Relocation of an internal proton donor in cytochrome c oxidase results in an altered pK(a) and a non-integer pumping stoichiometry

Cytochrome c oxidase from Rhodobacter sphaeroides has two proton-input pathways leading from the protein surface towards the catalytic site, located within the membrane-spanning part of the enzyme. One of these pathways, the D-pathway, contains a highly conserved Glu residue [E(I-286)], which plays an important role in proton transfer through the pathway. In a recent study, we showed that a mutant enzyme in which E(I-286) was re-located to the opposite side of the D-pathway [EA(I-286)/IE(I-112) double mutant enzyme] was able to pump protons, although with a stoichiometry that was lower than that of the wild-type enzyme (approximately 0.6 H(+)/e(-)) (Aagaard et al. (2000) Biochemistry 39, 15847-15850). These results showed that the residue must not necessarily be located at a specific place in the amino-acid sequence, but rather at a specific location in space. In this study, we have investigated the effect of moving E(I-286) on the kinetics of specific reaction steps of the catalytic cycle in the pH range 6-11. Our results show that during the reaction of the four-electron reduced enzyme with O(2), the rates of the two first transitions (up to formation of the 'peroxy' intermediate, P(r)) are the same for the double mutant as for the wild-type enzyme, but formation of the oxo-ferryl (F) and fully oxidized (O) states, associated with proton uptake from the bulk solution, are slowed by factors of approximately 30 and approximately 400, respectively. Thus, in spite of the dramatically reduced transition rates, the proton-pumping stoichiometry is reduced only by approximately 40%. The apparent pK(a) values in the pH-dependencies of the rates of the P(R)-->F and F-->O transitions were >3 and approximately 2 units lower than those of the corresponding transitions in the wild-type enzyme, respectively. The relation between the modified pK(a)s, the transition rates between oxygen intermediates and the pumping stoichiometry is discussed.     

Redox-driven proton pumping by heme-copper oxidases

One of the key problems of molecular bioenergetics is the understanding of the function of redox-driven proton pumps on a molecular level. One such class of proton pumps are the heme-copper oxidases. These enzymes are integral membrane proteins in which proton translocation across the membrane is driven by electron transfer from a low-potential donor, such as, e.g. cytochrome c, to a high-potential acceptor, O(2). Proton pumping is associated with distinct exergonic reaction steps that involve gradual reduction of oxygen to water. During the process of O(2) reduction, unprotonated high pK(a) proton acceptors are created at the catalytic site. Initially, these proton acceptors become protonated as a result of intramolecular proton transfer from a residue(s) located in the membrane-spanning part of the enzyme, but removed from the catalytic site. This residue is then reprotonated from the bulk solution. In cytochrome c oxidase from Rhodobacter sphaeroides, the proton is initially transferred from a glutamate, E(I-286), which has an apparent pK(a) of 9.4. According to a recently published structure of the enzyme, the deprotonation of E(I-286) is likely to result in minor structural changes that propagate to protonatable groups on the proton output (positive) side of the protein. We propose that in this way, the free energy available from the O(2) reduction is conserved during the proton transfer. On the basis of the observation of these structural changes, a possible proton-pumping model is presented in this paper. Initially, the structural changes associated with deprotonation of E(I-286) result in the transfer of a proton to an acceptor for pumped protons from the input (negative) side of the membrane. After reprotonation of E(I-286) this acceptor releases a proton to the output side of the membrane.     

Proton transfer from glutamate 286 determines the transition rates between oxygen intermediates in cytochrome c oxidase

We have investigated the electron-proton coupling during the peroxy (P(R)) to oxo-ferryl (F) and F to oxidised (O) transitions in cytochrome c oxidase from Rhodobacter sphaeroides. The kinetics of these reactions were investigated in two different mutant enzymes: (1) ED(I-286), in which one of the key residues in the D-pathway, E(I-286), was replaced by an aspartate which has a shorter side chain than that of the glutamate and, (2) ML(II-263), in which the redox potential of Cu(A) is increased by approximately 100 mV, which slows electron transfer to the binuclear centre during the F-->O transition by a factor of approximately 200. In ED(I-286) proton uptake during P(R)-->F was slowed by a factor of approximately 5, which indicates that E(I-286) is the proton donor to P(R). In addition, in the mutant enzyme the F-->O transition rate displayed a deuterium isotope effect of approximately 2.5 as compared with approximately 7 in the wild-type enzyme. Since the entire deuterium isotope effect was shown to be associated with a single proton-transfer reaction in which the proton donor and acceptor must approach each other (M. Karpefors, P. Adelroth, P. Brzezinski, Biochemistry 39 (2000) 6850), the smaller deuterium isotope effect in ED(I-286) indicates that proton transfer from E(I-286) determines the rate also of the F-->O transition. In ML(II-263) the electron-transfer to the binuclear centre is slower than the intrinsic proton-transfer rate through the D-pathway. Nevertheless, both electron and proton transfer to the binuclear centre displayed a deuterium isotope effect of approximately 8, i.e., about the same as in the wild-type enzyme, which shows that these reactions are intimately coupled.     

Intramolecular proton-transfer reactions in a membrane-bound proton pump: the effect of pH on the peroxy to ferryl transition in cytochrome c oxidase

In the membrane-bound redox-driven proton pump cytochrome c oxidase, electron- and proton-transfer reactions must be coupled, which requires controlled modulation of the kinetic and/or thermodynamic properties of proton-transfer reactions through the membrane-spanning part of the protein. In this study we have investigated proton-transfer reactions through a pathway that is used for the transfer of both substrate and pumped protons in cytochrome c oxidase from Rhodobacter sphaeroides. Specifically, we focus on the formation of the so-called F intermediate, which is rate limited by an internal proton-transfer reaction from a possible branching point in the pathway, at a glutamic-acid residue (E(I-286)), to the binuclear center. We have also studied the reprotonation of E(I-286) from the bulk solution. Evaluation of the data in terms of a model presented in this work gives a rate of internal proton transfer from E(I-286) to the proton acceptor at the catalytic site of 1.1 x 10(4) s(-1). The apparent pK(a) of the donor (E(I-286)), determined from the pH dependence of the F-formation kinetics, was found to be 9.4, while the pK(a) of the proton acceptor at the catalytic site is likely to be > or = 2.5 pH units higher. In the pH range up to pH 10 the proton equilibrium between the bulk solution and E(I-286) was much faster than 10(4) s(-1), while in the pH range above pH 10 the proton uptake from solution is rate limiting for the overall reaction. The apparent second-order rate constant for proton transfer from the bulk solution to E(I-286) is >10(13) M(-1) s(-1), which indicates that the proton uptake is assisted by a local buffer consisting of protonatable residues at the protein surface.     

Localized control of proton transfer through the D-pathway in cytochrome c oxidase: application of the proton-inventory technique

In the reaction cycle of cytochrome c oxidase from Rhodobacter sphaeroides, one of the steps that are coupled to proton pumping, the oxo-ferryl-to-oxidized transition (F --> O), displays a large kinetic deuterium isotope effect of about 7. In this study we have investigated in detail the dependence of the kinetics of this reaction step ?k(FO)(chi) on the fraction (chi) D(2)O in the enzyme solution (proton-inventory technique). According to a simplified version of the Gross-Butler equation, from the shape of the graph describing k(FO)(chi)/k(FO)(0), conclusions can be drawn concerning the number of protonatable sites involved in the rate-limiting proton-transfer reaction step. Even though the proton-transfer reaction during the F --> O transition takes place over a distance of at least 30 A and involves a large number of protonatable sites, the proton-inventory analysis displayed a linear dependence, which indicates that the entire deuterium isotope effect of 7 is associated with a single protonatable site. On the basis of experiments with site-directed mutants of cytochrome c oxidase, this localized proton-transfer rate control is proposed to be associated with glutamate (I-286) in the D-pathway. Consequently, the results indicate that proton transfer from the glutamate controls the rate of all events during the F --> O reaction step. The proton-inventory analysis of the overall enzyme turnover reveals a nonlinear plot characteristic of at least two protonatable sites involved in the rate-limiting step in the transition state, which indicates that this step does not involve proton transfer through the same pathway (or through the same mechanism) as during the F --> O transition.     

Deuterium isotope effect of proton pumping in cytochrome c oxidase

In mitochondria and many aerobic bacteria cytochrome c oxidase is the terminal enzyme of the respiratory chain where it catalyses the reduction of oxygen to water. The free energy released in this process is used to translocate (pump) protons across the membrane such that each electron transfer to the catalytic site is accompanied by proton pumping. To investigate the mechanism of electron-proton coupling in cytochrome c oxidase we have studied the pH-dependence of the kinetic deuterium isotope effect of specific reaction steps associated with proton transfer in wild-type and structural variants of cytochrome c oxidases in which amino-acid residues in proton-transfer pathways have been modified. In addition, we have solved the structure of one of these mutant enzymes, where a key component of the proton-transfer machinery, Glu286, was modified to an Asp. The results indicate that the P3-->F3 transition rate is determined by a direct proton-transfer event to the catalytic site. In contrast, the rate of the F3-->O4 transition, which involves simultaneous electron transfer to the catalytic site and is characteristic of any transition during CytcO turnover, is determined by two events with similar rates and different kinetic isotope effects. These reaction steps involve transfer of protons, that are pumped, via a segment of the protein including Glu286 and Arg481.     

Aspartate-132 in cytochrome c oxidase from Rhodobacter sphaeroides is involved in a two-step proton transfer during oxo-ferryl formation.

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.     

Transient Binding of CO to CuB in Cytochrome c Oxidase Is Dynamically Linked to Structural Changes around a Carboxyl Group: A Time-Resolved Step-Scan Fourier Transform Infrared Investigation

The redox-driven proton pump cytochrome c oxidase is that enzymatic machinery of the respiratory chain that transfers electrons from cytochrome c to molecular oxygen and thereby splits molecular oxygen to form water. To investigate the reaction mechanism of cytochrome c oxidase on the single vibrational level, we used time-resolved step-scan Fourier transform infrared spectroscopy and studied the dynamics of the reduced enzyme after photodissociation of bound carbon monoxide across the midinfrared range (2300-950 cm⁻¹). Difference spectra of the bovine complex were obtained at -20°C with 5 μs time resolution. The data demonstrate a dynamic link between the transient binding of CO to Cu_B and changes in hydrogen bonding at the functionally important residue E(I-286). Variation of the pH revealed that the pK_a of E(I-286) is >9.3 in the fully reduced CO-bound oxidase. Difference spectra of cytochrome c oxidase from beef heart are compared with those of the oxidase isolated from Rhodobacter sphaeroides. The bacterial enzyme does not show the environmental change in the vicinity of E(I-286) upon CO dissociation. The characteristic band shape appears, however, in redox-induced difference spectra of the bacterial enzyme but is absent in redox-induced difference spectra of mammalian enzyme. In conclusion, it is demonstrated that the dynamics of a large protein complex such as cytochrome c oxidase can be resolved on the single vibrational level with microsecond Fourier transform infrared spectroscopy. The applied methodology provides the basis for future investigations of the physiological reaction steps of this important enzyme.     

Structural elements involved in proton translocation by cytochrome c oxidase as revealed by backbone amide hydrogen-deuterium exchange of the E286H mutant

Cytochrome c oxidase is the terminal electron acceptor in the respiratory chains of aerobic organisms and energetically couples the reduction of oxygen to water to proton pumping across the membrane. The mechanisms of proton uptake, gating, and pumping have yet to be completely elucidated at the molecular level for these enzymes. For Rhodobacter sphaeroides CytcO (cytochrome aa3), it appears as though the E286 side chain of subunit I is a branching point from which protons are shuttled either to the catalytic site for O2 reduction or to the acceptor site for pumped protons. Amide hydrogen-deuterium exchange mass spectrometry was used to investigate how mutation of this key branching residue to histidine (E286H) affects the structures and dynamics of four redox intermediate states. A functional characterization of this mutant reveals that E286H CytcO retains approximately 1% steady-state activity that is uncoupled from proton pumping and that proton transfer from H286 is significantly slowed. Backbone amide H-D exchange kinetics indicates that specific regions of CytcO, perturbed by the E286H mutation, are likely to be involved in proton gating and in the exit pathway for pumped protons. The results indicate that redox-dependent conformational changes around E286 are essential for internal proton transfer. E286H CytcO, however, is incapable of these specific conformational changes and therefore is insensitive to the redox state of the enzyme. These data support a model where the side chain conformation of E286 controls proton translocation in CytcO through its interactions with the proton gate, which directs the flow of protons either to the active site or to the exit pathway. In the E286H mutant, the proton gate does not function properly and the exit channel is unresponsive. These results provide new insight into the structure and mechanism of proton translocation by CytcO.     

Pathways of Proton Transfer in Cytochrome c Oxidase

During the last few years our knowledge of the structure and function of heme copper oxidases has greatly profited from the use of site-directed mutagenesis in combination with biophysical techniques. This, together with the recently-determined crystal structures of cytochrome c oxidase, has now made it possible to design experiments aimed at targeting specific pump mechanisms. Here, we summarize results from our recent kinetic studies of electron and proton-transfer reactions in wild-type and mutant forms of cytochrome c oxidase from Rhodobacter sphaeroides. These studies have made it possible to identify amino acid residues involved in proton transfer during specific reaction steps and provide a basis for discussion of mechanisms of electron and proton transfer in terminal oxidases. The results indicate that the pathway through K(I-362)/T(I-359), but not through D(I-132)/E(I-286), is used for proton transfer to a protonatable group interacting electrostatically with heme a ₃, i.e., upon reduction of the binuclear center. The pathway through D(I-132)/E(I-286) is used for uptake of pumped and substrate protons during the pumping steps during O₂ reduction.     

Proton-transport mechanisms in cytochrome c oxidase revealed by studies of kinetic isotope effects

Cytochrome c oxidase (CytcO) is a membrane-bound enzyme, which catalyzes the reduction of di-oxygen to water and uses a major part of the free energy released in this reaction to pump protons across the membrane. In the Rhodobacter sphaeroides aa? CytcO all protons that are pumped across the membrane, as well as one half of the protons that are used for O? reduction, are transferred through one specific intraprotein proton pathway, which holds a highly conserved Glu286 residue. Key questions that need to be addressed in order to understand the function of CytcO at a molecular level are related to the timing of proton transfers from Glu286 to a "pump site" and the catalytic site, respectively. Here, we have investigated the temperature dependencies of the H/D kinetic-isotope effects of intramolecular proton-transfer reactions in the wild-type CytcO as well as in two structural CytcO variants, one in which proton uptake from solution is delayed and one in which proton pumping is uncoupled from O? reduction. These processes were studied for two specific reaction steps linked to transmembrane proton pumping, one that involves only proton transfer (peroxy-ferryl, P→F, transition) and one in which the same sequence of proton transfers is also linked to electron transfer to the catalytic site (ferryl-oxidized, F→O, transition). An analysis of these reactions in the framework of theory indicates that that the simpler, P→F reaction is rate-limited by proton transfer from Glu286 to the catalytic site. When the same proton-transfer events are also linked to electron transfer to the catalytic site (F→O), the proton-transfer reactions might well be gated by a protein structural change, which presumably ensures that the proton-pumping stoichiometry is maintained also in the presence of a transmembrane electrochemical gradient. Furthermore, the present study indicates that a careful analysis of the temperature dependence of the isotope effect should help us in gaining mechanistic insights about CytcO.     

Time-resolved step-scan Fourier transform infrared spectroscopy of the CO adducts of bovine cytochrome c oxidase and of cytochrome bo(3) from Escherichia coli

We have used cryogenic difference FTIR and time-resolved step-scan Fourier transform infrared (TR-FTIR) spectroscopies to explore the redox-linked proton-pumping mechanism of heme-copper respiratory oxidases. These techniques are used to probe the structure and dynamics of the heme a(3)-Cu(B) binuclear center and the coupled protein structures in response to the photodissociation of CO from heme Fe and its subsequent binding to and dissociation from Cu(B). Previous cryogenic (80 K) FTIR CO photodissociation difference results were obtained for cytochrome bo(3), the ubiquinol oxidase of Escherichia coli [Puustinen, A., et al. (1997) Biochemistry 36, 13195-13200]. These data revealed a connectivity between Cu(B) and glutamic acid E286, a residue which has been implicated in proton pumping. In the current work, the same phenomenon is observed using the CO adduct of bovine cytochrome aa(3) under cryogenic conditions, showing a perturbation of the equivalent residue (E242) to that in bo(3). Furthermore, using time-resolved (5 micros resolution) step-scan FTIR spectroscopy at room temperature, we observe the same spectroscopic perturbation in both cytochromes aa(3) and bo(3). In addition, we observe evidence for perturbation of a second carboxylic acid side chain, at higher frequency in both enzymes at room temperature. The high-frequency feature does not appear in the cryogenic difference spectra, indicating that the perturbation is an activated process. We postulate that the high-frequency IR feature is due to the perturbation of E62 (E89 in bo(3)), a residue near the opening of the proton K-channel and required for enzyme function. The implications of these results with respect to the proton-pumping mechanism are discussed. Finally, a fast loss of over 60% of the Cu(B)-CO signal in bo(3) is observed and ascribed to one or more additional conformations of the enzyme. This fast conformer is proposed to account for the uninhibited reaction with O(2) in flow-flash experiments.     

Ligand binding and the catalytic reaction of cytochrome caa(3) from the thermophilic bacterium Rhodothermus marinus

The ligand-binding dynamics and the reaction with O(2) of the fully (five-electron) reduced cytochrome caa(3) from the thermohalophilic bacterium Rhodothermus (R.) marinus were investigated. The enzyme is a proton pump which has all the residues of the proton-transfer pathways found in the mitochondrial-like enzymes conserved, except for one of the key elements of the D-pathway, the helix-VI glutamate [Glu(I-286), R. sphaeroides numbering]. In contrast to what has been suggested previously as general characteristics of thermophilic enzymes, during formation of the R. marinus caa(3)-CO complex, CO binds weakly to Cu(B), and is rapidly (k(Ba) = 450 s(-1)) trapped by irreversible (K(Ba) = 4.5 x 10(3)) binding to heme a(3). Upon reaction of the fully reduced enzyme with O(2), four kinetic phases were resolved during the first 10 ms after initiation of the reaction. On the basis of a comparison to reactions observed with the bovine enzyme, these phases were attributed to the following transitions between intermediates (pH 7.8, 1 mM O(2)): R --> A (tau congruent with 8 micros), A --> P(r) (tau congruent with 35 micros), P(r) --> F (tau congruent with 240 micros), F --> O (tau congruent with 2.5 ms), where the last two phases were associated with proton uptake from the bulk solution. Oxidation of heme c was observed only during the last two reaction steps. The slower transition times as compared to those observed with the bovine enzyme most likely reflect the replacement of Glu(I-286) of the helix-VI motif -XGHPEV- by a tyrosine in the R. marinus enzyme in the motif -YSHPXV-. The presence of an additional, fifth electron in the enzyme was reflected by two additional kinetic phases with time constants of approximately 20 and approximately 720 ms during which the fifth electron reequilibrated within the enzyme.     

Plasticity of proton pathway structure and water coordination in cytochrome c oxidase

Cytochrome c oxidase (CytcO) is a redox-driven, membrane-bound proton pump. One of the proton transfer pathways of the enzyme, the D pathway, used for the transfer of both substrate and pumped protons, accommodates a network of hydrogen-bonded water molecules that span the distance between an aspartate (Asp(132)), near the protein surface, and glutamate Glu(286), which is an internal proton donor to the catalytic site. To investigate how changes in the environment around Glu(286) affect the mechanism of proton transfer through the pathway, we introduced a non-hydrogen-bonding (Ala) or an acidic residue (Asp) at position Ser(197) (S197A or S197D), located approximately 7 A from Glu(286). Although Ser(197) is hydrogen-bonded to a water molecule that is part of the D pathway "proton wire," replacement of the Ser by an Ala did not affect the proton transfer rate. In contrast, the S197D mutant CytcO displayed a turnover activity of approximately 35% of that of the wild-type CytcO, and the O(2) reduction reaction was not linked to proton pumping. Instead, a fraction of the substrate protons was taken from the positive ("incorrect") side of the membrane. Furthermore, the pH dependence of the proton transfer rate was altered in the mutant CytcO. The results indicate that there is plasticity in the water coordination of the proton pathway, but alteration of the electrostatic potential within the pathway results in uncoupling of the proton translocation machinery.     

The entry point of the K-proton-transfer pathway in cytochrome c oxidase

Cytochrome c oxidase is a redox-driven proton pump. The enzyme has two proton input pathways, leading from the solution on the N-side to the binuclear center. One of these pathways, the K-pathway, is used for proton uptake upon reduction of the binuclear center. It is also important for local charge compensation during reaction of the fully reduced enzyme with O2. Two different locations have been proposed to constitute the entry point of the K-pathway: near S(I-299) or near E(II-101), respectively, in the Rhodobacter sphaeroides enzyme. The experiments discussed in this study are aimed at identifying the location of the entry point. The kinetics and extent of flash-induced proton release coupled to oxidation of heme a3 (tau congruent with 2 ms at pH 8.8 in the wild-type enzyme) in the absence of O2 were investigated in the ED(II-101), SD(I-299), and KM(I-362) mutant enzymes, i.e., at the two proposed entry points and in the middle of the pathway, respectively. This reaction was completely blocked in KM(I-362), while it was slowed by factors of 25 and 40 in the ED(II-101) and SD(I-299) mutant enzymes, respectively. During reaction of the fully reduced enzyme with O2, electron transfer from heme a to the catalytic site (during P(R)-formation) was blocked in the KM(I-362) and SD(I-299)/SG(I-299) but not in the ED(II-101)/ EA(II-101) mutant enzymes. The results are interpreted as follows: Residue K(I-362) is involved in both proton transfer and charge compensation (in different reaction steps). The impaired proton release in the S(I-299) mutant enzymes is an indirect effect due to an altered environment of K(I-362). E(II-101), on the other hand, is likely to be part of the K-pathway since mutation of this residue results in impaired proton release but does not affect the P(R) formation kinetics; i.e., the properties of K(I-362) are not altered. Consequently, we conclude that the entry point of the K-pathway is located near E(II-101).     

Kinetics of electron and proton transfer during O(2) reduction in cytochrome aa(3) from A. ambivalens: an enzyme lacking Glu(I-286)

Acidianus ambivalens is a hyperthermoacidophilic archaeon which grows optimally at approximately 80 degrees C and pH 2.5. The terminal oxidase of its respiratory system is a membrane-bound quinol oxidase (cytochrome aa(3)) which belongs to the heme-copper oxidase superfamily. One difference between this quinol oxidase and a majority of the other members of this family is that it lacks the highly-conserved glutamate (Glu(I-286), E. coli ubiquinol oxidase numbering) which has been shown to play a central role in controlling the proton transfer during reaction of reduced oxidases with oxygen. In this study we have investigated the dynamics of the reaction of the reduced A. ambivalens quinol oxidase with O(2). With the purified enzyme, two kinetic phases were observed with rate constants of 1.8&z.ccirf;10(4) s(-1) (at 1 mM O(2), pH 7.8) and 3. 7x10(3) s(-1), respectively. The first phase is attributed to binding of O(2) to heme a(3) and oxidation of both hemes forming the 'peroxy' intermediate. The second phase was associated with proton uptake from solution and it is attributed to formation of the 'oxo-ferryl' state, the final state in the absence of quinol. In the presence of bound caldariella quinol (QH(2)), heme a was re-reduced by QH(2) with a rate of 670 s(-1), followed by transfer of the fourth electron to the binuclear center with a rate of 50 s(-1). Thus, the results indicate that the quinol donates electrons to heme a, followed by intramolecular transfer to the binuclear center. Moreover, the overall electron and proton-transfer kinetics in the A. ambivalens quinol oxidase are the same as those in the E. coli ubiquinol oxidase, which indicates that in the A. ambivalens enzyme a different pathway is used for proton transfer to the binuclear center and/or other protonatable groups in an equivalent pathway are involved. Potential candidates in that pathway are two glutamates at positions (I-80) and (I-83) in the A. ambivalens enzyme (corresponding to Met(I-116) and Val(I-119), respectively, in E. coli cytochrome bo(3)).     

Defining the proton entry point in the bacterial respiratory nitric-oxide reductase

The bacterial respiratory nitric-oxide reductase (NOR) is a member of the superfamily of O(2)-reducing, proton-pumping, heme-copper oxidases. Even although nitric oxide reduction is a highly exergonic reaction, NOR is not a proton pump and rather than taking up protons from the cytoplasmic (membrane potential-negative) side of the membrane, like the heme-copper oxidases, NOR derives its substrate protons from the periplasmic (membrane potential-positive) side of the membrane. The molecular details of this non-electrogenic proton transfer are not yet resolved, so in this study we have explored a role in a proposed proton pathway for a conserved surface glutamate (Glu-122) in the catalytic subunit (NorB). The effect of substituting Glu-122 with Ala, Gln, or Asp on a single turnover of the reduced NOR variants with O(2), an alternative and experimentally tractable substrate for NOR, was determined. Electron transfer coupled to proton uptake to the bound O(2) is severely and specifically inhibited in both the E122A and E122Q variants, establishing the importance of a protonatable side chain at this position. In the E122D mutant, proton uptake is retained but it is associated with a significant increase in the observed pK(a) of the group donating protons to the active site. This suggests that Glu-122 is important in defining this proton donor. A second nearby glutamate (Glu-125) is also required for the electron transfer coupled to proton uptake, further emphasizing the importance of this region of NorB in proton transfer. Because Glu-122 is predicted to lie near the periplasmic surface of NOR, the results provide strong experimental evidence that this residue contributes to defining the aperture of a non-electrogenic "E-pathway" that serves to deliver protons from the periplasm to the buried active site in NOR.     

Effects of mutation of the conserved glutamic acid-286 in subunit I of cytochrome c oxidase from Rhodobacter sphaeroides

We have studied the effects of mutations, E286Q and E286D, of the conserved glutamate in subunit I of cytochrome c oxidase from Rhodobacter sphaeroides with a view to evaluating the role of this residue in redox-linked proton translocation. The mutation E286D did not have any dramatic effects on enzyme properties and retained 50% of wild-type catalytic activity. For E286Q a fraction of the binuclear center was trapped in an unreactive, spectrally distinct form which is most likely due to misfolded protein, but the majority of E286Q reacted normally with formate and cyanide in the oxidized state, and with carbon monoxide and cyanide in the dithionite-reduced form. The mutation also had little effect on the pH-dependent redox properties of haem a in the reactive fraction. However, formation of the P state from oxidized enzyme with hydrogen peroxide or by aerobic incubation with carbon monoxide was inhibited. In particular, only an F-type product was obtained, at less than 25% yield, in the reaction with hydrogen peroxide. The aerobic steady state in the presence of ferrous cytochrome c was characterized by essentially fully reduced haem a and ferric haem a3, suggesting that the mutation hinders electron transfer from haem a to the binuclear center. Under these conditions or after reoxidation, on a seconds time scale, of haem a3 following anaerobiosis, there was no indication of accumulation of significant amounts of P state. We propose that the glutamate is implicated in several steps in the catalytic cycle, O --> R, P --> F, and, possibly, F --> O. The results are discussed in relation to the "glutamate trap" model for proton translocation.     

A D-pathway mutation decouples the Paracoccus denitrificans cytochrome c oxidase by altering the side-chain orientation of a distant conserved glutamate

Asparagine 131, located near the cytoplasmic entrance of the D-pathway in subunit I of the Paracoccus denitrificans aa(3) cytochrome c oxidase, is a residue crucial for proton pumping. When replaced by an aspartate, the mutant enzyme is completely decoupled: while retaining full cytochrome c oxidation activity, it does not pump protons. The same phenotype is observed for two other substitutions at this position (N131E and N131C), whereas a conservative replacement by glutamine affects both activities of the enzyme. The N131D variant oxidase was crystallized and its structure was solved to 2.32-A resolution, revealing no significant overall change in the protein structure when compared with the wild type (WT), except for an alternative orientation of the E278 side chain in addition to its WT conformation. Moreover, remarkable differences in the crystallographically resolved chain of water molecules in the D-pathway are found for the variant: four water molecules that are observed in the water chain between N131 and E278 in the WT structure are not visible in the variant, indicating a higher mobility of these water molecules. Electrochemically induced Fourier transform infrared difference spectra of decoupled mutants confirm that the protonation state of E278 is unaltered by these mutations but indicate a distinct perturbation in the hydrogen-bonding environment of this residue. Furthermore, they suggest that the carboxylate side chain of the N131D mutant is deprotonated. These findings are discussed in terms of their mechanistic implications for proton routing through the D-pathway of cytochrome c oxidase.     

Impaired proton pumping in cytochrome c oxidase upon structural alteration of the D pathway

Cytochrome c oxidase is a membrane-bound enzyme, which catalyses the one-electron oxidation of four molecules of cytochrome c and the four-electron reduction of O(2) to water. Electron transfer through the enzyme is coupled to proton pumping across the membrane. Protons that are pumped as well as those that are used for O(2) reduction are transferred though a specific intraprotein (D) pathway. Results from earlier studies have shown that replacement of residue Asn139 by an Asp, at the beginning of the D pathway, results in blocking proton pumping without slowing uptake of substrate protons used for O(2) reduction. Furthermore, introduction of the acidic residue results in an increase of the apparent pK(a) of E286, an internal proton donor to the catalytic site, from 9.4 to ~11. In this study we have investigated intramolecular electron and proton transfer in a mutant cytochrome c oxidase in which a neutral residue, Thr, was introduced at the 139 site. The mutation results in uncoupling of proton pumping from O(2) reduction, but a decrease in the apparent pK(a) of E286 from 9.4 to 7.6. The data provide insights into the mechanism by which cytochrome c oxidase pumps protons and the structural elements involved in this process.