The reaction of hydrogen peroxide with pulsed cytochrome bo from Escherichia coli

The three-spin intermediate at the O-O cleavage and proton-pumping junction in heme-Cu oxidases

[Figure: see text].

Peroxide stimulated transition between the ferryl intermediates of bovine cytochrome c oxidase

During catalysis of cytochrome c oxidases (CcO) several ferryl intermediates of the catalytic heme a₃-Cu_B center are observed. In the P_M ferryl state, produced by the reaction of two-electron reduced CcO with O₂, the ferryl iron of heme a₃ and a free radical are present at the catalytic center. The radical reduction stimulates the transition of the P_M into another ferryl F state. Similar ferryl states can be also generated from the oxidized CcO (O) in the reaction with H₂O₂. The P_M, the product of the reaction of the O with one molecule of peroxide, is transformed into the F state by the second molecule of H₂O₂. However, the chemical nature of this transition has not been unambiguously elucidated yet. Here, we examined the redox state of the peroxide-produced P_M and F states by the one-electron reduction. The F form and interestingly also the major fraction of the P_M sample, likely another P-type ferryl form (P_R), were found to be the one oxidizing equivalent above the O state. However, the both P-type forms are transformed into the F state by additional molecule of H₂O₂. It is suggested that the P_R-to-F transition is due to the binding of H₂O₂ to Cu_B triggering a structural change together with the uptake of H⁺ at the catalytic center. In the P_M-to-F conversion, these two events are complemented with the annihilation of radical by the intrinsic oxidation of the enzyme.

A comparison of catalytic site intermediates of cytochrome c oxidase and peroxidases

Compounds I and II of peroxidases such as horseradish peroxidase and cytochrome c peroxidase are relatively well understood catalytic intermediates in terms of their structures and redox states of iron, heme, and associated radical species. The intermediates involved in the oxygen reduction chemistry of the cytochrome c oxidase superfamily are more complicated because of the need for four reducing equivalents and because of the linkage of the oxygen chemistry with vectorial proton translocations. Nevertheless, two of these intermediates, the peroxy and ferryl forms, have characteristics that can in many ways be considered to be counterparts of peroxidase compounds I and II. We explore the primary factors that minimize the generation of unwanted reactive oxygen species products and ensure that the principal enzymological function becomes either that of a peroxidase or an oxidase. These comparisons can provide insights into the nature of biological oxygen reduction chemistry and guidance for the engineering of biomimetic synthetic materials.

An elementary reaction step of the proton pump is revealed by mutation of tryptophan-164 to phenylalanine in cytochrome c oxidase from Paracoccus denitrificans

Cytochrome c oxidase couples reduction of dioxygen to water to translocation of protons over the inner mitochondrial or bacterial membrane. A likely proton acceptor for pumped protons is the Delta-propionate of heme a(3), which may receive the proton via water molecules from a conserved glutamic acid (E278 in subunit I of the Paracoccus denitrificans enzyme) and which receives a hydrogen bond from a conserved tryptophan, W164. Here, W164 was mutated to phenylalanine (W164F) to further explore the role of the heme a(3) Delta-propionate in proton translocation. FTIR spectroscopy showed changes in vibrations possibly attributable to heme propionates, and the midpoint redox potential of heme a(3) decreased by approximately 50 mV. The reaction of the oxidized W164F enzyme with hydrogen peroxide yielded substantial amounts of the intermediate F' even at high pH, which suggests that the mutation rearranges the local electric field in the binuclear center that controls the peroxide reaction. The steady-state proton translocation stoichiometry of the W164F enzyme dropped to approximately 0.5 H(+)/e(-) in cells and reconstituted proteoliposomes. Time-resolved electrometric measurements showed that when the fully reduced W164F enzyme reacted with O(2), the membrane potential generated in the fast phase of this reaction was far too small to account either for full proton pumping or uptake of a substrate proton from the inside of the proteoliposomes. Time-resolved optical spectroscopy showed that this fast electrometric phase occurred with kinetics corresponding to the transition from state A to P(R), whereas the subsequent transition to the F state was strongly delayed. This is due to a delay of reprotonation of E278 via the D-pathway, which was confirmed by observation of a slowed rate of Cu(A) oxidation and which explains the small amplitude of the fast charge transfer phase. Surprisingly, the W164F mutation thus mimics a weak block of the D-pathway, which is interpreted as an effect on the side chain isomerization of E278. The fast charge translocation may be due to transfer of a proton from E278 to a "pump site" above the heme groups and is likely to occur also in wild-type enzyme, though not distinguished earlier due to the high-amplitude membrane potential formation during the P(R)--> F transition.

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.

Microsecond freeze-hyperquenching: development of a new ultrafast micro-mixing and sampling technology and application to enzyme catalysis

A novel freeze-quench instrument with a characteristic <<dead-time>> of 137 +/- 18 micros is reported. The prototype has several key features that distinguish it from conventional freeze-quench devices and provide a significant improvement in time resolution: (a) high operating pressures (up to 400 bar) result in a sample flow with high linear rates (up to 200 m s(-1)); (b) tangential micro-mixer with an operating volume of approximately 1 nl yields short mixing times (up to 20 micros); (c) fast transport between the mixer and the cryomedium results in short reaction times: the ageing solution exits the mixer as a free-flowing jet, and the chemical reaction occurs "in-flight" on the way to the cryomedium; (d) a small jet diameter (approximately 20 microm) and a high jet velocity (approximately 200 m s(-1)) provide high sample-cooling rates, resulting in a short cryofixation time (up to 30 micros). The dynamic range of the freeze-quench device is between 130 micros and 15 ms. The novel tangential micro-mixer efficiently mixes viscous aqueous solutions, showing more than 95% mixing at eta < or = 4 (equivalent to protein concentrations up to 250 mg ml(-1)), which makes it an excellent tool for the preparation of pre-steady state samples of concentrated protein solutions for spectroscopic structure analysis. The novel freeze-quench device is characterized using the reaction of binding of azide to metmyoglobin from horse heart. Reaction samples are analyzed using 77 K optical absorbance spectroscopy, and X-band EPR spectroscopy. A simple procedure of spectral analysis is reported that allows (a) to perform a quantitative analysis of the reaction kinetics and (b) to identify and characterize novel reaction intermediates. The reduction of dioxygen by the bo3-type quinol oxidase from Escherichia coli is assayed using the MHQ technique. In these pilot experiments, low-temperature optical absorbance measurements show the rapid oxidation of heme o3 in the first 137 micros of the reaction, accompanied by the formation of an oxo-ferryl species. X-band EPR spectroscopy shows that a short-living radical intermediate is formed during the oxidation of heme o3. The radical decays within approximately 1 ms concomitant with the oxidation of heme b, and can be attributed to the PM reaction intermediate converting to the oxoferryl intermediate F. The general field of application of the freeze-quench methodology is discussed.

Dioxygen reduction by bo-type quinol oxidase from Escherichia coli studied by submillisecond-resolved freeze-quench EPR spectroscopy

The mechanism of the dioxygen (O(2)) reduction conducted by cytochrome bo-type quinol oxidase was investigated using submillisecond-resolved freeze-quench EPR spectroscopy. The fully reduced form of the wild-type enzyme (WT) with the bound ubiquinone-8 at the high-affinity quinone-binding site was mixed with an O(2)-saturated solution, and the subsequent reaction was quenched at different time intervals from 0.2 to 50 ms. The EPR signals derived from the binuclear center and heme b were weak in the time domain from 0.2 to 0.5 ms. The signals derived from the ferric heme b and hydroxide-bound ferric heme o increased simultaneously after 1 ms, indicating that the oxidation of heme b is coupled to the formation of hydroxy heme o. In contrast, the enzyme without the bound ubiquinone-8 (Delta UbiA) showed the faster oxidation of heme b and the slower formation of hydroxy heme o than WT. It is interpreted that the F(I) intermediate possessing ferryl-oxo heme o, cupric Cu(B), and ferric heme b is converted to the F(II) intermediate within 0.2 ms by an electron transfer from the bound ubiquinonol-8 to ferric heme b. The conversion of the F(II) intermediate to the hydroxy intermediate occurred after 1 ms and was accompanied by the one-electron transfer from heme b to the binuclear center. Finally, it is suggested that the hydroxy intermediate possesses no bridging ligand between heme o and Cu(B) and is the final intermediate in the turnover cycle of cytochrome bo under steady-state conditions.

Cytochrome bo(3) from Escherichia coli: the binding and turnover of nitric oxide

The reaction of nitric oxide (NO) with fast and reduced cytochrome bo(3)(cyt bo(3)) from Escherichia coli has been investigated. The stoichiometry of NO binding to cyt bo(3) was determined using an NO electrode in the [NO] range 1-14 microM. Under reducing conditions, the initial decrease in [NO] following the addition of cyt bo(3) corresponded to binding of 1 NO molecule per cyt bo(3) functional unit. After this "rapid" NO binding phase, there was a slow, but significant rate of NO consumption ( approximately 0.3molNOmol bo(3)(-1)min(-1)), indicating that cyt bo(3) possesses a low level of NO reductase activity. The binding of NO to fast pulsed enzyme was also investigated. The results show that in the [NO] range used (1-14 microM) both fast and pulsed oxidised cyt bo(3) bind NO with a stoichiometry of 1:1 with an observed dissociation constant of K(d)=5.6+/-0.6 microM and that NO binding was inhibited by the presence of Cl(-). The binding of nitrite to the binuclear centre causes spectral changes similar to those observed upon NO binding to fast cyt bo(3). These results are discussed in relation to the model proposed by Wilson and co-workers [FEBS Lett. 414 (1997) 281] where the binding of NO to Cu(B)(II) results in the formation of the nitrosonium (Cu(B)(I)-NO(+)) complex. NO(+) then reacts with OH(-), a Cu(B) ligand, to form nitrite, which can bind at the binuclear centre. This work suggests for the first time that the binding of NO to oxidised cyt bo(3) does result in the reduction of Cu(B).

Radicals associated with the catalytic intermediates of bovine cytochrome c oxidase

Two radicals have been detected previously by electron paramagnetic resonance (EPR) and electron nuclear double resonance (ENDOR) spectroscopies in bovine cytochrome oxidase after reaction with hydrogen peroxide, but no correlation could be made with predicted levels of optically detectable intermediates (P(M), F and F(z.rad;)) that are formed. This work has been extended by optical quantitation of intermediates in the EPR/ENDOR sample tubes, and by comparison with an analysis of intermediates formed by reaction with carbon monoxide in the presence of oxygen. The narrow radical, attributed previously to a porphyrin cation, is detectable at low levels even in untreated oxidase and increases with hydrogen peroxide treatments generally. It is presumed to arise from a side-reaction unrelated to the catalytic intermediates. The broad radical, attributed previously to a tryptophan radical, is observed only in samples with a significant level of F(z.rad;) but when F(z.rad;) is generated with hydrogen peroxide, is always accompanied by the narrow radical. When P(M) is produced at high pH with CO/O(2), no EPR-detectable radicals are formed. Conversion of the CO/O(2)-generated P(M) into F(z.rad;) when pH is lowered is accompanied by the appearance of a broad radical whose ENDOR spectrum corresponds to a tryptophan cation. Quantitation of its EPR intensity indicates that it is around 3% of the level of F(z.rad;) determined optically. It is concluded that low pH causes a change of protonation pattern in P(M) which induces partial electron redistribution and tryptophan cation radical formation in F(z.rad;). These protonation changes may mimic a key step of the proton translocation process.

From no-confidence to nitric oxide acknowledgement: a story of bacterial nitric-oxide reductase

The review briefly summarizes current knowledge of the bacterial nitric-oxide reductase (NOR). This membrane enzyme consists of two subunits, the smaller one contains haem C and the larger one two haems B and nonhaem iron. The protein sequence and structure of metal centres demonstrate the relationship of NOR to the family of terminal oxidases. The binuclear Fe-Fe reaction centre, consisting of antiferromagnetically coupled haem B and nonhaem iron, is analogous to Fe-Cu centre of terminal oxidases. The data on the structure and function of NOR and terminal oxidases suggest that all these enzymes are closely evolutionally related. The catalytic properties are determined most of all by the relatively high toxicity of nitric oxide as a substrate and the resulting strong need to maintain its concentration at nanomolar levels. A kinetic model of the action of the enzyme comprises substrate inhibition. NOR does not conserve the free energy of nitric oxide reduction because it does not work as a proton pump and, moreover, the protons coming into the reaction are taken from periplasm, i.e. they do not cross the membrane.

Oxygen activation and reduction in respiration: involvement of redox-active tyrosine 244

Cytochrome oxidase activates and reduces O(2) to water to sustain respiration and uses the energy released to drive proton translocation and adenosine 5'-triphosphate synthesis. A key intermediate in this process, P, lies at the junction of the O(2)-reducing and proton-pumping functions. We used radioactive iodide labeling followed by peptide mapping to gain insight into the structure of P. We show that the cross-linked histidine 240-tyrosine 244 (His240-Tyr244) species is redox active in P formation, which establishes its structure as Fe(IV) = O/Cu(B)2+-H240-Y244. Thus, energy transfer from O2 to the protein moiety is used as a strategy to avoid toxic intermediates and to control energy utilization in subsequent proton-pumping events.

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.

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.

Resonance raman studies of oxo intermediates in the reaction of pulsed cytochrome bo with hydrogen peroxide

Cytochrome bo from Escherichia coli, a member of the heme-copper terminal oxidase superfamily, physiologically catalyzes reduction of O(2) by quinols and simultaneously translocates protons across the cytoplasmic membrane. The reaction of its ferric pulsed form with hydrogen peroxide was investigated with steady-state resonance Raman spectroscopy using a homemade microcirculating system. Three oxygen-isotope-sensitive Raman bands were observed at 805/X, 783/753, and (767)/730 cm(-)(1) for intermediates derived from H(2)(16)O(2)/H(2)(18)O(2). The experiments using H(2)(16)O(18)O yielded no new bands, indicating that all the bands arose from the Fe=O stretching (nu(Fe)(=)(O)) mode. Among them, the intensity of the 805/X cm(-)(1) pair increased at higher pH, and the species giving rise to this band seemed to correspond to the P intermediate of bovine cytochrome c oxidase (CcO) on the basis of the reported fact that the P intermediate of cytochrome bo appeared prior to the formation of the F species at higher pH. For this intermediate, a Raman band assignable to the C-O stretching mode of a tyrosyl radical was deduced at 1489 cm(-)(1) from difference spectra. This suggests that the P intermediate of cytochrome bo contains an Fe(IV)=O heme and a tyrosyl radical like compound I of prostaglandin H synthase. The 783/753 cm(-)(1) pair, which was dominant at neutral pH and close to the nu(Fe)(=)(O) frequency of the oxoferryl intermediate of CcO, presumably arises from the F intermediate. On the contrary, the (767)/730 cm(-)(1) species has no counterpart in CcO. Its presence may support the branched reaction scheme proposed previously for O(2) reduction by cytochrome bo.

The reactions of hydrogen peroxide with bovine cytochrome c oxidase

Oxidised cytochrome c oxidase is known to react with two molecules of hydrogen peroxide to form consecutively 607 nm 'Peroxy' and 580-nm 'Ferryl' species. These are widely used as model compounds for the equivalent P and F intermediates of the catalytic cycle. However, kinetic analysis of the reaction with H(2)O(2) in the pH range 6.0-9.0 reveals a more complex situation. In particular, as the pH is lowered, a 580-nm compound can be formed by reaction with a single H(2)O(2). This species, termed F(&z.rad;), is spectrally similar, but not identical, to F. The reactions are equivalent to those previously reported for the bo type quinol oxidase from Escherichia coli (T. Brittain, R.H. Little, C. Greenwood, N.J. Watmough, FEBS Lett. 399 (1996) 21-25) where it was proposed that F(&z.rad;) is produced directly from P. However, in the bovine oxidase F(&z.rad;) does not appear in samples of the 607-nm form, P(M), produced by CO/O(2) treatment, even at low pH, although this form is shown to be identical to the H(2)O(2)-derived P state, P(H), on the basis of spectral characteristics and kinetics of reaction with H(2)O(2). Furthermore, lowering the pH of a sample of P(M) or P(H) generated at high pH results in F(&z.rad;) formation only on a minutes time scale. It is concluded that P and F(&z.rad;) are not in a rapid, pH-dependent equilibrium, but instead are formed by distinct pathways and cannot interconvert in a simple manner, and that the crucial difference between them lies in their patterns of protonation.

Cytochrome c oxidase: catalytic cycle and mechanisms of proton pumping--a discussion

Cytochrome c oxidase catalyzes the reduction of molecular oxygen to water, a process in which four electrons, four protons, and one molecule of oxygen are consumed. The reaction is coupled to the pumping of four additional protons across the membrane. According to the currently accepted concept, the pumping of all four protons occurs after the binding of oxygen to the reduced enzyme and is exclusively coupled to the last two electron transfer steps. A careful analysis of the existing data shows that there is no experimental evidence for this paradigm. It is more likely that only three protons are pumped during the second half of the catalytic cycle of cytochrome c oxidase after the reaction with oxygen. In this article a variant of a recent mechanistic model of proton pumping by electrostatic repulsion is discussed. It is based on the electroneutrality principle in a way that in the catalytic cycle each electron transfer to the membrane-embedded electron acceptors is charge-compensated by uptake of one proton. The mechanism takes into account the findings with mutant cytochrome c oxidases and explains the results of many recent experiments, including the effects of hydrogen peroxide.

Direct evidence for a tyrosine radical in the reaction of cytochrome c oxidase with hydrogen peroxide

Cytochrome c oxidase (COX) catalyzes the reduction of oxygen to water, a process which is accompanied by the pumping of four protons across the membrane. Elucidation of the structures of intermediates in these processes is crucial for understanding the mechanism of oxygen reduction. In the work presented here, the reaction of H(2)O(2) with the fully oxidized protein at pH 6.0 has been investigated with electron paramagnetic resonance (EPR) spectroscopy. The results reveal an EPR signal with partially resolved hyperfine structure typical of an organic radical. The yield of this radical based on comparison with other paramagnetic centers in COX was approximately 20%. Recent crystallographic data have shown that one of the Cu(B) ligands, His 276 (in the bacterial case), is cross-linked to Tyr 280 and that this cross-linked tyrosine is ideally positioned to participate in dioxygen activation. Here selectively deuterated tyrosine has been incorporated into the protein, and a drastic change in the line shape of the EPR signal observed above has been detected. This would suggest that the observed EPR signal does indeed arise from a tyrosine radical species. It would seem also quite possible that this radical is an intermediate in the mechanism of oxygen reduction.

Redox state of peroxy and ferryl intermediates in cytochrome c oxidase catalysis

The redox states of the "peroxy" (P) and "ferryl" (F) intermediates formed during reoxidation of reduced bovine cytochrome c oxidase have been probed by reduction with both ferrocytochrome c and acetylpyridine NADH under anaerobic conditions using optical spectroscopy. The reduction of the P and F forms revealed that both are in very similar redox states. One-electron reduction of either the P or F form yields an optical spectrum primarily due to oxidized enzyme implying that the heme iron of cytochrome a3 is in the ferryl state in both forms. The F and P forms were found to be 1 and less than 1.3 oxidizing equiv, respectively, above the oxidized enzyme. The slightly higher oxidation state in the P form is interpreted as being due to an optically undetectable redox center presumably located in the binuclear cavity.

The mechanism of proton pumping by cytochrome c oxidasex127e [comments]

Cytochrome c oxidase catalyzes the reduction of oxygen to water that is accompanied by pumping of four protons across the mitochondrial or bacterial membrane. Triggered by the results of recent x-ray crystallographic analyses, published data concerning the coupling of individual electron transfer steps to proton pumping are reanalyzed: Conversion of the conventional oxoferryl intermediate F to the fully oxidized form O is connected to pumping of only one proton. Most likely one proton is already pumped during the double reduction of O, and only three protons during conversion of the "peroxy" forms P to O via the oxoferryl form F. Based on the available structural, spectroscopic, and mutagenesis data, a detailed mechanistic model, carefully considering electrostatic interactions, is presented. In this model, each of the four reductions of heme a during the catalytic cycle is coupled to the uptake of one proton via the D-pathway. These protons, but never more than two, are temporarily stored in the regions of the heme a and a3 propionates and are driven to the outside ("pumped") by electrostatic repulsion from protons entering the active site during turnover. The first proton is pumped by uptake of one proton via the K-pathway during reduction, the second and third proton during the P --> F transition when the D-pathway and the active site become directly connected, and the fourth one upon conversion of F to O. Atomic structures are assigned to each intermediate including F' with an alternative route to O.

The reaction of halides with pulsed cytochrome bo from Escherichia coli

Cytochrome bo forms complexes with chloride, bromide and iodide in which haem o remains high-spin and in which the '630 nm' charge-transfer band is red-shifted by 7-8 nm. The chloride and bromide complexes each have a characteristic set of integer-spin EPR signals arising from spin coupling between haem o and CuB. The rate and extent of chloride binding decreases as the pH increases from 5.5 to 8.5. At pH 5.5 the dissociation constant for chloride is 2 mM and the first-order rate constant for dissociation is 2 x 10(-4) s-1. The order of rate of binding, and of affinity, at pH 5.5 is chloride (1) > bromide (0.3) >iodide (0.1). It is suggested that the halides bind in the binuclear site but, unlike fluoride, they are not direct ligands of the iron of haem o. In addition, both the stability of the halide complexes and the rate of halide binding seem to be increased by the co-binding of a proton.

Reaction of Escherichia coli cytochrome bo3 with substoichiometric ubiquinol-2: a freeze-quench electron paramagnetic resonance investigation

The reaction of the quinol oxidase cytochrome bo3 from Escherichia coli with ubiquinol-2 (UQ2H2) was carried out using substoichiometric (0.5 equiv) amounts of substrate. Reactions were monitored through the use of freeze-quench EPR spectroscopy. Under 1 atm of argon, semiquinone was formed at the QB site of the enzyme with a formation rate constant of 140 s-1; the QB semiquinone EPR signal decayed with a rate constant of about 5 s-1. Heme b and CuB were reduced within the 10-ms dead time of the freeze-quench experiment and remained at a constant level of reduction over the 1-s time course of the experiment. Quantitation of the reduction levels of QB and heme b during this reaction yielded a reduction potential of 30-60 mV for heme b. Under a dioxygen atmosphere, the rates of semiquinone formation and its subsequent decay were not altered significantly. However, accurate quantitation of the EPR signals for heme b and heme o3 could not be made, due to interference from dioxygen. In the reaction between the QB-depleted enzyme and UQ2H2 under substoichiometric conditions, there was no observable change in the EPR spectra of the enzyme over the time course of the reaction, suggesting an electron transfer from heme b to the binuclear site in the absence of QB which occurs within the dead time of the freeze-quench apparatus. Analysis of the thermodynamics and kinetics of electron transfers in this enzyme suggests that a Q-cycle mechanism for proton translocation is more likely than a cytochrome c oxidase-type ion-pump mechanism.

The dinuclear center of cytochrome bo3 from Escherichia coli

For the study of the dinuclear center of heme-copper oxidases cytochrome bo3 from Escherichia coli offers several advantages over the extensively characterized bovine cytochrome c oxidase. The availability of strains with enhanced levels of expression allows purification of the significant amounts of enzyme required for detailed spectroscopic studies. Cytochrome bo3 is readily prepared as the fast form, with a homogeneous dinuclear center which gives rise to characteristic broad EPR signals not seen in CcO. The absence of CuA and the incorporation of protohemes allows for a detailed interpretation of the MCD spectra arising from the dinuclear center heme o3. Careful analysis allows us to distinguish between small molecules that bind to heme o3, those which are ligands of CuB, and those which react to yield higher oxidation states of heme o3. Here we review results from our studies of the reactions of fast cytochrome bo3 with formate, fluoride, chloride, azide, cyanide, NO, and H2O2.

Fast cytochrome bo from Escherichia coli binds two molecules of nitric oxide at CuB

The reaction of nitric oxide (NO) with fast cytochrome bo from Escherichia coli has been studied by electronic absorption, MCD, and EPR spectroscopy. Titration of the enzyme with NO showed the formation of two distinct species, consistent with NO binding stoichiometries of 1:1 and 2:1 with observed dissociation constants at pH 7.5 of approximately 2.3 x 10(-)6 and 3.3 x 10(-)5 M. Monitoring the titration by EPR spectroscopy revealed that the broad EPR signals at g approximately 7.3, 3.7, and 2.8 due to magnetic interaction between high-spin heme o (S = 5/2) and CuBII (S = 1/2) are lost. A high-spin heme o signal at g = 6.0 appears as the 1:1 complex is formed but is lost again on formation of the 2:1 complex, which is EPR silent. The absorption spectrum shows that heme o remains in the high-spin FeIII state throughout the titration. These results are consistent with the binding of up to two NO molecules at CuBII. This has been confirmed by studies with the Cl- adduct of fast cytochrome bo. MCD evidence shows that heme o remains ligated by histidine and water. Addition of excess NO to the Cl- adduct leads to the appearance of a high-spin FeIII heme EPR signal. Hence chloride ion binds to CuB, blocking the binding of a second NO molecule. These results suggest a mechanism for the reduction of NO to nitrous oxide by cytochrome bo and cytochrome c oxidase in which the binding of two cis NO molecules at CuB permits the formation of an N-N bond and the abstraction of oxygen by the heme group.

A conserved glutamic acid in helix VI of cytochrome bo3 influences a key step in oxygen reduction

We have compared the reactions with dioxygen of wild-type cytochrome bo3 and a mutant in which a conserved glutamic acid at position-286 of subunit I has been changed to an alanine. Flow-flash experiments reveal that oxygen binding and the rate of heme-heme electron transfer are unaffected by the mutation. Reaction of the fully (3-electron) reduced mutant cytochrome bo3 with dioxygen yields a binuclear center which is substantially in the P (peroxy) state, not the well-characterized F (oxyferryl) state which is the product of the reaction of the fully reduced wild-type enzyme with dioxygen [Puustinen, A., et al. (1996) Proc. Natl. Acad. Sci. U.S.A. 93, 1545-1548]. These results confirm that proton uptake is important in controlling the later stages of dioxygen reduction in heme-copper oxidases and show that E286 is an important component of the channel that delivers these protons to the active site.

EPR spectroscopy of Escherichia coli cytochrome bo which lacks CuB

The spectroscopic and ligand-binding properties of a copper-deficient cytochrome bo3, a member of the haem-copper superfamily of terminal oxidases, are reported and contrasted with those of the native enzyme. The enzyme lacks the copper atom (CuB) which is normally an integral part of the catalytic site. The consequences of loss of the CuB are the loss of antiferromagnetic coupling to the high-spin haem and an inability to form any of the integer-spin derivatives of the enzyme. Low-spin compounds of the normally high-spin haem are still formed with appropriate ligands, although these are modified.

Comparison of the ligand-binding properties of native and copper-less cytochromes bo from Escherichia coli

The binding of four anionic ligands, cyanide, fluoride, azide and formate, to cytochrome bo purified from Escherichia coli cells grown with a copper supplement (+Cu cyt.bo) is described. Membrane-bound cytochrome bo that lacks the copper component, CuB, of its active site can be prepared from cells grown under conditions where the availability of copper is limited by the presence of a CuI chelator, 2,2'-bicinchinonic acid. The ligand-binding properties of this copper-less enzyme (-Cu cyt.bo) are compared with those of +Cu cyt. bo. As judged from near-UV/visible spectroscopic changes, cyanide forms a low-spin complex with +Cu cyt.bo, whereas azide, fluoride and formate form high-spin complexes. The pH-dependences of binding suggest that for all four of these anionic ligands, both the rates of binding and the binding affinities are primarily dependent on the concentration of their protonated forms. -Cu cyt.bo, which shows less than 15% of the duroquinol oxidase activity of +Cu cyt.bo, binds cyanide, azide and fluoride, but with greatly decreased affinity (<1/30, 1/2000 and 1/2500 respectively at pH5.5 compared with +Cu cyt.bo). The complex of azide with -Cu cyt.bo still seems to be high-spin and azide binding to -Cu cyt.bo is still pH-dependent, although less so than azide binding to +Cu cyt.bo.

Purification and initial kinetic and spectroscopic characterization of NO reductase from Paracoccus denitrificans

A new and relatively simple procedure to purify NO reductase from Paracoccus denitrificans by using the detergent lauryl maltoside has been developed. The purified enzyme consists of two subunits according to SDS polyacrylamide gel electrophoresis. Analysis of the content of prosthetic groups indicates the presence of non-haem iron in addition to the presence b and c cytochromes yielding a stoichiometry of haem b/haem c/non-haem iron = 2:1:1. The optical spectrum of reduced NO reductase shows bands of low-spin haem c and haem b with alpha-band absorbance maxima at 551 nm and 558 nm, respectively. The optical spectrum of oxidized NO reductase shows a broad absorbance hand around 590 nm which disappears upon reduction. This latter absorbance is ascribed to a high-spin haem b (charge-transfer) transition. The presence of high-spin haem b is also indicated by the shifts observed in the optical spectrum of oxidized NO reductase in the presence of NO or in the spectrum of reduced enzyme after addition of CO. The main features of the EPR spectrum of the oxidized enzyme are resonances from a highly anisotropic low-spin haem b (gz = 3.53) and from an anisotropic low-spin haem c with gz, y, x = 2.99, 2.28, 1.46, the two haems being present in an approximate 1:1 stoichiometry. Minor signals representing about 1% of the enzyme concentration due to high-spin haem b (g = 5.8-6.2) and a novel type of signal with g = 2.009 ascribed to high-spin non-haem ferric iron were also observed. The analysis of steady-state kinetic measurements of the NO reductase activity shows a sigmoidal relation between rate of NO reduction and NO concentration, consistent with a model describing sequential binding of two molecules of NO to the reduced enzyme. At high NO concentrations substrate inhibition occurs (Ki(apparent) = 13.5 microM) suggested to be due to binding of NO to oxidized enzyme. The absence from the EPR spectrum of signals originating from ferric non-haem iron and ferric high-spin haem b in stoichiometric amounts with respect to the enzyme concentration is suggested to be due to an antiferromagnetic coupling between these two centers. The steady-state kinetic behaviour and the optical and EPR spectroscopic properties of the NO reductase are incorporated into a tentative structural and mechanistic model.

The reaction of Escherichia coli cytochrome bo with H2O2: evidence for the formation of an oxyferryl species by two distinct routes

We have re-examined the reaction of fast oxidised cytochrome bo with H202 in a stopped-flow spectrophotometer. Monitoring the reaction at 582 nm allows us to observe the formation and decay of a spectroscopically distinct intermediate which accumulates transiently prior to the formation of an oxyferryl species previously characterised in this laboratory (Watmough, N.J., Cheesman, M.R., Greenwood, C. and Thomson, A.J. (1994) Biochem. J. 300, 469-475 [1]). The reaction shows three distinct phases of which the fast and intermediate phases are bimolecular and show a marked pH dependence. Initially these results appeared incompatible with the report that only one equivalent of H202 is required to generate the oxyferryl species (Moody, A.J. and Rich, P.R. (1994) Eur. J. Biochem. 226, 731-737 [21]. However, these data can be reconciled by a branched reaction mechanism whose contributions differ according to the peroxide concentration used.

Interconversion of fast and slow forms of cytochrome bo from Escherichia coli

The fully oxidized fast form of cytochrome bo from Escherichia coli is shown to convert spontaneously to a slow form when stored at -20 degrees C in 50 mM potassium borate, pH 8.5, containing 0.5 mM potassium EDTA. Evidence for the conversion, and that the form produced is analogous to the slow form of bovine heart cytochrome c oxidase, comes from (a) decreases in the extents of fast (k = 1-2 x 10(3) M-1 s-1) H2O2 binding and fast (k = 20-30 M-1 s-1) cyanide binding; (b) changes in the optical spectrum that are like those induced by formate, i.e., a blue shift in the Soret absorption band, loss of absorbance in the alpha and beta bands, and a red shift in the "630 nm" charge-transfer band; (c) changes in the EPR spectrum that are like those induced by formate, i.e., disappearance of signals at g = 8.6 and g = 3.71, and appearance of signals at g approximately 13, g = 3.14, and g = 2.58; and (d) appearance of a slow phase of reduction of heme o by dithionite. The mutant enzyme E286Q also converts to a slow form under the same conditions, as shown by (a) a decrease in the extent of fast H2O2 binding; (b) changes in the optical spectrum like those seen with wild-type enzyme; and (c) changes in the EPR spectrum that are like those induced by formate, i.e., disappearance of signals at g = 7.3 and g = 3.6 and appearance of signals at g approximately 13, g = 3.18, and g = 2.59.(ABSTRACT TRUNCATED AT 250 WORDS)