ATR-FTIR spectroscopy of the P(M) and F intermediates of bovine and Paracoccus denitrificans cytochrome c oxidase

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

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

Comparison of redox and ligand binding behaviour of yeast and bovine cytochrome c oxidases using FTIR spectroscopy

Redox and CO photolysis FTIR spectra of yeast cytochrome c oxidase WT and mutants are compared to those from bovine and P. denitrificans CcOs in order to establish common functional features. All display changes that can be assigned to their E242 (bovine numbering) equivalent and to weakly H-bonded water molecules. The additional redox-sensitive band reported at 1736 cm⁻¹ in bovine CcO and previously assigned to D51 is absent from yeast CcO and couldn't be restored by introduction of a D residue at the equivalent position of the yeast protein. Redox spectra of yeast CcO also show much smaller changes in the amide I region, which may relate to structural differences in the region around D51 and the subunit I/II interface.

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Redox-induced FTIR difference spectra of WT and mutant yeast CcO are presented.

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Functionally-relevant features are compared with other A1-type haem copper oxidases.

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On oxidoreduction, all show perturbations of bovine residue E242

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Introduction of bovine D51 in yeast doesn't result in an additional IR redox band.

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On photolysis of the FR-CO form all show perturbations of E242 and water molecules

Phenol-Induced O-O Bond Cleavage in a Low-Spin Heme-Peroxo-Copper Complex: Implications for O2 Reduction in Heme-Copper Oxidases

This study evaluates the reaction of a biomimetic heme-peroxo-copper complex, {[(DCHIm)(F8)FeIII]-(O22-)-[CuII(AN)]}+ (1), with a phenolic substrate, involving a net H-atom abstraction to cleave the bridging peroxo O-O bond that produces FeIV═O, CuII-OH, and phenoxyl radical moieties, analogous to the chemistry carried out in heme-copper oxidases (HCOs). A 3D potential energy surface generated for this reaction reveals two possible reaction pathways: one involves nearly complete proton transfer (PT) from the phenol to the peroxo ligand before the barrier; the other involves O-O homolysis, where the phenol remains H-bonding to the peroxo OCu in the transition state (TS) and transfers the H+ after the barrier. In both mechanisms, electron transfer (ET) from phenol occurs after the PT (and after the barrier); therefore, only the interaction with the H+ is involved in lowering the O-O cleavage barrier. The relative barriers depend on covalency (which governs ET from Fe), and therefore vary with DFT functional. However, as these mechanisms differ by the amount of PT at the TS, kinetic isotope experiments were conducted to determine which mechanism is active. It is found that the phenolic proton exhibits a secondary kinetic isotope effect, consistent with the calculations for the H-bonded O-O homolysis mechanism. The consequences of these findings are discussed in relation to O-O cleavage in HCOs, supporting a model in which a peroxo intermediate serves as the active H+ acceptor, and both the H+ and e- required for O-O cleavage derive from the cross-linked Tyr residue present at the active site.

Metal enzymes in "impossible" microorganisms catalyzing the anaerobic oxidation of ammonium and methane

Ammonium and methane are inert molecules and dedicated enzymes are required to break up the N-H and C-H bonds. Until recently, only aerobic microorganisms were known to grow by the oxidation of ammonium or methane. Apart from respiration, oxygen was specifically utilized to activate the inert substrates. The presumed obligatory need for oxygen may have resisted the search for microorganisms that are capable of the anaerobic oxidation of ammonium and of methane. However extremely slowly growing, these "impossible" organisms exist and they found other means to tackle ammonium and methane. Anaerobic ammonium-oxidizing (anammox) bacteria use the oxidative power of nitric oxide (NO) by forging this molecule to ammonium, thereby making hydrazine (N2H4). Nitrite-dependent anaerobic methane oxidizers (N-DAMO) again take advantage of NO, but now apparently disproportionating the compound into dinitrogen and dioxygen gas. This intracellularly produced dioxygen enables N-DAMO bacteria to adopt an aerobic mechanism for methane oxidation.Although our understanding is only emerging how hydrazine synthase and the NO dismutase act, it seems clear that reactions fully rely on metal-based catalyses known from other enzymes. Metal-dependent conversions not only hold for these key enzymes, but for most other reactions in the central catabolic pathways, again supported by well-studied enzymes from model organisms, but adapted to own specific needs. Remarkably, those accessory catabolic enzymes are not unique for anammox bacteria and N-DAMO. Close homologs are found in protein databases where those homologs derive from (partly) known, but in most cases unknown species that together comprise an only poorly comprehended microbial world.

Infrared and Raman spectroscopic investigation of the reaction mechanism of cytochrome c oxidase

Recent progress in studies on the proton-pumping and O₂reduction mechanisms of cytochrome c oxidase (CcO) elucidated by infrared (IR) and resonance Raman (rR) spectroscopy, is reviewed. CcO is the terminal enzyme of the respiratory chain and its O₂reduction reaction is coupled with H⁺ pumping activity across the inner mitochondrial membrane. The former is catalyzed by heme a3 and its mechanism has been determined using a rR technique, while the latter used the protein moiety and has been investigated with an IR technique. The number of H⁺ relative to e⁻ transferred in the reaction is 1:1, and their coupling is presumably performed by heme a and nearby residues. To perform this function, different parts of the protein need to cooperate with each other spontaneously and sequentially. It is the purpose of this article to describe the structural details on the coupling on the basis of the vibrational spectra of certain specified residues and chromophores involved in the reaction. Recent developments in time-resolved IR and Raman technology concomitant with protein manipulation methods have yielded profound insights into such structural changes. In particular, the new IR techniques that yielded the breakthrough are reviewed and assessed in detail. This article is part of a Special Issue entitled: Vibrational spectroscopies and bioenergetic systems.

IR signatures of the metal centres of bovine cytochrome c oxidase: assignments and redox-linkage

Assignments of IR bands of reduced minus oxidized IR difference spectra of bovine and related cytochrome c oxidases are reviewed and their linkages to specific metal centres are assessed. To aid this, redox-poised difference spectra in the presence of cyanide or carbon monoxide are presented. These ligands fix the redox states of either haem a3 alone or haem a3 and CuB respectively, while allowing redox cycling of the remaining centres.

Detection of a protein-bound water vibration of halorhodopsin in aqueous solution

Protein-bound water molecules play crucial roles in their structure and function, but their detection is an experimental challenge, particularly in aqueous solution at room temperature. By applying attenuated total reflection (ATR) Fourier-transform infrared (FTIR) spectroscopy to a light-driven Cl(-) pump pharaonis halorhodopsin (pHR), here we detected an O-H stretching vibration of protein-bound water molecules in the active center. The pHR(Cl(-)) minus pHR(Br(-)) ATR-FTIR spectra show random fluctuation at 3600-3000 cm(-1), frequency window of water vibration, which can be interpreted in terms of dynamical fluctuation of aqueous water at room temperature. On the other hand, we observed a reproducible spectral feature at 3617 (+)/3630 (-) cm(-1) in the pHR(Cl(-)) minus pHR(Br(-)) spectrum, which is absent in the pHR(Cl(-)) minus pHR(Cl(-)) and in the pHR(Br(-)) minus pHR(Br(-)) spectra. The water O-H stretching vibrations of pHR(Cl(-)) and pHR(Br(-)) at 3617 and 3630 cm(-1), respectively, are confirmed by light-induced difference FTIR spectra in isotope water (H2 (18)O) at 77 K. The observed water molecule presumably binds to the active center of pHR, and alter its hydrogen bond during the Cl(-) pumping photocycle.

Assignment of the CO-sensitive carboxyl group in mitochondrial forms of cytochrome c oxidase using yeast mutants

Point mutations of E243D and I67N were introduced into subunit I of a 6histidine-tagged (6H-WT) form of yeast Saccharomyces cerevisiae mitochondrial cytochrome c oxidase. The two mutants (6H-E243D(I) and 6H-I67N(I)) were purified and showed ≈50 and 10% of the 6H-WT turnover number. Light-induced CO photolysis FTIR difference spectra of the 6H-WT showed a peak/trough at 1749/1740cm(-1), as seen in bovine CcO, which downshifted by 7cm(-1) in D(2)O. The bands shifted to 1736/1762cm(-1) in 6H-E243D(I), establishing that the carboxyl group affected by CO binding in mitochondrial CcOs is E243. In 6H-I67N(I), the trough at 1740cm(-1) was shifted to 1743cm(-1) and its accompanying peak intensity was greatly reduced. This confirms that the I67N mutation interferes with conformational alterations around E243. This article is part of a Special Issue entitled: 17th European Bioenergetics Conference (EBEC 2012).

Electronic structure of a low-spin heme/Cu peroxide complex: spin-state and spin-topology contributions to reactivity

This study details the electronic structure of the heme–peroxo–copper adduct {[(F8)Fe(DCHIm)]-O2-[Cu(AN)]}+ (LS(AN)) in which O2(2–) bridges the metals in a μ-1,2 or “end-on” configuration. LS(AN) is generated by addition of coordinating base to the parent complex {[(F8)Fe]-O2-[Cu(AN)]}+ (HS(AN)) in which the O2(2–) bridges the metals in an μ-η2:η2 or “side-on” mode. In addition to the structural change of the O2(2–) bridging geometry, coordination of the base changes the spin state of the heme fragment (from S = 5/2 in HS(AN) to S = 1/2 in LS(AN)) that results in an antiferromagnetically coupled diamagnetic ground state in LS(AN). The strong ligand field of the porphyrin modulates the high-spin to low-spin effect on Fe–peroxo bonding relative to nonheme complexes, which is important in the O–O bond cleavage process. On the basis of DFT calculations, the ground state of LS(AN) is dependent on the Fe–O–O–Cu dihedral angle, wherein acute angles (<~150°) yield an antiferromagnetically coupled electronic structure while more obtuse angles yield a ferromagnetic ground state. LS(AN) is diamagnetic and thus has an antiferromagnetically coupled ground state with a calculated Fe–O–O–Cu dihedral angle of 137°. The nature of the bonding in LS(AN) and the frontier molecular orbitals which lead to this magneto-structural correlation provide insight into possible spin topology contributions to O–O bond cleavage by cytochrome c oxidase.

Water molecule reorganization in cytochrome c oxidase revealed by FTIR spectroscopy

Although internal electron transfer and oxygen reduction chemistry in cytochrome c oxidase are fairly well understood, the associated groups and pathways that couple these processes to gated proton translocation across the membrane remain unclear. Several possible pathways have been identified from crystallographic structural models; these involve hydrophilic residues in combination with structured waters that might reorganize to form transient proton transfer pathways during the catalytic cycle. To date, however, comparisons of atomic structures of different oxidases in different redox or ligation states have not provided a consistent answer as to which pathways are operative or the details of their dynamic changes during catalysis. In order to provide an experimental means to address this issue, FTIR spectroscopy in the 3,560-3,800 cm(-1) range has been used to detect weakly H-bonded water molecules in bovine cytochrome c oxidase that might change during catalysis. Full redox spectra exhibited at least four signals at 3,674(+), 3,638(+), 3,620(-), and 3,607(+) cm(-1). A more complex set of signals was observed in spectra of photolysis of the ferrous-CO compound, a reaction that mimics the catalytic oxygen binding step, and their D(2)O and H(2)(18)O sensitivities confirmed that they arose from water molecule rearrangements. Fitting with Gaussian components indicated the involvement of up to eight waters in the photolysis transition. Similar signals were also observed in photolysis spectra of the ferrous-CO compound of bacterial CcO from Paracoccus denitrificans. Such water changes are discussed in relation to roles in hydrophilic channels and proton/electron coupling mechanism.

Solvent effects on the physicochemical properties of the cross-linked histidine-tyrosine ligand of cytochrome c oxidase

Density functional theory was used to explore the effects of aqueous solvation on the structure, vibrational frequencies, and the electronic absorption spectrum of 2-(4-methylimidazol-1-yl)-phenol (Me-ImPhOH), a chemical analogue of the cross-linked histidine-tyrosine Cu(B) ligand of cytochrome c oxidase. In addition, the phenolic-OH pK(a), the anodic redox potential for the biring radical/anion couple, and the phenolic-OH bond dissociation energy were calculated relative to phenol using a series of isodesmic reactions. In the gas phase, the imidazole moiety stabilizes the biring anion for all the models and greatly decreases the phenolic-OH pK(a) relative to phenol. Moreover, the conductor-like polarizable continuum model (C-PCM)-water-solvated reactions predict Delta pK(a) values that are five times smaller than the gas-phase reactions, in agreement with the proposed role of the cross-linked histidine-tyrosine as a proton donor in the enzyme. For the neutral biring radical solvation models, the imidazole moiety induces a high degree of asymmetry into the phenol ring when compared to unmodified phenoxyl radical. The biring radical pi-bonds of the imidazole ring are more localized when compared to unmodified 1-methylimidazole and Me-ImPhOH solvation models, suggesting reduced aromaticity for all biring radical solvation models. The C-PCM-water-solvated reactions predict relative biring radical reduction potentials that are an order of magnitude smaller than the gas-phase reactions. The biring O-H bond is weakened relative to phenol by less than 4 kcal/mol for all the reactions studied, suggesting that the imidazole moiety does not facilitate H-atom abstraction in the enzyme. Together, these results demonstrate the sensitive nature of the proton and electron donating ability of the histidine-tyrosine cross-linked ligand in cytochrome c oxidase and suggest that for quantitative predictions of reaction energies and thermodynamic properties, models of this ligand should take care to account for changes in environment and, more specifically, hydrogen bonding interactions.

A spectroscopic investigation of a tridentate Cu-complex mimicking the tyrosine-histidine cross-link of cytochrome C oxidase

Heme-copper oxidases have a crucial role in the energy transduction mechanism, catalyzing the reduction of dioxygen to water. The reduction of dioxygen takes place at the binuclear center, which contains heme a3 and CuB. The X-ray crystal structures have revealed that the C6' of tyrosine 244 (bovine heart numbering) is cross-linked to a nitrogen of histidine 240, a ligand to CuB. The role of the cross-linked tyrosine at the active site still remains unclear. In order to provide insight into the function of the cross-linked tyrosine, we have investigated the spectroscopic and electrochemical properties of chemical analogues of the CuB-His-Tyr site. The analogues, a tridentate histidine-phenol cross-linked ether ligand and the corresponding Cu-containing complex, were previously synthesized in our laboratory (White, K.; et al. Chem. Commun. 2007, 3252-3254). Spectrophotometric titrations of the ligand and the Cu-complex indicate a pKa of the phenolic proton of 8.8 and 7.7, respectively. These results are consistent with the cross-linked tyrosine playing a proton delivery role at the cytochrome c oxidase active site. The presence of the phenoxyl radical was investigated at low temperature using electron paramagnetic resonance (EPR) and Fourier transform infrared (FT-IR) difference spectroscopy. UV photolysis of the ligand, without bound copper, generated a narrow g=2.0047 signal, attributed to the phenoxyl radial. EPR spectra recorded before and after UV photolysis of the Cu-complex showed a g=2 signal characteristic of oxidized copper, suggesting that the copper is not spin-coupled to the phenoxyl radical. An EPR signal from the phenoxyl radical was not observed in the Cu-complex, either due to spin relaxation of the two unpaired electrons or to masking of the narrow phenoxyl radical signal by the strong copper contribution. Stable isotope (13C) labeling of the phenol ring (C1') Cu-complex, combined with photoinduced difference FT-IR spectroscopy, revealed bands at 1485 and 1483 cm(-1) in the 12C-minus-13C-isotope-edited spectra of the ligand and Cu-complex, respectively. These bands are attributed to the radical v7a stretching frequency and are shifted to 1468 and 1472 cm(-1), respectively, with 13C1' labeling. These results show that a radical is generated in both the ligand and the Cu-complex and support the unambiguous assignment of a vibrational band to the phenoxyl radical v7a stretching mode. These data are discussed with respect to a possible role of the cross-linked tyrosine radical in cytochrome c oxidase.

Effects of Cu(2+) and Pb(2+) on different fish species: liver cytochrome P450-dependent monooxygenase activities and FTIR spectra

The effects of Cu(2+)-sulfate and Pb(2+)-acetate on carp (Cyprinus carpio L.), silver carp (Hypopthalmichtys molitrix V.) and wels (Silurus glanis L.) were studied. The liver microsomal Cyt P450 content, the EROD, ECOD and APND monooxygenase activities were measured. In vivo treatment with 1 mg L(-1) Cu(2+) significantly elevated the activities of these enzymes and Cyt P450 content in silver carp livers. The high-dose Cu(2+) treatment (10 mg L(-1)) on silver carp caused two-fold higher induction in the P450 dependent monooxygenase isoensymes than in wels. Although the 2 mg kg(-1) treatment with Pb(2+) in carp elevated significantly the P450 content, the EROD isoenzyme activities were significantly decreased after 1 day, showing the destructive effect of metal ion on the enzyme system. In vitro, Cu(2+) and Pb(2+) decreased the Cyt P450 content in the carp liver microsomes and the absorption peak shifted to higher wavelength. Fourier Transform Infrared (FTIR) spectroscopy was used to detect the damaging effects of the heavy metals. According to the inhibitory potency to Cu(2+), the most sensitive isoenzyme was the EROD in wels, the least was the silver carp's isoenzyme. The investigated fish P450 isoenzymes showed, that the Cu(2+) was a stronger inhibitor than Pb(2+).

Carboxyl group functions in the heme-copper oxidases: information from mid-IR vibrational spectroscopy

Carboxyl groups of possible functional importance in bovine and bacterial cytochrome c oxidases (CcO) are reviewed and assessed. A critical analysis is presented of available mid-infrared vibrational data that pertain to these functional carboxyl groups. These data and their interpretations are discussed in relation to current models of the mechanism of proton and electron coupling in the protonmotive CcO superfamily.

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.

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.

Thermodynamic and spectroscopic studies on the nickel arachidate-RNA polymerase Langmuir-Blodgett monolayer

The Langmuir-Blodgett (LB) monolayers offer a unique system to study molecular interaction at the air-water interface with reduced dimensionality. In order to develop this further to follow macromolecular interactions at equilibrium, we first characterized the Ni (II)-arachidate (NiA) monolayer at varying conditions. Subsequently, the interaction between NiA and histidine-tagged RNA polymerase (HisRNAP) were also studied. LB films of arachidic acid-NiA and NiA-RNAP with different mole fractions were fabricated systematically. Surface pressure versus area per molecule (P-A) isotherms were registered, and the excess Gibbs energy of mixing was calculated. The LB films were then deposited on solid supports for Fourier transform infrared (FTIR) spectroscopic measurements. The FTIR spectra revealed the change in the amount of incorporated Ni (II) ions into the arachidic acid monolayer with the change in pH and the increasing mole fraction of RNAP in the NiA monolayer with its increasing concentration in the subphase. The system developed here seems to be robust and can be utilized to follow macromolecular interactions.

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.

Methods to probe protein transitions with ATR infrared spectroscopy

We describe techniques that can be used in conjunction with modern attenuated total reflection (ATR) infrared micro-prisms to allow proteins to be manipulated cyclically between different states whilst simultaneously monitoring both mid-IR and UV/visible/near IR changes. These methods provide increased flexibility of the types of changes that can be induced in proteins in comparison to transmission methods. Quantitative measurements can be made of vibrational changes associated with conversion between stable catalytic reaction intermediates, ligand binding and oxidation-reduction. Both hydrophobic and soluble proteins can be analysed and the ability to induce transitions repetitively allows IR difference spectra to be acquired at a signal/noise sufficient to resolve changes due to specific cofactors or amino acids. Such spectra can often be interpreted at the atomic level by standard IR methods of comparisons with model compounds, by isotope and mutation effects and, increasingly, by ab initio simulations. Combination of such analyses with atomic 3D structural models derived from X-ray and NMR studies can lead to a deeper understanding of molecular mechanisms of enzymatic reactions.

Replacing Asn207 by aspartate at the neck of the D channel in the aa3-type cytochrome c oxidase from Rhodobacter sphaeroides results in decoupling the proton pump

Cytochrome oxidase catalyzes the reduction of O2 to water and conserves the considerable free energy available from this reaction in the form of a proton motive force. For each electron, one proton is electrogenically pumped across the membrane. Of particular interest is the mechanism by which the proton pump operates. Previous studies of the oxidase from Rhodobacter sphaeroides have shown that all of the pumped protons enter the enzyme through the D channel and that a point mutant, N139D, in the D channel completely eliminates proton pumping without reducing oxidase activity. N139 is one of three asparagines near the entrance of the D channel, where there is a narrowing or neck, through which a single file of water molecules pass. In the current work, it is shown that replacement of a second asparagine in this region by an asparate, N207D, also decouples the proton pump without altering the oxidase activity of the enzyme. Previous studies demonstrated that the N139D mutant results in an increase in the apparent pKa of E286, a functionally critical residue that is located 20 A away from N139 at the opposite end of the D channel. In the current work, it is shown that the N207 mutation also increases the apparent pKa of E286. This finding reinforces the proposal that the elimination of proton pumping is the result of an increase of the apparent proton affinity of E286, which, in turn, prevents the timely proton transfer to a proton accepter group within the exit channel of the proton pump.

Mutations which decouple the proton pump of the cytochrome c oxidase from Rhodobacter sphaeroides perturb the environment of glutamate 286

Mutants that decouple the proton pump of cytochrome c oxidase from Rhodobacter sphaeroides are postulated to do so by increasing the pK(a) of glutamate 286, which is 20 Angstrom away. The possibility that a conformational change near E286 is induced by the decoupling mutations (N139D and N207D) was investigated by FTIR difference spectroscopy. In both decoupled mutants, the reduced-minus-oxidized FTIR difference spectra show a shift of 2 cm(-1) to lower frequency of the band resulting from the absorbance of E286 in the oxidized enzyme. The decoupling mutants may influence E286 by altering the chain of water molecules which runs from the site of the mutations to E286.

Detection of toxic effects of Cd2+ on different fish species via liver cytochrome P450-dependent monooxygenase activities and FTIR spectroscopy

The in vivo and in vitro effects of Cd2+ and the CYP1A inductor beta-naphthoflavone(beta-NF) on the hepatic cytochrome P450 (Cyt 450) monooxygenases were studied in silver carp (Hypophthalmichtys molitrix V.), wels (Silurus glanis L.), and carp (Cyprinus carpio). In vivo treatment of carp with a high dose of Cd2+ (10 mg kg(-1), for 3 days) caused a strong inhibition of 7-ethoxyresorufin-O-deethylase (EROD) and a lower inhibition of 7-ethoxycoumarin-O-deethylase (ECOD) activity. The low-dose cadmium treatment (2 mg kg(-1) Cd2+, for 6+3 days) resulted in 4-fold increase in EROD and a 3-fold increase in ECOD activity. The combined treatment with Cd2+ and beta-NF in both cases led to a loss of EROD inducibility. The silver carp and wels were treated with 10 mg L(-1) Cd2+ for 72 h in water. The Cyt P450 content in the wels liver microsomes was increased significantly after treatment for 48 h, whereas there was only a slight, not significant increase in Cyt P450 content in the silver carp microsomes. While the Cd2+ treatment resulted in inhibition of the CYP1A isoenzymes (EROD and ECOD), the APND (aminopyrene-N-demethylase, CYP2B or CYP3A isoenzyme) activity was increased 3- to 4-fold in both fish species. In vitro experiments of the effect of Cd2+ led to a concentration-dependent inhibition in all three investigated fish species. The ECOD isoenzyme of silver carp was the most sensitive to Cd2+. The lowest concentration of Cd2+ resulted in 50% inhibition. The APND isoenzyme was similarly sensitive to Cd2+ in all three investigated fish species. The most sensitive species was the wels, and the least sensitive were the carp isoenzyme. FTIR spectroscopy confirmed that cadmium caused damage to the protein structure. These results support the enzyme activity measurements measured in vivo and in vitro.

A tyrosine residue deprotonates during oxygen reduction by thecaa3 reductase fromRhodothermus marinus

Heme-copper oxygen reductases catalyze proton translocation across the cellular membrane; this takes place during the reaction of oxygen to water. We demonstrate with attenuated total reflection-Fourier transform infrared (ATR-FTIR) difference spectroscopy that a tyrosine residue of the oxygen reductase from the thermohalophilic Rhodothermus marinus becomes deprotonated in the transition from the oxidized state to the catalytic intermediate ferryl state P(M). This tyrosine residue is most probably Y256, the helix VI tyrosine residue proposed to substitute for the D-channel glutamic acid that is absent in this enzyme. Comparison with the mitochondrial like oxygen reductase from Rhodobacter sphaeroides suggests that proton transfer from a strategically situated donor to the active site is a crucial step in the reaction mechanism of oxygen reductases.

Controlled uncoupling and recoupling of proton pumping in cytochrome c oxidase

Cytochrome c oxidase (CcO) is the terminal enzyme of the respiratory chain and couples energetically the reduction of oxygen to water to proton pumping across the membrane. The results from previous studies showed that proton pumping can be uncoupled from the O2-reduction reaction by replacement of one single residue, Asn-139 by Asp (N139D), located approximately 30 A from the catalytic site, in the D-proton pathway. The uncoupling was correlated with an increase in the pK(a) of an internal proton donor, Glu-286, from approximately 9.4 to >11. Here, we show that replacement of the acidic residue, Asp-132 by Asn in the N139D CcO (D132N/N139D double-mutant CcO) results in restoration of the Glu-286 pK(a) to the original value and recoupling of the proton pump during steady-state turnover. Furthermore, a kinetic investigation of the specific reaction steps in the D132N/N139D double-mutant CcO showed that proton pumping is sustained even if proton uptake from solution, through the D-pathway, is slowed. However, during single-turnover oxidation of the fully reduced CcO the P --> F transition, which does not involve electron transfer to the catalytic site, was not coupled to proton pumping. The results provide insights into the mechanism of proton pumping by CcO and the structural elements involved in this process.

Structural Character and Energetics of Tyrosyl Radical Formation by Electron/Proton Transfers of a Covalently Linked Histidine-Tyrosine: A Model for Cytochrome c Oxidase

The structural, energetic, and electronic and IR spectroscopic properties for a model of the cross-linked histidine-tyrosine (His-Tyr) residues as found in cytochrome c oxidase (CcO) are investigated by ab initio methods. The formation of a His-Tyr radical is studied by two paths: proton release followed by electron release and vice versa. The energetics for the proton/electron releases of the Tyr depend modestly on the cross-linked His substituent and, more sensitively, on the charge of the cation attached to the imino N site of the His residue. Protonation of the imino N site significantly increases the electron ionization potential and decreases the proton dissociation energy, making them competitive processes. A positive charge placed at the imino N site, whose value is scanned from zero to one, shows a continuous increase in ionization potential and a decrease in proton dissociation energy, with the +1 limit agreeing well with the protonated imino N site result, indicating a dominant electrostatic effect. The charge populations and the spin density distributions of the His-Tyr model, the radical cation formed by electron ionization, the anion formed by proton dissociation, and the final His-Tyr radical depend sensitively on the substituents, implying a modulation role on the charge transfer between the phenol and imidazole rings, especially for the charged species. His-Tyr and protonated His-Tyr exhibit differences among their respective structural isomers with consequences on their IR absorptions. Small barriers between their pseudo-cis and pseudo-trans rotamers demonstrate the relative flexibility between the two rings, and these may facilitate proton release and charge transfer. The cation effect demonstrates that the cationized cross-linked His-Tyr should be the best candidate to mimic the covalently ring-linked histidine-tyrosine structure in CcO.

Redox-induced Protein Structural Changes in Cytochrome bo Revealed by Fourier Transform Infrared Spectroscopy and [13C]Tyr Labeling

Cytochrome bo is a heme-copper terminal ubiquinol oxidase of Escherichia coli under highly aerated growth conditions. Tyr-288 present at the end of the K-channel forms a Cepsilon-Nepsilon covalent bond with one of the Cu(B) ligand histidines and has been proposed to be an acid-base catalyst essential for the O-O bond cleavage at the Oxy-to-P transition of the dioxygen reduction cycle (Uchida, T., Mogi, T., and Kitagawa, T. (2000) Biochemistry 39, 6669-6678). To probe structural changes at tyrosine residues, we examined redox difference Fourier transform infrared difference spectra of the wild-type enzyme in which either L-[1-13C]Tyr or L-[4-13C]Tyr has been biosynthetically incorporated in the tyrosine auxotroph. Spectral comparison between [1-13C]Tyr-labeled and unlabeled proteins indicated that substitution of the main chain carbonyl of a Tyr residue(s) significantly affected changes in the amide-I (approximately 1620-1680 cm(-1)) and -II ( approximately 1540-1560 cm(-1)) regions. In contrast, spectral comparison between [4-13C]Tyr-labeled and unlabeled proteins showed only negligible changes, which was the case for both the pulsed and the resting forms. Thus, protonation of an OH group of tyrosines including Tyr-288 in the vicinity of the heme o-Cu(B) binuclear center was not detected at pH 7.4 upon full reduction of cytochrome bo. Redox-induced main chain changes at a Tyr residue(s) are associated with structural changes at Glu-286 near the binuclear metal centers and may be related to switching of the K-channel operative at the reductive phase to D-channel at the oxidative phase of the dioxygen reduction cycle via conformational changes in the middle of helix VI.

Probing the Q-proton pathway of ba3-cytochrome c oxidase by time-resolved Fourier transform infrared spectroscopy

In cytochrome c oxidase, the terminal respiratory enzyme, electron transfers are strongly coupled to proton movements within the enzyme. Two proton pathways (K and D) containing water molecules and hydrophobic amino acids have been identified and suggested to be involved in the proton translocation from the mitochondrial matrix or the bacterial cytoplasm into the active site. In addition to the K and D proton pathways, a third proton pathway (Q) has been identified only in ba3-cytochrome c oxidase from Thermus thermophilus, and consists of residues that are highly conserved in all structurally known heme-copper oxidases. The Q pathway starts from the cytoplasmic side of the membrane and leads through the axial heme a3 ligand His-384 to the propionate of the heme a3 pyrrol ring A, and then via Asn-366 and Asp-372 to the water pool. We have applied FTIR and time-resolved step-scan Fourier transform infrared (TRS2-FTIR) spectroscopies to investigate the protonation/deprotonation events in the Q-proton pathway at ambient temperature. The photolysis of CO from heme a3 and its transient binding to CuB is dynamically linked to structural changes that can be tentatively attributed to ring A propionate of heme a3 (1695/1708 cm(-1)) and to deprotonation of Asp-372 (1726 cm(-1)). The implications of these results with respect to the role of the ring A propionate of heme a3-Asp372-H2O site as a proton carrier to the exit/output proton channel (H2O pool) that is conserved among all structurally known heme-copper oxidases, and is part of the Q-proton pathway in ba3-cytochrome c oxidase, are discussed.

Role of Tyr-288 at the dioxygen reduction site of cytochrome bo studied by stable isotope labeling and resonance raman spectroscopy

To explore the role of a cross-link between side chains of Tyr-288 and His-284 at the heme-copper binuclear center, we prepared cytochrome bo where d(4)-Tyr, 1-[(13)C]Tyr, or 4-[(13)C]Tyr has been biosynthetically incorporated. Unexpectedly, the d(4)-Tyr-labeled enzyme showed a large decrease in the ubiquinol-1 oxidase and CO binding activities. Optical absorption and resonance Raman spectra identified the defect in the distal side of the heme-copper binuclear center. In the CO-bound d(4)-Tyr-labeled enzyme, a large fraction of the nu((Fe-C)) mode was shifted from the normal 520-cm(-1) band to a broad band centered around 491 cm(-1), as found for the Y288F mutant. Our results suggested that the substitution of ring hydrogens of Tyr-288 with deuteriums slows down the formation of the His-Tyr cross-link essential for dioxygen reduction at the binuclear center.

Direct measurement of proton release by cytochrome c oxidase in solution during the F-->O transition

The mechanism by which electron transfer is coupled to proton pumping in cytochrome c oxidase is a major unsolved problem in molecular bioenergetics. In this work it is shown that, at least under some conditions, proton release from the enzyme occurs before proton uptake upon electron transfer to the heme/Cu active site of the enzyme. This sequence is similar to that of proton release and uptake observed for the light-activated proton pump bacteriorhodopsin. In the case of cytochrome c oxidase, this observation means that both the ejected proton and the proton required for the chemistry at the enzyme active site must come from an internal proton pool.

Structural elements involved in electron-coupled proton transfer in cytochrome c oxidase

Haem-copper oxidases are the last components of the respiratory chains in aerobic organisms. These membrane-bound enzymes energetically couple the electron transfer (eT) reactions associated with reduction of dioxygen to water, to proton pumping across the membrane. Even though the mechanism of proton pumping at the molecular level still remains to be uncovered, recent progress has presented us with the structural features of the pumping machinery and detailed information about the eT and proton-transfer reactions associated with the pumping process.