 nm in the oxidized form similar to that of the ox heart enzyme.