Interaction of bd-type quinol oxidase from Escherichia coli and carbon monoxide: Heme d binds CO with high affinity

Comparative studies on the interaction of the membrane-bound and detergent-solubilized forms of the enzyme in the fully reduced state with carbon monoxide at room temperature have been carried out. CO brings about a bathochromic shift of the heme d band with a maximum at 644 nm and a minimum at 624 nm, and a peak at 540 nm. In the Soret band, CO binding to cytochrome bd results in absorption decrease and minima at 430 and 445 nm. Absorption perturbations in the Soret band and at 540 nm occur in parallel with the changes at 630 nm and reach saturation at 3-5 microM CO. The peak at 540 nm is probably either beta-band of the heme d-CO complex or part of its split alpha-band. In both forms of cytochrome bd, CO reacts predominantly with heme d. Addition of high CO concentrations to the solubilized cytochrome bd results in additional spectral changes in the gamma-band attributable to the reaction of the ligand with 10-15% of low-spin heme b558. High-spin heme b595 does not bind CO even at high concentrations of the ligand. The apparent dissociation constant values for the heme d-CO complex of the membrane-bound and detergent-solubilized forms of the fully reduced enzyme are about 70 and 80 nM, respectively.     

Electrogenic reactions of cytochrome bd

Cytochrome bd is one of the two terminal quinol oxidases in the respiratory chain of Escherichia coli. The enzyme catalyzes charge separation across the bacterial membrane during the oxidation of quinols by dioxygen but does not pump protons. In this work, the reaction of cytochrome bd with O(2) and related reactions has been studied by time-resolved spectrophotometric and electrometric methods. Oxidation of the fully reduced enzyme by oxygen is accompanied by rapid generation of membrane potential (delta psi, negative inside the vesicles) that can be described by a two-step sequence of (i) an initial oxygen concentration-dependent, electrically silent, process (lag phase) corresponding to the formation of a ferrous oxy compound of heme d and (ii) a subsequent monoexponential electrogenic phase with a time constant <60 mus that matches the formation of ferryl-oxo heme d, the product of the reaction of O(2) with the 3-electron reduced enzyme. No evidence for generation of an intermediate analogous to the "peroxy" species of heme-copper oxidases could be obtained in either electrometric or spectrophotometric measurements of cytochrome bd oxidation or in a spectrophotometric study of the reaction of H(2)O(2) with the oxidized enzyme. Backflow of electrons upon flash photolysis of the singly reduced CO complex of cytochrome bd leads to transient generation of a delta psi of the opposite polarity (positive inside the vesicles) concurrent with electron flow from heme d to heme b(558) and backward. The amplitude of the delta psi produced by the backflow process, when normalized to the reaction yield, is close to that observed in the direct reaction during the reaction of fully reduced cytochrome bd with O(2) and is apparently associated with full transmembrane translocation of approximately one charge.     

Discovery of the true peroxy intermediate in the catalytic cycle of terminal oxidases by real-time measurement

The sequence of the catalytic intermediates in the reaction of cytochrome bd terminal oxidases from Escherichia coli and Azotobacter vinelandii with oxygen was monitored in real time by absorption spectroscopy and electrometry. The initial binding of O(2) to the fully reduced enzyme is followed by the fast (5 micros) conversion of the oxy complex to a novel, previously unresolved intermediate. In this transition, low spin heme b(558) remains reduced while high spin heme b(595) is oxidized with formation of a new heme d-oxygen species with an absorption maximum at 635 nm. Reduction of O(2) by two electrons is sufficient to produce (hydro)peroxide bound to ferric heme d. In this case, the O-O bond is left intact and the newly detected intermediate must be a peroxy complex of heme d (Fe (3+)(d)-O-O-(H)) corresponding to compound 0 in peroxidases. The alternative scenario where the O-O bond is broken as in the P(M) intermediate of heme-copper oxidases and compound I of peroxidases is not very likely, because it would require oxidation of a nearby amino acid residue or the porphyrin ring that is energetically unfavorable in the presence of the reduced heme b(558) in the proximity of the catalytic center. The formation of the peroxy intermediate is not coupled to membrane potential generation, indicating that hemes d and b(595) are located at the same depth of the membrane dielectric. The lifetime of the new intermediate is 47 micros; it decays into oxoferryl species due to oxidation of low spin heme b(558) that is linked to significant charge translocation across the membrane.     

Interactions between heme d and heme b595 in quinol oxidase bd from Escherichia coli: a photoselection study using femtosecond spectroscopy

Femtosecond spectroscopy was performed on CO-liganded (fully reduced and mixed-valence states) and O(2)-liganded quinol oxidase bd from Escherichia coli. Substantial polarization effects, unprecedented for optical studies of heme proteins, were observed in the CO photodissociation spectra, implying interactions between heme d (the chlorin ligand binding site) and the close-lying heme b(595) on the picosecond time scale; this general result is fully consistent with previous work [Vos, M. H., Borisov, V. B., Liebl, U., Martin, J.-L., and Konstantinov, A. A. (2000) Proc. Natl. Acad. Sci. U.S.A. 97, 1554-1559]. Analysis of the data obtained under isotropic and anisotropic polarization conditions and additional flash photolysis nanosecond experiments on a mutant of cytochrome bd mostly lacking heme b(595) allow to attribute the features in the well-known but unusual CO dissociation spectrum of cytochrome bd to individual heme d and heme b(595) transitions. This renders it possible to compare the spectra of CO dissociation from reduced and mixed-valence cytochrome bd under static conditions and on a picosecond time scale in much more detail than previously possible. CO binding/dissociation from heme d is shown to perturb ferrous heme b(595), causing induction/loss of an absorption band centered at 435 nm. In addition, the CO photodissociation-induced absorption changes at 50 ps reveal a bathochromic shift of ferrous heme b(595) relative to the static spectrum. No evidence for transient binding of CO to heme b(595) after dissociation from heme d is found in the picosecond time range. The yield of CO photodissociation from heme d on a time scale of < 15 ps is found to be diminished more than 3-fold when heme b(595) is oxidized rather than reduced. In contrast to other known heme proteins, molecular oxygen cannot be photodissociated from the mixed-valence cytochrome bd at all, indicating a unique structural and electronic configuration of the diheme active site in the enzyme.     

Interaction of cytochrome bd with carbon monoxide at low and room temperatures: evidence that only a small fraction of heme b595 reacts with CO

Azotobacter vinelandii is an obligately aerobic bacterium in which aerotolerant dinitrogen fixation requires cytochrome bd. This oxidase comprises two polypeptide subunits and three hemes, but no copper, and has been studied extensively. However, there remain apparently conflicting reports on the reactivity of the high spin heme b(595) with ligands. Using purified cytochrome bd, we show that absorption changes induced by CO photodissociation from the fully reduced cytochrome bd at low temperatures demonstrate binding of the ligand with heme b(595). However, the magnitude of these changes corresponds to the reaction with CO of only about 5% of the heme. CO binding with a minor fraction of heme b(595) is also revealed at room temperature by time-resolved studies of CO recombination. The data resolve the apparent discrepancies between conclusions drawn from room and low temperature spectroscopic studies of the CO reaction with cytochrome bd. The results are consistent with the proposal that hemes b(595) and d form a diheme oxygen-reducing center with a binding capacity for a single exogenous ligand molecule that partitions between the hemes d and b(595) in accordance with their intrinsic affinities for the ligand. In this model, the affinity of heme b(595) for CO is about 20-fold lower than that of heme d.     

Glutamate 107 in subunit I of cytochrome bd from Escherichia coli is part of a transmembrane intraprotein pathway conducting protons from the cytoplasm to the heme b595/heme d active site

Cytochrome bd is a terminal quinol:O 2 oxidoreductase of the respiratory chain of Escherichia coli. The enzyme generates protonmotive force without proton pumping and contains three hemes, b 558, b 595, and d. A highly conserved glutamic acid residue of transmembrane helix III in subunit I, E107, was suggested to be part of a transmembrane pathway delivering protons from the cytoplasm to the oxygen-reducing site. When E107 is replaced with leucine, the hemes are retained but the ubiquinol-1-oxidase activity is lost. We compared wild-type and E107L mutant enzymes during single turnover using absorption and electrometric techniques with a microsecond time resolution. Both wild-type and E107L mutant cytochromes bd in the fully reduced state bind O 2 rapidly, but the formation of the oxoferryl species in the mutant is dramatically retarded as compared to the wild type. Intraprotein electron redistribution induced by the photolysis of CO bound to ferrous heme d in the one-electron-reduced wild-type enzyme is coupled to the membrane potential generation, whereas the mutant cytochrome bd shows no such potential generation. The E107L mutation also causes decrease of midpoint redox potentials of hemes b 595 and d by 25-30 mV and heme b 558 by approximately 70 mV. There are two protonatable groups redox-linked to hemes b 595 and d in the active site, one of which has been recently identified as E445, whereas the second group remains unknown. Here we propose that E107 is either the second group or a key residue of a proposed proton delivery pathway leading from the cytoplasm toward this second group.     

Oxygenated complex of cytochrome bd from Escherichia coli: stability and photolability

Cytochrome bd is one of the two terminal ubiquinol oxidases in the respiratory chain of Escherichia coli catalyzing reduction of O2 to H2O. The enzyme is expressed under low oxygen tension; due to high affinity for O2 it is isolated mainly as a stable oxygenated complex. Direct measurement of O2 binding to heme d in the one-electron reduced isolated enzyme gives K(d(O2)) of approximately 280 nM. It is possible to photolyse the heme d oxy-complex by illumination of the enzyme for several minutes under microaerobic conditions; the light-induced difference absorption spectrum is virtually identical to the inverted spectrum of O2 binding to heme d.     

Oxoferryl-porphyrin radical catalytic intermediate in cytochrome bd oxidases protects cells from formation of reactive oxygen species

The quinol-linked cytochrome bd oxidases are terminal oxidases in respiration. These oxidases harbor a low spin heme b(558) that donates electrons to a binuclear heme b(595)/heme d center. The reaction with O(2) and subsequent catalytic steps of the Escherichia coli cytochrome bd-I oxidase were investigated by means of ultra-fast freeze-quench trapping followed by EPR and UV-visible spectroscopy. After the initial binding of O(2), the O-O bond is heterolytically cleaved to yield a kinetically competent heme d oxoferryl porphyrin π-cation radical intermediate (compound I) magnetically interacting with heme b(595). Compound I accumulates to 0.75-0.85 per enzyme in agreement with its much higher rate of formation (~20,000 s(-1)) compared with its rate of decay (~1,900 s(-1)). Compound I is next converted to a short lived heme d oxoferryl intermediate (compound II) in a phase kinetically matched to the oxidation of heme b(558) before completion of the reaction. The results indicate that cytochrome bd oxidases like the heme-copper oxidases break the O-O bond in a single four-electron transfer without a peroxide intermediate. However, in cytochrome bd oxidases, the fourth electron is donated by the porphyrin moiety rather than by a nearby amino acid. The production of reactive oxygen species by the cytochrome bd oxidase was below the detection level of 1 per 1000 turnovers. We propose that the two classes of terminal oxidases have mechanistically converged to enzymes in which the O-O bond is broken in a single four-electron transfer reaction to safeguard the cell from the formation of reactive oxygen species.     

Redox control of fast ligand dissociation from Escherichia coli cytochrome bd

Bacterial bd-type quinol oxidases, such as cytochrome bd from Escherichia coli, contain three hemes, but no copper. In contrast to heme-copper oxidases and similarly to globins, single electron-reduced cytochrome bd forms stable complexes with O(2), NO and CO at ferrous heme d. Kinetics of ligand dissociation from heme d(2+) in the single electron- and fully-reduced cytochrome bd from E. coli has been investigated by rapid mixing spectrophotometry at 20 degrees C. Data show that (i) O(2) dissociates at 78 s(-1), (ii) NO and CO dissociation is fast as compared to heme-copper oxidases and (iii) dissociation in the single electron-reduced state is hindered as compared to the fully-reduced enzyme. Presumably, rapid ligand dissociation requires reduced heme b(595). As NO, an inhibitor of respiratory oxidases, is involved in the immune response against microbial infection, the rapid dissociation of NO from cytochrome bd may have important bearings on the patho-physiology of enterobacteria.     

Catalytic intermediates of cytochrome bd terminal oxidase at steady-state: ferryl and oxy-ferrous species dominate

The cytochrome bd ubiquinol oxidase from Escherichia coli couples the exergonic two-electron oxidation of ubiquinol and four-electron reduction of O(2) to 2H(2)O to proton motive force generation by transmembrane charge separation. The oxidase contains two b-type hemes (b(558) and b(595)) and one heme d, where O(2) is captured and converted to water through sequential formation of a few intermediates. The spectral features of the isolated cytochrome bd at steady-state have been examined by stopped-flow multiwavelength absorption spectroscopy. Under turnover conditions, sustained by O(2) and dithiothreitol (DTT)-reduced ubiquinone, the ferryl and oxy-ferrous species are the mostly populated catalytic intermediates, with a residual minor fraction of the enzyme containing ferric heme d and possibly one electron on heme b(558). These findings are unprecedented and differ from those obtained with mammalian cytochrome c oxidase, in which the oxygen intermediates were not found to be populated at detectable levels under similar conditions [M.G. Mason, P. Nicholls, C.E. Cooper, The steady-state mechanism of cytochrome c oxidase: redox interactions between metal centres, Biochem. J. 422 (2009) 237-246]. The data on cytochrome bd are consistent with the observation that the purified enzyme has the heme d mainly in stable oxy-ferrous and ferryl states. The results are here discussed in the light of previously proposed models of the catalytic cycle of cytochrome bd.     

Interaction of the bacterial terminal oxidase cytochrome bd with nitric oxide

Cytochrome bd is a prokaryotic terminal oxidase catalyzing O2 reduction to H2O. The oxygen-reducing site has been proposed to contain two hemes, d and b595, the latter presumably replacing functionally CuB of heme-copper oxidases. We show that NO, in competition with O2, rapidly and potently (Ki = 100 +/- 34 nM at approximately 70 microM O2) inhibits cytochrome bd isolated from Escherichia coli and Azotobacter vinelandii in turnover, inhibition being quickly and fully reverted upon NO depletion. Under anaerobic reducing conditions, neither of the two enzymes reveals NO reductase activity, which is proposed to be associated with CuB in heme-copper oxidases.     

Cloning and mutagenesis of genes encoding the cytochrome bd terminal oxidase complex in Azotobacter vinelandii: mutants deficient in the cytochrome d complex are unable to fix nitrogen in air.

The genome of Azotobacter vinelandii contains DNA sequences homologous to the structural genes for the Escherichia coli cytochrome bd terminal oxidase complex. Two recombinant clones bearing cydA- and cydB-like sequence were isolated from an A. vinelandii gene library and subcloned into the plasmid vector pACYC184. Physical mapping demonstrated that the cydA- and cydB-like regions in A. vinelandii are contiguous. The cydAB and flanking DNA was mutagenized by the insertion of Tn5-B20. Mutations in the cydB-hybridizing region resulted in the loss of spectral features associated with cytochromes b595 and d. A new locus, cydB, encoding cytochromes b595 and d in A. vinelandii is proposed. A second region adjacent to cydB was also involved in expression of the cytochrome bd complex in A. vinelandii, since mutations in this region resulted in an increase in the levels of both cytochrome b595 and cytochrome d. The regions involved in expression of the cytochrome bd complex and cydB are transcribed in the same direction. Mutants deficient in cytochromes b595 and d were unable to grow on N-deficient medium when incubated in air but could fix nitrogen when the environmental O2 concentration was reduced to 1.5% (vol/vol). It is proposed that the branch of the respiratory chain terminated by the cytochrome bd complex supports the high respiration rates required for the respiratory protection of nitrogenase.     

Purification and characterization of the cytochrome bd complex from Azotobacter vinelandii: comparison to the complex from Escherichia coli.

Partial purification of a cytochrome bd complex from Azotobacter vinelandii grown under high aeration was achieved by isolating respiratory particles enriched in this hemoprotein via differential centrifugation and detergent extraction. The cytochrome bd complex was subsequently solubilized from the inner membrane with dodecyl maltoside and purified to near homogeneity via DEAE-Sepharose chromatography. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis indicated that the complex consisted of two subunits, with sizes in good agreement with those predicted from the cloned cyd locus (59.7 and 42 kDa). Spectral analysis of the purified complex indicated that the heme components present were cytochromes b560, b595, and d; CO difference spectral studies identified cytochrome d as a CO-reactive component. The complex had a Km for ubiquinol-1 approximately seven times larger than that for the analogous bd complex from Escherichia coli, and O2 consumption curves revealed a Km value for O2 three times greater than that which we determined for the E. coli bd complex.     

A role for the protein in internal electron transfer to the catalytic center of cytochrome c oxidase

Internal electron transfer (ET) to heme a(3) during anaerobic reduction of oxidized bovine heart cytochrome c oxidase (CcO) was studied under conditions where heme a and Cu(A) were fully reduced by excess hexaamineruthenium. The data show that ET to heme a(3) is controlled by the state of ionization of a single protolytic residue with a pK(a) of 6.5 +/- 0.2. On the basis of the view that ET to the catalytic site is limited by coupled proton transfer, this pK(a) was attributed to Glu60 which is located at the entrance of the proton-conducting K channel on the matrix side of CcO. It is proposed that Glu60 controls proton entry into the channel. However, even with this channel open, there is the second factor that regulates ET, and this is ascribed to the rate of proton diffusion in the channel. In addition, it is concluded that proton transfer in the K channel is reversibly inhibited by the detergent Triton X-100. It is also found that the rate of ET to heme a(3) in the as-isolated resting enzyme and in CcO "activated" by reaction of fully reduced enzyme with O(2) is the same, implying that the catalytic sites of these two forms of oxidized enzyme are essentially identical.     

The oxygenated complexes of the two catalytically active oxidation-reduction states of L-tryptophan-2,3-dioxygenase.

The oxygenated complexes of the two catalytically active forms of pseudomonad and rat liver L-tryptophan-2,3-dioxygenase (EC 1.13.11.11) have been studied. As was previously reported (ISHIMURA, Y., NORZAKI, M., HAYAISHI, O., TAMURA, M., AND YAMAZAK-I I. (1970) J. Biol. Chem. 245, 3593-3602), we observe that the fully reduced form of pseudomonad tryptophan oxygenase during steady state catalysis exists predominantly as the L-tryptophan ferroheme-O2 enzyme complex (lambdamax = 415 nm, 540 nm, 570 nm). However, during steady state catalysis by a half-reduced form of both the pseudomonad and hepatic enzymes, the predominant species present manifest absorption spectra indicative of ternary complexes in which all the heme exists as ferriheme (Soret, 407 nm), there being no trace of a ferroheme-O2 complex. Carbon monoxide is a competitive inhibitor with respect to molecular oxygen of catalysis by either the half-reduced or fully reduced forms of pseudomonad tryptophan oxygenase. During steady state catalysis in the presence of CO, the fully reduced form of the enzyme exists as a mixture of the oxyferroheme (Soret = 415 nm) and carboxyferroheme (Soret = 421 nm) enzyme complexes. However, if the same experiment is repeated with the half-reduced form of the pseudomonad enzyme, all of the enzyme is in the ferriheme state, even though CO is inhibiting this form of the enzyme to the same degree as it does the fully reduced form. We conclude that for the half-reduced form of pseudomonad tryptophan oxygenase the substrate, O2, and the inhibitor, CO, are not binding to the heme moieties, but are bound elsewhere, presumably to the Cu(I) moieties. Examination of the kinetic mechanisms of the half-reduced and fully reduced forms of pseudomonad tryptophan oxygenase using the inhibitors carbon monoxide and 5-fluorotryptophan confirmed that the fully reduced enzyme binds L-tryptophan before O2 (FORMAN, H., AND FEIGELSON, P. (1971) Biochemistry 10, 760-763) and that for the half-reduced enzyme O2 binds first. In the presence of 5-fluorotryptophan a relatively stable oxyferroheme enzyme complex was generated with the fully reduced form of pseudomonad tryptophan oxygenase. Thus, saturation of the catalytic site alone either with the substrate, L-tryptophan, or the competitive inhibitor, 5-fluorotryptophan, enhances binding of O2 to the ferroheme moieties of the enzyme. The resistance of this complex to photolysis indicates that the bound molecular oxygen is predominantly present as superoxide, O2-minus.     

Nitric oxide reacts with the ferryl-oxo catalytic intermediate of the CuB-lacking cytochrome bd terminal oxidase

Cytochrome bd is a bacterial respiratory oxidase carrying three hemes but no copper. We show that nitric oxide (NO) reacts with the intermediate F of cytochrome bd from Azotobacter vinelandii: (i) with a 1:1 stoichiometry, (ii) rapidly (k=1.2 +/- 0.1 x 10(5)M(-1)s(-1) at 20 degrees C), and (iii) yielding the oxidized enzyme with nitrite bound to heme d at the active site. Unexpectedly, the NO reaction mechanism of this catalytic intermediate in the Cu(B)-lacking cytochrome bd appears similar to that of beef heart cytochrome c oxidase, where Cu(B) was proposed to play a key role.     

Strong excitonic interactions in the oxygen-reducing site of bd-type oxidase: the Fe-to-Fe distance between hemes d and b595 is 10 A

Absorption and circular dichroism (CD) spectra of cytochrome bd from Escherichia coli have been compared for the wild type enzyme and an inactive mutant in which a highly conserved E445 in subunit I has been replaced by alanine [Zhang, J., Hellwig, P., Osborne, J. P., Huang, H. W., Moenne-Loccoz, P., Konstantinov, A. A., and Gennis, R. B. (2001) Biochemistry 40, 8548-8556]. The absorption bands of ferrous heme b595 are absent from the spectrum of the dithionite-reduced E445A form of cytochrome bd. The difference between the spectra of the dithionite-reduced WT and E445A enzymes indicates that in the mutant, heme b595 is present but is not reducible by dithionite. Cytochrome bd reveals intense CD signals dominated by heme d, with almost no contribution from heme b595 or heme b558. The CD spectrum of the reduced wild type enzyme in the Soret band indicates strong excitonic interactions between ferrous heme d and ferrous heme b595, and these interactions are not observed in dithionite-reduced E445A mutant, in which heme b595 remains in the ferric state. Modeling the excitonic interactions in both absorption and CD spectra has been carried out, yielding an estimate of the Fe-to-Fe distance between heme d and heme b595 of about 10 A. The physical proximity supports the hypothesis that heme d and heme b595 can form a di-heme oxygen reducing site, a unique structure for respiratory oxidases.     

Spectroscopic and quantitative analysis of the oxygenated and peroxy states of the purified cytochrome d complex of Escherichia coli

Oxygenated and peroxy states of the cytochrome d complex of Escherichia coli have been proposed as intermediates in the reaction mechanism of this ubiquinol oxidase. In this report, several stable states of the purified enzyme were examined spectroscopically at room temperature. As purified, the cytochrome d complex exists in an oxygenated state characterized by an absorbance band at 650 nm. Removal of oxygen results in loss of absorbance at this wavelength, which is restored upon the return of oxygen. The presence of one oxygen molecule in the oxygenated state was quantified by measuring oxygen released when excess hydrogen peroxide was added to the oxygenated state by passage of argon generates a "partially reduced" state with an absorbance peak at 628 nm, apparently due to reduced cytochrome d. Addition of equimolar hydrogen peroxide to the fully oxidized state produces the peroxy state. This peroxy state is also formed upon addition of excess hydrogen peroxide to the oxygenated state via a stable intermediate termed "peroxy intermediate." It is likely that 1) the oxygenated state consists of one molecule of oxygen bound to reduced heme d, and 2) there are at least two stable states that have bound peroxide at room temperature, the peroxy state and a newly discovered peroxy intermediate.     

Probing molecular structure of dioxygen reduction site of bacterial quinol oxidases through ligand binding to the redox metal centers

Cytochromes bo and bd are structurally unrelated terminal ubiquinol oxidases in the aerobic respiratory chain of Escherichia coli. The high-spin heme o-CuB binuclear center serves as the dioxygen reduction site for cytochrome bo, and the heme b595-heme d binuclear center for cytochrome bd. CuB coordinates three histidine ligands and serves as a transient ligand binding site en route to high-spin heme o one-electron donor to the oxy intermediate, and a binding site for bridging ligands like cyanide. In addition, it can protect the dioxygen reduction site through binding of a peroxide ion in the resting state, and connects directly or indirectly Tyr288 and Glu286 to carry out redox-driven proton pumping in the catalytic cycle. Contrary, heme b595 of cytochrome bd participate a similar role to CuB in ligand binding and dioxygen reduction but cannot perform such versatile roles because of its rigid structure.