Kinetic studies of Rhus vernicifera laccase. Evidence for multi-electron transfer and an oxygen intermediate in the reoxidation reaction.

1. The reoxidation of reduced Rhus vernicifera laccase (monophenol,dihydroxyphenylalanine:oxygen oxidoreductase, EC 1.14.18.1) by molecular oxygen has been studied by optical absorption and EPR methods. 2. The reoxidation by oxygen of the type 1 Cu+ and the two-electron acceptor is characterized by a second-order rate constant of about 5-10(6) M-1-s-1. 3. The appearance of an optical intermediate (with an absorbance maximum around 360 nm) parallels the reoxidation of type 1 Cu+ and the two-electron acceptor. It disappears in a first-order reaction with a half-time of 20 s. A similar intermediate is formed during normal turnover. 4. The type 2 Cu+ appears to be reoxidized in an intramolecular reaction with a half-time of about 20 s, suggesting a correlation between the reoxidation of this site and the disappearance of the optical intermediate. 5. The results suggest that three electrons are rapidly transferred to oxygen leading to the formation of an enzyme-bound oxygen intermediate.     

EPR studies on the anaerobic reduction of fungal laccase. Evidence for participation of type 2 copper in the reduction mechanism.

1. In anaerobic reduction studies on fungal laccase B (p-diphenol:O2 oxidoreductase, EC 1.14.18.1) with the EPR and stopped-flow techniques it was found that the type 2 copper of the enzyme is rapidly undergoing a reduction-oxidation cycle which is followed by a slower reduction in a couple of seconds. An intermediate EPR signal of unknown origin is formed in the same time-range as the initial reduction of type 2 copper and disappears again when this copper ion is reoxidized. 2. The rate of the anaerobic reoxidation of type 2 copper is similar to the reduction rate of the two-electron acceptor, suggesting that they are interacting in the electron transfer of the enzyme. 3. The changes in the reaction rates of both type 2 and type 3 copper appear to be affected in a similar way by changes in pH. 4. The EPR signal of the type 2 Cu2+ suggests that this ion is liganded to one or more nitrogens.     

New method for removing type 2 copper from Rhus laccase

A new procedure is described for preparing tree laccase that is missing the type 2 copper. The derivative has only about 5% of the activity of the native enzyme, and some, or all, of the residual activity could be due to traces of holoprotein. The type 1 copper is fully oxidized in the purified type-2-depleted protein, while the type 3 site is reduced to the extent of at least 85%. However, the type 3 coppers can be reoxidized by treatment with excess H2O2. Reconstitution is achieved by incubation with Cu(I), and the remetalated protein exhibits the activity and the spectral properties of the native enzyme. The type 2 copper is removed by dialysis against a redox buffer containing ferri- and ferrocyanide ions as well as EDTA. More than 25% of the total copper is removed from laccase during the procedure, but the type-2-depleted fraction is readily isolated by means of an ion-exchange column. The practical advantages of this procedure are described. Finally, the simplicity of the method raises hopes that the mechanism of depletion can be defined.     

An epr signal from the half-reduced type 3 copper pair in Rhus vernicifera laccase

A new type of Cu(II) epr signals have been produced in native and type 2 copper depleted Rhus vernicifera laccase. They are shown to originate from one of the type 3 copper ions that are epr silent in the resting enzyme. The new epr signals show high rhombicity in g tensor and are similar to those observed in other proteins, such as superoxide dismutase and half-met hemocyanin. The half-reduced type 3 copper pair is formed by reduction with an electron from type 1 Cu(I) but only after a reoxidation of the copper pair, either by peroxide or dioxygen. It is suggested that the half-reduction of the type 3 copper pair only occurs in molecules where type 2 copper ion is either reduced or absent.     

Cu(I) analysis of blue copper proteins.

A simple colorimetric test for the Cu(I) content in blue copper proteins is described. The procedure is based on the formation of a complex between Cu(I) and 2,2'-biquinoline in an acetic acid medium. Analyses of spinach plastocyanin, Pseudomonas aeruginosa azurin and Rhus vernicifera stellacyanin show that the cysteine residue in the type 1 site does not induce Cu(II) reduction under our conditions. There is evidence in laccase samples for the presence of an endogenous reductant that can reduce 0.14 +/- 0.04 mol of Cu(II)/mol of protein; however, the addition of EDTA eliminates the interference. The analysis shows that 25 +/- 2% of the type 3 copper ions are in the reduced form in the resting enzyme and that 80 +/- 15% of the type 3 copper ions are reduced in preparations of type-2-depleted laccase. There is growing interest in the development of chemically modified forms of laccase, and our method should be very useful for establishing the valence state of the metal centres in the various derivatives.     

Effect of temperature on ppp(A2''p)nA binding protein activities in rabbit reticulocyte lysates and other mammalian extracts

New epr features consistent with a novel type of Cu(II) are observed in partially reduced Type 2 copper depleted laccase molecules. Cu(II) hyperfine lines appear near 2590 G and 2770 G, and a rhombic g1 feature is also observed. These reflect a Cu(II) emergent on reductive disruption of the binuclear Type 3 site in T2D laccase. Additionally, much of the new, magnetically isolated Cu(II) is retained on full reoxidation of partly reduced Type 2 copper depleted laccase. The proportion of disrupted Type 3 Cu(II) sites remaining after reoxidation appears to depend on the prior distribution of electrons within T2D laccase.     

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.     

Kinetic studies of Rhus vernicifera laccase. Role of the metal centers in electron transfer.

The reactions of Rhus vernicifera (monophenol,dihydroxyphenylalanine: oxygen oxidoreductase, EC 1.14.18.1) with the reducing substrates hydroquinone and ascorbic acid have been investigated with the stopped-flow technique. Rhus laccase appears to be present in two molecular forms with a pH-sensitive equilibrium constant regulating the relative concentrations of each species. A model for the reaction of Rhus laccase with reducing substrates has been formulated. The model is similar to one formulated earlier for the anaerobic reduction of laccase from Polyporus versicolor (Andréasson, L.-E., Malstr?m, B.G., Str?mberg, C. and V?nng?rd, T. (1973) Eur. J. Biochem. 34, 434-439) and accounts for the reduction also of this enzyme. The essentials of the model are as follows: Electrons are taken up from reductants one at a time. The type 1 Cu2+ has a central role in mediating the transfer of at least one of the electrons needed for the reduction of the co-operative two-electron acceptor. Intramolecular reactions determine the concentrations of two molecular forms of the enzyme and influence the rate of reduction of the two-electron acceptor. The model, which has been used for successful simulations of the anaerobic reduction of Rhus laccase, is capable of explaining the reduction of laccases also in the presence of the inhibitor F-. In addition, the model gives an explanation of the behaviour of the laccases when reducing substrates and O2 are simultaneously present and is consistent with earlier observations of the post-steady-state reduction of the type 1 Cu2+ and the two-electron accetor (Holwerda, R.A. and Gray, H.B. (1974) J. Am. Chem. Soc. 96, 6008-6022).     

Characterization of cucumber ascorbate oxidase and its reaction with hexacyanoferrate (II)

The spectroscopic features of cucumber ascorbate oxidase (AOase) and its type-2 copper-depleted (T2D) derivative, and the electron pathway among the copper sites in the enzyme have been investigated. The electronic and CD spectra of native and T2D AOase in the visible region bear a striking resemblance to those of plastocyanin or azurin, which contain type-1 copper alone. The electronic absorption shoulder of the native enzyme at around 330 nm for the native enzyme which has been assigned to type-3 copper disappears with the depletion of the type-2 copper. The reduction of AOase with a large excess of hexacyanoferrate(II) results in a selective reduction of the type-2 Cu, giving rise to an additional EPR-detectable species which is considered to be originated from partly reduced type-3 copper. The type-1 copper is, however, not reduced even in the presence of excess hexacyanoferrate(II). The redox potential of type-1 Cu was determined to be +350 mV, which is distinctly lower than that of hexacyanoferrate(II-III). Type-2 copper was supposed to be a mediator of the electron transfer between type-1 and type-3 coppers in consideration of the extremely low activity of the T2D enzyme under the same condition. A comparison of the electron pathway in AOase with that in laccase is also argued.     

Optical properties of japanese-lacquer-tree (Rhus vernicifera) laccase depleted of type 2 copper(II). Involvement of type-2 copper(II) in the 330nm chromophore.

1. Spectroscopic and functional properties of Japanese-lacquer-tree (Rhus vernicifera) laccase were re-investigated, with special emphasis on the relationships between the different types of copper centres (Types 1, 2, and 3). 2. On removal of the Type 2 Cu(II), a decrease of absorbance occurred in the wavelength region above 650 nm (delta epsilon 750 = 300 M-1 . cm-1) and around 330 nm (delta episom 330 up to 2200 M-1 . cm-1). 3. Reductive titrations with ascorbic acid or ferrocyanide showed that the electron-accepting capacity of the partial apoprotein is one electron-equivalent lower than that of the native protein, i.e. the protein two-electron acceptor is present in the oxidized state in spite of absorbance loss at 330 nm. 4. The 330 nm chromophore apparently depends on the presence of both the Type 2 and the Type 3 copper in the oxidized state. 5. This finding may have implications in the relative location of Type 2 and 3 copper centres and on the redox behaviour of laccase.     

Titrations with ferrocyanide of japanese-lacquer-tree (Rhus vernicifera) laccase and of the type 2 copper-depleted enzyme. Interrelation of the copper sites.

1. Redox titrations are reported of the metal centres in Japanese-lacquer-tree (Rhus vernicifera) laccase with ferrocyanide. 2. The redox potential of Type 1 Cu was found to increase with ferrocyanide concentration up to a limiting value similar to that for the Type 1 Cu in Type 2 Cu-depleted enzyme (which is independent of ferrocyanide concentration). 3. The redox potential of the two-electron acceptor (Type 3 Cu) is also independent of ferrocyanide concentration in Type 2 Cu-depleted enzyme and lower than values reported for the native enzyme. 4. The two-electron acceptor is present in the oxidized state in the Type 2 Cu-depleted enzyme, though the latter lacks the 330 nm absorption band. 5. The redox potential of Type 2 Cu also depends on ferrocyanide concentration, at least in the presence of azide. 6. The redox potentials are affected by freezing the solutions and/or addition of azide, the latter binding to Type 2 Cu with affinity dependent on the redox state of the two-electron acceptor.     

Which Copper is Paramagnetic in the Type 2/Type 3 Cluster of Laccase?

 Understanding the structure and function of the three copper atoms in the dioxygen reduction site of the blue oxidases such as laccase has been a long standing challenge. In the case of a widely studied derivative, known as type 2-depleted laccase, the removal of one copper from the cluster abolishes the EPR signal of the so-called type 2 copper. However, the present studies of isotopically enriched protein from Polyporus versicolor show that the readily replaceable copper is not active in the low-temperature EPR spectrum of fungal laccase or its difluoride adduct. The same is true for the difluoride adduct of the tree enzyme. Thus, in type 2-depleted laccase the pattern of antiferromagnetic coupling is quite different from that of the native protein or the difluoride adduct. Received: 5 October 1998 / Accepted: 13 January 1999     

Type 2-depleted fungal laccase.

Although copper is quantitatively removed from fungal laccase (Polyporus versicolor) by extended dialysis against high concentrations of cyanide, we have been unable to reconstitute the protein by addition of Cu(I) ions. However, two new methods for reversibly removing the type 2 Cu centre have been developed. The visible absorption at 610 nm, which is attributable to type 1 Cu, is unaffected by the procedure, but the absorbance of the type 3 Cu at 330 nm is decreased by 60 +/- 10%. The decrease is due, at least in part, to partial reduction of the binuclear type 3 centre, although there may be some change in the molar absorptivity of the oxidized chromophore as well. The change in the c.d. spectrum that occurs at approx. 350 nm may be explained in the same way, but it may also reflect the loss of a signal due to the type 2 Cu. Upon removal of the type 2 Cu an absorbance increase appears at approx. 435 nm, and it is assigned to the semi-reduced form of the type 3 pair. In the e.p.r. spectrum of the type 2-depleted enzyme the type 1 Cu signal exhibits well-resolved ligand hyperfine splitting, which can be simulated on the basis of contributions from two N and two H nuclei (AH congruent to AN congruent to 25 MHz). The H atoms are assumed to be attached to the beta-carbon of the covalently bonded cysteine ligand. A signal from a semi-reduced form(s) of the type 3 site can also be resolved in the spectrum of the type 2-depleted enzyme, and on the basis of the second integral of the e.p.r. spectrum 40% of the type 3 pairs are believed to be in a partially reduced state. The semi-reduced type 3 site is remarkably stable and is not readily oxidized by H2O2 or IrCl6(2-) or reduced by Fe(CN)6(4-). Intramolecular electron transfer is apparently quite slow in at least some forms of the type 2-depleted enzyme, and this may explain why the activity is at best 5% of that of the native enzyme. Full activity returns when type 2 copper is restored.     

Copper transfer from Rhus vernicifera laccase.

Tree laccase, a multi-copper oxidase, has been studied as a copper donor in conjunction with the demetalated forms of three blue copper proteins. Copper transfer could be observed under reducing conditions in the absence of air. Only about 10% of the total copper in laccase could be transferred regardless of the amount of acceptor present in solution, hence, the laccase is heterogeneous as isolated. Potential sources of the heterogeneity are considered. After transfer, laccase could be partially resolved into copper-deficient and nearly holoprotein fractions that would not donate copper when recombined with acceptor protein. EPR results in conjunction with thiol titrations indicate that there is no net loss of type 1 copper from laccase but that there is loss of type 2 copper as well as a small amount of type 3 copper. Very little transfer is observed when type 2-depleted laccase is used as the donor. Finally, the implications that these results could have in the elucidation of possibly more physiologically relevant processes are briefly summarized.     

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.     

A new copper(II) electron paramagnetic resonance signal in two laccases and in cytochrome c oxidase

A new EPR signal from Cu2+ has been discovered in reductive experiments with type 2 copper-depleted laccase from Polyporus versicolor. A novel EPR signal has also been found in native laccase from Rhus vernicifera on oxidation of the reduced protein with H2O2. In reoxidation experiments with cytochrome c oxidase from beef heart, a new Cu2+ signal has been observed. With Rhus laccase, the new signal is shown to originate from one of the copper ions that are nondetectable in the resting enzyme, and evidence is presented for the signals in Polyporus laccase and cytochrome c oxidase also stemming from the metal pairs that are antiferromagnetically coupled in the oxidized enzymes. The new signals show strong rhombic character, and the EPR parameters place them in a category different from the signals of type 1 as well as of type 2 Cu2+ ions.     

A novel mixed valence form of Rhus vernicifera laccase and its reaction with dioxygen to give a peroxide intermediate bound to the trinuclear center

Rhus vernicifera laccase, in a novel mixed valence state [T1oxT23red: type 1 Cu as Cu(II), and type 2 and 3 Cus as Cu(I)], was formed by reacting Cu(I) on the type 2 Cu-depleted laccase [T1oxT3red: type 1 Cu as Cu(II) and type 3 Cus as Cu(I)] under argon. Contrary to T1oxT3red, T1oxT23red was highly reactive with dioxygen, and gave the three transient bands at 340, 475, and 680 nm due to the two-electron reduced form of dioxygen [charge transfer bands from peroxide to Cu(II)]. The first order decays were highly dependent on pH, which led to the successful detection of the intermediate for ca. 2 h at pH 7.5. Another mixed valence derivative, T12oxT3red [type 1 and type 2 Cus as Cu(II), and type 3 Cus as Cu(I)] prepared through the action of Cu(II) on T1oxT3red was not reactive with dioxygen, but showed high enzyme activity as to the oxidation of N,N-dimethyl-p-phenylenediamine. The whole reaction mechanism of the reduction of dioxygen by laccase was proposed based on the present results together with data for the former detection and characterization of the three-electron reduced form of dioxygen [Huang, H. et al. (1999) J. Biol. Chem. 274, 46, 32718-32724].     

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 characterization and O2 reactivity of the trinuclear Cu cluster of mutants of the multicopper oxidase Fet3p

Fet3p is a multicopper oxidase that uses four copper ions (one type 1, one type 2, and one type 3 binuclear site) to couple substrate oxidation to the reduction of O(2) to H(2)O. The type 1 Cu site shuttles electrons between the substrate and the type 2/type 3 Cu sites which form a trinuclear Cu cluster that is the active site for O(2) reduction. This study extends the spectroscopic and reactivity studies that have been conducted with type 1-substituted Hg (T1Hg) laccase to Fet3p and a mutant of Fet3p in which the trinuclear Cu cluster is perturbed. To examine the reaction between the trinuclear Cu cluster and O(2), the type 1 Cu Cys(484) was mutated to Ser, resulting in a type 1-depleted (T1D) form of the enzyme. Additional His to Gln mutations were made at the trinuclear cluster to further probe specific contributions to reactivity. One of these mutants (His(126)Gln) produces the first stable but perturbed trinuclear Cu cluster (T1DT3' Fet3p). Spectroscopic characterization (absorption, circular dichroism, magnetic circular dichroism, and electron paramagnetic resonance) of the resting trinuclear sites in T1D and T1DT3' Fet3p reveal that the His(126)Gln mutation changes the electronic structure of both the type 3 and type 2 Cu sites. The trinuclear clusters in T1D and T1DT3' Fet3p react with O(2) to produce peroxide intermediates analogous to that observed in T1Hg laccase. Spectroscopic data on the peroxide intermediates in the three forms provide further insight into the structure of this intermediate. In T1D Fet3p, the decay of this peroxide intermediate is pH-dependent, and the rate of decay is 10-fold higher at low pH. In T1DT3' Fet3p, the decay of the peroxide intermediate is pH-independent and is slow at all pH's. This change in the pH dependence provides new insight into the mechanism of intermediate decay involving reductive cleavage of the O-O bond.     

The 1H-NMR relaxation of Rhus laccase: assignment to different types of copper

1H-NMR relaxation measurements of Rhus laccase showed that a portion of the relaxivity was specifically abolished by less than stoichiometric EDTA. Another portion of relaxivity was removed by addition of N3(-) to the EDTA saturated enzyme. This treatment or selective removal of the Type 2 Cu left a large residual paramagnetic relaxivity (1700 M-1s-1) which was assigned to the Type 1 Cu. It is concluded that only a portion of the laccase relaxivity can be assigned to the Type 1 Cu and that this copper type does not behave homogeneously: the two fractions have different relaxivity, 5200 and less than or equal to 2400 M-1s-1 respectively.