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.

The type 2 copper of ascorbate oxidase.

Ascorbate oxidase, dissolved in Hepes or sodium phosphate buffers, was analyzed by EPR and activity measurements before and after storage at -30 degrees C and 77 K. The specific activity was somewhat higher in the phosphate buffer, about 3500-3700 Dawson units compared to about 3100 units of the enzyme dissolved in Hepes buffer. After storage at -30 degrees C the activity fell to 1400-2000 units in the phosphate buffer but only to 2600-2800 units in the Hepes buffer. Large changes occurred in the EPR spectrum of enzyme dissolved in the phosphate buffer after storing at -30 degrees C suggesting an alteration of the type 2 copper site. These changes were, however, reverted when the samples were thawed and rapidly frozen at 77 K. Copper analysis showed that about 50% of the total copper was EPR detected. The type 2 Cu2+ EPR intensity was in most samples close to 25% of the total EPR intensity. This low contribution of type 2 Cu2+ could not be changed if the enzyme was completely reduced and reoxidized, treated with Fe(CN)6(3), large excess of NaF, addition of 50% (v/v) ethylene glycol or dialyzed against 0.1 M Mes buffer (pH 5.5). Since the crystal structure shows that there are one each of types 1 and 2 copper in the monomers there must be another species with an EPR signal rather different from these two copper species. This signal is proposed to originate from some trinuclear centers. The EPR simulations show that it is possible to house a broad unresolved signal under the resolved type 1 and 2 signals so that the total integral becomes 50% of the total copper in the molecule.

Effect of pH and ligand binding on the structure of the Cu site of the Met121Glu mutant of azurin from Pseudomonas aeruginosa.

A pH-dependent X-ray absorption fine structure (XAFS) study has been undertaken to provide a structural interpretation of the spectroscopic properties of the Met121 Glu mutant of azurin from Pseudomonas aeruginosa (Azp). Ligand binding studies have been carried out to investigate the effect of the cavity formed at the Cu site as a result of the mutation. The optical spectrum at pH 4 exhibits an intense band at approximately 600 nm and a weaker band at approximately 450 nm, typical for the blue copper proteins. As the pH is increased, these bands decrease in intensity and shift to 570 and 413 nm, respectively, with the latter becoming the more intense of the two [Karlsson, B.G., et al. (1991) Protein Eng. 4 (3), 343-349]. These changes are accompanied by a change in the EPR spectrum from a rhombic type 1 Cu spectrum at pH 4 to a spectrum with the rhombic splitting decreasing to zero and the hyperfine coupling increasing from 25 to 83 G. X-ray absorption a the Cu K-edge shows that this change results from the lengthening of the Cu-His (by 0.07 A) and Cu-Cys (by 0.06 A) bonds and the coordination of one of the oxygen atoms of the glutamate ligand at pH 8, at a distance as close as 1.90 A. The copper site thus changes from a normal type 1 copper center with three strong bonds at pH 4 to a copper site with four strong bonds at pH 8, with Cu-His distances significantly longer than known distances for type 1 copper centres measured using the XAFS technique. The XAFS of the azide derivative measured at pH 8 shows a similar Cu coordination, with azide replacing glutamate as the fourth ligand. Azide binding at pH 8 is accompanied by a further increase in the EPR hyperfine coupling to 110 G. This structural information when taken together with recent structural sudies on copper proteins points toward the need for a reexamination of the basis on which copper proteins are classified.

Development of a gas-phase oxygen biosensor using a blue copper-containing oxidase.

A gas-phase oxygen biosensor based on blue copper-containing oxidases was developed. Blue-oxidase enzymes, including laccase and ascorbate oxidase, have a blue chromophore prosthetic group, type 1 Cu+2, which can be reduced and decolorized with reducing substrates. When the enzyme is reoxidized with molecular oxygen, there is a concomitant return of the blue color. The oxygen biosensor consisted of the Rhus vernicifera laccase and ascorbate as substrate enclosed in pouches of low-density polyethylene under nitrogen gas. Operational stability of the biosensor was established by exposing it to different oxygen/nitrogen gas mixtures at 5 degrees C. Gas-phase oxygen concentrations were measured by keeping it under nitrogen gas and subsequently recording the rate of reappearance of the enzyme blue color, both visually and spectrophotometrically at 610 nm. The oxygen biosensor was able to detect a wide range of oxygen concentrations. The time required to recover the blue color, namely the biosensor response time, at the optimized assay conditions of 5 degrees C and a high-water activity level, was determined. This research describes the development of an oxygen biosensor with adequate activity and stability to measure gas-phase oxygen concentrations at 5 degrees C and high-water activity levels. The oxygen biosensor could be used to indicate oxygen concentrations above acceptable levels in headspace oxygen concentration which could affect the quality and safety of products packaged under initial low levels of oxygen concentration.

Structural and spectroscopic studies of the copper site of stellacyanin.

The structure of the copper site in oxidized and reduced Rhus vernicifera stellacyanin has been studied by X-ray absorption (XAFS) spectroscopy at different pH values. Data for the oxidized protein are consistent with the fourth ligand being an O- or N-donating ligand rather than a cysteine from the disulfide bridge. The fourth ligand is not present in the inner coordination sphere, but makes a more distant interaction 2.7 A from the copper atom. Only minor changes in the details of the Cu(II) coordination occur when the pH is varied. Direct structural information on reduced stellacyanin is provided. Upon reduction, one of the histidine ligands moves away from the copper atom by at least 0.2 A. A low-Z (O or N) scatterer is present approximately 2.4 A from the Cu(I) atom in the protein at low pH, and this ligand is lost at high pH. There is no evidence for an S-donating fourth ligand in the reduced protein. The XAFS results are presented in relation to the spectroscopic and structural information available for some methionine-121 mutants of azurin. The data reveal that there are spectroscopic similarities between stellacyanin and some of the mutant proteins, but distinct structural differences exist that preclude these proteins as suitable models for the copper site of stellacyanin.

Crystallization and preliminary crystallographic data for the azurin mutant End-121 from Pseudomonas aeruginosa.

Pseudomonas aeruginosa azurin has been crystallized from a mutant where residues from Met 121 to Lys128 have been deleted from the protein. The crystals form pale-blue well formed prisms in the orthorhombic space group P2(1)2(1)2(1), with cell dimensions a = 60.79 (5), b = 123.47 (5), c = 187.77 (5) A. The crystals diffract to 3.0 A and there are eight molecules in the asymmetric unit.

Structural characterization of azurin from Pseudomonas aeruginosa and some of its methionine-121 mutants.

Azurin from Pseudomonas aeruginosa and two mutants where the methionine ligand has been mutated have been studied in order to directly investigate the functional and structural significance of this ligand in the blue copper proteins. Reduction potentials, X-ray absorption fine structure (XAFS), electron paramagnetic resonance (EPR), and optical spectra are obtained in an attempt to provide a direct correlation between the spectrochemical properties and the immediate structure of this redox center.

Comparison of lignin peroxidase, horseradish peroxidase and laccase in the oxidation of methoxybenzenes.

Lignin peroxidase oxidizes non-phenolic substrates by one electron to give aryl-cation-radical intermediates, which react further to give a variety of products. The present study investigated the possibility that other peroxidative and oxidative enzymes known to catalyse one-electron oxidations may also oxidize non-phenolics to cation-radical intermediates and that this ability is related to the redox potential of the substrate. Lignin peroxidase from the fungus Phanerochaete chrysosporium, horseradish peroxidase (HRP) and laccase from the fungus Trametes versicolor were chosen for investigation with methoxybenzenes as a homologous series of substrates. The twelve methoxybenzene congeners have known half-wave potentials that differ by as much as approximately 1 V. Lignin peroxidase oxidized the ten with the lowest half-wave potentials, whereas HRP oxidized the four lowest and laccase oxidized only 1,2,4,5-tetramethoxybenzene, the lowest. E.s.r. spectroscopy showed that this congener is oxidized to its cation radical by all three enzymes. Oxidation in each case gave the same products: 2,5-dimethoxy-p-benzoquinone and 4,5-dimethoxy-o-benzoquinone, in a 4:1 ratio, plus 2 mol of methanol for each 1 mol of substrate. Using HRP-catalysed oxidation, we showed that the quinone oxygen atoms are derived from water. We conclude that the three enzymes affect their substrates similarly, and that whether an aromatic compound is a substrate depends in large part on its redox potential. Furthermore, oxidized lignin peroxidase is clearly a stronger oxidant than oxidized HRP or laccase. Determination of the enzyme kinetic parameters for the methoxybenzene oxidations demonstrated further differences among the enzymes.

Proton-metal distance determination in cobalt(II) stellacyanin by 1H nuclear magnetic resonance relaxation measurements including Curie-spin effects: a proposed structure of the metal-binding region.

1H nuclear magnetic resonance (1H NMR) experiments on Co(II)-substituted stellacyanin have been performed. Large paramagnetic hyperfine shifts are observed, the whole spectrum covering a range of 190 ppm. Experiments were mainly performed at 270 MHz from which temperature and pH* dependencies of the out-shifted resonances were reported, as well as determinations of the longitudinal (T1) and transverse (T2) relaxation times. These relaxation times are among other things, dependent on the individual proton-metal distance, and the aim of this work has been to determine these distances, by use of the Solomon-Bloembergen equations modified to include the so-called "Curie spin". The application of this method to a protein has not been reported earlier. Experiments were also performed at 100, 400, and 500 MHz in order to estimate the size of the Curie spin from the field dependence of the line widths. Furthermore, determination of the values for the rotational correlation time, tau r, and the effective magnetic moment, mu eff, was necessary for the present approach. With apostellacyanin, tau r was found to be (6.0 +/- 0.4) X 10-8 s. From the paramagnetic susceptibility of Co(II) stellacyanin, the value (4.53 +/- 0.03)beta was determined for mu eff. The proposed assignments of several paramagnetically out-shifted resonances. the proton-metal distances obtained, and the known peptide sequence of stellacyanin have allowed us to build a three-dimensional model of the metal site and its surrounding structure consistent with all the experimental data. It is revealed that both histidine ligands bind the metal with their 3-nitrogens. Also we find strong indications that a second sulfur atom is actually binding the metal, this being the long-sought-after fourth ligand. The model suggests that this sulfur belongs to Cys-59, which together with Cys-93 constitutes the disulfide bridge known to be present in the structure. A potential fifth ligand, an amide oxygen from Asn-47, is also found.

The metal site of stellacyanin: EXAFS studies of the Cu(II), Cu(I), Ni(II) and Co(II) derivatives.

Extended X-ray absorption fine structure (EXAFS) studies of Cu(II) (oxidized), Cu(I) (reduced), Ni(II) and Co(II) stellacyanin from Rhus vernicifera are reported. For Cu(II) stellacyanin, the coordination by three close ligands, viz. 2 N and 1 S, with the presence of smaller shells pointing to imidazole coordination, indicates similarities with the coordination in other so-called type 1 or 'blue'-copper proteins. Upon reduction, slightly longer ligand distances and an additional sulphur ligand are found. Ni(II) and Co(II) stellacyanin resemble Cu(I) and Cu(II) stellacyanin, respectively, in ligand distances, but have a tendency for three rather than two N (or O) ligands in the first shell. The results are compared with the three-dimensional model derived from 1H-NMR relaxation measurements for Co(II) stellacyanin, and are consistent with the proposal that apart from the three close ligands found in all blue-copper proteins, a sulphur from a disulphide bridge and the amide oxygen from an asparagine residue come to within coordinating distance of the metal in stellacyanin.

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.

EPR of azurins from Pseudomonas aeruginosa and Alcaligenes denitrificans demonstrates pH-dependence of the copper-site geometry in Pseudomonas aeruginosa protein.

The X- and Q-band EPR spectra of Pseudomonas aeruginosa (63Cu)azurin and Alcaligenes denitrificans azurin have been measured at pH = 5.2 and 9.2, in the presence and absence of 40% glycerol. The EPR spectra of both proteins could properly be simulated by taking into account a spread in the tetrahedral angle of the copper site. The change in the EPR spectrum of Pseudomonas aeruginosa (63Cu)azurin that is observed upon an increase of the pH from 5.2 to 9.2 is consistent with a small decrease of the average tetrahedral angle from 61 degrees to 60 degrees. This geometrical change is consistent with the interpretation of earlier NMR and EXAFS observations. No pH effect is observed for Alcaligenes denitrificans azurin, in agreement with predictions based on crystallographic evidence. Glycerol has only a marginal effect on the appearance of the EPR spectra, and does not alleviate the "g-strain."

63/65Cu and 1/2H2O isotope shifts in the low-temperature resonance Raman spectrum of fungal laccase.

Resonance Raman spectra are reported for the type 1 Cu site of fungal laccase at 295 and 77 K. The low-temperature spectra show enhanced resolution and reveal several weak bands not previously observed, as well as overtone and combination bands associated with the strong approximately equal to 400 cm-1 fundamentals. A novel low-temperature Raman difference technique has been used to obtain 63/65Cu and 1/2H2O isotope shifts. The strong band at 428 cm-1, and the moderate intensity bands at 408 and 387 cm-1 show small (under 0.6 cm-1 63/65Cu isotope shifts. The aggregate shift is substantially less than that expected for an isolated Cu-S(cys) stretch, implying a high degree of mixing of this coordinate with internal modes of the ligands. 1/2H2O shifts of 1.1 and approximately equal to 0.3 cm-1 are observed for the 387 and 428 cm-1 bands. The isotope shift patterns are quite similar for fungal and tree laccase, as are the frequencies of the dominant bands, indicating that the large differences in relative intensity are primarily associated with differences in the excited state potential. The frequency and isotope shift patterns are appreciably different, however, from those observed for azurin and stellacyanin. In contrast to the other 'blue' Cu proteins, fungal laccase shows no moderate intensity band near 270 cm-1 which can be associated with Cu-imidazole stretching; weak features are seen in this region, but the intensities are too low to determine their 1/2H2O sensitivity. The C-S stretching mode of fungal laccase is identified at 737 cm-1, shifting to 741 cm-1 at 77 K. It is about 10 cm-1 lower than for most 'blue' Cu proteins, and the difference is suggested to reflect smaller kinematic coupling between the C-S and Cu-S coordinates, associated with a smaller Cu-S-C angle. Combination modes of the approx. 400 cm-1 fundamentals are substantially stronger, relative to the overtones, than is predicted by first-order scattering theory, implying changes in the excited-state normal modes (Dushinsky effect) associated with force constant alterations.

Direct measurement of the self-exchange rate of stellacyanin by a novel e.p.r. method.

A method for reconstituting the blue copper protein stellacyanin with the stable copper isotopes 63Cu and 65Cu is reported. Small differences in the e.p.r. spectra of the two isotopic forms of stellacyanin have been used to monitor the electron self-exchange reaction of stellacyanin by rapid-freeze e.p.r. methods. The self-exchange rate constant (k11) for stellacyanin has been determined as 1.2 X 10(5) M-1 X S-1 at 20 degrees C. This value is in close agreement with values obtained from less-direct methods.

Coordination environment for the type 3 copper center of tree laccase and CuB of cytochrome c oxidase as determined by electron nuclear double resonance.

A new rhombic EPR signal was recently discovered in the partially reduced type 2 copper-depleted Rhus vernicifera laccase (Reinhammar, B. (1983) J. Inorg. Biochem., in press). The signal originates from one of the type 3 Cu(II) ions that becomes EPR-detectable as a result of the selective reduction of the other copper ion in the exchange-coupled Cu(II)-Cu(II) pair. The 14N and 1H and 63,65Cu electron nuclear double resonance (ENDOR) of this uncoupled Cu(II) now have been collected and represent the first ENDOR measurements of a type 3 copper site. The data indicate that the copper is coordinated by at least three nitrogenous ligands, at least one of which is an imidazole. H/D exchange suggests a nearby H2O or OH-, perhaps as a fourth ligand. A similar EPR signal is seen for CuB of reduced cytochrome c oxidase under turnover conditions. The 14N ENDOR, and, therefore, the structure, of this site corresponds extremely closely to that of the laccase type 3 (Cu(II).

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.

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.

The reaction of mercaptans with tyrosinases and hemocyanins.

1. Titration of Neurospora tyrosinase with 2-mercaptoethanol shows that the increase of absorbance at 700 nm is directly correlated to the loss of enzymatic activity. Approximately 2 mol of 2-mercaptoethanol per mole of protein are needed for full development of the green, enzymatically inactive complex. The increase of absorbance at 700 nm is also proportional to the intensity of the EPR signal and the amount of non-covalently bound 2-[35S] mercaptoethanol to the enzyme. The maximal EPR intensity reaches 70% of the protein concentration and at most 0.7--0.8 mol of 2-[35S] mercaptoethanol is bound per mol of enzyme. 2. Stopped-flow measurements show that in the reaction between 2-mercaptoethanol and Neurospora tyrosinase a raction intermediate with a strong absorption band at 360 nm is formed in an apparent second-order reaction. This intermediate displays no EPR-detectable signals. The intermediate decays in a similar complex fashion as the absorption band at 700 nm is formed. 3. The reaction of Neurospora tyrosinase with a variety of sulfhydryl compounds was also investigated. In most cases green coloured, enzymatically inactive complexes are formed displaying slightly different EPR signals. However, with cysteine and cysteamine violet coloured, enzymatically inactive complexes are formed which show rather different EPR signals. The integrated EPR intensities amount to 40--70% of the protein concentration. Based on simulations of 9 and 35 GHz spectra all observed EPR spectra can be represented as true S = 1/2 systems. The cysteamine complex can be interpreted as arising from a mixed valence Cu2+ . Cu+ complex. The 2-mercaptoethanol spectra can, however, arise from sulphur radicals. 4. Treatment of Agaricus bispora tyrosinase and Cancer pagures hemocyanin with 2-mercaptoethanol results in green-coloured, EPR detectable complexes similar to the one found with Neurospora tyrosinase. No such complexes are formed when hemocyanins from Helix pomatia and Panulirus interruptus were treated with this reagent.

The state of copper in Neurospora laccase.

1. Neurospora crassa laccase has been prepared from the growth medium and studied by optical absorption, circular dichroism and electron paramagnetic resonance (EPR) spectroscopy. The molecular weight, the copper content and the amino acid composition have also been determined. 2. The molecular weight as determined by gel filtration in 6 M guanidine hydrochloride and by sodium dodecyl sulfate gel electrophoresis is found to be 64 000. The enzyme contains 3.8 copper ions per 64 000. 3. The visible and the near ultraviolet difference absorption spectrum shows two maxima, at 330 and 595 nm, and a shoulder at about 720 nm. The circular dichroism spectrum between 300 and 760 nm contains five bands in the oxidized enzyme. After reduction of the enzyme with ascorbate there remains only a band at 305 nm. 4. EPR measurements show that 52% of the total copper in the protein is paramagnetic. Two EPR signals of equal intensity with different hyperfine splitting constants, of 9 and 18.5 mT, are present, which are assigned to Type 1 Cu2+ and Type 2 Cu2+, respectively, as found in other blue copper-containing oxidases.