Structural perturbation of the a3-CuB site in mitochondrial cytochrome c oxidase by alcohol solvents

Ethanol has been observed to cause a perturbation of the catalytic center of the major respiratory protein cytochrome c oxidase. These effects were examined by Fourier transform infrared spectroscopy of carbon monoxide complexes of cytochrome a3Fe and of CuB formed by low-temperature photodissociation of the a3FeCO complex. Carbon monoxide binds to reduced cytochrome oxidase in two major structural forms, alpha and beta, both of which are altered by ethanol. In the absence of ethanol, 15-22% of the total cytochrome oxidase in beef heart mitochondria was observed as beta-forms. Ethanol addition caused a concentration-dependent elimination of the beta-forms with 40% disappearing at 0.05 M (0.23%) ethanol, a concentration that can readily be achieved in the blood of intoxicated individuals. At 0.5 M (2.3%) ethanol and above, almost no beta-forms were detectable. The alpha-CuBCO absorption normally splits into two bands at temperatures below 40 K. This effect was decreased in the presence of ethanol and eliminated by high ethanol concentrations. It appears that ethanol increases the structural fluctuations at the active site of the enzyme, analogous to the effects of increased temperature. There was an 8-10% decrease in the maximum rate of oxygen reduction by mitochondrial cytochrome oxidase in 0.05 M ethanol at 24 degrees C, while higher concentrations of ethanol caused no further inhibition. This is the first demonstration that alpha- and beta-forms of cytochrome c oxidase can be modified by an externally added reagent. Changes in the spectra of alpha-CuBCO in the presence of 50% (v/v) ethylene glycol were quite striking, but variable.(ABSTRACT TRUNCATED AT 250 WORDS)     

Oxido-reductive titrations of cytochrome c oxidase followed by EPR spectroscopy.

Experiments are described on oxido-reductive titrations of cytochrome c oxidase as followed by low-temperature EPR and reflectance spectroscopy. The reductants were cytochrome c or NADH and the oxidant ferricyanide. Experiments were conducted in the presence and absence of either cytochrome c or carbon monoxide, or both. An attempt is made to provide a complete quantitative balance of the changes observed in the major EPR signals. During reduction, the maximal quantity of heme represented in the high-spin ferric heme signals (g approximately 6; 2) is 25% of the total heme present, and during reoxidation 30%. With NADH reduction there is little difference between the pattern of disappearance of the low-spin ferric heme signals in the absence or presence of cytochrome c. The copper and high-spin heme signals, however, disappear at higher titrant concentrations in the presence of cytochrome c than in its absence. In these titrations, as well as in those with ferrocytochrome c, the quantitative balance indicates that, in addition to EPR-detectable components, EPR-undetectable components are also reduced, increasingly so at higher titrant concentrations. The quantity of EPR-undectable components reduced appears to be inverely related to pH. A similar inverse relationship exists between pH and appearance of high-spin signals during yhe titration. At pH 9.3 the quantity of heme represented in the high-spin signals is less than 5%, whereas it approximately doubles from pH 7.4 to pH 6.1. In the presence of CO less of the low-spin heme and copper signals disappears for the same quantity of titrant consumed, again implying reduction of EPR undetectable components. At least one of these components is represented in a broad absorption band centered at 655 nm. The stoichiometry observed on reoxidation, particularly in the presence of CO, is not compatible with the notion that the copper signal represents 100% of the active copper of the enzyme as a pair of interacting copper atoms.     

Photoperturbation of the heme a3-CuB binuclear center of cytochrome c oxidase CO complex observed by Fourier transform infrared spectroscopy.

Purified cytochrome c oxidase CO complex from beef heart has been studied by Fourier transform infrared absorbance difference spectroscopy. Photolysis at 10-20 Kelvin results in dissociation of a3FeCO, formation of CuBCO, and perturbation of the a3-heme and CuB complex. The vibrational perturbation spectrum between 900 and 1700 cm-1 contains a wealth of information about the binuclear center. Appearance in infrared photoperturbation difference spectra of virtually all bands previously reported from resonance Raman spectra indicate the importance of polarization along the 4-vinyl:8-formyl axis, which results in the reduction of heme symmetry to C2v. Frequency-shifted bands due to the 8-formyl and 4-vinyl groups of the a3-heme have been identified and quantitated. The frequency shifts have been interpreted as being due to a change in porphyrin polarization with change in spin state of the iron by photodissociation of CO or perturbation of the CuB coordination complex.     

Structures of reaction intermediates of bovine cytochrome c oxidase probed by time-resolved vibrational spectroscopy

Structures of reaction intermediates of bovine cytochrome c oxidase (CcO) in the reactions of its fully reduced form with O2 and fully oxidized form with H2O2 were investigated with time-resolved resonance Raman (RR) and infrared spectroscopy. Six oxygen-associated RR bands were observed for the reaction of CcO with O2. The isotope shifts for an asymmetrically labeled dioxygen, (16)O(18)O, has established that the primary intermediate of cytochrome a3 is an end-on type dioxygen adduct and the subsequent intermediate (P) is an oxoiron species with Fe=O stretch (nu(Fe=O)) at 804/764 cm(-1) for (16)O2/(18)O2 derivatives, although it had been long postulated to be a peroxy species. The P intermediate is converted to the F intermediate with nu(Fe=O) at 785/751 cm(-1) and then to a ferric hydroxy species with nu(Fe-OH) at 450/425 cm(-1) (443/417 cm(-1) in D2O). The rate of reaction from P to F intermediates is significantly slower in D2O than in H2O. The reaction of oxidized CcO with H2O2 yields the same oxygen isotope-sensitive bands as those of P and F, indicating the identity of intermediates. Time-resolved infrared spectroscopy revealed that deprotonation of carboxylic acid side chain takes place upon deligation of a ligand from heme a3. UV RR spectrum gave a prominent band due to cis C=C stretch of phospholipids tightly bound to purified CcO.     

The catalytic reaction of cytochrome c oxidase probed by in situ gas titrations and FTIR difference spectroscopy

Cytochrome c oxidase (CcO) is a transmembrane heme‑copper metalloenzyme that catalyzes the reduction of O₂ to H₂O at the reducing end of the respiratory electron transport chain. To understand this reaction, we followed the conversion of CcO from Rhodobacter sphaeroides between several active-ready and carbon monoxide-inhibited states via attenuated total reflection Fourier-transform infrared (ATR FTIR) difference spectroscopy. Utilizing a novel gas titration setup, we prepared the mixed-valence, CO-inhibited R₂CO state as well as the fully-reduced R₄ and R₄CO states and induced the “active ready” oxidized state O_H. These experiments are performed in the dark yielding FTIR difference spectra exclusively triggered by exposure to O₂, the natural substrate of CcO. Our data demonstrate that the presence of CO at heme a₃ does not impair the catalytic oxidation of CcO when the cycle starts from the fully-reduced states. Interestingly, when starting from the R₂CO state, the release of the CO ligand upon purging with inert gas yield a product that is indistinguishable from photolysis-induced states. The observed changes at heme a₃ in the catalytic binuclear center (BNC) result from the loss of CO and are unrelated to electronic excitation upon illumination. Based on our experiments, we re-evaluate the assignment of marker bands that appear in time-resolved photolysis and perfusion-induced experiments on CcO.     

The cytochrome c binding site on cytochrome c oxidase.

Cytochrome $\text{c}$ was chemically coupled to cytochrome $\text{c}$ oxidase using the reagent 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide (EDC) which couples amine groups to carboxyl residues. The products of this reaction were analyzed on 2.5–27% polyacrylamide gradient gels electrophoretically. Since cytochrome $\text{c}$ binds to cytochrome oxidase electrostatically in an attraction between certain of its lysine residues and carboxyl residues on the oxidase surface, EDC is an especially appropriate reagent probe for binding-subunit studies. Coupling of polylysine to cytochrome oxidase using EDC was also performed, and the products of this reaction indicate that polylysine, an inhibitor of the cytochrome $\text{c}$ reaction with oxidase, binds to the same oxidase subunit as does cytochrome $\text{c}$, subunit IV in the gel system used.     

Accommodation of NO in the active site of mammalian and bacterial cytochrome c oxidase aa3

Following different reports on the stoichiometry and configuration of NO binding to mammalian and bacterial reduced cytochrome c oxidase aa(3) (CcO), we investigated NO binding and dynamics in the active site of beef heart CcO as a function of NO concentration, using ultrafast transient absorption and EPR spectroscopy. We find that in the physiological range only one NO molecule binds to heme a(3), and time-resolved experiments indicate that even transient binding to Cu(B) does not occur. Only at very high (approximately 2 mM) concentrations a second NO is accommodated in the active site, although in a different configuration than previously observed for CcO from Paracoccus denitrificans [E. Pilet, W. Nitschke, F. Rappaport, T. Soulimane, J.-C. Lambry, U. Liebl and M.H. Vos. Biochemistry 43 (2004) 14118-14127], where we proposed that a second NO does bind to Cu(B). In addition, in the bacterial enzyme two NO molecules can bind already at NO concentrations of approximately 1 microM. The unexpected differences highlighted in this study may relate to differences in the physiological relevance of the CcO-NO interactions in both species.     

Multifrequency EPR evidence for a bimetallic center at the CuA site in cytochrome c oxidase

Multifrequency electron paramagnetic resonance (EPR) spectra of the Cu(II) site in bovine heart cytochrome c oxidase (COX) and nitrous oxide reductase (N2OR) from Pseudomonas stutzeri confirm the existence of Cu-Cu interaction in both enzymes. C-band (4.5 GHz) proves to be a particularly good frequency complementing the spectra of COX and N2OR recorded at 2.4 and 3.5 GHz. Both the high and low field region of the EPR spectra show the presence of a well-resolved 7-line pattern consistent with the idea of a binuclear Cu center in COX and N2OR. Based on this assumption consistent g-values are calculated for gz and gx at four frequencies. No consistent g-values are obtained with the assumption of a 4-line pattern indicative for a mononuclear Cu site.     

The EPR spectrum for CuB in cytochrome c oxidase

Incubation of cytochrome c oxidase (CcO) in its resting state in saturated ammonium sulfate, at room temperature overnight, gave EPR signals characteristic of a single Cu(II) center. From the g// and A// values it is concluded that this is a square-planar type 2 copper center, and superhyperfine splitting shows the presence of three nearly equivalent 14N nuclei in the plane. It is suggested that this center, also formed by incubating the enzyme in 10% methanol followed by direct irradiation, must be the CuB center. This type 2 copper EPR spectrum is identical to the EPR spectrum of CuB reported for the isolated cytochrome bo3 complex from Escherichia coli; and to the EPR spectrum reported for the sulfobetaine 12 heat-treated cytochrome c oxidase complex. It is argued that a small perturbation in the system causes decoupling of the magnetic coupling of the heme a3-CuB binuclear center and the appearance of the type 2 EPR signal.     

Hyperfine structure resolved by 2 to 4 GHz EPR of cytochrome c oxidase.

Using low frequency 2 to 4 GHz EPR at 10 K, we have resolved previously unseen hyperfine structure associated with the EPR-detectable copper signal of cytochrome c oxidase. The observed hyperfine structure appears consistent with hyperfine coupling to copper; although to account for all of the observed structure, an additional magnetic interaction is required as well. This work points out the utility of the 2 to 4 GHz EPR technique for resolving electronic hyperfine structural information from copper and possibly other paramagnetic sites in biomolecules when random variation in electronic g values is a cause of EPR line-broadening.     

The proton-pumping site of cytochrome c oxidase: a model of its structure and mechanism

Cytochrome c oxidase is an electron-transfer driven proton pump. In this paper, we propose a complete chemical mechanism for the enzyme's proton-pumping site. The mechanism achieves pumping with chemical reaction steps localized at a redox center within the enzyme; no indirect coupling through protein conformational changes is required. The proposed mechanism is based on a novel redox-linked transition metal ligand substitution reaction. The use of this reaction leads in a straightforward manner to explicit mechanisms for achieving all of the processes previously determined (Blair, D.F., Gelles, J. and Chan, S.I. (1986) Biophys. J. 50, 713-733) to be needed to accomplish redox-linked proton pumping. These processes include: (1) modulation of the energetics of protonation/deprotonation reactions and modulation of the energetics of redox reactions by the structural state of the pumping site; (2) control of the rates of the pump's redox reactions with its electron-transfer partners during the turnover cycle (gating of electrons); and (3) regulation of the rates of the protonation/deprotonation reactions between the pumping site and the aqueous phases on the two sides of the membrane during the reaction cycle (gating of protons). The model is the first proposed for the cytochrome oxidase proton pump which is mechanistically complete and sufficiently specific that a realistic assessment can be made of how well the model pump would function as a redox-linked free-energy transducer. This assessment is accomplished via analyses of the thermodynamic properties and steady-state kinetics expected of the model. These analyses demonstrate that the model would function as an efficient pump and that its behavior would be very similar to that observed of cytochrome oxidase both in the mitochondrion and in purified preparations. The analysis presented here leads to the following important general conclusions regarding the mechanistic features of the oxidase proton pump. (1) A workable proton-pump mechanism does not require large protein conformational changes. (2) A redox-linked proton pump need not display a pH-dependent midpoint potential, as has frequently been assumed. (3) Mechanisms for redox-linked proton pumps that involve transition metal ligand exchange reactions are quite attractive because such reactions readily lend themselves to the linked gating processes necessary for proton pumping.     

Polyanion binding to cytochrome c probed by resonance Raman spectroscopy

The interaction of ferricytochrome c with negatively charged heteropolytungstates was studied by resonance Raman spectroscopy. In analogy to previous findings on ferricytochrome c bound to other types of charged interface (Hildebrandt, P. and Stockburger, M. (1989) Biochemistry 28, 6710-6721, 6722-6728), it was shown that in these complexes the conformational states I and II are stabilized. While in state I, the structure is the same as is in the uncomplexed heme protein, in state II three different coordination configurations coexist, i.e., a six-coordinated low-spin, a five-coordinated high-spin and a six-coordinated high-spin form. These configurations constitute thermal coordination equilibria whose thermodynamic properties were determined. The detailed analysis of the low-frequency resonance Raman spectra reveals that in state II the heme pocket assumes an open structure leading to a significantly higher flexibility of the heme group compared to the native ferricytochrome c. It is concluded that these structural changes are the result of Coulombic attractions between the polyanions and the lysine residues around the exposed heme edge which destabilize the heme crevice. Modifications of these interactions upon variation of the ionic strength, the pH or the type of the polytungstate are sensitively reflected by changes of the coordination equilibria in state II as well as of the conformational equilibrium of state I and state II. The conformational changes in state II significantly differ from those associated with the alkaline transition of ferricytochrome c. However, there are some structural similarities between the acid form of the heme protein stable below pH 2.5 in aqueous solution and the six-coordinated high-spin configuration of the bound ferricytochrome c at neutral pH (state II). This suggests that electrostatic interactions with the heteropolytungstates perturb the ionic equilibria of those amino acid side chains which are involved in the acid-induced transition leading to a significant upshift of the apparent pKa.     

The location of CuA in mammalian cytochrome c oxidase

Imposition of a protonmotive force across the inner membrane of coupled cyanide-inhibited, beef heart mitochondria by addition of ATP causes reduction of cytochrome c and CuA with concomitant oxidation of haem aA. The data are consistent with previous demonstrations of an intramembrane location of haem aA but further indicate that CuA is very close to the cytosolic surface of the membrane. The implications of this finding for electron transfer route and the site of the proton pumping chemistry are discussed.     

Phosphorylation and kinetics of mammalian cytochrome c oxidase

The influence of protein phosphorylation on the kinetics of cytochrome c oxidase was investigated by applying Western blotting, mass spectrometry, and kinetic measurements with an oxygen electrode. The isolated enzyme from bovine heart exhibited serine, threonine, and/or tyrosine phosphorylation in various subunits, except subunit I, by using phosphoamino acid-specific antibodies. The kinetics revealed slight inhibition of oxygen uptake in the presence of ATP, as compared with the presence of ADP. Mass spectrometry identified the phosphorylation of Ser-34 at subunit IV and Ser-4 and Thr-35 at subunit Va. Incubation of the isolated enzyme with protein kinase A, cAMP, and ATP resulted in serine and threonine phosphorylation of subunit I, which was correlated with sigmoidal inhibition kinetics in the presence of ATP. This allosteric ATP-inhibition of cytochrome c oxidase was also found in rat heart mitochondria, which had been rapidly prepared in the presence of protein phosphatase inhibitors. The isolated rat heart enzyme, prepared from the mitochondria by blue native gel electrophoresis, showed serine, threonine, and tyrosine phosphorylation of subunit I. It is concluded that the allosteric ATP-inhibition of cytochrome c oxidase, previously suggested to keep the mitochondrial membrane potential and thus the reactive oxygen species production in cells at low levels, occurs in living cells and is based on phosphorylation of cytochrome c oxidase subunit I.     

Components of cytochrome c oxidase detectable by EPR spectroscopy

A procedure for the preparation from frozen beef heart mitochondria of cytochrome c oxidase (EC 1.9.3.1) of high heme ( 14 μmoles/mg protein) and low extraneous copper ( 1.1 atoms Cu/mole heme) and low lipid ( 0.05 g phospholipid/g protein) content is described. EPR signals observed with the enzyme between 6 and 100 °K at various states of oxidation and at different conditions of pH and presence of solutes are described in detail. The quantities of paramagnetic species represented by these signals are estimated. Under no conditions does the sum of the EPR detectable species represent more than approx. 50% of the potentially paramagnetic components of the enzyme. Comparisons are made to the corresponding signals as observed in whole tissue, mitochondria and submitochondrial particles from a number of species. The assignment of the observed signals to known components of cytochrome c oxidase is discussed briefly.     

Redox properties of the diheme cytochrome c4 from Azotobacter vinelandii and characterisation of the two hemes by NMR, MCD and EPR spectroscopy

From biphasic stopped-flow kinetic studies it has been established that the two heme centres of cytochrome c4 from Azotobacter vinelandii undergo redox change with [Co(terpy)2]3+/2+ (260 mV) at different rates. Rate constants for oxidation and reduction at pH 7.5 give reduction potentials for the two heme centres in agreement with previous values from spectrophotometric titrations (263 and 317 mV). From NMR studies on the fully reduced protein two sharp methyl methionine resonances are observed at -3.16 and -3.60 ppm, consistent with axial methionine coordination. On titration with [Fe(CN)6]3- the -3.16 ppm resonance is the first to disappear, and is assigned to the less positive reduction potential. Line-broadening effects are observed on partial oxidation, which are dominated by intermolecular processes in an intermediate time-range exchange process. The hemes of the oxidised protein are distinguishable by EPR g-values of 3.64 and 3.22. The former is of interest because it is at an unusually low field for histidine/methionine coordination, and has an asymmetric or ramp shape. The latter assigned to the low potential heme is similar to that of a cytochrome c551. The MCD spectra of the fully oxidised protein are typical of low-spin Fe(III) heme centres, with a negative peak at 710 nm characteristic of methionine coordination, and an NIR peak at 1900 nm characteristic of histidine/methionine (axial) coordination. Of the four histidines per molecule only two undergo diethyl pyrocarbonate (DEPC) modification.