Electron relaxation and solvent accessibility of the metal site in wild-type and mutated azurins as determined from nuclear magnetic relaxation dispersion experiments

The interaction of water molecules with copper in wild-type azurin and different site-directed mutants of the coordinated residues is studied by nuclear magnetic relaxation dispersion. Different degrees of solvent accessibility are found. The low relaxivity of wild-type azurin agrees with a solvent-protected copper site in solution, the closest water being found at a distance of more than 5?Å from the copper. This low relaxivity contrasts with the relatively large relaxivity of the His46Gly and His117Gly azurin mutants, which shows clear evidence of copper-coordinated water. The data on the latter mutants are best analyzed in terms of one and two water molecules coordinated to the copper in His46Gly and His117Gly, respectively. The Met121His azurin mutant shows an intermediate behavior. The data are analyzed in terms of an increased solvent accessibility with respect to the wild-type azurin, resulting in semi-coordination of water at low pH. These different modes of coordination lead to different geometries, ranging from the trigonal type 1 site of wild-type azurin to the tetragonal type 2 copper sites of the His117Gly and His46Gly azurin mutants through a so-called type 1.5 site of the Met121His mutant. A correlation is found between the relaxation time (τ_s) of the unpaired electron of copper(II) and the geometry of the metal site: as the tetragonal character decreases the relaxation becomes significantly faster. τ_s values of ≤1?ns are found for the tetrahedrally distorted type 1 and type 1.5 sites and of 5–15?ns for the tetragonal type 2 sites.     

Conformational equilibria accompanying the electron transfer between cytochrome c (P551) and azurin from Pseudomonas aeruginosa.

The redox reaction between cytochrome c (Cyt c) (P-551) and the blue copper protein azurin, both from Pseudomonas aeruginosa, was studied using the temperature-jump technique. Two relaxation times were observed in a mechanism assumed to involve three equilibria. The fast relaxation time (0.4 less than tau less than 8 ms) was ascribed to the electron exchange step. The slow relaxation time (tau congruent to 37 ms) was assigned to a conformational equilibrium of the reduced azurin that was coupled through the electron exchange step to a faster conformational equilibrium of the oxidized Cyt c (P551). But because the Cyt c (P551) isomerization, being very rapid, was uncoupled from the two slower equilibria, and was assumed to involve no spectral change, the amplitude of its relaxation time (tau congruent to 0.1 ms) would be zero. At 25 degrees C and pH 7.0 the rate constants for the oxidation and reduction of Cyt c (P551) by azurin were 6.1 X 10(6) and 7.8 X 10(6) M-1 s-1, respectively; for the formation and disappearance of the reactive conformational isomer of azurin they were 12 and 17 s-1, respectively. The rates for the Cyt c (P551) isomerization could only be estimated at approximately 10(4) s-1. The thermodynamic parameters of each reaction step were evaluated from the amplitudes of the relaxations and from Eyring plots of the rate constants. Measurements of the overall equilibrium constant showed it to be temperature independent (5-35 degrees C), i.e. deltaHtot = 0. This zero enthalpy change was found to be compatible with the enthalpies calculated for the individual steps. In the electron exchange equilibrium, the values of the activation enthalpies were two to three times higher than the values published for various low molecular weight reagents in their electron exchange with copper proteins, yet the rate of exchange between Cyt c (P551) and azurin was some hundreds of times faster. This was explained in terms of the measured positive or zero entropies of activation that could result from a high level of specificity between the proteins particularly in areas of complementary charges. The mechanism of electron transfer was considered as essentially an outer sphere reaction, of which the rate could be approximated by the Marcus theory.     

Modification of the electron-transfer sites of Pseudomonas aeruginosa azurin by site-directed mutagenesis

Site-directed mutagenesis of the structural gene for azurin from Pseudomonas aeruginosa has been used to prepare azurins in which amino acid residues in two separate electron-transfer sites have been changed: His-35-Lys and Glu-91-Gln at one site and Phe-114-Ala at the other. The charge-transfer band and the EPR spectrum are the same as in the wild-type protein in the first two mutants, whereas in the Phe-114-Ala azurin, the optical band is shifted downwards by 7 nm and the copper hyperfine splitting is decreased by 4.10(-4)/cm. This protein also shows an increase of 20-40 mV in the reduction potential compared to the other azurins. The potentials of all four azurins decrease with increasing pH in phosphate but not in zwitterionic buffers with high ionic strength. The rate constant for electron exchange with cytochrome c551 is unchanged compared to the wild-type protein in the Phe-114-Ala azurin, but is increased in the other two mutant proteins. The results suggest that Glu-91 is not important for the interaction with cytochrome c551 and that His-35 plays no critical role in the electron transfer to the copper site.     

A spin-labeled derivative of Procion brilliant blue MX-R. Synthesis and interaction with pig heart nucleoside diphosphate kinase

The ¹H-NMR spectrum of cucumber basic blue protein (CBP) has been recorded. Examination of the spectrum of the reduced protein suggests that one or more sidechains exist in conformations which interconvert slowly at ambient temperatures. His 39, His 84 and Met 89 are identified as copper ligands by redox titration and by amino acid sequence homology with plastocyanin and azurin. The importance of a Phe sidechain close to the Met ligand in the potential blue copper site is confirmed. Broadening of His ligand resonances at elevated temperatures reveals an exchange process at the reduced copper centre.     

The binding of imidazole in an azurin-like blue-copper site

 Frozen solutions of the azurin mutant His117Gly in the presence of excess of methyl-substituted imidazoles have been investigated by electron spin-echo envelope modulation (ESEEM) spectroscopy at 9 GHz. The addition of imidazole is known to reconstitute a blue-copper site and variation of the non-protein bound ligand [N-methyl-, 2-methyl-, 4(5)-methylimidazole] has allowed the study of the copper-imidazole binding as a model for histidine binding in such sites. Quadrupole and hyperfine tensors of the remote nitrogen of the imidazoles have been determined. The quadrupole tensors indicate that the methyl-substituted imidazoles in the mutant adopt the same orientation relative to copper as the histidine-117 in the wild-type protein. Analysis of the hyperfine tensors in terms of spin densities reveals that the spin density on the remote nitrogen of the substituted imidazole has σ and a variable π character, depending on the position of the methyl group. For azurin the corresponding spin density is of virtually pure σ character. In conclusion, blue-copper sites show subtle variations as regards the histidine/imidazole centred part of the wavefunction of the unpaired electron. Received: 27 October 1998 / Accepted: 9 February 1999     

Complex formation between the copper protein, azurin and the cytochrome c peroxidase of Pseudomonas aeruginosa.

Reduced azurin reacts with the resting, oxidized cytochrome c peroxidase of Pseudomonas aeruginosa to yield time courses observed at 420 nm, which consist of the sum of two exponential processes. Each process exhibits a hyperbolic dependence of the observed rate constant on the reduced azurin concentration. The fraction of the total optical density change which each process contributes is found to be dependent on the reduced azurin concentration. This pattern of reactivity is maintained at pH values between 5.5 and 8.0. The data has been analyzed in terms of a complex formation between the two proteins followed by an intramolecular electron exchange reaction. This analysis yields values for the binding constants at each pH value. The intramolecular exchange reaction is independent of pH, whilst the pH dependence of the binding reaction suggests the involvement of a histidine residue in this process.     

Photoinduced electron transfer in singly labeled thiouredopyrenetrisulfonate azurin derivatives.

A novel method for the initiation of intramolecular electron transfer reactions in azurin is reported. The method is based on laser photoexcitation of covalently attached thiouredopyrenetrisulfonate (TUPS), the reaction that generates the low potential triplet state of the dye with high quantum efficiency. TUPS derivatives of azurin, singly labeled at specific lysine residues, were prepared and purified to homogeneity by ion exchange HPLC. Transient absorption spectroscopy was used to directly monitor the rates of the electron transfer reaction from the photoexcited triplet state of TUPS to Cu(II) and the back reaction from Cu(I) to the oxidized dye. For all singly labeled derivatives, the rate constants of copper ion reduction were one or two orders of magnitude larger than for its reoxidation, consistent with the larger thermodynamic driving force for the former process. Using 3-D coordinates of the crystal structure of Pseudomonas aeruginosa azurin and molecular structure calculation of the TUPS modified proteins, electron transfer pathways were calculated. Analysis of the results revealed a good correlation between separation distance from donor to Cu ligating atom (His-N or Cys-S) and the observed rate constants of Cu(II) reduction.     

Characterization and crystal structure of zinc azurin, a by-product of heterologous expression in Escherichia coli of Pseudomonas aeruginosa copper azurin.

Azurin*, a by-product of heterologous expression of the gene encoding the blue copper protein azurin from Pseudomonas aeruginosa in Escherichia coli, was characterized by chemical analysis and electrospray ionization mass spectrometry, and its structure determined by X-ray crystallography. It was shown that azurin* is native azurin with its copper atom replaced by zinc in the metal binding site. Zinc is probably incorporated in the apo-protein after its expression and transport into the periplasm. Holo-azurin can be reconstituted from azurin* by prolonged exposure of the protein to high copper ion concentrations or unfolding of the protein and refolding in the presence of copper ions. An X-ray crystallographic analysis of azurin* at 0.21-nm resolution revealed that the overall structure of azurin is not perturbed by the metal exchange. However, the geometry of the co-ordination sphere changes from trigonal bipyramidal in the case of copper azurin to distorted tetrahedral for the zinc protein. The copper ligand Met121 is no longer co-ordinated to zinc which adopts a position close to the carbonyl oxygen atom from residue Gly45. The polypeptide structure surrounding the metal site undergoes moderate reorganization upon zinc binding. The largest displacement observed is for the carbonyl oxygen from residue Gly45, which is involved in copper and zinc binding. It moves by 0.03 nm towards the zinc, thereby reducing its distance to the metal from 0.29 nm in the copper protein to 0.23 nm in the derivative.     

Redox properties of an engineered purple Cu(A) azurin

Purple Cu(A) centers are a class of binuclear, mixed-valence copper complexes found in cytochrome c oxidase and nitrous oxide reductase. An engineered Cu(A) protein was formed by replacing a portion of the amino acid sequence that contains three of the ligands to the native type I copper center of Pseudomonas aeruginosa azurin with the corresponding portion of sequence from the Cu(A) center of cytochrome c oxidase from Paracoccus denitrificans [Proc. Natl. Acad. Sci. USA 93 (1996) 461]. Oxidation-reduction midpoint potential (E(m)) values of the Cu(A) azurin of +399+/-10 and +380+/-2mV, respectively, were determined by cyclic voltammetry and spectrochemical titration. An n value of one was obtained, indicating that the redox reaction is cycling between the mixed valence and the fully reduced states. Whereas the E(m) value of native azurin is pH dependent, the E(m) value of Cu(A) azurin is not, as expected for the Cu(A) center. Similarities and differences in the redox properties are discussed in terms of the known crystal structures of Cu(A) centers in cytochrome c oxidase and Cu(A) azurin.     

1H nuclear magnetic resonance study of the protonation behaviour of the histidine residues and the electron self-exchange reaction of azurin from Alcaligenes denitrificans

The proton nuclear magnetic resonance spectrum of azurin from Alcaligenes denitrificans at pH 6.0 and 309 K is reported. Proton signals from all methionine and histidine residues (among them the copper ligands) have been assigned. The data have been used to study the pH behaviour of His35 and to establish the electron self-exchange rate of the protein. His35 appears to be protonated at pH less than 4.5, possibly after rupture of a salt bridge. No effects of this protonation on the tertiary structure around the copper site are observed, however, contrary to the case of Pseudomonas aeruginosa azurin. The electron self-exchange rate amounts to 4 x 10(5) M-1 S-1 at pH 6.7 and 297 K. The data support the conclusion that the electron self-exchange takes place by way of the hydrophobic surface patch around His117, and that His35 is not involved in this reaction. Oxidation of azurin increases the acidity of the freely titrating His32 and His83 by 0.07 and 0.25 pKa units, respectively. The data can be used to test the theory of electrostatic interactions in proteins. The optical extinction coefficient at 625 nm was experimentally determined and amounts to 4.8(+/- 0.1) x 10(3) M-1 cm-1.     

The importance of Asn47 for structure and reactivity of azurin from Alcaligenes denitrificans as studied by site-directed mutagenesis and spectroscopy.

To study the importance of a rigid copper site for the structure and function of azurin, a mutant with a reduced number of internal hydrogen bonds around the copper has been prepared and characterized. To this purpose, the previously cloned azu gene from Alcaligenes denitrificans (Hoitink, C. W. G., Woudt, L. P., Turenhout, J. C. M., Van de Kamp, M., and Canters, G. W. (1990) Gene (Amst.) 90, 15-20) was expressed in Escherichia coli and an isolation and purification procedure for the azurin was developed. The azurin obtained after heterologous expression in E. coli appears spectroscopically indistinguishable from azurin derived from A. denitrificans. The hydrogen bonding network around the copper site was altered by replacing Asn47 by a leucine by means of site-directed mutagenesis. Asn47 is a conserved residue in all blue copper proteins of which the primary structure has been reported. Characterization of the mutant protein with UV-visible, electron spin resonance, and NMR spectroscopy, and comparison with the wild type azurin revealed that the structure of the copper site as well as the overall structure of the protein have been largely retained. The redox activity as measured by the electron self-exchange rate appears not to have changed either. However, the mutant differs from the wild type azurin with respect to stability and midpoint potential. Midpoint potentials of mutant and wild type azurin amount to 396 and 286 mV, respectively. The difference is due to sizable entropic and enthalpic contributions which to a large extent cancel. Possible explanations for the outcome of these experiments are discussed.     

Pseudomonas aeruginosa cytochrome oxidase. Product inhibition by low thermodynamic driving force

The steady-state kinetics of Pseudomonas aeruginosa cytochrome oxidase were studied. Reduced cytochrome c551 and azurin from the same bacteria were used as the electron-donating substrates, while dioxygen served as the electron acceptor. Oxidized cytochrome c551 and azurin exhibited product inhibition of the reaction. However, apo-azurin and azurin derivatives in which the copper was substituted by the redox-inert ions Ni2+, Co2+, Cd2+ and Zn2+, did not show any effect on the kinetics. These observations implied that complex formation between the substrates or the products and the enzyme is not a rate-limiting step and is not the cause for product inhibition. The integrated rate law for a reaction scheme in which we assumed that complex formation was not rate limiting was fitted to the complete reaction traces. The results suggested that it is the low thermodynamic driving force, expressed in the small differences in redox potential between the substrates and heme c of the enzyme, which cause the observed product inhibition.     

The effect of driving force on intramolecular electron transfer in proteins. Studies on single-site mutated azurins.

An intramolecular electron-transfer process has previously been shown to take place between the Cys3--Cys26 radical-ion (RSSR-) produced pulse radiolytically and the Cu(II) ion in the blue single-copper protein, azurin [Farver, O. & Pecht, I. (1989) Proc. Natl Acad. Sci. USA 86, 6868-6972]. To further investigate the nature of this long-range electron transfer (LRET) proceeding within the protein matrix, we have now investigated it in two azurins where amino acids have been substituted by single-site mutation of the wild-type Pseudomonas aeruginosa azurin. In one mutated protein, a methionine residue (Met44) that is proximal to the copper coordination sphere has been replaced by a positively charged lysyl residue ([M44K]azurin), while in the second mutant, another residue neighbouring the Cu-coordination site (His35) has been replaced by a glutamine ([H35Q]azurin). Though both these substitutions are not in the microenvironment separating the electron donor and acceptor, they were expected to affect the LRET rate because of their effect on the redox potential of the copper site and thus on the driving force of the reaction, as well as on the reorganization energies of the copper site. The rate of intramolecular electron transfer from RSSR- to Cu(II) in the wild-type P. aeruginosa azurin (delta G degrees = -68.9 kJ/mol) has previously been determined to be 44 +/- 7 s-1 at 298 K, pH 7.0. The [M44K]azurin mutant (delta G degrees = -75.3 kJ/mol) was now found to react considerably faster (k = 134 +/- 12 s-1 at 298 K, pH 7.0) while the [H35Q]azurin mutant (delta G degrees = -65.4 kJ/mol) exhibits, within experimental error, the same specific rate (k = 52 +/- 11 s-1, 298 K, pH 7.0) as that of the wild-type azurin. From the temperature dependence of these LRET rates the following activation parameters were calculated: delta H++ = 37.9 +/- 1.3 kJ/mol and 47.2 +/- 0.7 kJ/mol and delta S++ = -86.5 +/- 5.8 J/mol.K and -46.4 +/- 4.4 J/mol.K for [H35Q]azurin and [M44K]azurin, respectively. Using the Marcus relation for intramolecular electron transfer and the above parameters we have determined the reorganization energy, lambda and electronic coupling factor, beta. The calculated values fit very well with a through-bond LRET mechanism.     

Complete sequential 1H and 15N nuclear magnetic resonance assignments and solution secondary structure of the blue copper protein azurin from Pseudomonas aeruginosa.

Complete sequential 1H and 15N resonance assignments for the reduced Cu(I) form of the blue copper protein azurin (M(r) 14,000, 128 residues) from Pseudomonas aeruginosa have been obtained at pH 5.5 and 40 degrees C by using homo- and heteronuclear two-dimensional (2D) and three-dimensional (3D) nuclear magnetic resonance spectroscopic experiments. Combined analysis of a 3D homonuclear 1H Hartmann-Hahn nuclear Overhauser (3D 1H HOHAHA-NOESY) spectrum and a 3D heteronuclear 1H nuclear Overhauser 1H[15N] single-quantum coherence (3D 1H[15N] NOESY-HSQC) spectrum proved especially useful. The latter spectrum was recorded without irradiation of the water signal and provided for differential main chain amide (NH) exchange rates. NMR data were used to determine the secondary structure of azurin in solution. Comparison with the secondary structure of azurin obtained from X-ray analysis shows a virtually complete resemblance; the two beta-sheets and a 3(10)-alpha-3(10) helix are preserved at 40 degrees C, and most loops contain well-defined turns. Special findings are the unexpectedly slow exchange of the Asn-47 and Phe-114 NH's and the observation of His-46 and His-117 N epsilon 2H resonances. The implications of these observations for the assignment of azurin resonance Raman spectra, the rigidity of the blue copper site, and the electron transfer mechanism of azurin are discussed.     

Role of ligand substitution on long-range electron transfer in azurins.

Azurin contains two potential redox sites, a copper centre and, at the opposite end of the molecule, a cystine disulfide (RSSR). Intramolecular electron transfer between a pulse radiolytically produced RSSR- radical anion and the blue Cu(II) ion was studied in a series of azurins in which single-site mutations were introduced into the copper ligand sphere. In the Met121His mutant, the rate constant for intramolecular electron transfer is half that of the corresponding wild-type azurin. In the His46Gly and His117Gly mutants, a water molecule is co-ordinated to the copper ion when no external ligands are added. Both these mutants also exhibit slower intramolecular electron transfer than the corresponding wild-type azurin. However, for the His117Gly mutant in the presence of excess imidazole, an azurin-imidazole complex is formed and the intramolecular electron-transfer rate increases considerably, becoming threefold faster than that observed in the native protein. Activation parameters for all these electron-transfer processes were determined and combined with data from earlier studies on intramolecular electron transfer in wild-type and single-site-mutated azurins. A linear relationship between activation enthalpy and activation entropy was observed. These results are discussed in terms of reorganization energies, driving force and possible electron-transfer pathways.     

High resolution structural studies of mutants provide insights into catalysis and electron transfer processes in copper nitrite reductase

We present high-resolution crystal structures and functional analysis of T1Cu centre mutants of nitrite reductase that perturb the redox potential and the Cys130-His129 "hard-wired" bridge through which electron transfer to the catalytic T2Cu centre occurs. These data provide insight into how activity can be altered through mutational manipulation of the electron delivery centre (T1Cu). The alteration of Cys to Ala results in loss of T1Cu and enzyme inactivation with azurin as electron donor despite the mutant enzyme retaining full nitrite-binding capacity. These data establish unequivocally that no direct transfer of electrons occurs from azurin to the catalytic type 2 Cu centre. The mutation of the axial ligand Met144 to Leu increases both the redox potential and catalytic activity, establishing that the rate-determining step of catalysis is the intermolecular electron transfer from azurin to nitrite reductase.     

1H, 13C and 15N resonance assignment of the soluble form of the Lipid-modified Azurin from Neisseria gonorrhoeae

Lipid-modified azurin (Laz) from Neisseria gonorrhoeae is a type 1 copper protein proposed to be the electron donor to several enzymes involved in the resistance mechanism to reactive oxygen and nitrogen species. Here we report the backbone and side-chain resonance assignment of Laz in the reduced form, which has been complete at 97 %. The predicted secondary structure indicates that this protein belongs to the azurin subfamily of type 1 copper proteins.     

Importance of polarization effect in the study of metalloproteins: Application of polarized protein specific charge scheme in predicting the reduction potential of azurin

Molecular dynamics (MD) simulation is commonly used in the study of protein dynamics, and in recent years, the extension of MD simulation to the study of metalloproteins is gaining much interest. Choice of force field is crucial in MD studies, and the inclusion of metal centers complicates the process of accurately describing the electrostatic environment that surrounds the redox centre. Herein, we would like to explore the importance of including electrostatic contribution from both protein and solvent in the study of metalloproteins. MD simulations with the implementation of thermodynamic integration will be conducted to model the reduction process of azurin from Pseudomonas aeruginosa. Three charge schemes will be used to derive the partial charges of azurin. These charge schemes differ in terms of the amount of immediate environment, respective to copper, considered during charge fitting, which ranges from the inclusion of copper and residues in the first coordination sphere during density functional theory charge fitting to the comprehensive inclusion of protein and solvent effect surrounding the metal centre using polarized protein‐specific charge scheme. From the simulations conducted, the relative reduction potential of the mutated azurins respective to that of wild‐type azurin (ΔE_cal) were calculated and compared with experimental values. The ΔE_cal approached experimental value with increasing consideration of environmental effect hence substantiating the importance of polarization effect in the study of metalloproteins. This study also attests the practicality of polarized protein‐specific charge as a computational tool capable of incorporating both protein environment and solvent effect into MD simulations. Proteins 2014; 82:2209–2219. © 2014 Wiley Periodicals, Inc.     

The production of azurin and similar proteins

Summary It has been shown that, in the organisms tested, the production of azurin or similar blue, copper-protein complexes is confined to bacterial species of the three genera Bordetella, Alcaligenes and Pseudomonas. In the strain of Pseudomonas aeruginosa used, there appeared to be no difference in the amount of azurin occurring when the strain was grown aerobically and anaerobically. The amount of azurin produced by representative strains of Ps. aeruginosa, B. bronchiseptica and A. denitrificans varied with the copper content of the medium. Above a level of 5 g copper/ml of medium, the azurin content was constant for the three species tested; below a copper level of 0.5 g/ml there was an almost total absence of azurin although good growth occurred. Under similar growth conditions, the azurin content of the three bacterial species studied was not significantly different.The possible role of azurin is discussed.     

NMR study of structure and electron transfer mechanism of Pseudomonas aeruginosa azurin

The nuclear spin-spin and spin-lattice relaxation times of the C epsilon 1-proton of His-35 and the C delta 2-proton of His-46 of reduced Pseudomonas aeruginosa azurin have been determined at 298 and 320 K and at pH 4.5 and 9.0 at various concentrations of total azurin and in the presence of varying amounts of oxidized azurin. The relaxation times appear strongly influenced by the electron self-exchange reaction between oxidized and reduced protein. The T1 data of the His-35 proton have been analyzed according to the "fast-exchange limit," while the "slow-exchange limit" appears to obtain for the T2 data of the His-46 proton. Analysis of the proton relaxation data yields values of the electron self-exchange rate constants of (9.6 +/- 0.7) X 10(5) M-1 S-1 (pH 4.5) and (7.0 +/- 1.3) X 10(5) M-1 S-1 (pH 9.0) at 298 K. The dipolar correlation time amounts to 1-2.5 ns in the temperature range of 298-320 K. A Fermi-contact interaction of about 100 mG for the C delta 2-proton of His-46 is compatible with the experimental observations. The pH-induced conformational changes lead to variations on the order of about 1 A in the distance from the copper to the His-35 protons. The data implicate the "hydrophobic patch" around His-117 as the site of electron transfer in the self-exchange reaction of the azurin.