Reaction of formate with the fast form of cytochrome oxidase: a model for the fast to slow conversion.

The ability to isolate preparations of cytochrome oxidase which are highly homogeneous has facilitated a study of the effects of various reagents on the purified enzyme. The addition of either sodium formate, formamide, formaldehyde, or sodium nitrite to enzyme which reacts in a single rapid kinetic phase with cyanide causes a blue-shift of 4-6 nm of the net (cytochrome a + cytochrome a3) Soret maximum. Only the derivative prepared by adding sodium formate demonstrates measurable intensity in the g' = 12 region of the low-temperature electron paramagnetic resonance (EPR) spectrum. This g' = 12 resonance is characteristic of cytochrome oxidase which has undergone a modification at the binuclear center and thereby reacts sluggishly with cyanide. As the site of cyanide binding in resting enzyme as been demonstrated to be CuB [Yoshikawa, S., & Caughey, W.S. (1990) J. Biol. Chem. 265, 7945-7958], it is proposed that formate can bind to CuB and the fast to slow transition is rationalized by using this proposal. The g' = 12 signal is also produced upon the addition of sodium formate to mitochondrial preparations, suggesting that the species responsible for this behavior may have possible physiological relevance. Physical properties of the formate derivative and data for other reagents reacted with the fast-reacting enzyme preparation are presented.     

Characterization of a novel g' = 2.95 EPR signal from the binuclear center of mitochondrial cytochrome c oxidase.

The oxidized binuclear heme a3/CuB center of slow forms of bovine cytochrome oxidase exhibits a characteristic EPR signal at g' = 12. Following the (rapid) dithionite reduction of heme a and CuA, an additional EPR signal becomes apparent at g' = 2.95. As electrons enter the binuclear center this signal decays at the same slow rate as the g' = 12 signal. In the fully oxidized slow enzyme the small g' = 2.95 signal is usually masked by the g = 3 heme a signal, but it is readily detectable at low temperatures and high microwave powers. It is present in both the intrinsic and formate-ligated slow enzymes, but not in any form of fast preparation. The g' = 2.95 signal has similar temperature dependence and microwave power saturation characteristics to the g' = 12 signal. We conclude that the signal arises from the same population of binuclear centers responsible for the g' = 12 signal. The appearance of a signal at g' = 2.95 in X-band EPR is consistent with, but does not prove, the model of Hagen where the g' = 12 signal arises from a ferryl heme a3, with CuB cuprous and EPR-silent (Hagen, W. R. (1982) Biochim. Biophys. Acta 708, 82-98).     

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)     

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 · 10⁴ M⁻¹ · s⁻¹. In the absence of cyanide, ferrocytochrome a₃ appears at a rate (k_obs) 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 (k_obs ≈ 0.02 s) entry of a third electron. Above +200 mV, the number of electrons taken up in the initial fast phase drops as a redox center (presumably Cu_A) titrates with an apparent mid-point potential of +240 mV. The slow phase of reduction remains at the more positive redox values. (4) The results are interpreted in terms of an initial fast reduction of cytochrome a (and Cu_A at redox values more negative than +240 mV) followed by a slow reduction of Cu_B. Cu_B reduction is proposed to spin-uncouple cytochrome a₃ to form a cyanide sensitive center, and trigger a conformational change to an activated form of the enzyme with faster intramolecular electron transfer.     

Heme-copper and heme-heme interactions in the cytochrome bo-containing quinol oxidase of Escherichia coli

The cytochrome bo quinol oxidase of Escherichia coli is one of two respiratory O2 reductases which the bacterium synthesizes. The enzyme complex contains copper and 2 mol of b-type heme. Electron paramagnetic resonance (epr) spectroscopy of membranes from a strain having amplified levels of this enzyme complex reveals signals from low- and high-spin b-type hemes, but the copper, now established as a component of the oxidase, is not directly detectable by epr. The high-spin signal from the cytochrome bo complex, which we attribute to cytochrome o, when titrated potentiometrically, gives a bell-shaped curve. The low potential side of this curve is biphasic (Em7 approximately 180 and 280 mV) and corresponds to the reduction/oxidation of the cytochrome(s). The high potential side of the bell-shaped curve is monophasic (Em7 approximately 370 mV) and is proposed to be due to reduction/oxidation of a copper center which, when in the Cu(II) form, is tightly spin-coupled to a heme, probably cytochrome o, resulting in a net even spin system and loss of the epr spectrum. The low-spin cytochrome b titrates biphasically with Em7 values of approximately 180 and 280 mV, similar to the high-spin component but without the loss of signal at high potentials.     

Biochemical and biophysical studies on cytochrome c oxidase. XX. Reaction with sulphide.

1.Upon addition of sulphide to oxidized cytochrome c oxidase, a low-spin heme sulphide compound is formed with an EPR signal at gx = 2.54, gy = 2.23 and gz = 1.87. Concomitantly with the formation of this signal the EPR-detectable low-spin heme signal at g = 3 and the copper signal near g = 2 decrease in intensity, pointing to a partial reduction of the enzyme by sulphide. 2. The addition of sulphide to cytochrome c oxidase, previously reduced in the presence of azide or cyanide, brings about a disappearance of the azido-cytochrome c oxidase signal at gx = 2.9, gy = 2.2, and gz = 1.67 and a decrease of the signal at g = 3.6 of cyano-cytochrome c oxidase. Concomitantly the sulphide-induced EPR signal is formed. 3. These observations demonstrate that azide, cyanide and sulphide are competitive for an oxidized binding site on cytochrome c oxidase. Moreover, it is shown that the affinity of cyanide and sulphide for this site is greater than that of azide.     

Characterisation of 'fast' and 'slow' forms of bovine heart cytochrome-c oxidase.

We have prepared cytochrome-c oxidase from bovine heart (using a modification of the method of Kuboyama et al. (1972) J. Biol. Chem. 247, 6375-6383) which binds cyanide rapidly, shows no kinetic distinction between the two haems on reduction by dithionite, has a Soret absorption maximum above 424 nm, and has a negligible 'g' = 12' EPR signal. On incubation at pH 6.5 this 'fast' oxidase reverts to the 'slow' ('resting') form characterised by slow cyanide binding, slow reduction of haem a3 by dithionite, a blue-shifted Soret maximum and a large 'g' = 12' signal. Incubation of 'fast' oxidase with formate produces a form of the enzyme with properties almost identical to those of 'slow' oxidase. The kinetics of formate binding to 'fast' oxidase are found to be biphasic, revealing the presence of at least two 'fast' subpopulations in our preparations. Evidence is presented that there is an equilibrium mixture of high-spin and low-spin forms of haem a3 in both 'fast' subpopulations at room temperature. Incubation of 'fast' oxidase with chloride or bromide at pH 6.5 produces forms of oxidase with much lower rates of cyanide binding. Our working hypothesis is that formate mimics a binuclear centre ligand which is present in the 'slow' form of cytochrome oxidase. Although we show that chloride and bromide can also be ligands of the binuclear centre, possibly onto CuB, we can rule out either of these being the ligand present in the 'slow' enzyme. We will argue that the 'fast' and 'slow' forms of oxidase are equivalent to the 'pulsed' and 'resting' forms of oxidase, respectively.     

Angular dependences of perpendicular and parallel mode electron paramagnetic resonance of oxidized beef heart cytochrome c oxidase

Cytochrome c oxidase catalyzes the reduction of oxygen to water with a concomitant conservation of energy in the form of a transmembrane proton gradient. The enzyme has a catalytic site consisting of a binuclear center of a copper ion and a heme group. The spectroscopic parameters of this center are unusual. The origin of broad electron paramagnetic resonance (EPR) signals in the oxidized state at rather low resonant field, the so-called g' = 12 signal, has been a matter of debate for over 30 years. We have studied the angular dependence of this resonance in both parallel and perpendicular mode X-band EPR in oriented multilayers containing cytochrome c oxidase to resolve the assignment. The "slow" form and compounds formed by the addition of formate and fluoride to the oxidized enzyme display these resonances, which result from transitions between states of an integer-spin multiplet arising from magnetic exchange coupling between the five unpaired electrons of high spin Fe(III) heme a(3) and the single unpaired electron of Cu(B). The first successful simulation of similar signals observed in both perpendicular and parallel mode X-band EPR spectra in frozen aqueous solution of the fluoride compound of the closely related enzyme, quinol oxidase or cytochrome bo(3), has been reported recently (Oganesyan et al., 1998, J. Am. Chem. Soc. 120:4232-4233). This suggested that the exchange interaction between the two metal ions of the binuclear center is very weak (|J| approximately 1 cm(-1)), with the axial zero-field splitting (D approximately 5 cm(-1)) of the high-spin heme dominating the form of the ground state. We show that this model accounts well for the angular dependences of the X-band EPR spectra in both perpendicular and parallel modes of oriented multilayers of cytochrome c oxidase derivatives and that the experimental results are inconsistent with earlier schemes that use exchange coupling parameters of several hundred wavenumbers.     

The inhibition of cytochrome oxidase by diaminomaleonitrile

Diaminomaleonitrile, a tetramer of cyanide, was examined as a possible antagonist to cyanide inhibition of cytochrome oxidase (EC 1.9.3.1). This compound was found to inhibit cytochrome oxidase in vitro; however, despite their structural similarities, diaminomaleonitrile and cyanide inhibit cytochrome oxidase by different mechanisms and bind to the enzyme at different sites. Diaminomaleonitrile inhibition of cytochrome oxidase is described in terms of a partially competitive mechanism. Biological oxidation of diaminomaleonitrile may lead to the formation of cyanide.     

Purification of cytochrome c oxidase by lysine-affinity chromatography.

A method for the purification of cytochrome c oxidase that is based on the affinity of this enzyme for polycations such as poly-L-lysine is described. When detergent extracts of bovine cardiac mitochondria were applied to either a poly-L-lysine-agarose or a lysine-Sepharose column at low ionic strength, cytochrome c oxidase was found to adhere tightly, whereas the bulk of the proteins were eluted by washing with the same buffer. The cytochrome c oxidase was eluted by application of a linear potassium chloride gradient to the columns. The resulting enzyme was identical to that obtained by more traditional purification methods in terms of its subunit composition, optical and resonance Raman spectra, and cytochrome c oxidizing activity. When detergent extracts of spheroplasts from Paracoccus denitrificans were applied to these columns, the cytochrome c oxidase from this organism was also found to adhere tightly. Thus this purification method appears applicable to both prokaryotic and eukaryotic forms of the enzyme. The advantages of this new purification method are that it is less labor intensive than the traditional procedure and less expensive than methods based on cytochrome c-affinity chromatography.     

A novel electron paramagnetic resonance signal of "oxygenated" cytochrome c oxidase.

It had been observed previously that a pair of transient EPR resonances (g = 1.78 and 1.69) appears within less than 5 ms on reoxidation of reduced cytochrome c oxidase by O2. Since the location of other lines that are part of the same signal was not known, the quantity of the paramagnetic species involved, and thus the significance of the observed resonances, remained questionable. We have now found a broad resonance at g = 5 which is obviously associated with those at g = 1.78 and 1.69. The width of the signal (approximately 250 mT) at the observed intensity suggests that it represents a significant fraction of one of the components of the enzyme. The signal disappears within less than 5 ms on addition of cyanide or sulfide but only within several hundred milliseconds after addition of ferrocytochrome c. This behavior suggests that it originates from the a3 component of the enzyme. It is suggested that the species represented in the signal is either identical with or part of what has been named collectively the "oxygenated" form and recently described "activated" forms of the enzyme. On reoxidation of reduced oxidase with oxygen enriched 90% in 17O, no change of signal shape was seen.     

The use of a maleimido spin label to detect conformational changes in cytochrome c oxidase.

Spin labeling with a maleimido spin label has been used to investigate conformational changes of bovine cytochrome c oxidase. These experiments show that the spin label is immobilized to a lesser degree when the enzyme is in the “oxygenated” form than it is in the oxidized state and support the view that the oxygenated form is a conformational variant. Experiments in which the maleimido spin-labeled cytochrome c oxidase was titrated with H₂O₂ reveal that the peroxide-treated enzyme, although possessing an absorption spectrum similar to that of the oxygenated form, has an electron paramagnetic resonance (epr) spectrum that is different from that of either the oxygenated form or the oxidized state. Extremes of pH cause a marked decrease in the degree of immobilization of maleimido spin labels bound to the oxidase. Alterations in the epr spectrum are reversible if the pH is held between 5.3 and 10.2 but are irreversible outside that range. Urea and guanidine hydrochloride also decrease the immobilization of the spin labels bound to the oxidase. The nature of the epr spectra indicates that under these conditions the enzyme assumes a more open conformation. Exposure to concentrations of sodium dodecyl sulfate as high as 10% does not result in as much loss of the immobilization as with urea or guanidine. Detergents such as cholate, Tween 80, and Triton X-100 have no significant effect on the epr spectrum of maleimido spin-labeled cytochrome c oxidase.     

Purification of cytochrome-c oxidase retaining its pulsed form

A new purification procedure for cytochrome-c oxidase from bovine heart mitochondria is described. The enzyme was purified by selective solubilization in Triton X-100 and subsequent hydroxyapatite and gel chromatography. The preparation was highly pure and active. The subunit composition and steady-state kinetics were found to be the same as those reported for other preparations. In contrast to most of the previously published protocols the method presented here resulted in a preparation which had a rapid intramolecular electron transfer from cytochrome a to cytochrome a3, i.e. it was found to have retained its pulsed state. This correlated with monoexponential cyanide-binding kinetics. The formation of resting kinetics and biphasic cyanide-binding kinetics was shown to be induced by a short incubation at pH 5.0.     

Some properties of the redox components of cytochrome c oxidase and their interactions.

The electron paramagnetic resonance (epr) properties of cytochrome c oxidase have been examined with special attention to the effect of added ligands and of interactions between the redox components. The fully oxidized preparations have a very small g6 signal which increases greatly as the redox potential is made more negative, a process exactly paralleling the disappearance of the g3 signal. The potential for half appearance or disappearance (E_m), respectively, is 380 mV at pH 7.0 and 300 mV at pH 8.5. This identifies the changes as accompanying reduction of cytochrome a₃ because the E_m of the “invisible copper” is 340 mV and pH independent. Nitric oxide (NO) binds reduced cytochrome a₃ to form a paramagnetic species. This resulting epr signal is strongly dependent on the redox state of cytochrome a, another expression of heme-heme interaction in cytochrome oxidase. The NO compound is also unique in that under the appropriate conditions three of the four redox components (cytochrome a₃, cytochrome a, and the “visible” copper) are epr active. In potentiometric titrations in the presence of azide the formation of the azide compound responsible for the g2.9 signal appears to require reduction of both cytochrome a₃ and the “invisible copper.” An internal sulfur compound is present which, at alkaline pH values, can bind the heme responsible for the g6 signal and change it to a low-spin sulfur compound with a signal at approximately g2.6. Evidence is also presented for the cytochrome c oxidase in situ being an equilibrium mixture of two different conformational states.     

Biochemical and biophysical studies on cytochrome c oxidase. XIX. An EPR study of the photodissociation of carboxycytochrome c oxidase in the presence of azide

1. The photodissociation reaction of the cytochrome c oxidase-CO compound in the presence of azide was studied by EPR at 15°K. Addition of CO in the dark to cytochrome c oxidase, partially reduced (2 electrons per 4 metal ions) in the presence of azide brings about a decrease in intensity of the azide-induced low-spin heme signal at g = 2.9, 2.2 and 1.67 and an increase in intensity of both the low-spin heme signal at g = 3 and the copper signal at g = 2. Subsequent illumination with white light at room temperature of this sample causes an enhancement of the azide-induced signal at g = 2.9, and a decrease in intensity of both signals at g = 3 and g = 2. It is shown that these changes in the EPR spectrum are reversible.

2. These results demonstrate that upon photodissociation, CO is replaced by azide wheras upon incubation in the dark CO expels azide from its binding site in cytochrome c oxidase.

3. Concomitantly with the binding of CO and dissociation of the azide molecule, and vice versa, electron redistributions occur as inferred from the changes in the intensity of the copper signal at g = 2.

4. The results are explained in a model of cytochrome c oxidase with either a common binding site (cytochrome a₃)^* for CO and azide or in a model with anti-cooperative interaction between two different sites of binding.

5. Similar types of experiments with cyanide instead of azide show that cyanide is more firmly bound to partially reduced cytochrome c oxidase than CO and azide. The affinity of ligands for partially reduced enzyme decreases in the sequence: cyanide, CO (dark), azide and CO (illuminated).     

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.     

The possible role of the closed-open transition in proton pumping by cytochrome c oxidase: the pH dependence of cyanide inhibition

The rate of oxidation of reduced cytochrome c catalyzed by cytochrome oxidase in the presence and absence of cyanide has been measured spectrophotometrically at pH 5.5, 6.4, 7.4 and 8.3. At the cytochrome c concentration used (272 microM), the uninhibited rate is maximal at pH 6.4 and drops to a value about one sixth of this maximum at pH 8.3. In the presence of cyanide, the rate initially drops rapidly, but with the cyanide concentration used (5.5 microM) there is still a measurable rate of oxidation when maximal inhibition has been reached. This inhibited rate decreases as the pH increases, whereas the apparent rate constant for cyanide binding is almost independent of pH. The results have been analyzed on the basis of a model in which two-electron reduction of the oxidized enzyme triggers a transition from a closed to an open conformation. It is assumed that cyanide can only bind to the open conformation and, furthermore, that rapid internal electron transfer to the dioxygen-reducing site occurs in this state alone. The analysis shows that the true constant for cyanide binding decreases with decreasing pH to a constant value at low pH. It also indicates that the increase in the catalytic constant with decreasing pH is associated with an increase in the rate of the closed-open conformational transition on protonation of the enzyme, and it is proposed that this transition is operative in electron gating in the proton-pump function of the enzyme.     

Properties of bovine heart mitochondrial cytochrome b560

A large-scale preparation of the two-subunit protein complex (QPs) that converts succinate dehydrogenase into succinate-ubiquinone reductase from cytochrome b-c1 particles is achieved by a procedure involving Triton X-100 solubilization and calcium phosphate column chromatography at different pH values. The isolated two-subunit QPs contains 25 nmol of cytochrome b560/mg of protein and is able to reconstitute with soluble succinate dehydrogenase to form a TTFA-sensitive succinate-ubiquinone reductase. The maximum reconstitutive activity is 100 mumol of succinate oxidized per min per mg of QPs protein at 23 degrees C. Although cytochrome b560 in isolated QPs is not succinate reducible and its dithionite reduced form is reactive to carbon monoxide, cytochrome b560 is shown to be physically associated with succinate dehydrogenase by the following observations. The dithionite reduced form of cytochrome b560 in isolated QPs has a symmetrical alpha-absorption peak, which upon reconstitution with succinate dehydrogenase becomes slightly broadened and shows a shoulder at around 553 nm, identical to that of cytochrome b560 in succinate-ubiquinone reductase. Upon addition of succinate dehydrogenase to QPs, about 50% of the reduced form of cytochrome b560 in the QPs becomes insensitive to carbon monoxide treatment. The redox potential of cytochrome b560 in QPs is -144 mV which is higher than that of cytochrome b560 in succinate-ubiquinone reductase (-185 mV). Upon addition of succinate dehydrogenase, the redox potential of about 46% of the cytochrome b560 in QPs preparation becomes identical to that of cytochrome b560 in succinate-ubiquinone reductase. Cytochrome b560 in the QPs preparation shows two epr signals, g = 3.07 and g = 2.92, whereas cytochrome b560 in succinate-ubiquinone reductase exhibits only one epr signal at g = 3.46. When QPs is reconstituted with succinate dehydrogenase to form succinate-ubiquinone reductase, the g = 3.46 epr signal reappears at the expense of the g = 3.07 signal. Based on epr measurement at liquid helium temperature, about 18% of the total cytochrome b in the isolated active succinate-cytochrome c reductase is cytochrome b560, indicating that cytochrome b560 is indeed a unique cytochrome b and not a denatured product of cytochrome b562 or b565.     

Control of electron transfer by the electrochemical potential gradient in cytochrome-c oxidase reconstituted into phospholipid vesicles

The kinetics of electron transfer between cytochrome-c oxidase and ruthenium hexamine has been characterized using the native enzyme or its cyanide complex either solubilized by detergent (soluble cytochrome oxidase) or reconstituted into artificial phospholipid vesicles (cytochrome oxidase-containing vesicles). Ru(NH3)2+6 (Ru(II] reduces oxidized cytochrome a, following (by-and-large) bimolecular kinetics; the second order rate constant using the cyanide complex of the enzyme is 1.5 x 10(6) M-1 s-1, for the enzyme in detergent, and slightly higher for COV. In the case of COV the kinetics are not affected by the addition of ionophores. Upon mixing fully reduced cytochrome oxidase with oxygen (in the presence of excess reductants), the oxidation leading to the pulsed enzyme is followed by a steady state phase and (eventually) by complete re-reduction. When the concentrations of dioxygen and oxidase are sufficiently low (micromolar range), the time course of oxidation can be resolved by stopped flow at room temperature, yielding an apparent bimolecular rate constant of 5 x 10(7) M-1 s-1. After exhaustion of oxygen and end of steady state, re-reduction of the pulsed enzyme by the excess Ru(II) is observed; the concentration dependence shows that the rate of re-reduction is limited at 3 s-1 in detergent; this limiting value is assigned to the intramolecular electron transfer process from cytochrome a-Cua to the binuclear center. Using the reconstituted enzyme, the internal electron transfer step is sensitive to ionophores, increasing from 2-3 to 7-8 s-1 upon addition of valinomycin and carbonyl cyanide m-chlorophenylhydrazone. This finding indicates for the first time an effect of the electrochemical potential across the membrane on the internal electron transfer rate; the results are compared with expectations based on the hypothesis formulated by Brunori et al. (Brunori, M., Sarti, P., Colosimo, A., Antonini, G., Malatesta, F., Jones, M.G., and Wilson, M.T. (1985) EMBO J. 4, 2365-2368), and their bioenergetic relevance is discussed with reference to the proton pumping activity of the enzyme.     

A study of the magnetic properties of haem a3 in cytochrome c oxidase by using magnetic-circular-dichroism spectroscopy.

M.c.d. (magnetic-circular-dichroism) spectroscopy was used to study the magnetization properties of the haem centres in cytochrome c oxidase with magnetic fields of between 0 and 5.3 T over the temperature range 1.5--200 K. The oxidized, oxidized cyanide and partially reduced cyanide forms of the enzyme were studied. In the oxidized state only cytochrome a3+ is detectable by m.c.d. spectroscopy, and its magnetization characteristics show it to be a low-spin ferric haem. In the partially reduced cyanide form of the enzyme cytochrome a is in the diamagnetic low-spin ferrous form, whereas cytochrome a3--CN is e.p.r.-detectable and gives an m.c.d.-magnetization curve typical of a low-spin ferric haem. In the oxidized cyanide form of the enzyme both cytochrome a and cytochrome a3--CN are detectable by m.c.d. spectroscopy, although only cytochrome a gives an e.p.r. signal. The magnetization characteristics of haem a3--CN show clearly that its ground state is an electronic doublet and that another state, probably a spin singlet, lies greater than 10 cm-1 above this. These features are well accounted for by an electronic state of spin S = 1 with a predominantly axial distortion, which leaves the doublet, Ms = +/- 1, as the ground state and the component Ms = 0 as the excited state. This state would not give an e.p.r. signal. Such an electronic state could arise either from a ferromagnetic coupling between haem a3+(3)-CN and the cupric ion, Cua3, or form a haem in the Fe(IV) state.