The pH and redox-state dependence of the copper site in azurin from Pseudomonas aeruginosa as studied by EXAFS

The EXAFS of the K-edge of copper in azurin from Pseudomonas aeruginosa has been measured in solutions of the oxidized and reduced protein, at both low and high pH. Model compounds of known molecular structure, exhibiting Cu-N and Cu-S bonds of varying length, were studied as well. The major shell of the high-pH oxidized azurin EXAFS contains contributions of two N(His) at 1.95 +/- 0.03 A, and one S(Cys) at 2.23 +/- 0.03 A. Some minor contributions from the carbon atoms of the histidine residues and the distal sulfur atom are observed in the 3-4 A region. Upon reduction a decrease is seen in amplitude of the main peak in the Fourier transform, due to a lengthening of one of the Cu-N(His) bonds (2.05 +/- 0.03 A), and a shortening of the other (1.89 +/- 0.03 A), both by approx. 0.1 A. Indications for a Cu-S(Met) bond are found in the reduced azurin data (2.70 +/- 0.05 A). However, in the oxidized protein, this bond could not be determined unambiguously, in line with results of a model compound featuring weak Cu-thioether coordination. The effect of pH is only slight for both the oxidized and the reduced protein, and no significant changes in bond lengths are found upon a change of pH from 4.1 to 9.1. The relevance of these findings for the interpretation of the existing data on the redox activity of the protein is discussed.     

Resonance Raman spectroscopy of amicyanin, a blue copper protein from Paracoccus denitrificans

The copper binding site of amicyanin from Paracoccus denitrificans has been examined by resonance Raman spectroscopy. The pattern of vibrational modes is clearly similar to those of the blue copper proteins azurin and plastocyanin. Intense resonance-enhanced peaks are observed at 377, 392, and 430 cm-1 as well as weaker overtones and combination bands in the high frequency region. Most of the peaks below 500 cm-1 shift 0.5-1.5 cm-1 to lower energy when the protein is exposed to D2O. Based on the pattern of conserved amino acids, the axial type EPR spectrum, and the resonance Raman spectrum, it is proposed that the copper binding site in amicyanin contains a Cu(II) ion in a distorted trigonal planar geometry with one cysteine and two histidine ligands and an axial methionine ligand at a considerably longer distance. Furthermore, the presence of multiple intense Raman peaks in the 400 cm-1 region which are sensitive to deuterium substitution leads to the conclusion that the Cu-S stretch is coupled with internal ligand vibrational modes and that the sulfur of the cysteine ligand is likely to be hydrogen-bonded to the polypeptide backbone.     

A copper-methionine interaction controls the pH-dependent activation of peptidylglycine monooxygenase

The pH dependence of native peptidylglycine monooxygenase (PHM) and its M314H variant has been studied in detail. For wild-type (WT) PHM, the intensity of the Cu-S interaction visible in the Cu(I) extended X-ray absorption fine structure (EXAFS) data is inversely proportional to catalytic activity over the pH range of 3-8. A previous model based on more limited data was interpreted in terms of two protein conformations involving an inactive Met-on form and an active flexible Met-off form [Bauman, A. T., et al. (2006) Biochemistry 45, 11140-11150] that derived its catalytic activity from the ability to couple into vibrational modes critical for proton tunneling. The new studies comparing the WT and M314H variant have led to the evolution of this model, in which the Met-on form has been found to be derived from coordination of an additional Met residue, rather than a more rigid conformer of M314 as previously proposed. The catalytic activity of the mutant decreased by 96% because of effects on both k(cat) and K(M), but it displayed the same activity-pH profile with a maximum around pH 6. At pH 8, the reduced Cu(I) form gave spectra that could be simulated by replacement of the Cu(M) Cu-S(Met) interaction with a Cu-N/O interaction, but the data did not unambiguously assign the ligand to the imidazole side chain of H314. At pH 3.5, the EXAFS still showed the presence of a strong Cu-S interaction, establishing that the Met-on form observed at low pH in WT cannot be due to a strengthening of the Cu(M)-methionine interaction but must arise from a different Cu-S interaction. Therefore, lowering the pH causes a conformational change at one of the Cu centers that brings a new S donor residue into a favorable orientation for coordination to copper and generates an inactive form. Cys coordination is unlikely because all Cys residues in PHM are engaged in disulfide cross-links. Sequence comparison with the PHM homologues tyramine β-monooxygenase and dopamine β-monooxygenase suggests that M109 (adjacent to H site ligands H107 and H108) is the most likely candidate. A model is presented in which H108 is protonated with a pK(a) of 4.6 to generate the inactive low-pH form with Cu(H) coordinated by M109, H107, and H172.     

EXAFS of the type-1 copper site of rusticyanin

Extended X-ray absorption fine structure (EXAFS) spectra at the Cu K-edge have been recorded of the oxidized and reduced form at pH 3.5 of rusticyanin, the type-1 or 'blue'-copper protein from Thiobacillus ferrooxidans. The EXAFS of oxidized rusticyanin is well simulated with models assuming a ligand set of 2 N(His) and 1 S(Cys) at 1.99 and 2.16 A, respectively. Upon reduction, the average Cu-N ligand distance increases by approx. 0.08A. For both redox states studied, the fit by the simulation is significantly improved by including a contribution of an additional sulfur ligand at approx. 2.8 A. From comparison with structural data of other blue-copper proteins, it is concluded that the copper coordination environment is relatively rigid, which may be a clue to its high redox potential.     

Characterization of the tryptophan-derived quinone cofactor of methylamine dehydrogenase by resonance Raman spectroscopy

The resonance Raman (RR) spectrum of oxidized methylamine dehydrogenase (MADHOX) exhibits a set of C-H, C-C, C = C, and C = O vibrational modes between 900 and 1700 cm-1 that are characteristic of the quinone moiety of the tryptophan tryptophlyquinone (TTQ) cofactor. The close similarity of the RR spectra for MADHs from Paracoccus denitrificans (Pd), Thiobacillus versutus (Tv), and bacterium W3A1 proves that the same cofactor is present in all three proteins. The MADHs from Pd and Tv have a v(C = O) mode at approximately 1625 cm-1 that shifts approximately 20 cm-1 upon 18O substitution of one of the carbonyl oxygens and is assigned to the in-phase symmetric stretch of the two C = O groups. The semiquinone form of Pd MADH has its own characteristic RR spectrum with altered peak frequencies and intensities as well as a decrease in the total number of peaks. The hydroxide and ammonia adducts of MADHOX produce RR spectra similar to that of the semiquinone. The spectral changes in all three cases are interpreted as being due to reduced conjugation of the cofactor. The ammonia adduct is formulated as a carbinolamine, a likely intermediate in the enzymatic mechanism. In contrast, formation of the electron-transfer complex between amicyanin and MADHOX has no effect on the vibrational frequencies (and, hence, structure) of either the MADH quinone or the amicyanin blue copper site. The behavior of the TTQ cofactors of Pd and Tv MADHs are very similar to one another and somewhat different from W3A1 MADH, particularly with regard to adduct formation and ability to undergo isotope exchange with solvent. These differences are ascribed to the cofactor environments within the proteins rather than to the structure of the cofactor itself.     

Quantifying energetic contributions to ground state destabilization

Solution differential scanning calorimetry (DSC) of oxidized amicyanin, a Type I copper protein, at pH 7.5 reveals two thermal transitions. The major transition at 67.7 degrees C corresponds to the disruption of the Cys(92) thiolate to Cu(II) charge transfer as evidenced by a corresponding temperature-dependent loss of amicyanin visible absorbance. A minor transition at 75.5 degrees C describes the further irreversible protein unfolding. Reduced amicyanin exhibits a pH-dependent change of the copper ligand geometry. At pH 8.5 where the Type I tetrahedral geometry is maintained, DSC reveals two thermal transitions with T(m) values similar to that of oxidized amicyanin. At pH 6.2 where the Cu(I) coordination is trigonal planar, reduced amicyanin exhibits a single thermal transition with a lower T(m) of 64.0 degrees C. Apoamicyanin, from which copper has been removed, also exhibits a single thermal transition but with a much lower T(m) of 51.8 degrees C. Thus, the thermal stability of amicyanin is dictated both by the presence or absence of copper and its ligand geometry, but not its redox state. The physiological relevance of these data is discussed.     

Resonance Raman spectra of plastocyanin and pseudoazurin: evidence for conserved cysteine ligand conformations in cupredoxins (blue copper proteins)

New resonance Raman (RR) spectra at 15 K are reported for poplar (Populus nigra) and oleander (Oleander nerium) plastocyanins and for Alcaligenes faecalis pseudoazurin. The spectra are compared with those of other blue copper proteins (cupredoxins). In all cases, nine or more vibrational modes between 330 and 460 cm-1 can be assigned to a coupling of the Cu-S(Cys) stretch with Cys ligand deformations. The fact that these vibrations occur at a relatively constant set of frequencies is testimony to the highly conserved ground-state structure of the Cu-Cys moiety. Shifts of the vibrational modes by 1-3 cm-1 upon deuterium exchange can be correlated with N-H...S hydrogen bonds from the protein backbone to the sulfur of the Cys ligand. There is marked variability in the intensities of these Cys-related vibrations, such that each class of cupredoxin has its own pattern of RR intensities. For example, plastocyanins from poplar, oleander, French bean, and spinach have their most intense feature at approximately 425 cm-1; azurins show greatest intensity at approximately 410 cm-1, stellacyanin and ascorbate oxidase at approximately 385 cm-1, and nitrite reductase at approximately 360 cm-1. These variable intensity patterns are related to differences in the electronic excited-state structures. We propose that they have a basis in the protein environment of the copper-cysteinate chromophore. A further insight into the vibrational spectra is provided by the structures of the six cupredoxins for which crystallographic refinements at high resolution are available (plastocyanins from P. nigra, O. nerium, and Enteromorpha prolifera, pseudoazurin from A. faecalis, azurin from Alcaligenes denitrificans, and cucumber basic blue protein). The average of the Cu-S(Cys) bond lengths is 2.12 +/- 0.05 A. Since the observed range of bond lengths falls within the precision of the determinations, this variation is considered insignificant. The Cys ligand dihedral angles are also highly conserved. Cu-S gamma-C beta-C alpha is always near -170 degrees and S gamma-C beta-C alpha-N near 170 degrees. As a result, the Cu-S gamma bond is coplanar with the Cys side-chain atoms and part of the polypeptide backbone. The coplanarity accounts for the extensive coupling of Cu-S stretching and Cys deformation modes as seen in the RR spectrum. The conservation of this copper-cysteinate conformation in cupredoxins may indicate a favored pathway for electron transfer.     

Crystal structure analyses of reduced (CuI) poplar plastocyanin at six pH values

The structure of poplar plastocyanin in the reduced (CuI) state has been determined and refined, using counter data recorded from crystals at pH 3.8, 4.4, 5.1, 5.9, 7.0 and 7.8 (resolution 1.9 A, 1.9 A, 2.05 A, 1.7 A, 1.8 A and 2.15 A; the final residual R value was 0.15, 0.15, 0.16, 0.17, 0.16 and 0.15, respectively). The molecular and crystal structure of the protein is substantially the same in the reduced state as in the oxidized state. The refinements of the structures of the six forms of the reduced protein could therefore be commenced with a model derived from the known structure of CuII-plastocyanin. The refinements were made by reciprocal space least-squares calculations interspersed with inspections of electron-density difference maps. Precautions were taken to minimize any bias of the results of the refinements in the direction of the starting model. The most significant differences among the structures of the reduced protein at the six pH values, or between them and the structure of the oxidized protein, are concentrated at the Cu site. In the reduced protein at high pH (pH 7.8), the CuI atom is co-ordinated by the N delta(imidazole) atoms of His37 and His87, the S gamma(thiolate) atom of Cys84, and the S delta(thioether) atom of Met92, just as in CuII-plastocyanin. The distorted tetrahedral geometry and the unusually long Cu-S(Met92) bond are retained. The only effects of the change in oxidation state are a lengthening of the two Cu-N(His) bonds by about 0.1 A, and small changes in two bond angles involving the Cu-S(Cys) bond. The high-pH form of reduced plastocyanin accordingly meets all the requirements for efficient electron transfer. As the pH is lowered, the Cu atom and the four Cu-binding protein side-chains appear to undergo small but concerted movements in relation to the rest of the molecule. At low pH (pH 3.8), the CuI atom is trigonally co-ordinated by N delta(His37), S gamma(Cys84) and S delta(Met92). The fourth Cu-ligand bond is broken, the Cu atom making only a van der Waals' contact with the imidazole ring of His87. The trigonal geometry of the Cu atom strongly favours CuI, so that this form of the protein should be redox-inactive. This is known to be the case.(ABSTRACT TRUNCATED AT 400 WORDS)     

Extended x-ray absorption fine structure and electron paramagnetic resonance of nitrous oxide reductase from Pseudomonas aeruginosa strain P2.

The copper centers of nitrous oxide reductase from Pseudomonas aeruginosa strain P2 were studied by x-ray and electron paramagnetic resonance (EPR) spectroscopy. The enzyme is dimeric and contains four Cu atoms and about seven cysteine residues/subunit of Mr = 73,000. The extended x-ray absorption fine structure (EX-AFS) spectrum was analyzed for enzyme as isolated (oxidized or slightly reduced), enzyme exposed briefly to air, reduced enzyme, and enzyme at pH 7 after having been activated by standing at pH 10. The average Cu ligand environment in the first shell was best modeled for all forms of the enzyme by a combination of N/O and S atoms at a total coordination number between 3 and 4 and bond distances ranging from 1.96-2.03 A for Cu-N/O and 2.20-2.25 A for Cu-S. The data could be fit without using Cu-Cu interactions. Overall the results are similar to those reported for the enzyme for Pseudomonas stutzeri (Scott, R. A., Zumft, W.G., Coyle, C.L., and Dooley, D.M. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 4082-4086). The first derivative EPR spectra of the Cu(II) centers at 15 and 45 K were qualitatively similar among enzyme as isolated and enzyme exposed to N2O or air. These three nominally oxidized samples showed an axial signal with g perpendicular = 2.03 and g parallel = 2.15-2.16. Hyperfine structure was observed in both the g parallel and g perpendicular regions with splittings of 43 and 25 gauss, respectively. These hyperfine components are attributed to exchange coupled Cu(I)-Cu(II) S = 1/2 (half-met) centers. In the enzyme as isolated and after exposure to N2O, about 3/4 of the Cu was EPR silent, whereas after exposure to air the signal integrated to about half the Cu concentration. The EPR spectrum of enzyme activated at pH 10 but frozen at pH 7 was a composite of spectra from activated and inactive species. The activated species presented a complex set of narrow hyperfine components which may arise from contributions from more than one species of half-met center.     

Structural studies of two mutants of amicyanin from Paracoccus denitrificans that stabilize the reduced state of the copper

Mutation of Pro94 to phenylalanine or alanine significantly alters the redox properties of the type I copper center of amicyanin. Each mutation increases the redox midpoint potential (E(m)) value by at least 140 mV and shifts the pK(a) for the pH dependence of the E(m) value to a more acidic value. Atomic resolution (0.99-1.1 A) structures of both the P94F and P94A amicyanin have been determined in the oxidized and reduced states. In each amicyanin mutant, an electron-withdrawing hydrogen bond to the copper-coordinating thiolate sulfur of Cys92 is introduced by movement of the amide nitrogens of Phe94 and Ala94 much closer to the thiolate sulfur than in wild-type amicyanin. This is the likely explanation for the much more positive E(m) values which result from each of these mutations. The observed decrease in the pK(a) value for the pH dependence of the E(m) value that is seen in the mutants seems to be correlated with steric hindrance to the rotation of the His95 copper ligand which results from the mutations. In wild-type amicyanin the His95 side chain undergoes a redox and pH-dependent conformational change which accounts for the pH dependence of the E(m) value of amicyanin. The reduced P94A amicyanin exhibits two alternate conformations with the positions of the copper 1.4 A apart. In one of these conformations, a water molecule appears to have replaced Met98 as a copper ligand. The relevance of these structures to the electron transfer properties of P94F and P94A amicyanin are also discussed.     

Structure of the copper cluster in canine hepatic metallothionein using X-ray absorption spectroscopy

The metal binding site in the lysosomal copper metallothionein from canine liver (LyCuLP) was examined with X-ray edge and extended X-ray absorption fine structure (EXAFS) spectroscopies. The k-absorption edge spectrum of LyCuLP was consistent with the coordination of univalent copper. The Fourier transform of the EXAFS data showed four resolved shells of backscattering atoms. Comparisons between the phase and amplitude functions derived from the isolated shells to those of Cu-Cu, Cu-S, and Cu-N model compounds showed that each copper was coordinated by four sulfur atoms at a distance of 2.27 +/- 0.02 A. Analysis of the outer shell data indicated backscattering copper atoms at 2.74 +/- 0.05, 3.32 +/- 0.05, and 3.88 +/- 0.05 A. Interatomic distances determined from the EXAFS data were compared to the distances observed by X-ray crystallographic analysis of adamantane-like clusters containing four and five copper atoms and a cubic cluster containing four copper atoms, structurally similar to the 4Fe-4S clusters in some ferredoxins. The results of these comparisons suggest that the copper complexed in LyCuLP is arranged in an adamantane-like cluster. The structure derived for this protein may be conserved in other copper metallothioneins.     

Site-directed mutagenesis of proline 94 to alanine in amicyanin converts a true electron transfer reaction into one that is kinetically coupled

Amicyanin is a type I copper protein that mediates electron transfer (ET) from methylamine dehydrogenase (MADH) to cytochrome c-551i. Pro(94) resides in the "ligand loop" of amicyanin, a sequence of amino acids that contains three of the four copper ligands. ET from the reduced O-quinol tryptophan tryptophylquinone of MADH to oxidized P94A amicyanin is a true ET reaction that exhibits values of electronic coupling (H(AB)) and reorganization energy (lambda) that are the same as for the reaction of native amicyanin. In contrast, the parameters for the ET reaction from reduced P94A amicyanin to oxidized cytochrome c-551i have been significantly altered as a consequence of the mutation. These values of H(AB) and lambda are 8.3 cm(-)(1) and 2.3 eV, respectively, compared to values of 0.3 cm(-)(1) and 1.2 eV for the reaction of native reduced amicyanin. The crystal structure of reduced P94A amicyanin exhibits two alternate conformations with the positions of the copper 1.4 A apart [Carrell, C. J., Sun, D., Jiang, S., Davidson, V. L., and Mathews, F. S. (2004) Biochemistry 43, 9372-9380]. In one of these, conformation B, a water molecule has replaced Met(98) as a copper ligand, and the ET distance to the heme of the cytochrome is increased by 1.4 A. Analysis of these structures suggests that the true k(ET) for ET from the copper in conformation B to heme would be much less than for ET from conformation A. A novel kinetic mechanism is proposed to explain these data in which the reduction of Cu(2+) by methylamine dehydrogenase is a true ET reaction while the oxidation of Cu(1+) by cytochrome c-551i is kinetically coupled ET. By comparison of the temperature dependence of the observed rate of the coupled ET reaction from reduced P94A amicyanin to cytochrome c-551i with the predicted rates and temperature dependence for the true ET reaction from conformation A, it was possible to determine the K(eq) and values of DeltaH degrees and DeltaS degrees that are associated with the non-ET reaction that modulates the observed ET rate.     

Structure of oxidized poplar plastocyanin at 1.6 A resolution

The structure of poplar plastocyanin in the oxidized (CuII) state at pH 6.0 has been refined, using 1.6 A resolution counter data. The starting co-ordinates were obtained from the 2.7 A electron density map computed with phases derived by the multiple isomorphous replacement method. The model was refined successively by constrained real space, unrestrained reciprocal space, and restrained reciprocal space least-squares methods. The final residual R value is 0.17 for 8285 reflections (I greater than 2 sigma (I)). It is estimated that the root-mean-square standard deviation of the atomic positions is 0.1 A when averaged over all atoms, and 0.05 A for the Cu ligand atoms alone. The refined structure retains all the essential features of the 2.7 A model. The co-ordination geometry of the copper atom is confirmed as being distorted tetrahedral. The two Cu-N(His) bonds, 2.10 and 2.04 A, are within the range normally found in low molecular weight CuII complexes with Cu-N(imidazole) bonds. The Cu-S(Cys) bond, 2.13 A, is also normal, but the Cu-S(Met) bond, 2.90 A, is sufficiently long to raise important questions about its significance. The hydrogen-bonding and secondary structure can now be assigned confidently. Forty-four water molecules are included in the final model. Repetition of the refinement, using new data to 1.9 A resolution recorded from crystals at pH 4.2, has led to a residual R value of 0.16 for 6060 reflections (I greater than sigma (I)). There are few significant changes in the structure of poplar CuII-plastocyanin between pH 6.0 and pH 4.2. In particular, the geometry of the copper site is not affected. The observed changes in redox behaviour of plastocyanin at low pH are therefore unlikely to be connected with structural changes in the oxidized form of the protein. A number of features of the molecular structure appear to be directly related to the function of plastocyanin as an electron carrier in photosynthesis. Comparison between the known amino acid sequences of 67 plant plastocyanins reveals 52 conserved and 11 conservatively substituted residues in a total of 99. If three algal plastocyanin sequences are included in the comparison, there are still 26 conserved and 12 conservatively substituted residues. In many cases, the importance of these residues in determining the tertiary structure can be rationalized.     

Infrared evidence of cyanide binding to iron and copper sites in bovine heart cytochrome c oxidase. Implications regarding oxygen reduction

Cyanide binding to bovine heart cytochrome c oxidase at five redox levels has been investigated by use of infrared and visible-Soret spectra. A C-N stretch band permits identification of the metal ion to which the CN- is bound and the oxidation state of the metal. Non-intrinsic Cu, if present, is detected as a cyanide complex. Bands can be assigned to Cu+CN at 2093 cm-1, Cu2+CN at 2151 or 2165 cm-1, Fe3+CN at 2131 cm-1, and Fe2+CN at 2058 cm-1. Fe2+CN is found only when the enzyme is fully reduced whereas the reduced Cu+CN occurs in 2-, 3-, and 4-electron reduced species. A band for Fe3+CN is not found for the complex of fully oxidized enzyme but is for all partially reduced species. Cu2+CN occurs in both fully oxidized and 1-electron-reduced oxidase. CO displaces the CN- at Fe2+ to give a C-O band at 1963.5 cm-1 but does not displace the CN- at Cu+. Another metal site, noted by a band at 2042 cm-1, is accessible only in fully reduced enzyme and may represent Zn2+ or another Cu+. Binding of either CN- or CO may induce electron redistribution among metal centers. The extraordinary narrowness of ligand infrared bands indicates very little mobility of the components that line the O2 reduction site, a property of potential advantage for enzyme catalysis. The infrared evidence that CN- can bind to both Fe and Cu supports the possibility of an O2 reduction mechanism in which an intermediate with a mu-peroxo bridge between Fe and Cu is formed. On the other hand, the apparent independence of Fe and Cu ligand-binding sites makes a heme hydroperoxide (Fe-O-O-H) intermediate an attractive alternative to the formation an Fe-O-O-Cu linkage.     

Extended X-ray absorption fine structure study of Rhodospirillum rubrum and Rhodospirillum molischianum cytochromes c': relationship between heme stereochemistry and spin state

An EXAFS study on the oxidized and reduced forms of cytochromes c' from Rhodospirillum rubrum and Rhodospirillum molischianum was performed at pH 7. The cytochromes c' have an apparent coordination number of 5 in both oxidation states. Average Fe-ligand bond lengths of 2.02 +/- 0.025 and 2.06 +/- 0.025 A are obtained in their oxidized and reduced forms, respectively. By use of suitable values for the Fe-NHis bond length and Fe out-of-plane displacement, as determined by small molecule crystallographic techniques, the Fe-Npyrrole bond lengths and the porphyrin center-to-Npyrrole distance have been estimated for cytochrome c' in both of its oxidation states. With this model, estimates of the Fe-Npyrrole bond lengths are 2.01 +/- 0.03 and 2.05 +/- 0.03 A, for the oxidized and reduced cytochromes c', respectively. The center-to-Npyrrole distance is estimated to be 1.99 +/- 0.03 A for oxidized cytochrome c' and 2.03 +/- 0.03 A for reduced cytochrome c'.     

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.     

Does superoxide channel between the copper centers in peptidylglycine monooxygenase? A new mechanism based on carbon monoxide reactivity

Peptidylglycine monooxygenase (PHM) carries out the hydroxylation of the alpha-C atom of glycine-extended propeptides, the first step in the amidation of peptide hormones by the bifunctional enzyme peptidyl-alpha-amidating monooxygenase (PAM). Since PHM is a copper-containing monooxygenase, a study of the interaction between the reduced enzyme and carbon monoxide has been carried out as a probe of the interaction of the Cu(I) sites with O(2). The results show that, in the absence of peptide substrate, reduced PHM binds CO with a stoichiometry of 0.5 CO/Cu(I), indicating that only one of the two copper centers, Cu(B), forms a Cu(I)-carbonyl. FTIR spectroscopy shows a single band in the 2200-1950 cm(-)(1) energy region with nu(CO) = 2093 cm(-)(1) assigned to the intraligand C-O stretch via isotopic labeling with (13)CO. A His242Ala mutant of PHM, which deletes the Cu(B) site by replacing one of its histidine ligands, completely eliminates CO binding. EXAFS spectroscopy is consistent with binding of a single CO ligand with a Cu-C distance of 1.82 +/- 0.03 A. The Cu-S(met) distance increases from 2.23 +/- 0. 02 A in the reduced unliganded enzyme to 2.33 +/- 0.01 A in the carbonylated enzyme, suggesting that the methionine-containing Cu(B) center is the site of CO binding. The binding of the peptide substrate N-Ac-tyr-val-gly perturbs the CO ligand environment, eliciting an IR band at 2062 cm(-)(1) in addition to the 2093 cm(-)(1) band. (13)CO isotopic substitution assigns both frequencies as C-O stretching bands. The CO:Cu binding stoichiometry and peptide/CO FTIR titrations indicate that the 2062 cm(-)(1) band is due to binding of CO at a second site, most likely at the Cu(A) center. This suggests that peptide binding may activate the Cu(A) center toward O(2) binding and reduction to superoxide. As a result of these findings, a new mechanism is proposed involving channeling of superoxide across the 11 A distance between the two copper centers.     

Optical spectroscopic investigation of the alkaline transition in umecyanin from horseradish root

Umecyanin (UMC) from horseradish root belongs to the stellacyanin subclass of the phytocyanins, a family of plant cupredoxins. The protein possesses the typical type-1 His(2)Cys equatorial ligand set at its mononuclear copper site but has an axial Gln ligand in place of the usual weakly coordinated Met of the plantacyanins, uclacyanins, and most other cupredoxins. UMC exhibits, like other phytocyanins, altered visible, EPR, and paramagnetic (1)H NMR spectra at elevated pH values and also a modified reduction potential. This alkaline transition occurs with a pK(a) of approximately 10 [Dennison, C., Lawler, A. T. (2001) Biochemistry 40, 3158-3166]. In this study, we investigate the alkaline transition by complementary optical spectroscopic techniques. The contemporary use of absorption, fluorescence, dynamic light scattering, and resonance Raman spectroscopy allows us to demonstrate that the alkaline transition induces a reorganization of the protein and that the overall size of UMC increases, but protein aggregation does not occur. The transition does not have a dramatic influence on the active-site environment of UMC, but there are subtle alterations in the Cu site geometry. Direct evidence for the strengthening of a Cu-N(His) bond is presented, which is in agreement with the hypothesis that the deprotonation of the N(epsilon2)H moiety of one of the His ligands is the cause of the alkaline transition. A weakening of the Cu-S(Cys) bond is also observed which, along with a weakened axial interaction, must be due to the enhanced Cu-N(His) interaction.     

Refinement of the nickel site structure in Desulfovibrio gigas hydrogenase using range-extended EXAFS spectroscopy

We have reexamined the Ni EXAFS of oxidized, inactive (as-isolated) and H(2) reduced Desulfovibrio gigas hydrogenase. Better spatial resolution was achieved by analyzing the data over a 50% wider k-range than was previously available. A lower k(min) was obtained using the FEFF code for phase shifts and amplitudes. A higher k(max) was obtained by removing an interfering Cu signal from the raw spectra using multiple energy fluorescence detection. The larger k-range allowed us to better resolve the Ni-S bond lengths and to define more accurately the Ni-O and Ni-Fe bond lengths. We find that as-isolated, hydrogenase has two Ni-S bonds at approximately 2.2 A, but also 1-2 Ni-S bonds in the 2.35+/-0.05 A range. A Ni-O interaction is evident at 1.91 A. The as-isolated Ni-Fe distance cannot be unambiguously determined. Upon H(2) reduction, two short Ni-S bonds persist at approximately 2.2 A, but the remaining Ni-S bonds lengthen to 2.47+/-0.05 A. Good simulations are obtained with a Ni-Fe distance at 2.52 A, in agreement with crystal structures of the reduced enzyme. Although not evident in the crystal structures, an improvement in the fit is obtained by inclusion of one Ni-O interaction at 2.03 A. Implications of these distances for the spin-state of H(2) reduced H(2)ase are discussed.     

X-ray absorption studies of the Cu-dependent phenylalanine hydroxylase from Chromobacterium violaceum. Comparison of the copper coordination in oxidized and dithionite-reduced enzymes.

The coordination chemistry of the Cu sites of phenylalanine hydroxylase (PAH) from Chromobacterium violaceum has been studied by X-ray absorption spectroscopy (XAS). The EXAFS of the Cu(II) form of the enzyme resembles that of other non-blue copper proteins such as plasma amine oxidases and dopamine-beta-hydroxylase and is characteristic of a mixed N/O coordination shell containing histidine ligation. Detailed simulations of the raw EXAFS data have been carried out using full curved-wave restrained refinement methodologies which allow imidazole ligands to be treated as structural units. The results suggest a Cu(II) coordination of two histidines and two additional O/N-donor groups. A reasonable fit to both data sets can be obtained by assuming that the non-imidazole first-shell donor atoms are derived from solvent (H2O or OH-). The EXAFS of the reduced enzyme shows major differences. The amplitude of the first shell in the Fourier transform is only 50% of that of the oxidized enzyme, indicative of a substantial reduction in coordination number. In addition, the first shell of the transform is split into two components. Simulations of the reduced data can be obtained by either two histidines at a long distance of 2.08 A and an O ligand at a short distance of 1.88 A or two histidines at a short distance of 1.90 A and one second-row scatterer such as S or Cl at 2.20 A. Comparison of absorption edge data on the reduced enzyme with data from Cu(I) bis- and tris(1,2-dimethylimidazole) complexes suggests a pseudo-three-coordinate structure.