Fatty acids stimulate activity and restore respiratory control in a proton channel mutant of cytochrome c oxidase

Interaction of Terminal Oxidases with Amphipathic Molecules

The review focuses on recent advances regarding the effects of natural and artificial amphipathic compounds on terminal oxidases. Terminal oxidases are fascinating biomolecular devices which couple the oxidation of respiratory substrates with generation of a proton motive force used by the cell for ATP production and other needs. The role of endogenous lipids in the enzyme structure and function is highlighted. The main regularities of the interaction between the most popular detergents and terminal oxidases of various types are described. A hypothesis about the physiological regulation of mitochondrial-type enzymes by lipid-soluble ligands is considered.

Interaction of Amphipathic Peptide from Influenza Virus M1 Protein with Mitochondrial Cytochrome Oxidase

The Bile Acid Binding Site (BABS) of cytochrome oxidase (CcO) binds numerous amphipathic ligands. To determine which of the BABS-lining residues are critical for interaction, we used the peptide P4 and its derivatives A1-A4. P4 is composed of two flexibly bound modified α-helices from the M1 protein of the influenza virus, each containing a cholesterol-recognizing CRAC motif. The effect of the peptides on the activity of CcO was studied in solution and in membranes. The secondary structure of the peptides was examined by molecular dynamics, circular dichroism spectroscopy, and testing the ability to form membrane pores. P4 was found to suppress the oxidase but not the peroxidase activity of solubilized CcO. The K_i(app) is linearly dependent on the dodecyl-maltoside (DM) concentration, indicating that DM and P4 compete in a 1:1 ratio. The true K_i is 3 μM. The deoxycholate-induced increase in K_i(app) points to a competition between P4 and deoxycholate. A1 and A4 inhibit solubilized CcO with K_i(app)~20 μM at 1 mM DM. A2 and A3 hardly inhibit CcO either in solution or in membranes. The mitochondrial membrane-bound CcO retains sensitivity to P4 and A4 but acquires resistance to A1. We associate the inhibitory effect of P4 with its binding to BABS and dysfunction of the proton channel K. Trp residue is critical for inhibition. The resistance of the membrane-bound enzyme to inhibition may be due to the disordered secondary structure of the inhibitory peptide.

Membrane-Anchored Cyclic Peptides as Effectors of Mitochondrial Oxidative Phosphorylation

The echinocandins are membrane-anchored, cyclic lipopeptides (CLPs) with antifungal activity due to their ability to inhibit a glucan synthase located in the plasma membrane of fungi such as Candida albicans. A hydrophobic tail of an echinocandin CLP inserts into a membrane, placing a six-amino acid cyclic peptide near the membrane surface. Because processes critical for the function of the electron transfer complexes of mitochondria, such as proton uptake and release, take place near the surface of the membrane, we have tested the ability of two echinocandin CLPs, caspofungin and micafungin, to affect the activity of electron transfer complexes in isolated mammalian mitochondria. Indeed, caspofungin and micafungin both inhibit whole chain electron transfer in isolated mitochondria at low micromolar concentrations. The effects of the CLPs are fully reversible, in some cases simply via the addition of bovine serum albumin to bind the CLPs via their hydrophobic tails. Each CLP affects more than one complex, but they still exhibit specificity of action. Only caspofungin inhibits complex I, and the CLP inhibits liver but not heart complex I. Both CLPs inhibit heart and liver complex III. Caspofungin inhibits complex IV activity, while, remarkably, micafungin stimulates complex IV activity nearly 3-fold. Using a variety of assays, we have developed initial hypotheses for the mechanisms by which caspofungin and micafungin alter the activities of complexes IV and III. The dication caspofungin partially inhibits cytochrome c binding at the low-affinity binding site of complex IV, while it also appears to inhibit the release of protons from the outer surface of the complex, similar to Zn(2+). Anionic micafungin appears to stimulate complex IV activity by enhancing the transfer of protons to the O2 reduction site. For complex III, we hypothesize that each CLP binds to the cytochrome b subunit and the Fe-S subunit to inhibit the required rotational movement of the latter.

Respiratory conservation of energy with dioxygen: cytochrome C oxidase

Cytochrome c oxidase (CcO) is the terminal oxidase of cell respiration which reduces molecular oxygen (O₂) to H2O coupled with the proton pump. For elucidation of the mechanism of CcO, the three-dimensional location and chemical reactivity of each atom composing the functional sites have been extensively studied by various techniques, such as crystallography, vibrational and time-resolved electronic spectroscopy, since the X-ray structures (2.8 Å resolution) of bovine and bacterial CcO have been published in 1995.X-ray structures of bovine CcO in different oxidation and ligand binding states showed that the O₂reduction site, which is composed of Fe (heme a 3) and Cu (CuB), drives a non-sequential four-electron transfer for reduction of O₂to water without releasing any reactive oxygen species. These data provide the crucial structural basis to solve a long-standing problem, the mechanism of the O₂reduction.Time-resolved resonance Raman and charge translocation analyses revealed the mechanism for coupling between O₂reduction and the proton pump: O₂is received by the O₂reduction site where both metals are in the reduced state (R-intermediate), giving the O₂-bound form (A-intermediate). This is spontaneously converted to the P-intermediate, with the bound O₂fully reduced to 2 O²⁻. Hereafter the P-intermediate receives four electron equivalents from the second Fe site (heme a), one at a time, to form the three intermediates, F, O, and E to regenerate the R-intermediate. Each electron transfer step from heme a to the O₂reduction site is coupled with the proton pump.X-ray structural and mutational analyses of bovine CcO show three possible proton transfer pathways which can transfer pump protons (H) and chemical (water-forming) protons (K and D). The structure of the H-pathway of bovine CcO indicates that the driving force of the proton pump is the electrostatic repulsion between the protons on the H-pathway and positive charges of heme a, created upon oxidation to donate electrons to the O₂reduction site. On the other hand, mutational and time-resolved electrometric findings for the bacterial CcO strongly suggest that the D-pathway transfers both pump and chemical protons. However, the structure for the proton-gating system in the D-pathway has not been experimentally identified. The structural and functional diversities in CcO from various species suggest a basic proton pumping mechanism in which heme a pumps protons while heme a 3 reduces O₂as proposed in 1978.

Current advances in research of cytochrome c oxidase

The function of cytochrome c oxidase as a biomolecular nanomachine that transforms energy of redox reaction into protonmotive force across a biological membrane has been subject of intense research, debate, and controversy. The structure of the enzyme has been solved for several organisms; however details of its molecular mechanism of proton pumping still remain elusive. Particularly, the identity of the proton pumping site, the key element of the mechanism, is still open to dispute. The pumping mechanism has been for a long time one of the key unsolved issues of bioenergetics and biochemistry, but with the accelerating progress in this field many important details and principles have emerged. Current advances in cytochrome oxidase research are reviewed here, along with a brief discussion of the most complete proton pumping mechanism proposed to date, and a molecular basis for control of its efficiency.

Role of aspartate 132 at the orifice of a proton pathway in cytochrome c oxidase

Proton transfer across biological membranes underpins central processes in biological systems, such as energy conservation and transport of ions and molecules. In the membrane proteins involved in these processes, proton transfer takes place through specific pathways connecting the two sides of the membrane via control elements within the protein. It is commonly believed that acidic residues are required near the orifice of such proton pathways to facilitate proton uptake. In cytochrome c oxidase, one such pathway starts near a conserved Asp-132 residue. Results from earlier studies have shown that replacement of Asp-132 by, e.g., Asn, slows proton uptake by a factor of ∼5,000. Here, we show that proton uptake at full speed (∼10(4) s(-1)) can be restored in the Asp-132-Asn oxidase upon introduction of a second structural modification further inside the pathway (Asn-139-Thr) without compensating for the loss of the negative charge. This proton-uptake rate was insensitive to Zn(2+) addition, which in the wild-type cytochrome c oxidase slows the reaction, indicating that Asp-132 is required for Zn(2+) binding. Furthermore, in the absence of Asp-132 and with Thr at position 139, at high pH (>9), proton uptake was significantly accelerated. Thus, the data indicate that Asp-132 is not strictly required for maintaining rapid proton uptake. Furthermore, despite the rapid proton uptake in the Asn-139-Thr/Asp-132-Asn mutant cytochrome c oxidase, proton pumping was impaired, which indicates that the segment around these residues is functionally linked to pumping.

A conserved amphipathic ligand binding region influences k-path-dependent activity of cytochrome C oxidase

A conserved, crystallographically defined bile acid binding site was originally identified in the membrane domain of mammalian and bacterial cytochrome c oxidase (CcO). Current studies show other amphipathic molecules including detergents, fatty acids, steroids, and porphyrins bind to this site and affect the already 50% inhibited activity of the E101A mutant of Rhodobacter sphaeroides CcO as well as altering the activity of wild-type and bovine enzymes. Dodecyl maltoside, Triton X100, C12E8, lysophophatidylcholine, and CHOBIMALT detergents further inhibit RsCcO E101A, with lesser inhibition observed in wild-type. The detergent inhibition is overcome in the presence of micromolar concentrations of steroids and porphyrin analogues including deoxycholate, cholesteryl hemisuccinate, bilirubin, and protoporphyrin IX. In addition to alleviating detergent inhibition, amphipathic carboxylates including arachidonic, docosahexanoic, and phytanic acids stimulate the activity of E101A to wild-type levels by providing the missing carboxyl group. Computational modeling of dodecyl maltoside, bilirubin, and protoporphyrin IX into the conserved steroid site shows energetically favorable binding modes for these ligands and suggests that a groove at the interface of subunit I and II, including the entrance to the K-path and helix VIII of subunit I, mediates the observed competitive ligand interactions involving two overlapping sites. Spectral analysis indicates that ligand binding to this region affects CcO activity by altering the K-path-dependent electron transfer equilibrium between heme a and heme a(3). The high affinity and specificity of a number of compounds for this region, and its conservation and impact on CcO activity, support its physiological significance.

Gating and regulation of the cytochrome c oxidase proton pump

As a consumer of 95% of the oxygen we breathe, cytochrome c oxidase plays a major role in the energy balance of the cell. Regulation of its oxygen reduction and proton pumping activity is therefore critical to physiological function in health and disease. The location and structure of pathways for protons that are required to support cytochrome c oxidase activity are still under debate, with respect to their requirements for key residues and fixed waters, and how they are gated to prevent (or allow) proton backflow. Recent high resolution structures of bacterial and mammalian forms reveal conserved lipid and steroid binding sites as well as redox-linked conformational changes that provide new insights into potential regulatory ligands and gating modes. Mechanistic interpretation of these findings and their significance for understanding energy regulation is discussed.

Alternative initial proton acceptors for the D pathway of Rhodobacter sphaeroides cytochrome c oxidase

To characterize protein structures that control proton uptake, we assayed forms of cytochrome c oxidase (CcO) containing a carboxyl or a thiol group in line with the initial, internal waters of the D pathway for proton transfer in the presence and absence of subunit III. Subunit III provides approximately half of the protein surrounding the entry region of the D pathway. The N139D/D132N mutant contains a carboxyl group 6 Å within the D pathway and lacks the normal, surface-exposed proton acceptor, Asp-132. With subunit III, the steady-state activity of this mutant is slow, but once subunit III is removed, its activity is the same as that of wild-type CcO lacking subunit III (∼1800 H+/s). Thus, a carboxyl group∼25% within the pathway enhances proton uptake even though the carboxyl has no direct contact with bulk solvent. Protons from solvent apparently move to internal Asp-139 through a short file of waters, normally blocked by subunit III. Cys-139 also supports rapid steady-state proton uptake, demonstrating that an anion other than a carboxyl can attract and transfer protons into the D pathway. When both Asp-132 and Asp/Cys-139 are present, the removal of subunit III increases CcO activity to rates greater than that of normal CcO because of simultaneous proton uptake by two initial acceptors. The results show how the environment of the initial proton acceptor for the D pathway in these CcO forms dictates the pH range of CcO activity, with implications for the function of Asp-132, the normal proton acceptor.

Decoupling mutations in the D-channel of the aa(3)-type cytochrome c oxidase from Rhodobacter sphaeroides suggest that a continuous hydrogen-bonded chain of waters is essential for proton pumping

The aa(3)-type cytochrome c oxidase from Rhodobacter sphaeroides utilizes two proton-input channels to provide all the protons for chemistry (water formation) and proton pumping. The D-channel is responsible for the uptake of all pumped protons, four protons per O(2). Several substitutions of either N139 or N207, near the entrance of the D-channel, were previously reported to decouple the proton pump from oxidase activity. In this work, the characteristics of additional mutations in this region of the protein (N139, N207, N121, and S142) are determined to elucidate the mechanism of decoupling. With the exception of the substitution of a large, hydrophobic residue (N139L), all the mutations of N139 resulted in an enzyme with high oxidase activity but with a severely diminished proton pumping stoichiometry. Whereas N207D was previously shown to be decoupled, N207A and N207T exhibit nearly wild-type behavior. The new data display a pattern. Small, nonionizable substitutions of N139 or N121 result in decoupling of the proton pump but maintain high turnover rates. These residues are directly hydrogen bonded to two water molecules (Water6574 and Water6584) that are part of the single-file chain of water molecules within the D-channel leading to E286 at the top of the channel. The data suggest that the integrity of this water chain within the D-channel is critical for rapid proton transfer. The mechanism of decoupling is most likely due to the slowing of the rate of proton delivery below a threshold that is required for protonation of the putative proton loading site. Protons delivered outside this time window are delivered to the active site where they are consumed in the formation of water. The rate of proton delivery required to protonate the pump site must be significantly faster than the rate of delivery of protons to the catalytic site. For this reason, mutations can result in decoupling of the proton pump without slowing the catalytic turnover by the enzyme.

Partial steps of charge translocation in the nonpumping N139L mutant of Rhodobacter sphaeroides cytochrome c oxidase with a blocked D-channel

The N139L substitution in the D-channel of cytochrome oxidase from Rhodobacter sphaeroides results in an approximately 15-fold decrease in the turnover number and a loss of proton pumping. Time-resolved absorption and electrometric assays of the F --> O transition in the N139L mutant oxidase result in three major findings. (1) Oxidation of the reduced enzyme by O(2) shows approximately 200-fold inhibition of the F --> O step (k approximately 2 s(-1) at pH 8) which is not compatible with enzyme turnover ( approximately 30 s(-1)). Presumably, an abnormal intermediate F(deprotonated) is formed under these conditions, one proton-deficient relative to a normal F state. In contrast, the F --> O transition in N139L oxidase induced by single-electron photoreduction of intermediate F, generated by reaction of the oxidized enzyme with H(2)O(2), decelerates to an extent compatible with enzyme turnover. (2) In the N139L mutant, the protonic phase of Deltapsi generation coupled to the flash-induced F --> O transition greatly decreases in rate and magnitude and can be assigned to the movement of a proton from E286 to the binuclear site, required for reduction of heme a(3) from the Fe(4+) horizontal lineO(2-) state to the Fe(3+)-OH(-) state. Electrogenic reprotonation of E286 from the inner aqueous phase is missing from the F --> O step in the mutant. (3) In the N139L mutant, the KCN-insensitive rapid electrogenic phase may be composed of two components with lifetimes of approximately 10 and approximately 40 mus and a magnitude ratio of approximately 3:2. The 10 mus phase matches vectorial electron transfer from Cu(A) to heme a, whereas the 40 mus component is assigned to intraprotein proton displacement across approximately 20% of the membrane dielectric thickness. This proton displacement might be triggered by rotation of the charged K362 side chain coupled to heme a reduction. The two components of the rapid electrogenic phase have been resolved subsequently with other D-channel mutants as well as with cyanide-inhibited wild-type oxidase. The finding helps to reconcile the unusually high relative contribution of the microsecond electrogenic phase in the bacterial enzyme ( approximately 30%) with the net electrogenicity of the F --> O transition coupled to transmembrane transfer of two charges per electron.

A chemically explicit model for the mechanism of proton pumping in heme-copper oxidases

A mechanism for proton pumping is described that is based on chemiosmotic principles and the detailed molecular structures now available for cytochrome oxidases. The importance of conserved water positions and a step-wise gated process of proton translocation is emphasized, where discrete electron transfer events are coupled to proton uptake and expulsion. The trajectory of each pumped proton is the same for all four substrate electrons. An essential role for the His-Tyr cross-linked species is discussed, in gating of the D- and K-channels and as an acceptor/donor of electrons and protons at the binuclear center.

A conserved steroid binding site in cytochrome C oxidase

Micromolar concentrations of the bile salt deoxycholate are shown to rescue the activity of an inactive mutant, E101A, in the K proton pathway of Rhodobacter sphaeroides cytochrome c oxidase. A crystal structure of the wild-type enzyme reveals, as predicted, deoxycholate bound with its carboxyl group at the entrance of the K path. Since cholate is a known potent inhibitor of bovine oxidase and is seen in a similar position in the bovine structure, the crystallographically defined, conserved steroid binding site could reveal a regulatory site for steroids or structurally related molecules that act on the essential K proton path.

Crystallographic location and mutational analysis of Zn and Cd inhibitory sites and role of lipidic carboxylates in rescuing proton path mutants in cytochrome c oxidase

Cytochrome c oxidase (CcO) transfers protons from the inner surface of the enzyme to the buried O2 reduction site through two different pathways, termed K and D, and from the outer surface via an undefined route. These proton paths can be inhibited by metals such as zinc or cadmium, but the sites of inhibition have not been established. Anomalous difference Fourier analyses of Rhodobacter sphaeroides CcO crystals, with cadmium added, reveal metal binding sites that include the proposed initial proton donor/acceptor of the K pathway, Glu-101 of subunit II. Mutant forms of CcO that lack Glu-101II (E101A and E101A/H96A) exhibit low activity and eliminate metal binding at this site. Significant activity is restored to E101A and E101A/H96A by adding the lipophilic carboxylic compounds, arachidonic acid and cholic acid, but not by their non-carboxylic analogues. These amphipathic acids likely provide their carboxylic groups as substitute proton donors/acceptors in the absence of Glu-101II, as previously observed for arachidonic acid in mutants that alter Asp-132I of the D pathway. The activity of E101A/H96A is still inhibited by zinc, but this remaining inhibition is nearly eliminated by removal of subunit III, which is known to alter the D pathway. The results identify the Glu-101/His-96 site of subunit II as the site of metal binding that inhibits the uptake of protons into the K pathway and indicate that subunit III contributes to zinc binding and/or inhibition of the D pathway. By removing subunit III from E101A/H96A, thereby eliminating zinc inhibition of the uptake of protons from the inner surface of CcO, we confirm that an external zinc binding site is involved in inhibiting the backflow of protons to the active site.

Energy transduction: proton transfer through the respiratory complexes

A series of metalloprotein complexes embedded in a mitochondrial or bacterial membrane utilize electron transfer reactions to pump protons across the membrane and create an electrochemical potential (DeltamuH+). Current understanding of the principles of electron-driven proton transfer is discussed, mainly with respect to the wealth of knowledge available from studies of cytochrome c oxidase. Structural, experimental, and theoretical evidence supports the model of long-distance proton transfer via hydrogen-bonded water chains in proteins as well as the basic concept that proton uptake and release in a redox-driven pump are driven by charge changes at the membrane-embedded centers. Key elements in the pumping mechanism may include bound water, carboxylates, and the heme propionates, arginines, and associated water above the hemes. There is evidence for an important role of subunit III and proton backflow, but the number and nature of gating mechanisms remain elusive, as does the mechanism of physiological control of efficiency.

Altering Conserved Lipid Binding Sites in Cytochrome c Oxidase of Rhodobacter sphaeroides Perturbs the Interaction between Subunits I and III and Promotes Suicide Inactivation of the Enzyme

Subunit III of the three-subunit catalytic core of cytochrome c oxidase (CcO) contains no metal centers, but it does bind two lipids, within a deep cleft, in binding sites conserved from bacteria to humans. Subunit III binds to subunit I, where it prevents the spontaneous suicide inactivation of CcO by decreasing the probability of side reactions at the heme-Cu O2 reduction site in subunit I. Subunit III prevents suicide inactivation by (1) maintaining adequate rates of proton delivery to the heme-Cu active site and (2) stabilizing the structure of the active site during turnover [Mills and Hosler (2005) Biochemistry 44, 4656]. Here, we first show that mutating several individual residues of the conserved lipid binding sites in subunit III disturbs the subunit I-III interface. Then, two lipid binding site mutants were constructed with an affinity tag on subunit III such that the mutant CcOs could be isolated with 100% subunit III. R226A eliminates an ion pair to the phosphate of the outermost lipid of the cleft, while W59A-F86A disrupts interactions with the fatty acid tails of both lipids. Once these mutant CcOs are placed into soybean phospholipid vesicles, where extensive exchange of bacterial for soybean lipids takes place, it is shown that altering the lipid binding sites mimics a major loss of subunit III, even though subunit III is completely retained, in that suicide inactivation becomes much more probable. The rate of proton delivery to the active site remains rapid, ruling out slow proton uptake as the primary reason for increased suicide inactivation upon alteration of the lipid binding sites. We conclude that altering the lipid binding sites of subunit III may promote side reactions leading to suicide inactivation by allowing greater movement to occur in and around the O2 reduction site of subunit I during the catalytic cycle.

Surface Proton Donors for the D-Pathway of Cytochrome c Oxidase in the Absence of Subunit III

The major proton-transfer pathway into the buried active site of cytochrome c oxidase (CcO) is the D-pathway that begins with the subunit I residue Asp-132 on the inner protein surface (the cytoplasmic surface of the aa3-type CcO of Rhodobacter sphaeroides). Asp-132 is surrounded by residues from both subunits I and III. In the absence of subunit III, CcO retains activity, but the functional characteristics of the D-pathway are significantly altered such that the transfer of protons from Asp-132 into the pathway becomes the rate-limiting step. Determination of the pH-dependence of the rate constant for D-pathway proton uptake during the single-turnover of CcO indicates that the pKa of Asp-132 in the absence of subunit III is approximately 7. The removal of subunit III also allows for alternative surface proton donor/acceptors other than Asp-132. With Asp-132 altered to alanine, the rate constant for D-pathway proton uptake is very slow (5 s(-1)) in the presence of subunit III. Once subunit III is removed, the proton uptake rate constant increases 80-fold, to 400 s(-1). The pKa associated with this uptake is >10, and the initial proton donor/acceptor in D132A III (-) is proposed to be a water of the D-pathway rather than an amino acid residue. Arachidonic acid (Aa), which stimulates the activity of several D-pathway mutant CcOs, appears to become the initial proton donor/acceptor in the absence of subunit III, whether or not Asp-132 is altered. Aa shifts the pKa of the initial proton donor to 7.6 for both wild-type (WT) III (-) and D132A III (-). The results indicate that subunit III creates a barrier that helps prevent protons from donors other than Asp-132 from directly accessing the internal waters of the D-pathway, while the subunit also provides an environment that increases the rate at which Asp-132 transfers protons into the D-pathway.

Interaction of free fatty acids with mitochondria: coupling, uncoupling and permeability transition

Long chain free fatty acids (FFA) exert, according to their actual concentration, different effects on the energy conserving system of mitochondria. Sub-micromolar concentrations of arachidonic acid (AA) rescue DeltapH-dependent depression of the proton pumping activity of the bc1 complex. This effect appears to be due to a direct interaction of AA with the proton-input mouth of the pump. At micromolar concentrations FFA increase the proton conductance of the inner membrane acting as protonophores. FFA can act as natural uncouplers, causing a mild uncoupling, which prevents reactive oxygen species production in the respiratory resting state. When Ca(2+)-loaded mitochondria are exposed to micromolar concentrations of FFA, the permeability of the inner membrane increases, resulting in matrix swelling, rupture of the outer membrane and release of intermembrane pro-apoptotic proteins. The characteristics of AA-induced swelling appear markedly different in mitochondria isolated from heart or liver. While in the latter it presents the canonical features of the classical permeability transition (PT), in heart mitochondria substantial differences are observed concerning CsA sensitivity, DeltaPsi dependence, reversibility by BSA and specificity for the activating divalent cation. In heart mitochondria, the AA-dependent increase of the inner membrane permeability is affected by ANT ligands such as adenine nucleotides and atractyloside. AA apparently causes a Ca2+-mediated conversion of ANT from a translocator to a channel system. Upon diamide treatment of heart mitochondria, the Ca2+/AA-induced CsA insensitive channel is converted into the classical PT pore. The relevance of these observations in terms of tissue-specific components of the putative PTP and heart ischemic and post-ischemic process is discussed.

An arginine to lysine mutation in the vicinity of the heme propionates affects the redox potentials of the hemes and associated electron and proton transfer in cytochrome c oxidase

Cytochrome c oxidase pumps protons across a membrane using energy from electron transfer and reduction of oxygen to water. It is postulated that an element of the energy transduction mechanism is the movement of protons to the vicinity of the hemes upon reduction, to favor charge neutrality. Possible sites on which protons could reside, in addition to the conserved carboxylate E286, are the propionate groups of heme a and/or heme a(3). A highly conserved pair of arginines (R481 and R482) interact with these propionates through ionic and hydrogen bonds. This study shows that the conservative mutant, R481K, although as fully active as the wild type under many conditions, exhibits a significant decrease in the midpoint redox potential of heme a relative to Cu(A) (DeltaE(m)) of approximately equal 40 mV, has lowered activity under conditions of high pH or in the presence of a membrane potential, and has a slowed heme a(3) reduction with dithionite. Another mutant, D132A, which strongly inhibits proton uptake from the internal side of the membrane, has <4% of the activity of the wild type and appears to be dependent on proton uptake from the outside. A double mutation, D132A/R481K, is even more strongly inhibited ( approximately 1% of that of the wild type). The more-than-additive effect supports the concept that R481K not only lowers the midpoint potential of heme a but also limits a supply route for protons from the outside of the membrane used by the D132 mutant. The results are consistent with an important role of R481 and heme a/a(3) propionates in proton movement in a reversible exit path.

G204D, a Mutation That Blocks the Proton-Conducting D-Channel of the aa3-Type Cytochrome c Oxidase from Rhodobacter sphaeroides

Cytochrome c oxidase uses the free energy of oxygen reduction to establish a transmembrane proton gradient. The proton-conducting D-channel in this enzyme is the major input pathway for protons which go to the binuclear center for water formation ("chemical protons") and likely the only input pathway for protons that get translocated across the lipid membrane ("pumped protons"). The D-channel starts at an acidic residue near the protein surface (D132, Rhodobacter sphaeroides numbering) and leads to another acidic residue near the binuclear center. Recent studies have shown that mutants that introduce an additional acidic residue in the channel (N139D) have the remarkable effect of accelerating steady-state oxidase activity but completely eliminating proton pumping. In this work, an aspartic acid was introduced at the position of glycine 204, G204D, which is also within the D-channel, and the effects were examined. In contrast to N139D, the G204D mutation results in a dramatic decrease of the steady-state oxygen reductase activity (<2% of wild type) [Aagaard, A., and Brzezinski, P. (2001) FEBS Lett. 494, 157-160]. The residual activity is not coupled to the proton pump, and furthermore, in reconstituted vesicles the mutant enzyme exhibits a reverse respiration control ratio; i.e., the mutant oxidase activity is stimulated rather than inhibited when working against a protonmotive force. Hence, the mutant behaves very much like the D132N, which blocks proton uptake through the D-channel. Single-turnover experiments show that the rate-limiting step in the reaction of O2 with the fully reduced G204D mutant is the F --> O transition, similar to the D132N mutant. The block of the D-channel in the D132N mutant can be partly bypassed by biochemically removing subunit III from the enzyme, indicating that removal of the subunit reveals an alternate entrance for protons to the channel. However, this is not observed with the G204D mutant. This suggests that the cryptic entrance to the D-channel that is revealed by the removal of subunit III is between the levels of G204 and D132.

Slow proton transfer through the pathways for pumped protons in cytochrome c oxidase induces suicide inactivation of the enzyme

In the absence of subunit III the aa(3)-type cytochrome c oxidase exhibits a shortened catalytic life span (total number of turnovers) due to an increased probability of undergoing irreversible inactivation during steady-state turnover. Inactivation results from structural alteration of the heme a(3)-Cu(B) active site in subunit I [Hosler (2004) Biochim. Biophys. Acta 1655, 332-339]. The absence of subunit III also dramatically slows proton uptake to the active site via the D proton pathway, as well as inhibiting the proton backflow/exit pathway that connects the active site/proton pump with the outer surface of the oxidase complex. Here we demonstrate that these phenomena are linked: slow proton delivery to the active site through these pathways induces suicide inactivation, thus shortening the catalytic life span of the enzyme. Mutations that inhibit the D pathway, but not the K pathway, increase the probability of suicide inactivation. Strong inhibition of the D pathway allows suicide inactivation to occur even in the presence of subunit III. Arachidonic acid, which stimulates proton uptake by the D pathway, retards suicide inactivation. Steady-state turnover in the presence of DeltaPsi and DeltapH, which inhibits proton uptake from the inner surface of the protein, enhances suicide inactivation. Simultaneous inhibition of proton uptake from both sides of the protein by a double mutation affecting the D pathway and the proton backflow/exit pathway greatly shortens the catalytic life span of the oxidase even in the presence of subunit III. Thus, maintenance of rapid proton transfer through the D pathway and the backflow/exit pathway is one mechanism by which subunit III normally functions to prevent suicide inactivation of cytochrome c oxidase. The experiments suggest that increased lifetimes of the heme a(3) oxoferryl intermediates as well as the anionic form of Glu286 of the D pathway cause suicide inactivation in the active site.

Electrostatic study of the proton pumping mechanism in bovine heart cytochrome C oxidase

Cytochrome c oxidase (CcO) is the terminal enzyme of the cell respiratory chain in mitochondria and aerobic bacteria. It catalyzes the reduction of oxygen to water and utilizes the free energy of the reduction reaction for proton pumping across the inner-mitochondrial membrane, a process that results in a membrane electrochemical proton gradient. Although the structure of the enzyme has been solved for several organisms, the molecular mechanism of proton pumping remains unknown. In the present paper, continuum electrostatic calculations were employed to evaluate the electrostatic potential, energies, and protonation state of bovine heart cytochrome c oxidase for different redox states of the enzyme along its catalytic cycle. Three different computational models of the enzyme were employed to test the stability of the results. The energetics and pH dependence of the P-->F, F-->O, and O-->E steps of the cycle have been investigated. On the basis of electrostatic calculations, two possible schemes of redox-linked proton pumping are discussed. The first scheme involves His291 as a pump element, whereas the second scheme involves a group linked to propionate D of heme a(3). In both schemes, loading of the pump site is coupled to ET between the two hemes of the enzyme, while transfer of a chemical proton is accompanied by ejection of the pumped H(+). The two models, as well as the energetics results are compared with recent experimental kinetic data. The proton pumping across the membrane is an endergonic process, which requires a sufficient amount of energy to be provided by the chemical reaction in the active site. In our calculations, the conversion of OH(-) to H(2)O provides 520 meV of energy to displace pump protons from a loading site and overall about 635 meV for each electron passing through the system. Assuming that the two charges are translocated per electron against the membrane potential of 200 meV, the model predicts an overall efficiency of 63%.

The influence of subunit III of cytochrome c oxidase on the D pathway, the proton exit pathway and mechanism-based inactivation in subunit I

Although subunit III of cytochrome c oxidase is part of the catalytic core of the enzyme, its function has remained enigmatic. Comparison of the wild-type oxidase and forms lacking subunit III shows that the presence of subunit III maintains rapid proton uptake into the D pathway at the pH of the bacterial cytoplasm or mitochondrial matrix, apparently by contributing to the protein environment of D132, the initial proton acceptor of the D pathway. Subunit III also appears to contribute to the conformation of the normal proton exit pathway, allowing this pathway to take up protons from the outer surface of the oxidase in the presence of DeltaPsi and DeltapH. Subunit III prevents turnover-induced inactivation of the oxidase (suicide inactivation) and the subsequent loss of Cu(B) from the active site. This function of subunit III appears partly related to its ability to maintain rapid proton flow to the active site, thereby shortening the lifetime of reactive O(2) reduction intermediates. Analysis of proton pumping by subunit III-depleted oxidase forms leads to the proposal that the trapping of two protons in the D pathway, one on E286 and one on D132, is required for efficient proton pumping.

A role for subunit III in proton uptake into the D pathway and a possible proton exit pathway in Rhodobacter sphaeroides cytochrome c oxidase

Protons are transferred from the inner surface of cytochrome c oxidase to the active site by the D and K pathways, as well as from the D pathway to the outer surface by a largely undefined proton exit route. Alteration of the initial proton acceptor of the D pathway, D132, to alanine has previously been shown to greatly inhibit oxidase turnover and slow proton uptake into the D pathway. Here it is shown that the removal of subunit III restores a substantial rate of O(2) reduction to D132A. Presumably an alternative proton acceptor for the D pathway becomes active in the absence of subunit III and D132. Thus, in the absence of subunit III cytochrome oxidase shows greater flexibility in terms of proton entry into the D pathway. In the presence of DeltaPsi and DeltapH, turnover of the wild-type oxidase or D132A is slower in the absence of subunit III. Comparison of the turnover rates of subunit III-depleted wild-type oxidase to those of the zinc-inhibited wild-type oxidase containing subunit III, both reconstituted into vesicles, leads to the hypothesis that the absence of subunit III inhibits the ability of the normal proton exit pathway to take up protons from the outside in the presence of DeltaPsi and DeltapH. Thus, subunit III appears to affect the transfer of protons from both the inner and outer surfaces of cytochrome oxidase, perhaps accounting for the long-observed lower efficiency of proton pumping by the subunit III-depleted oxidase.

Intrinsic and extrinsic uncoupling of oxidative phosphorylation

This article reviews parameters of extrinsic uncoupling of oxidative phosphorylation (OxPhos) in mitochondria, based on induction of a proton leak across the inner membrane. The effects of classical uncouplers, fatty acids, uncoupling proteins (UCP1-UCP5) and thyroid hormones on the efficiency of OxPhos are described. Furthermore, the present knowledge on intrinsic uncoupling of cytochrome c oxidase (decrease of H(+)/e(-) stoichiometry=slip) is reviewed. Among the three proton pumps of the respiratory chain of mitochondria and bacteria, only cytochrome c oxidase is known to exhibit a slip of proton pumping. Intrinsic uncoupling was shown after chemical modification, by site-directed mutagenesis of the bacterial enzyme, at high membrane potential DeltaPsi, and in a tissue-specific manner to increase thermogenesis in heart and skeletal muscle by high ATP/ADP ratios, and in non-skeletal muscle tissues by palmitate. In addition, two mechanisms of respiratory control are described. The first occurs through the membrane potential DeltaPsi and maintains high DeltaPsi values (150-200 mV). The second occurs only in mitochondria, is suggested to keep DeltaPsi at low levels (100-150 mV) through the potential dependence of the ATP synthase and the allosteric ATP inhibition of cytochrome c oxidase at high ATP/ADP ratios, and is reversibly switched on by cAMP-dependent phosphorylation. Finally, the regulation of DeltaPsi and the production of reactive oxygen species (ROS) in mitochondria at high DeltaPsi values (150-200 mV) are discussed.

Voltage-gated proton channels and other proton transfer pathways

Proton channels exist in a wide variety of membrane proteins where they transport protons rapidly and efficiently. Usually the proton pathway is formed mainly by water molecules present in the protein, but its function is regulated by titratable groups on critical amino acid residues in the pathway. All proton channels conduct protons by a hydrogen-bonded chain mechanism in which the proton hops from one water or titratable group to the next. Voltage-gated proton channels represent a specific subset of proton channels that have voltage- and time-dependent gating like other ion channels. However, they differ from most ion channels in their extraordinarily high selectivity, tiny conductance, strong temperature and deuterium isotope effects on conductance and gating kinetics, and insensitivity to block by steric occlusion. Gating of H(+) channels is regulated tightly by pH and voltage, ensuring that they open only when the electrochemical gradient is outward. Thus they function to extrude acid from cells. H(+) channels are expressed in many cells. During the respiratory burst in phagocytes, H(+) current compensates for electron extrusion by NADPH oxidase. Most evidence indicates that the H(+) channel is not part of the NADPH oxidase complex, but rather is a distinct and as yet unidentified molecule.

Substitutions for glutamate 101 in subunit II of cytochrome c oxidase from Rhodobacter sphaeroides result in blocking the proton-conducting K-channel

Two functional input pathways for protons have been characterized in the heme-copper oxidases: the D-channel and the K-channel. These two proton-conducting channels have different functional roles and have been defined both by X-ray crystallography and by the characterization of site-directed mutants. Whereas the entrance of the D-channel is well-defined as D132(I) (subunit I; Rhodobacter sphaeroides numbering), the entrance of the K-channel has not been clearly defined. Previous mutagenesis studies of the cytochrome bo(3) quinol oxidase from Escherichia coli implicated an almost fully conserved glutamic acid residue within subunit II as a likely candidate for the entrance of the K-channel. The current work examines the properties of mutants of this conserved glutamate in the oxidase from R. sphaeroides (E101(II)I,A,C,Q,D,N,H) and residues in the immediate vicinity of E101(II). It is shown that virtually any substitution for E101(II), including E101(II)D, strongly reduces oxidase turnover (to 8-29%). Furthermore, the low steady-state activity correlates with an inhibition of the rate of reduction of heme a(3) prior to the reaction with O(2). These are phenotypes expected of K-channel mutants. It is concluded that the predominant entry point for protons going into the K-channel of cytochrome oxidase is the surface-exposed glutamic acid E101(II) in subunit II.

A mutation in subunit I of cytochrome oxidase from Rhodobacter sphaeroides results in an increase in steady-state activity but completely eliminates proton pumping

The heme-copper oxidases convert the free energy liberated in the reduction of O(2) to water into a transmembrane proton electrochemical potential (protonmotive force). One of the essential structural elements of the enzyme is the D-channel, which is thought to be the input pathway, both for protons which go to form H(2)O ("chemical protons") and for protons that get translocated across the lipid membrane ("pumped protons"). The D-channel contains a chain of water molecules extending about 25 A from an aspartic acid (D132 in the Rhodobacter sphaeroides oxidase) near the cytoplasmic ("inside") enzyme surface to a glutamic acid (E286) in the protein interior. Mutations in which either of these acidic residues is replaced by their corresponding amides (D132N or E286Q) result in severe inhibition of enzyme activity. In the current work, an asparagine located in the D-channel has been replaced by the corresponding acid (N139 to D; N98 in bovine enzyme) with dramatic consequences. The N139D mutation not only completely eliminates proton pumping but, at the same time, confers a substantial increase (150-300%) in the steady-state cytochrome oxidase activity. The N139D mutant of the R. sphaeroides oxidase was further characterized by examining the rates of individual steps in the catalytic cycle. Under anaerobic conditions, the rate of reduction of heme a(3) in the fully oxidized enzyme, prior to the reaction with O(2), is identical to that of the wild-type oxidase and is not accelerated. However, the rate of reaction of the fully reduced enzyme with O(2) is accelerated by the N139D mutation, as shown by a more rapid F --> O transition. Whereas the rates of formation and decay of the oxygenated intermediates are altered, the nature of the oxygenated intermediates is not perturbed by the N139D mutation.

Influence of structure, pH and membrane potential on proton movement in cytochrome oxidase

Cytochrome c oxidase (CcO) reconstituted into phospholipid vesicles and subject to a membrane potential, exhibits different characteristics than the free enzyme, with respect to effects of mutations, pH, inhibitors, and native structural differences between CcO from different species. The results indicate that the membrane potential influences the conformation of CcO and the direction of proton movement in the exit path. The importance of the protein structure above the hemes in proton exit, back leak and respiratory control is discussed.

Membrane potential-controlled inhibition of cytochrome c oxidase by zinc

Like many voltage-sensitive ion pumps, cytochrome c oxidase is inhibited by zinc. Binding of zinc to the outside surface of Rhodobacter sphaeroides cytochrome c oxidase inhibits the enzyme with a K(I) of < or = 5 microm when the enzyme is reconstituted into phospholipid vesicles in the presence of a membrane potential. In the absence of a membrane potential and a pH gradient, millimolar concentrations of zinc are required to inhibit. This differential inhibition causes a dramatic increase in the respiratory control ratio from 6 to 40 for wild-type oxidase. The external zinc inhibition is removed by EDTA and is not competitive with cytochrome c binding but is competitive with protons. Only Cd(2+) of the many metals tested (Mg(2+), Mn(2+), Ca(2+), Ba(2+), Li(2+), Cs(2+), Hg(2+), Ni(2+), Co(2+), Cu(2+) Tb(3+), Tm(3+)) showed inhibitory effects similar to Zn(2+). Proton pumping is slower and less efficient with zinc. The results suggest that zinc inhibits proton movement through a proton exit path, which can allow proton back-leak at high membrane potentials. The physiological and mechanistic significance of proton movement in the exit pathway and its blockage by zinc is discussed in terms of regulation of the efficiency of energy transduction.

Where is 'outside' in cytochrome c oxidase and how and when do protons get there?

Cytochrome c oxidase moves both electrons and protons in its dual role as a terminal electron acceptor and a contributor to the proton motive force which drives the formation of ATP. Although the sequence of electron transfer events is well-defined, the correlated mechanism and routes by which protons are translocated across the membrane are not. A recent model [Michel, Proc. Natl. Acad. Sci. USA 95 (1998) 12819] offers a detailed molecular description of when and how protons are translocated through the protein to the outside, which contrasts with previous models in several respects. This article reviews the behavior of site-directed mutants of Rhodobacter sphaeroides cytochrome c oxidase in the context of these different models. Studies of the internally located lysine 362 on the K channel and aspartate 132 on the D channel, indicate that D132, but not K362, is connected to the exterior region. Analysis of the externally located arginine pair, 481 and 482, and the Mg/Mn ligands, histidine 411 and aspartate 412, which are part of the hydrogen-bonded network that includes the heme propionates, indicates that alterations in this region do not strongly compromise proton pumping, but do influence the pH dependence of overall activity and the control of activity by the pH gradient. The results are suggestive of a region of 'sequestered' protons: beyond a major energetic gate, but selectively responsive to the external environment.

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.

Proton uptake and release in cytochrome c oxidase: separate pathways in time and space?

Analysis of mutant forms of cytochrome c oxidase in conjunction with knowledge from high resolution crystal structures is providing important clues as to the location and specificity of proton channels and the timing of proton movements with respect to electron transfer events. Mutant forms of Rhodobacter sphaeroides cytochrome c oxidase at the highly conserved aspartate 132, in the 'D-channel' and at lysine 362, in the 'K-channel', are compared with respect to the nature of their residual activity and their reactions with H2O2. The results argue for physical separation and specificity in these two proton input routes, due to their distinctive kinetics with peroxide and the apparent connection of the D-channel, but not the K-channel, to the proton exit pathway. The reversible nature and possible location of the exit pathway are discussed in the context of direct and indirect mechanisms of energy coupling.

The generation of proton electrochemical potential gradient by cytochrome c oxidase

Cytochrome c oxidase, the terminal oxidase of mitochondria and some bacteria, catalyzes the four electron reduction of oxygen, and generates a proton electrochemical potential gradient (Delta microH). The recently determined structures of the bacterial and the bovine enzymes, together with studies of site directed mutants of a bacterial cytochrome c oxidase and a closely related ubiquinol oxidase, have greatly advanced our understanding of the mechanism by which oxygen reduction is coupled to the generation of Delta microH. Two different mechanisms contribute to the generation of Delta microH: protons that are consumed by the reduction of oxygen, are taken exclusively from the mitochondrial matrix ('consumed' protons), while other protons are translocated by the enzyme across the membrane ('pumped' protons). It is suggested that both proton consumption and proton pumping are driven by the electrostatic charging of the enzyme reaction center by the reducing electrons. Proton consumption is suggested to result from the electrostatically driven ejection of hydroxyls into the matrix that is catalyzed by a tyrosine residue in the reaction center. Proton pumping is suggested to result from the electrostatically driven translocation of a glutamate residue near the reaction center, and is assisted by secondary acceptors that release the translocated protons.

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 a3, 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.

Identification and characterization of a catalytic base in bacterial luciferase by chemical rescue of a dark mutant

Mutation of the His44 residue of the alpha subunit of Vibrio harveyi luciferase to an alanine was known to reduce the enzyme bioluminescence activity by five orders of magnitude [Xin, X., Xi, L., and Tu, S.-C. (1991) Biochemistry 30, 11255-11262]. We found that the residual activity of the alpha H44A luciferase was markedly enhanced by exogenously added imidazole and other simple amines. The peak luminescence intensity in nonturnover assays was linearly proportional to levels of alpha H44A and the rescue agent, indicating a lack of significant binding under our experimental conditions. The rescue effect of imidazole was pH dependent and quantitatively correlated well with the amount of imidazole base. The rescue efficiencies of imidazole and amines were found to be regulated by both their molecular volume and pKa. A Brønsted analysis revealed a beta value of 0.8 +/- 0.1. The enhancement of alpha H44A activity by imidazole took place after the formation of the flavin 4a-hydroperoxide intermediate. The predominant form of the flavin 4a-hydroperoxide intermediate generated by alpha H44A was inactive in bioluminescence, but was reactive with the aldehyde substrate for bioluminescence in the presence of imidazole. These findings, taken together, provide evidence for assigning a role for the alpha His44 imidazole as a catalytic base in the luciferase reaction. This study provides the first characterization of a catalytic residue for bacterial luciferase and the first demonstration of the rescue of a histidine-mutated enzyme by exogenous imidazole and amines.