In aerobic organisms, cellular respiration involves electron transfer to oxygen through a series of membrane-bound protein complexes. The process maintains a transmembrane electrochemical proton gradient that is used, for example, in the synthesis of ATP. In mitochondria and many bacteria, the last enzyme complex in the electron transfer chain is cytochrome c oxidase (CytcO), which catalyses the four-electron reduction of O2 to H2O using electrons delivered by a water-soluble donor, cytochrome c. The electron transfer through CytcO, accompanied by proton uptake to form H2O drives the physical movement (pumping) of four protons across the membrane per reduced O2. So far, the molecular mechanism of such proton pumping driven by electron transfer has not been determined in any biological system. Here we show that proton pumping in CytcO is mechanistically coupled to proton transfer to O2 at the catalytic site, rather than to internal electron transfer. This scenario suggests a principle by which redox-driven proton pumps might operate and puts considerable constraints on possible molecular mechanisms by which CytcO translocates protons.
The reaction with dioxygen of solubilized fully-reduced wild-type and EQ(I-286) (exchange of glutamate 286 of subunit I for glutamine) mutant cytochrome c oxidase from Rhodobacter sphaeroides has been studied using the flow-flash technique in combination with optical absorption spectroscopy. Proton uptake was measured using a pH-indicator dye. In addition, internal electron-transfer reactions were studied in the absence of oxygen. Glutamate 286 is found in a proton pathway proposed to be used for pumped protons from the crystal structure of cytochrome c oxidase from Paracoccus denitrificans [Iwata et al. (1995) Nature 376, 660-669; E278 in P.d. numbering]. It is the residue closest to the oxygen-binding binuclear center that is clearly a part of the pathway. The results show that the wild-type enzyme becomes fully oxidized in a few milliseconds at pH 7.4 and displays a biphasic proton uptake from the medium. In the EQ(I-286) mutant enzyme, electron transfer after formation of the peroxy intermediate is impaired, CuA remains reduced, and no protons are taken up from the medium. Thus, the results suggest that E(I-286) is necessary for proton uptake after formation of the peroxy intermediate and transfer of the fourth electron to the binuclear center. The results also indicate that the proton uptake associated with formation of the ferryl intermediate controls the electron transfer from CuA to heme a.
Absorbance changes following CO dissociation by flash photolysis from mixed-valence aa3 cytochrome oxidase from Rhodobacter sphaeroides have been followed in the Soret and alpha regions. They reflect internal electron transfer in the partially reduced enzyme, and the kinetics of the reactions has been determined. As with the bovine enzyme, three kinetic phases are found with relaxation time constants at neutral pH of about 3 microseconds, 35 microseconds, and 1 ms. The first reaction phase represents electron transfer from cytochrome a3 to cytochrome a, and the extent of this reaction is about 3 times larger compared to the bovine enzyme. The energetics of the reaction has been analyzed on the basis of measurements of its temperature dependence. The reorganization energy is close to 120 kJ mol-1, and it is suggested that this rather high value is the result of changes in solvation at the cytochrome a3-CuB site. The subsequent electron transfer between cytochrome a and CuA, with a time constant of 35 microseconds, is almost activationless and has a very low reorganization energy. The final phase, with a time constant close to 1 ms at neutral pH, represents a further shift in the equilibrium between cytochrome a3 and cytochrome a, and it is limited by proton-transfer reactions. The pKa values of the groups involved are significantly shifted in the bacterial oxidase compared to the bovine one. The total extent of electron transfer in the three backflow reactions has also been determined by a comparison of the CO-recombination rates in the mixed-valence and fully reduced enzymes.(ABSTRACT TRUNCATED AT 250 WORDS)
In this study we have combined the use of site-directed mutants with time-resolved optical absorption spectroscopy to investigate the role of the protonatable subunit-I residues lysine-362 (K(I-362)) and threonine-359 (T(I-359)) in cytochrome c oxidase from Rhodobacter sphaeroides in electron and proton transfer. These residues have been proposed to be part of a proton-transfer pathway in cytochrome oxidases from Paracoccus denitrificans and bovine heart. Mutation of K(I-362) and T(I-359) to methionine and alanine, respectively, results in reduction of the overall turnover activities to <2% and ∼35%, respectively, of those in the wild-type enzyme. The results show that in the absence of dioxygen, electron transfer between hemes a 3 and a with a time constant of ∼3 µs, not coupled to protonation reactions, is not affected in the mutant enzymes. However, the slower electron transfer between hemes a 3 and a, coupled to proton release with a time constant of ∼3 ms (at pH 9.0) is impaired in the KM(I-362) and TA(I-359) mutant enzymes. This is consistent with the slow reduction rate of heme a 3 in the oxidized KM(I-362) enzyme because in the wild-type enzyme reduction of heme a 3 is coupled to proton uptake. On the other hand, when reacting with O 2 , both the wild-type and mutant fully reduced enzymes become oxidized in ∼5 ms, and proton uptake on this time scale is not affected. Hence, the results indicate that the KM(
We have investigated the kinetics of the single-turnover reaction of fully reduced solubilised cytochrome c oxidase (cytochrome aa3) from Rhodobacter sphaeroides with dioxygen using the flow-flash methodology and compared the results to those obtained with the well-characterised bovine mitochondrial enzyme. The overall reaction sequence was the same in the two enzymes, but the extents and rates of the electron-transfer reactions differed, implying differences in redox potentials, and/or interaction energies between electrons and protons during oxygen reduction. As with the bovine enzyme, the R. sphaeroides enzyme displayed two major kinetic phases of proton uptake with rate constants of approximately 5000 s-1 and approximately 500 s-1 at pH 7.9, concomitant with the peroxy to oxoferryl and oxoferryl to oxidised states. The net number of protons taken up in the R. sphaeroides enzyme was about approximately 1.9, which implies that upon reduction, the enzyme has to pick up approximately 2.1 H+ from the medium. On the basis of the comparison of electron-transfer reactions in the two enzymes, we conclude that the transfer rate of the fourth electron to the binuclear centre is not only determined by the electron-transfer rate from haem a to the binuclear centre, but also by the electron equilibrium between CuA and haem a. In addition, in contrast to the bovine enzyme, where the electron- and proton-transfer rates during oxidation of the fully reduced enzyme by O2 are all faster than the overall turnover rate, in the R. sphaeroides enzyme, the slowest kinetic phase was rate limiting for the overall turnover. Moreover, the comparison of the reactions in the two systems shows that in the R. sphaeroides enzyme, the electrons are more evenly distributed among the redox centres during oxygen reduction. This enables investigations of effects also of minor perturbations on, e.g., the electron-transfer characteristics in mutant enzymes, for which this study forms the basis.
Cytochrome c oxidase is a membrane-bound enzyme that catalyzes the four-electron reduction of oxygen to water. This highly exergonic reaction drives proton pumping across the membrane. One of the key questions associated with the function of cytochrome c oxidase is how the transfer of electrons and protons is coupled and how proton transfer is controlled by the enzyme. In this study we focus on the function of one of the proton transfer pathways of the R. sphaeroides enzyme, the so-called K-proton transfer pathway (containing a highly conserved Lys(I-362) residue), leading from the protein surface to the catalytic site. We have investigated the kinetics of the reaction of the reduced enzyme with oxygen in mutants of the enzyme in which a residue [Ser(I-299)] near the entry point of the pathway was modified with the use of sitedirected mutagenesis. The results show that during the initial steps of oxygen reduction, electron transfer to the catalytic site (to form the ''peroxy'' state, P r) requires charge compensation through the proton pathway, but no proton uptake from the bulk solution. The charge compensation is proposed to involve a movement of the K(I-362) side chain toward the binuclear center. Thus, in contrast to what has been assumed previously, the results indicate that the K-pathway is used during oxygen reduction and that K(I-362) is charged at pH Ϸ 7.5. The movement of the Lys is proposed to regulate proton transfer by ''shutting off'' the protonic connectivity through the K-pathway after initiation of the O 2 reduction chemistry. This ''shutoff'' prevents a short-circuit of the protonpumping machinery of the enzyme during the subsequent reaction steps.flow-flash ͉ proton pumping ͉ cytochrome aa3 ͉ flash photolysis ͉ gating ͉ R. sphaeroides
The aspartate-132 in subunit I (D(I-132)) of cytochrome c oxidase from Rhodobacter sphaeroides is located on the cytoplasmic surface of the protein at the entry point of a proton-transfer pathway used for both substrate and pumped protons (D-pathway). Replacement of D(I-132) by its nonprotonatable analogue asparagine (DN(I-132)) has been shown to result in a reduced overall activity of the enzyme and impaired proton pumping. The results from this study show that during oxidation of the fully reduced enzyme the reaction was inhibited after formation of the oxo-ferryl (F) intermediate (tau congruent with 120 microseconds). In contrast to the wild-type enzyme, in the mutant enzyme formation of this intermediate was not associated with proton uptake from solution, which is the reason the DN(I-132) enzyme does not pump protons. The proton needed to form F was presumably taken from a protonatable group in the D-pathway (e.g., E(I-286)), which indicates that in the wild-type enzyme the proton transfer during F formation takes place in two steps: proton transfer from the group in the pathway is followed by faster reprotonation from the bulk solution, through D(I-132). Unlike the wild-type enzyme, in which F formation is coupled to internal electron transfer from CuA to heme a, in the DN(I-132) enzyme this electron transfer was uncoupled from formation of the F intermediate, which presumably is due to the impaired charge-compensating proton uptake from solution. In the presence of arachidonic acid which has been shown to stimulate the turnover activity of the DN(I-132) enzyme (Fetter et al. (1996) FEBS Lett. 393, 155), proton uptake with a time constant of approximately 2 ms was observed. However, no proton uptake associated with formation of F (tau congruent with 120 micros) was observed, which indicates that arachidonic acid can replace the role of D(I-132), but it cannot transfer protons as fast as the Asp. The results from this study show that D(I-132) is crucial for efficient transfer of protons into the enzyme and that in the DN(I-132) mutant enzyme there is a "kinetic barrier" for proton transfer into the D-pathway.
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