Crystal structures of multicopper oxidase CueO bound to copper(I) and silver(I): functional role of a methionine-rich sequence

The multicopper oxidase CueO oxidizes toxic Cu(I) and is required for copper homeostasis in Escherichia coli. Like many proteins involved in copper homeostasis, CueO has a methionine-rich segment that is thought to be critical for copper handling. How such segments function is poorly understood. Here, we report the crystal structure of CueO at 1.1 Å with the 45-residue methionine-rich segment fully resolved, revealing an N-terminal helical segment with methionine residues juxtaposed for Cu(I) ligation and a C-terminal highly mobile segment rich in methionine and histidine residues. We also report structures of CueO with a C500S mutation, which leads to loss of the T1 copper, and CueO with six methionines changed to serine. Soaking C500S CueO crystals with Cu(I), or wild-type CueO crystals with Ag(I), leads to occupancy of three sites, the previously identified substrate-binding site and two new sites along the methionine-rich helix, involving methionines 358, 362, 368, and 376. Mutation of these residues leads to a ∼4-fold reduction in k_cat for Cu(I) oxidation. Ag(I), which often appears with copper in nature, strongly inhibits CueO oxidase activities in vitro and compromises copper tolerance in vivo, particularly in the absence of the complementary copper efflux cus system. Together, these studies demonstrate a role for the methionine-rich insert of CueO in the binding and oxidation of Cu(I) and highlight the interplay among cue and cus systems in copper and silver homeostasis.     

Crystal structures of E. coli laccase CueO at different copper concentrations

CueO protein is a hypothetical bacterial laccase and a good laccase candidate for large scale industrial application. Four CueO crystal structures were determined at different copper concentrations. Low copper occupancy in apo-CueO and slow copper reconstitution process in CueO with exogenous copper were demonstrated. These observations well explain the copper dependence of CueO oxidase activity. Structural comparison between CueO and other three fungal laccase proteins indicates that Glu106 in CueO constitutes the primary counter-work for reconstitution of the trinuclear copper site. Mutation of Glu106 to a Phe enhanced CueO oxidation activity and supported this hypothesis. In addition, an extra alpha-helix from Leu351 to Gly378 covers substrate biding pocket of CueO and might compromises the electron transfer from substrate to type I copper.     

Fluoride effects on the activity of Rhus laccase and the catalytic mechanism under steady-state conditions

Laccase uses three types of Cu(II) sites to catalyze the reduction of O2 to H2O. Fluoride binds to the type 2 site. The effects of F- on the kinetics of O2 reduction were examined to determine the catalytic roles of the copper sites. Under steady-state conditions, F- rapidly inhibits the oxidation of dimethylphenylenediamine. Both reductant-dependent and -independent steps are inhibited. Rapid-freeze ESR spectra under steady-state conditions showed that F- decreased the steady-state concentrations of oxidized type 1 copper and oxidized type 2 copper while increasing the concentration of an oxygen radical intermediate. Stopped-flow kinetic experiments were used to determine the catalytic step(s) affected by F-. The most significant effect of F- was on the reductant-dependent rate of reduction of the type 3 site. While a strictly first-order dependence was observed in the absence of F-, a hyperbolic dependence was detected in the presence of F- indicating a limiting reductant-independent step. The steady-state kinetic rapid-freeze ESR and stopped-flow kinetic data are consistent with the implicated step being the reduction of the oxygen radical in an intermediate containing reduced type 1 and reduced type 2 copper. The results suggest a role for the type 2 Cu(I) site in binding the oxygen radical and catalyzing its reduction to H2O.     

Enhancement of laccase activity through the construction and breakdown of a hydrogen bond at the type I copper center in Escherichia coli CueO and the deletion mutant Δα5-7 CueO

CueO is a multicopper oxidase involved in a copper efflux system of Escherichia coli and has high cuprous oxidase activity but little or no oxidizing activity toward various organic substances. However, its activity toward oxidization of organic substrates was found to be considerably increased by the removal of the methionine-rich helical segment that covers the substrate-binding site (Δα5-7 CueO) [Kataoka, K., et al. (2007) J. Mol. Biol. 373, 141]. In the study presented here, mutations at Pro444 to construct a second NH-S hydrogen bond between the backbone amide and coordinating Cys500 thiolate of the type I copper are shown to result in positive shifts in the redox potential of this copper center and enhanced oxidase activity in CueO. Analogous enhancement of the activity of Δα5-7 CueO has been identified only in the Pro444Gly mutant because Pro444 mutants limit the incorporation of copper ions into the trinuclear copper center. The activities of both CueO and Δα5-7 CueO were also enhanced by mutations to break down the hydrogen bond between the imidazole group of His443 that is coordinated to the type I copper and the β-carboxy group of Asp439 that is located in the outer sphere of the type I copper center. A synergetic effect of the positive shift in the redox potential of the type I copper center and the increase in enzyme activity has been achieved by the double mutation of Pro444 and Asp439 of CueO. Absorption, circular dichroism, and resonance Raman spectra indicate that the characteristics of the Cu(II)-S(Cys) bond were only minimally perturbed by mutations involving formation or disruption of a hydrogen bond from the coordinating groups to the type I copper. This study provides widely applicable strategies for tuning the activities of multicopper oxidases.     

A labile regulatory copper ion lies near the T1 copper site in the multicopper oxidase CueO

CueO, a multicopper oxidase, is part of the copper-regulatory cue operon in Escherichia coli, is expressed under conditions of copper stress and shows enhanced oxidase activity when additional copper is present. The 1.7-A resolution structure of a crystal soaked in CuCl2 reveals a Cu(II) ion bound to the protein 7.5 A from the T1 copper site in a region rich in methionine residues. The trigonal bipyramidal coordination sphere is unusual, containing two methionine sulfur atoms, two aspartate carboxylate oxygen atoms, and a water molecule. Asp-439 both ligates the labile copper and hydrogen-bonds to His-443, which ligates the T1 copper. This arrangement may mediate electron transfer from substrates to the T1 copper. Mutation of residues bound to the labile copper results in loss of oxidase activity and of copper tolerance, confirming a regulatory role for this site. The methionine-rich portion of the protein, which is similar to that of other proteins involved in copper homeostasis, does not display additional copper binding. The type 3 copper atoms of the trinuclear cluster in the structure are bridged by a chloride ion that completes a square planar coordination sphere for the T2 copper atom but does not affect oxidase activity.     

Structure and function of the engineered multicopper oxidase CueO from Escherichia coli--deletion of the methionine-rich helical region covering the substrate-binding site

CueO is a multicopper oxidase (MCO) that is involved in the homeostasis of Cu in Escherichia coli and is the sole cuprous oxidase to have ever been found. Differing from other MCOs, the substrate-binding site of CueO is deeply buried under a methionine-rich helical region including alpha-helices 5, 6, and 7 that interfere with the access of organic substrates. We deleted the region Pro357-His406 and replaced it with a Gly-Gly linker. The crystal structures of a truncated mutant in the presence and in the absence of excess Cu(II) indicated that the scaffold of the CueO molecule and metal-binding sites were reserved in comparison with those of CueO. In addition, the high thermostability of the protein molecule and its spectroscopic and magnetic properties due to four Cu centers were also conserved after truncation. As for functions, the cuprous oxidase activity of the mutant was reduced to ca 10% that of recombinant CueO owing to the decrease in the affinity of the labile Cu site for Cu(I) ions, although activities for laccase substrates such as 2,2'-azino-bis(3-ethylbenzothiazoline-6-sulfonic acid), p-phenylenediamine, and 2,6-dimethoxyphenol increased due to changes in the access of these organic substrates to the type I Cu site. The present engineering of CueO indicates that the methionine-rich alpha-helices function as a barrier to the access of bulky organic substrates, which provides CueO with specificity as a cuprous oxidase.     

Four-electron Reduction of Dioxygen by a Multicopper Oxidase, CueO, and Roles of Asp112 and Glu506 Located Adjacent to the Trinuclear Copper Center

The mechanism of the four-electron reduction of dioxygen by a multicopper oxidase, CueO, was studied based on reactions of single and double mutants with Cys⁵⁰⁰, a type I copper ligand, and the noncoordinating Asp¹¹² and Glu⁵⁰⁶, which form hydrogen bonds with the trinuclear copper center directly and indirectly via a water molecule. The reaction of C500S containing a vacant type I copper center produced intermediate I in an EPR-silent peroxide-bound form. The formation of intermediate I from C500S/D112N was restricted due to a reduction in the affinity of the trinuclear copper center for dioxygen. The state of intermediate I was realized to be the resting form of C500S/E506Q and C500S of the truncated mutant Δα5–7CueO, in which the 50 amino acids covering the substrate-binding site were removed. Reactions of the recombinant CueO and E506Q afforded intermediate II, a fully oxidized form different from the resting one, with a very broad EPR signal, g < 2, detectable only at cryogenic temperatures and unsaturated with high power microwaves. The lifetime of intermediate II was prolonged by the mutation at Glu⁵⁰⁶ involved in the donation of protons. The structure of intermediates I and II and the mechanism of the four-electron reduction of dioxygen driven by Asp¹¹² and Glu⁵⁰⁶ are discussed.CueO is a multicopper oxidase involved in a copper efflux system of Escherichia coli (1–3). In contrast to other multicopper oxidases such as laccase and ascorbate oxidase (4), CueO exhibits strong activity toward cuprous ion but does not show activity toward most organic substrates such as 2,6-dimethoxyphenol, catechol, and guaiacol, except considerably low levels toward 2,2′-azinobis(3-ethylbenzothiazoline-6-sulfonic acid) (ABTS)² and p-phenylenediamine. This substrate specificity, unique to CueO, originates in the methionine-rich helical region covering the substrate-binding site (5–7). Nevertheless, CueO has the same catalytic copper centers as other multicopper oxidases: a type I copper that mediates electron transfer and a trinuclear copper center comprised of a type II copper and a pair of type III copper atoms, where dioxygen is reduced to two water molecules (5, 7). The type I copper is responsible for the intense charge transfer band at 610 nm due to Cys(S^-)_π → Cu²⁺ and the bands at 430, ∼500, and ∼750 nm due to the charge transfers His(N) → Cu²⁺ and Cys(S^-)_σ → Cu²⁺ and d-d transitions, respectively (4). The type III copper atoms bridged with a hydroxide ion afford an intense charge transfer band, OH^- → Cu²⁺ at ∼330 nm, whereas the type II copper does not give a conspicuous band in the visible region. The type I and II coppers give rise to EPR signals with the hyperfine splitting of small (6.7 milliteslas (mT)) and normal (18.5 mT) magnitudes, respectively, whereas the type III copper atoms are EPR-silent because of the strong anti-ferromagnetic interaction (7–9).Special attention has been paid to the four-electron reduction of dioxygen by multicopper and terminal oxidases because activated oxygen species such as superoxide, peroxide, etc. are not formed or, if formed, are effectively converted into water molecules without damage to protein molecules. Therefore, this four-electron reduction of dioxygen by multicopper oxidases has been expected to be applicable to biofuel cells (10–12). Two reaction intermediates have been detected during reactions of some multicopper oxidases. One of them, intermediate I, could be trapped by the following modified multicopper oxidases so as to interrupt the electron transfer from the type I copper: a plant laccase whose type I copper was substituted with mercury (13); a mixed valent laccase in which the type I copper was oxidized, but the trinuclear copper center was reduced (14); and a Cys → Ser mutant of bilirubin oxidase (15) and Fet3p (16) whose type I copper center became vacant. Although the trinuclear copper center must be fully reduced to produce intermediate I, it has been considered to be a two-electron reduced form and, therefore, also called the peroxide intermediate (13, 16). Another reaction intermediate, II, also called the native intermediate, has been detected at the final stage of a single turnover (15, 17–19). Four electrons have already been transferred to dioxygen in this intermediate, and accordingly, intermediate II is in a fully oxidized form to give the g < 2 EPR signal at cryogenic temperatures. Under catalytic conditions, intermediate II is not detected because of its prompt conversion to the fully reduced form for the next enzyme cycle without decaying to the resting form. Both intermediates have a half-life in the order of seconds to minutes, but information to directly show their structures has not been obtained yet. They afford analogous absorption bands at ∼330–350, 450–470, and 680 nm, of which the former two bands have been assigned to the charge transfer from a certain oxygen group to Cu²⁺ (σ and π transitions) and the latter to the d-d transitions of the trinuclear copper center in the cupric state. The d-d transitions of intermediate II are masked by strong absorption due to the oxidized type I copper (13–19).In the present study, we succeeded in trapping intermediates I and II from reactions of a recombinant form of CueO (rCueO) and mutants altered at Cys⁵⁰⁰, a ligand to the type I copper, and at Asp¹¹² and Glu⁵⁰⁶ located adjacent to the trinuclear copper center to modify the dioxygen reduction process. The Asp residue is conserved in every multicopper oxidase except for ceruloplasmin, which has Glu instead (Fig. 1). According to the x-ray crystal structures of rCueO (5) and the truncated mutant, Δα5–7CueO, missing the 50 amino acids covering the substrate-binding site (Fig. 2) (7, 20), Asp¹¹² forms a hydrogen bond with His⁴⁴⁸, a ligand to a type III copper, and indirectly with the water molecule coordinating the type II copper through an ordered water molecule. In a preliminary study on the Asp¹¹² mutants (21), we showed that this acidic amino acid functions in the binding of dioxygen at the trinuclear copper center and may also be involved in the donation of protons to the reaction intermediate(s). On the other hand, one to three acidic amino acids are present in the spacers to connect the copper ligands of multicopper oxidases, His-Cys-His-XXX-His-XXXX-Met-(Leu/Phe). Fig. 2 shows that Glu⁵⁰⁶ of CueO in this spacer is directly hydrogen-bonded with the His¹⁴³ ligand to one of the type III copper atoms and indirectly with the hydroxide ion bridged between the type III copper atoms through an ordered water molecule. Therefore, Glu⁵⁰⁶ is also speculated to play a crucial role in the reduction of dioxygen. We singly and doubly mutated Cys⁵⁰⁰, Asp¹¹², and Glu⁵⁰⁶ of CueO to trap intermediates I and II and to elucidate the mechanism behind the four-electron reduction of dioxygen.Open in a separate windowFIGURE 1.Homology of amino acid sequence around the copper binding sites of multicopper oxidase. The numbers 1, 2, and 3 represent the type I, II, and III copper ligands, respectively. BO, Myrothecium verrucaria bilirubin oxidase; RvLc, Rhus vernicifera laccase; CpAO, Cucurbita pepo ascorbate oxidase; TvLc, Trametes versicolor laccase; CcLc, Coprinus cinereus laccase; Fet3p, multicopper oxidase from Saccharomyces cerevisiae; CumA, multicopper oxidase from Pseudomonas putida; CotA, multicopper oxidase from Bacillus subtilis; SLAC, small laccase from Streptomyces coelicolor; hCp, human ceruloplasmin. The single asterisk represents the conserved acidic amino acid residue in all multicopper oxidases, and the double asterisk represents Glu⁵⁰⁶ in CueO, which forms a hydrogen bond with a His residue coordinating a type III copper and the hydroxide ion bridged between type III coppers.Open in a separate windowFIGURE 2.Structure around the active site of the truncated mutant of CueO (7). Type I, II, and III coppers are represented as spheres. Small spheres, oxygen atoms. The two networks of hydrogen bonds lead to the exterior of the protein molecule, forming the pathway to let protons in and water molecules out. Mutated amino acid residues, Cys⁵⁰⁰, Glu⁵⁰⁶, and Asp¹¹², and the networks of hydrogen bonds are indicated.     

Reactions of nitric oxide with tree and fungal laccase

The reactions of nitric oxide (NO) with the oxidized and reduced forms of fungal and tree laccase, as well as with tree laccase depleted in type 2 copper, are reported. The products of the reactions were determined by NMR and mass spectroscopy, whereas the oxidation states of the enzymes were monitored by EPR and optical spectroscopy. All three copper sites in fungal laccase are reduced by NO. In addition, NO forms a specific complex with the reduced type 2 copper. NO similarly reduces all of the copper sites in tree laccase, but it also oxidizes the reduced sites produced by ascorbate or NO reduction. A catalytic cycle is set up in which N2O, NO2-, and various forms of the enzyme are produced. On freezing of fully reduced tree laccase in the presence of NO, the type 1 copper becomes reoxidized. This reaction does not occur with the enzyme depleted in type 2 copper, suggesting that it involves intramolecular electron transfer from the type 1 copper to NO bound to the type 2 copper. When the half-oxidized tree laccase is formed in the presence of NO, a population of molecules exists which exhibits a type 3 EPR signal. A triplet EPR signal is also seen in the same preparation and is attributed to a population of the enzyme molecules in which NO is bound to the reduced copper of a half-oxidized type 3 copper site.     

Spectroscopic and catalytic properties of Rhus vernicifera laccase depleted in type 2 copper.

1. The type 2 copper in Rhus vernicifera laccase was completely removed without loss of other types of copper. The properties of this protein derivative and the role of type 2 copper in the catalytic action of laccase was investigated. 2. The molar extinction coefficient at 614 nm of the blue chromophore decreases from 5700 to 4700 cm-1 on removal of type 2 copper. There are no apparent absorption changes at other wavelengths in the visible or near ultraviolet region when this copper is taken away. The electron-paramagnetic-resonance (epr) parameter A parallel and the linewidth of type 1 Cu2+ decreases on removal of type 2 copper. 3. The rate of reduction of type 1 Cu2+ is not affected by removal of type 2 copper but the reduction of the two-electron acceptor is greatly impaired. These results strongly support the idea that type 1 Cu2+ is the primary site for electron transfer between substrate and enzyme and that the two-electron acceptor in the native enzyme is reduced by simultaneous electron transfer from reduced types 1 and 2 copper. 4. Reoxidation of types 1 and 3 copper and the formation of the oxygen intermediate are the same processes in native and type-2-depleted enzyme. These observations suggests that type 2 copper is not involved in the formation and rapid decay of the oxygen intermediate and that it is not necessary for the stabilization of this intermediate. 5. Two new epr signals are observed on reoxidation of reduced type-2-depleted laccase. One is temporarily formed on re-reduction of reoxidized enzyme and it is suggested that it might arise from copper, possibly type 3 copper. The other one is stable for hours and it is proposed that it might come from a modified oxygen intermediate.     

The mechanism of electron transfer in laccase-catalysed reactions.

1. The reaction of the electron acceptors in Rhus vernicifera laccase (monophenol, dihydroxyphenylalanine:oxygen oxidoreductase, EC 1.14.18.1) have been studied with stopped-flow and rapid-freeze EPR techniques. The studies have been directed mainly towards elucidation of the role of the type 2Cu2+ as a possible pH-sensitve regulator of electron transfer. 2. Anaerobic reduction experiments with Rhus laccase indicate that the type 1 and 2 sites contribute one electron each to the reduction of the two-electron-accepting type 3 site. There is also evidence that the reduction of the type 1 Cu2+ triggers the reduction of the type 2 Cu2+. 3. Only at pH values at which the reduction of the two-electron acceptor is limited by a slow intramolecular reaction can an OH- be displaced from the type 2 Cu2+ by the inhibitor F-. 4. A model describing the role of the electron-accepting sites in catalysis is formulated.     

An e.p.r. study of the non-equivalence of the copper sites of caeruloplasmin.

The two Type 1 (blue) copper-binding sites of caeruloplasmin were spectroscopically differentiated by the kinetic analysis of the e.p.r. spectra during the redox cycle. One blue copper, with a hyperfine splitting constant (A parallel) of 6.8 mT, which was rapidly reduced, was not reoxidized by oxygen, whereas it was reoxidized by H2O2. The other blue copper (A parallel = 5.8 mT), which was reduced slowly, was rapidly reoxidized by either oxygen or H2O2. A conformational change of the Type 2 copper was concomitant with the fast reduction of Type 1 copper, whereas its reduction occurred during the slow phase. This sequence of events was reversed in the reoxidation step, that is, the Type 2 copper reappeared rapidly as the species with altered conformation and reverted to the symmetry typical of the native state in the slow phase. The specific reaction of a blue-copper site with the H2O2 can tentatively be related to the established ability of caeruloplasmin to prevent 'oxidative' attack of proteins and lipids.     

Optical properties and a new epr signal from type 3 copper in metal-depleted Rhus vernicifera laccase

Due to conflicting reports on the properties of Rhus laccase depleted in type 2 copper a further investigation of this protein derivative has been undertaken. In contrast to most other reports it is shown that the type 3 copper site retains its absorbance at 330 nm when type 2 copper is removed. The type 3 copper ions are oxidized in the resting protein and part of the type 3 Cu(II) can be made electron paramagnetic resonance (epr) detectable on reduction by ascorbate. This new epr signal is highly rhombic and the epr parameters are comparable to those found in other metalloproteins containing Cu(II) in binuclear sites. Certain preparations of type 2 deficient protein exhibit lower extinction coefficients at 330 nm. Since these protein derivatives have lost some type 3 copper, it is inferred that the absorbance at 330 nm is dependent on a native type 3 copper site. Also in contrast to other reports, it is found that the extinction coefficient at 614 nm of the type 1 Cu(II) decreases from 5700 to 4700 M^?1cm^?1 when type 2 copper is removed. The oxidized-reduced difference spectrum also shows a substantial decrease in the absorbance between 700 and 800 nm. The changes in absorbance above 600 nm are probably due to a modification of the type 1 Cu(II) site on removal of type 2 copper. The present results also suggest some explanations to the apparent discrepancies among the earlier reports.     

Cuprous oxidase activity of CueO from Escherichia coli

We have found CueO from Escherichia coli to have a robust cuprous oxidase activity, severalfold higher than any homologue. These data suggest that a functional role for CueO in protecting against copper toxicity in vivo includes the removal of Cu(I).     

Spectroscopic analysis of the trinuclear cluster in the Fet3 protein from yeast, a multinuclear copper oxidase

The Fet3 protein (Fet3p) is a multinuclear copper oxidase essential for high-affinity iron uptake in yeast. Fet3p contains one type 1, one type 2, and a strongly antiferromagnetically coupled binuclear Cu(II)-Cu(II) type 3 copper. The type 2 and type 3 sites constitute a structurally distinct trinuclear cluster at which dioxygen is reduced to water. In Fet3p, as in ceruloplasmin, Fe(II) is oxidized to Fe(III) at the type 1 copper; this is the ferroxidase reaction that is fundamental to the physiologic function of these two enzymes. Using site-directed mutagenesis, we have generated type 1-depleted (T1D), type 2-depleted (T2D), and T1D/T2D mutants. None were active in the essential ferroxidase reaction catalyzed by Fet3p. However, the spectroscopic signatures of the remaining Cu(II) sites in any one of the three mutants were indistinguishable from those exhibited by the wild type. Although the native protein and the T1D mutant were isolated in the completely oxidized Cu(II) form, the T2D and T1D/T2D mutants were found to be completely reduced. This result is consistent with the essential role of the type 2 copper in dioxygen turnover, and with the suggestions that cuprous ion is the valence state of intracellular copper. Although stable to dioxygen, the Cu(I) sites in both proteins were readily oxidized by hydrogen peroxide. The double mutant was extensively analyzed by X-ray absorption spectroscopy. Edge and near-edge features clearly distinguished the oxidized from the reduced form of the binuclear cluster. EXAFS was strongly consistent with the expected coordination of each type 3 copper by three histidine imidazoles. Also, copper scattering was observed in the oxidized cluster along with scattering from a ligand corresponding to a bridging oxygen. The data derived from the reduced cluster indicated that the bridge was absent in this redox state. In the reduced form of the double mutant, an N/O ligand was apparent that was not seen in the reduced form of the T1D protein. This ligand in T1D/T2D could be either the remaining type 2 copper imidazole ligand (from His416) or a water molecule that could be stabilized at the type 3 cluster by H-bonding to this side chain. If present in the native protein, this H(2)O could provide acid catalysis of dioxygen reduction at the reduced trinuclear center.     

Linkage between catecholate siderophores and the multicopper oxidase CueO in Escherichia coli

The multicopper oxidase CueO had previously been demonstrated to exhibit phenoloxidase activity and was implicated in intrinsic copper resistance in Escherichia coli. Catecholates can potentially reduce Cu(II) to the prooxidant Cu(I). In this report we provide evidence that CueO protects E. coli cells by oxidizing enterobactin, the catechol iron siderophore of E. coli, in the presence of copper. In vitro, a mixture of enterobactin and copper was toxic for E. coli cells, but the addition of purified CueO led to their survival. Deletion of fur resulted in copper hypersensitivity that was alleviated by additional deletion of entC, preventing synthesis of enterobactin. In addition, copper added together with 2,3-dihydroxybenzoic acid or enterobactin was able to induce a Phi(cueO-lacZ) operon fusion more efficiently than copper alone. The reaction product of the 2,3-dihydroxybenzoic acid oxidation by CueO that can complex Cu(II) ions was determined by gas chromatography-mass spectroscopy and identified as 2-carboxymuconate.     

Photoreduction of copper chromophores in blue oxidases.

The low temperature (77 K) irradiation of oxidized ceruloplasmin and Rhus vernicifera laccase at the 330 nm absorption which arises from type 3 copper leads to the reduction of type 1 copper as demonstrated by bleaching of the 610 nm chromophore and the decrease of the EPR signal associated with this species. Type 2 copper remains unaffected. Concomitant with the type 1 copper reduction, a new EPR signal which is possibly that of a biradical appears. Upon thawing, type 1 copper is reversibly oxidized and the radical signal disappears. Irradiation of oxidized protein at the absorption band of type 1 copper produces no spectral change. An EPR study at room temperature confirms the wave-length specificity and reversibility of the photoreduction of type 1 copper and radical formation. Radical appearance and disappearance at room temperature are extremely slow (tau1/2 approximately 30 min). Optical studies at room temperature show that upon anaerobic irradiation of laccase in the 330 nm absorption band, both type 3 and type 1 chromophores are slowly reduced. Upon return to the dark and in the presence of O2, both type 3 and type 1 centers are reoxidized. Oxidizing equivalents either from O2 or K3Fe(CN)6 are required for the reoxidation reaction. These studies demonstrate that there is a direct energy transfer between type 3 and type 1 copper sites in blue copper oxidases.     

Simulation of the cavity-binding site of three bacterial multicopper oxidases upon complex stabilization: interactional profile and electron transference pathways

Previous studies have shown that multicopper oxidases (MCOs) oxidize organic and inorganic compounds through oxidation–reduction reactions in which three structurally and functionally arranged copper centers coordinate the uptake of an electron from a reduced substrate. Structural comparisons among three bacterial MCOs, with high structural homology and available three-dimensional information, reveal that the primary structural differences between these MCOs are located near the mononuclear copper center (T1Cu), where substrate oxidation occurs, as opposed to where the reduction of oxygen to water occurs at the trinuclear center. Nevertheless, this substrate oxidation is achieved through an outer-sphere electron transfer mechanism that does not generate a stable substrate–enzyme complex. In this study, MCOs from Thermus thermophilus (Tth-MCO), Bacillus subtilis (CotA), and Escherichia coli (CueO), which have been previously determined through X-ray crystallography, were used as models to analyze the binding modes of these MCOs to three organic molecules, with specific interest in the substrate-binding site. The binding mode of the electron-donor molecule to the electron transfer binding site was primarily attributed to hydrophobic contacts, which likely play an important role in the determination of substrate specificity. Some complexes generated in this study showed an electron donor molecule conformation in which an electron could be directly transferred to the histidines coordinating T1Cu, while for others additional electron transference pathways were also possible through the participation of charged residues during electron transfer.     

Functional intermediates in the reaction of membrane-bound cytochrome oxidase with oxygen.

Flash photolysis of the membrane-bound cytochrome oxidase/carbon monoxide compound in the presence of oxygen at low temperatures and in the frozen state leads to the formation of three types of intermediates functional in electron transfer in cytochrome oxidase and reduction of oxygen by cytochrome oxidase. The first category (A) does not involve electron transfer to oxygen between -125 degrees and -105 degrees, and includes oxy compounds which are spectroscopically similar for the completely reduced oxidase (Cu1+alpha3(2+)-O2) or for the ferricyanide-pretreated oxidase (Cu2+alpha3(3+)-O2). Oxygen is readily dissociated from compounds of type A. The second category (B) involves oxidation of the heme and the copper moiety of the reduced oxidase to form a peroxy compound (Cu2+alpha 3(3+)-O2=or Cu2+alpha3(2+)-O2H2) in the temperature range from -105 degrees to -60 degrees. Above -60 degrees, compounds of type B serve as effective electron acceptors from cytochromes a, c, and c1. The third category (C) is formed above -100 degrees from mixed valency states of the oxidase obtained by ferricyanide pretreatment, and may involve higher valency states of the heme iron (Cu2+alpha3(4+)-O2=). These compounds act as electron acceptors for the respiratory chain and as functional intermediates in oxygen reduction. The remarkable features of cytochrome oxidase are its highly dissociable "oxy" compound and its extremely effective electron donor reaction which converts this rapidly to tightly bound reduced oxygen and oxidized oxidase.     

CueO is a multi-copper oxidase that confers copper tolerance in Escherichia coli

The putative multi-copper oxidase CueO had previously been implicated in intrinsic copper resistance in Escherichia coli. In this report we showed that the presence of CueO in the periplasm protected alkaline phosphatase from copper-induced damage. CueO contained four copper atoms per molecule and displayed spectroscopic properties typical of blue copper oxidases. CueO catalyzed the oxidation of p-phenylenediamine (pPD), 2,6-dimethoxyphenol (DMP) and exhibited ferroxidase activity in vitro.     

Met144Ala mutation of the copper-containing nitrite reductase from Alcaligenes xylosoxidans reverses the intramolecular electron transfer

Pulse radiolysis has been employed to investigate the intramolecular electron transfer (ET) between the type 1 (T1) and type 2 (T2) copper sites in the Met144Ala Alcaligenes xylosoxidans nitrite reductase (AxCuNiR) mutant. This mutation increases the reduction potential of the T1 copper center. Kinetic results suggest that the change in driving force has a dramatic influence on the reactivity: The T2Cu(II) is initially reduced followed by ET to T1Cu(II). The activation parameters have been determined and are compared with those of the wild-type (WT) AxCuNiR. The reorganization energy of the T2 site in the latter enzyme was calculated to be 1.6+/-0.2 eV which is two-fold larger than that of the T1 copper center in the WT protein.