"Peroxidatic" form of cytochrome oxidase as studied by X-ray absorption spectroscopy

Structure of the binuclear heme iron-copper site in the quinol-oxidizing cytochrome aa3 from Bacillus subtilis

Cytochrome aa3-600 is a terminal quinol oxidase of Bacillus subtilis, belonging to the large family of structurally and functionally related respiratory enzymes to which the mitochondrial cytochrome c oxidase also belongs. However, the CuA center typical of the cytochrome c oxidases is lacking from cytochrome aa3-600. The presence of only one copper, viz. CuB of the binuclear heme iron-copper site, makes cytochrome aa3-600 especially suitable for XAS analysis of this structure. Cu and Fe XAS data for fully oxidized cytochrome aa3-600 indicate a structure for the binuclear site similar to that previously reported for mitochondrial cytochrome c oxidase (see Powers et al. (1981) Biophys. J. 34, 465-468). Heme Fea3 has a proximal histidine nitrogen ligand 2.10 +/- 0.02 A from the iron, and a distal S or Cl ligand at 2.36 +/- 0.03 A. The latter is also a ligand of CuB (2.21 +/- 0.02 A), and apparently forms a bridge between the two metals which are 3.70 +/- 0.06 A apart. CuB has two more close-lying ligands at 1.95 +/- 0.02 A, which are likely histidine nitrogens. The similarity between EXAFS of CuB and type 1 'blue' copper is contrasted to EPR and optical spectroscopic properties of CuB, and the nature of the bridging ligand is discussed.

Cytochrome oxidase-catalyzed superoxide generation from hydrogen peroxide

Superoxide dismutase is shown to affect spectral changes observed upon cytochrome c oxidase reaction with H2O2, which indicates a possibility of O2- radicals being formed in the reaction. Using DMPO as a spin trap, generation of superoxide radicals from H2O2 in the presence of cytochrome oxidase is directly demonstrated. The process is inhibited by cyanide and is not observed with a heat-denatured enzyme pointing to a specific reaction in the oxygen-reducing centre of cytochrome c oxidase. The data support a hypothesis on a catalase cycle catalyzed by cytochrome c oxidase in the presence of excess H2O2 (Vygodina and Konstantinov (1988) Ann. NY Acad. Sci., 550, 124-138): (formula: see text)

Cytochrome c oxidase metal centers: location and function

Cytochrome c oxidase of Paracoccus denitrificans is spectroscopically and functionally very similar to the mammalian enzyme. However, it has a very much simpler quaternary structure, consisting of only three subunits instead of the 13 of the bovine enzyme. The known primary structure of the Paracoccus denitrificans subunits, the knowledge of a large number of sequences from other species, and data on the controlled proteolytic digestion of the enzyme allow structural restrictions to be placed on the models describing the binding of the active metal centers to the polypeptide structure.

Effect of pH on the spectrum of cytochrome c oxidase hydrogen peroxide complex

Hydrogen peroxide binding to ferric cytochrome c oxidase in proteoliposomes brings about a red-shift of the enzyme Soret band and increased absorption in the visible range with two prominent peaks at approx. 570 and 607 nm. The molar absorptivity of the H2O2-induced difference spectrum is virtually pH-independent in the Soret band and at 570 nm, whereas the peak at 607 nm increases approx. 3-fold upon alkalinization in a narrow pH range 6.0-7.2, the effect being reversible. The pH profile of this transition indicates ionization of two acid-base groups with close pK values of 6.7. The lineshape of the peroxide compound difference spectrum is found to respond to pH changes inside the proteoliposomes. It is suggested that peroxide-complexed enzyme can undergo a pH-dependent transition to a form with increased extinction at 605-607 nm, possibly corresponding to the 420 nm (or 'pulsed') conformer of the ferric cytochrome oxidase formed as an early product of the enzyme oxidation. Accordingly, relaxation of the '420 nm' form to the resting state would be linked to an uptake of two protons from the M-aqueous phase. This protolytic reaction might be a partial step of the cytochrome oxidase proton pumping mechanism or it could serve to regulate interconversion between the active 'pulsed' and less active 'resting' states of the enzyme in the membrane.

Activation by reduction of the resting form of cytochrome c oxidase: tests of different models and evidence for the involvement of CuB

(1) The reaction of the resting form of oxidised cytochrome c oxidase from ox heart with dithionite has been studied in the presence and absence of cyanide. In both cases, cytochrome a reduction in 0.1 M phosphate (pH 7) occurs at a rate of 8.2.10(4) M-1.s-1. In the absence of cyanide, ferrocytochrome a3 appears at a rate (kobs) of 0.016 s-1. Ferricytochrome a3 maintains its 418 nm Soret maximum until reduced. The rate of a3 reduction is independent of dithionite concentration over a range 0.9 mM-131 mM. In the presence or cyanide, visible and EPR spectral changes indicate the formation of a ferric a3/cyanide complex occurs at the same rate as a3 reduction in the absence of cyanide. A g = 3.6 signal appears at the same time as the decay of a g = 6 signal. No EPR signals which could be attributed to copper in any significant amounts could be detected after dithionite addition, either in the presence or absence of cyanide. (2) Addition of dithionite to cytochrome oxidase at various times following induction of turnover with ascorbate/TMPD, results in a biphasic reduction of cytochrome a3 with an increasing proportion of the fast phase of reduction occurring after longer turnover times. At the same time, the predominant steady state species of ferri-cytochrome a3 shifts from high to low spin and the steady-state level of reduction of cytochrome a drops indicating a shift in population of the enzyme molecules to a species with fast turnover. In the final activated form, oxygen is not required for fast internal electron transfer to cytochrome a3. In addition, oxygen does not induce further electron uptake in samples of resting cytochrome oxidase reduced under anaerobic conditions in the presence of cyanide. Both findings are contrary to predictions of certain O-loop types of mechanism for proton translocation. (3) A measurement of electron entry into the resting form of cytochrome oxidase in the presence of cyanide, using TMPD or cytochrome c under anaerobic conditions, shows that three electrons per oxidase enter below a redox potential of around +200 mV. An initial fast entry of two electrons is followed by a slow (kobs approximately 0.02 s) entry of a third electron.(ABSTRACT TRUNCATED AT 400 WORDS)

Spectrophotometric characterization of intermediate redox states of cytochrome oxidase

The spectrophotometric characteristics of hemes a and a3 in cytochrome oxidase have been examined over the range 380 nm to 900 nm. Difference spectra (relative to the oxidized form) are presented for ferrous, high-spin oxidized, low-spin oxidized, early "pulsed," late "pulsed," and two-peroxide-treated states of the enzyme. Comparisons indicate that the decay product of the initial peroxide complex of the enzyme is identical to a low-spin pulsed form of the enzyme. A high-spin pulsed form of the enzyme persists for several hours to days after preparation.

H2O2-induced conversion of cytochrome c oxidase peroxy complex to oxoferryl state

Addition of high H2O2 concentrations to a peroxy complex of proteoliposome-bound cytochrome oxidase converts the complex to a spectrally distinct species. The difference spectrum of the high-peroxide compound versus the oxidized enzyme is characterized in a visible range by a broad symmetrical band at 580 nm (delta epsilon approximately equal to 4 mM-1 cm-1) with a minor second maximum at approximately 535 nm; a complete disappearance of the 605-607-nm peak occurs which is typical of the peroxy complex. In the Soret band, the spectrum of the high H2O2 compound is virtually indistinguishable from that of the initial peroxide adduct. The high-peroxide compound appears to be identical with an oxoferryl intermediate formed in the forward and reversed cytochrome oxidase reaction. The transition of the peroxy complex to the oxoferryl state is favored by alkaline pH and counteracted by ferricyanide. The peroxy and oxoferryl complexes of cytochrome c oxidase can also be formed with t-butylhydroperoxide.

Conformational change of cytochrome a3 induced by oxidized cytochrome c

Cyanide binding with the oxidized resting Yonetani-type cytochrome c-oxidase followed spectrophotometrically reveals a relatively rapid initial phase the rate of which shows saturation behaviour with respect to [HCN] and secondary slower absorption changes to a first approximation independent of the ligand concentration. Oxidized cytochrome c greatly accelerates the initial phase of cyanide binding but does not affect significantly contribution or rate constant of the slow phase. The same effect is exerted by poly-L-lysine. Within a framework of a reaction mechanism assuming Cu2+B to be the initial HCN-binding site, cytochrome c3+ and other polycations are likely to bring about a conformational-change of cytochrome oxidase resulting in an increased affinity of Cu2+B for HCN. This could occur by virtue of loosening a bond between Cu2+B and one of its endogenous ligands facilitating displacement of the latter by HCN.

Cytochrome c oxidase from Paracoccus denitrificans: both hemes are located in subunit I

The two-subunit cytochrome c oxidase from Paracoccus denitrificans has been sequentially digested with chymotrypsin and Staphylococcus aureus V8 protease. The smaller subunit of the enzyme (apparent Mr 32,000) was split into numerous peptides that were removed by anion-exchange HPLC. The larger subunit was only digested to a limited extent (from an apparent Mr 45,000 to Mr 43,000), and the spectral properties were preserved relative to the native enzyme (a reduced minus oxidized difference spectrum with maxima at 447 and 607 nm in the Soret and alpha region, respectively). As judged from CO-reduced spectra this proteolytically digested, one-fragment oxidase was found to contain an equal amount of cytochromes a and a3. The enzymatic activity with reduced cytochrome c as substrate in the presence of Triton X-100 proceeded with equal affinity (apparent Km = 0.5-1.0 microM) and with a Vmax of approximately 20% (40 s-1) of that found with the native enzyme (200 s-1). When the assay system was supplemented with soybean phospholipids, the Km became 2 microM for both enzymes and the Vmax became 730 and 170 s-1 for the native and the digested enzyme, respectively. Thus subunit I of P. denitrificans oxidase, and most probably of the other cytochrome c oxidases as well, contains both hemes and at least one Cu atom and has significant enzymatic activity.

Enhanced superoxide dismutase activity of pulsed cytochrome oxidase

The superoxide dismutase (SOD) activity of beef heart cytochrome oxidase, both in the resting (as isolated) and pulsed (reduced and reoxidized) states, has been investigated using their ability to inhibit the autoxidation rate of pyrogallol and epinephrine. Resting oxidase showed variable SOD activity, while in the pulsed state the SOD activity of cytochrome oxidase (CcO) increased by an order of magnitude. These results are discussed in terms of a physiological role for the pulsed oxidase.

Theoretical approaches to D-amino acid oxidase

Several substrates and roles have been proposed for D-amino acid oxidase (E.C. 1.4.3.3.); however, there is no proof that they possess the required characteristics to account for the ubiquity, large amounts and great activity of the enzyme as found in diverse cells and tissues. Based on the similar stereoposition of identically charged atoms and lateral side chain (R) with respect to the alpha-hydrogen atoms in beta-sheet conformation and in D-amino acids, it is proposed that its substrates may include several membrane-related proteins, partially in beta-sheet conformation, whose alpha-hydrogen atoms would be the real object of D-amino acid oxidase catalysis. A monooxygenase-like enzymatic activity of D-amino acid oxidase with these novel substrates is considered, for which the final products are hypothesized to be protein alpha-carbon hydroxyls resulting from the incorporation of one atom of oxygen into the substrate, the other being reduced to water. Alternatively, it is also proposed that D-amino acid oxidase (and possibly other monooxygenase enzymes) would have a hydroperoxide-synthetase activity. In this case, protein alpha-carbon hydroperoxide and not water, but another reduced molecule, would be the final products. The new enzymatic performances of D-amino acid oxidase and the possible role of its potential final products in redox and other biochemical processes are discussed.

Cytochrome c peroxidase compound ES is identical with horseradish peroxide compound I in iron-ligand distances

X-ray absorption studies of compound ES of cytochrome c peroxidase show a short iron-oxygen distance of 1.67 +/- 0.04 A, an iron-histamine distance of 1.91 +/- 0.03 A, and an iron-pyrrole nitrogen average distance of 2.02 +/- 0.02 A. This is identical within the error with the reported structure of horseradish peroxidase compound I [Chance, B., Powers, L., Ching, Y., Poulos, T., Yamazaki, I., & Paul, K. G. (1984) Arch. Biochem. Biophys. 235, 596-611]. Comparisons of the structures of myoglobin peroxide [Chance, M., Powers, L., Kumar, C., & Chance, B. (1986) Biochemistry (preceding paper in this issue)], compound ES, and the intermediates of horseradish peroxidase reveal the possible mechanisms for the stabilization of the free radical species generated during catalysis. The proximal histidine regulates the structure and function of the pyrrole nitrogens and the heme, allowing for the formation and maintenance of the characteristic intermediates.

X-ray absorption studies of myoglobin peroxide reveal functional differences between globins and heme enzymes

X-ray absorption studies of myoglobin peroxide show that although it is not identical with compound I or II of horseradish peroxidase [Chance, B., Powers, L., Ching, Y., Poulos, T., Yamazaki, I., & Paul, K. G. (1984) Arch. Biochem. Biophys. 235, 596-611], it has some structural features in common with both. As seen in compound I, the Fe-O distance is short, but the iron-pyrrole nitrogen distance is contracted with a longer iron-histidine distance like compound II. The iron has a higher oxidation state than Fe3+, suggesting an oxyferryl ion type species. Comparison of the structures of various peroxidase and myoglobin compounds points out systematic differences that may explain the catalytic activity of the pi cation radical as well as some of the differences between globins and heme enzymes.

Chemiosmotic coupling in cytochrome oxidase. Possible protonmotive O loop and O cycle mechanisms

Using the principle of specific vectorial ligand conduction, we outline directly coupled protonmotive O loop and O cycle mechanisms of cytochrome oxidase action that are analogous to protonmotive Q loop and Q cycle mechanisms of QH2 dehydrogenase action. We discuss these directly coupled mechanisms in the light of available experimental knowledge, and suggest that they may stimulate useful new research initiatives designed to elucidate the osmochemistry of protonmotive oxygen reduction in cytochrome oxidase.

Resonance Raman spectroscopy and enhanced photoreducibility for the 420 nm pulsed form of cytochrome oxidase

Resonance Raman (RR) spectra, with 413.1 nm Kr+ laser excitation, are reported for cytochrome oxidase in resting, reduced, and 428 nm (oxygenated) forms, and for the first time, in the 420 nm (pulsed) forms [(1984) J. Biol. Chem. 259, 2073-2076]. The differences between the resting, 420 nm, and 428 nm forms' RR spectra are small. All these forms contain FeIII only, as indicated by single v4 bands at approximately 1371 cm-1, and the reoxidized forms show partial conversion from high- to intermediate- or low-spin heme a3 (intensity shift from 1575 to 1588 cm-1 for v2). The 420 nm form differs strikingly from both the 428 nm and resting forms, however, in being much more readily photoreduced by the laser illumination. This property is linked to the protein conformational change believed to be responsible for the greater accessibility to exogenous ligands of the heme a3 in the 420 nm form.

The mechanism of photosynthetic water oxidation

Photosynthetie water oxidation is unique to plants and cyanobacteria, it occurs in thylakoid membranes. The components associated with this process include: a reaction center polypeptide, having a molecular weight (Mr) of 47-50 kilodaltons (kDa), containing a reaction center chlorophyll a labeled as P680, a plastoquinol(?)-electron donor Z, a primary electron acceptor pheophytin, and a quinone electron acceptor QA; three 'extrinsic' polypeptides having Mr of approximately 17 kDa, 23 kDa, and 33 kDa; and, in all likelihood, an approximately 34 kDa 'intrinsic' polypeptide associated with manganese (Mn) atoms. In addition, chloride and calcium ions appear to be essential components for water oxidation. Photons, absorbed by the so-called photosystem II, provide the necessary energy for the chemical oxidation-reduction at P680; the oxidized P680 (P680(+)), then, oxidizes Z, which then oxidizes the water-manganese system contained, perhaps, in a protein matrix. The oxidation of water, leading to O2 evolution and H(+) release, requires four such independent acts, i.e., there is a charge accumulating device (the so-called S-states). In this minireview, we have presented our current understanding of the reaction center P680, the chemical nature of Z, a possible working model for water oxidation, and the possible roles of manganese atoms, chloride ions, and the various polypeptides, mentioned above. A comparison with cytochrome c oxidase, which is involved in the opposite process of the reduction of O2 to H2O, is stressed.This minireview is a prelude to the several minireviews, scheduled to be published in the forthcoming issues of Photosynthesis Research, including those on photosystem II (by H.J. van Gorkom); polypeptides of the O2-evolving system (by D.F. Ghanotakis and C.F. Yocum); and the role of chloride in O2 evolution (by S. Izawa).

Multiple structures and functions of cytochrome oxidase

X-ray absorption studies have been used to investigate the structure of the four redox centers (2Fe, 2Cu) of the terminal enzyme in the respiratory chain, cytochrome c oxidase in the resting oxidized form as well as in the functional intermediates that are freeze-trapped. Methods of x-ray fluorescence detection for these low-concentration samples together with low-temperature cryostats and simultaneous optical monitoring were developed to ensure good signal-to-noise data and sample integrity. The resting oxidized form contains a sulfur bridge between the copper and iron of the active site which are separated by approximately 3.8 A. This separation of the active site metal atoms was uniquely identified by comparison of both the iron and copper EXAFS data and iron EXAFS of the copper-depleted enzyme. In the reduced state, the CO or O2 is bound to the active site iron having a structure identical to CO or oxy hemoglobin while the sulfur remains with the active site copper. Little change in structure is observed for the other iron and copper. It is the sulfur bridged active site form that is isolated by the Yonetani and Caughy methods with greater than or equal to 85% homogeneity but not the Hartzell-Beinert or similar methods. Another form observed in the redox cycle is also fully oxidized but lacks the sulfur bridged active site with the iron of the active site having a structure identical to that of the peroxidases. This form exhibits peroxidase as well as oxidase activity, and a stable intermediate is formed with hydrogen and ethylhydrogen peroxide in which the iron of the active site is structurally similar to that of the peroxidase intermediate. The active site copper, however, does not participate in the peroxidatic role and the structures of the other iron and copper are identical to those of the sulfur bridged resting oxidized form. Thus this unique enzyme has peroxidase activity which may serve to safeguard its main oxidase function.

Pulsed cytochrome c oxidase

The identification of two functionally distinct states, called pulsed and resting, has led to a number of investigations on the conformational variants of the enzyme. However, the catalytic properties of cytochrome oxidase may depend on a number of experimental conditions related to the solvent as well as to the protocol followed to determine the turnover number of the enzyme. This paper reports results which illustrate that the steady-state differences between pulsed and resting oxidase may, or may not, be detected depending on experimental conditions.

Flow-flash, time-resolved resonance Raman spectroscopy of the oxidation of reduced and of mixed valence cytochrome oxidase by dioxygen

Time-resolved resonance Raman spectroscopy has been used to study the reduction of oxygen by both reduced and mixed valence cytochrome oxidase. Laser flash photodissociation of CO from the carbon monoxy complex of the enzyme, after this species had been rapidly mixed with oxygenated buffer, was used to initiate the reaction for both forms of the enzyme. The CO photolysis product of the mixed valence enzyme contains cytochrome a3+ and cytochrome a3(2+) in its unligated form. This species reacts with O2 in the first few microseconds to form a photolabile intermediate which has Raman frequencies characteristic of oxygenated heme. This indicates that an oxyhemoglobinlike complex of oxygen with a3(2+) is the precursor to oxygen reduction. A similar intermediate is detected in the fully reduced enzyme reaction. In the mixed valence oxidase system, the oxy intermediate is replaced by a nonphotolabile species in which a3 is oxidized with t1/2 approximately equal to 200 musec. These results demonstrate the feasibility of applying time-resolved vibrational techniques to irreversible electron transfer reactions and, in particular, elucidate some of the transient species in the cytochrome oxidase/O2 system.

X-ray absorption studies of intermediates in peroxidase activity

The structures of the enzyme-substrate compounds of peroxidases and catalase determined by X-ray absorption spectroscopy are presented. The valence state of the iron in Compounds I and II is determined from the edge to be higher than Fe+3. A short Fe-Ne (proximal histidine) distance is observed in all forms except Compound II, forcing the Fe-Np average distance to be long, a result which differentiates the peroxidases from the oxygen transport hemoproteins and plays a pivotal role in the mechanism. A correlation is shown between the ratio of peaks in the low k (ligand field indicator ratio) region, the Fe-Np (heme pyrrole nitrogen) average distance, and the magnetic susceptibility, which provides a sensitive indicator of spin state. The mechanism of H2O2 reduction is shown by analysis of the structural changes observed in the intermediates. Possible relationship of these compounds to that of the peroxidatic form of cytochrome oxidase is suggested by these results.

Pulsed cytochrome c oxidase from the thermophilic bacterium PS3

A caa3-type terminal cytochrome c oxidase (EC 1.9.3.1) from the thermophilic bacterium PS3 containing three subunits showed conversion from resting into pulsed form. Upon pulsing (reduction and re-oxidation), the cytochrome c oxidase activity increased over 10-fold. This enhanced activity of the pulsed enzyme gradually decayed. Addition of phospholipids, necessary for the enzyme activity, did not affect this decay process. Small changes in the absorption spectrum were observed for the resting-into-pulsed transition and for H2O2 ligation to the pulsed enzyme. The e.p.r. spectrum of the resting enzyme was very similar to that of mitochondrial enzyme, but the transient g = 5, 1.78 and 1.69 set of e.p.r. signals, associated with the pulsed bovine heart oxidase, were not observed in the case of pulsed bacterium-PS3 enzyme.