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.     

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.     

Probing copper ligands in denatured <Emphasis Type="Italic">Pseudomonas aeruginosa</Emphasis> azurin: unfolding His117Gly and His46Gly mutants

Azurin is a single-domain beta-barrel protein with a redox-active copper cofactor. Upon Pseudomonas aeruginosa azurin unfolding, the cofactor remains bound to the polypeptide, coordinating three ligands: cysteine-112, one histidine imidazole, and a third, unknown ligand. In order to identify which histidine (histidine-117 and histidine-46 both coordinate copper in native azurin) is involved in copper coordination in denatured azurin, two single-site (histidine to glycine) mutants, His117Gly and His46Gly azurin, are investigated here. Equilibrium denaturation experiments of His46Gly azurin loaded with copper demonstrate that copper remains bound to this mutant in high urea concentrations where the protein's secondary structure is lost. In contrast, for copper-loaded His117Gly azurin, copper does not stay coordinated upon polypeptide unfolding. The copper absorption at 370 nm in denatured His46Gly azurin agrees with that for copper in complex with a peptide corresponding to residues 111-123 in azurin, suggesting similar metal coordination. We conclude that histidine-117 (and not histidine-46) is the histidine copper ligand in denatured azurin. This is also in accord with the proximity of histidine-117 to cysteine-112 in the primary sequence.     

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.     

Ligand replacement study at the His120 site of purple CuA azurin

The CuA center is a dinuclear Cu2S2(Cys) electron transfer center found in cytochrome c oxidase and nitrous oxide reductase. In a previous investigation of the equatorial histidine ligands' effect on the reduction potential, electron transfer and spectroscopic properties of the CuA center, His120 in the engineered CuA azurin was mutated to Asn, Asp, and Ala. The identical absorption and EPR spectra of these mutants indicate that a common ligand is bound to the copper center. To identify this replacement ligand, the His120Gly CuA azurin mutant was constructed and purified. Absorption and X-band EPR spectra show that His120Gly is similar to the other His120X (X = Asn, Asp, Ala) mutant proteins. Titrations with chloride, imidazole, and azide suggest that the replacement ligand is not exchangeable with exogenous ligands. The possibility of an internal amino acid acting as the replacement ligand for His120 in the His120X mutant proteins was investigated by analyzing the CuA azurin crystal structure and then converting the likely internal ligand, Asn 119, to Asp, Ser, or Ala in the His120Gly mutant. The double mutants H120G/Asn 119X (X = Asp, Ser, or Ala) displayed UV-Vis absorption and EPR spectra that are identical to His120Gly and the other His120X mutants, indicating that Asn119 is not the internal ligand replacing His120 in the His120X mutant proteins. These results demonstrate the remarkable stability of the dinuclear His120 mutants of CuA azurin.     

Involvement of the hydrophobic patch of azurin in the electron-transfer reactions with cytochrome C551 and nitrite reductase

The electron-transfer reactions of site-specific mutants of the blue copper protein azurin from Pseudomonas aeruginosa with its presumed physiological redox partners cytochrome c551 and nitrite reductase were investigated by temperature-jump and stopped-flow experiments. In the hydrophobic patch of azurin Met44 was replaced by Lys, and in the His35 patch His35 was replaced by Phe, Leu and Gln. Both patches were previously thought to be involved in electron transfer. 1H-NMR spectroscopy revealed only minor changes in the three-dimensional structure of the mutants compared to wild-type azurin. Observed changes in midpoint potentials could be attributed to electrostatic effects. The slow relaxation phase observed in temperature-jump experiments carried out on equilibrium mixtures of wild-type azurin and cytochrome c551 was definitively shown to be due to a conformational relaxation involving His35. Analysis of the kinetic data demonstrated the involvement of the hydrophobic but not the His35 patch of azurin in the electron transfer reactions with both cytochrome c551 and nitrite reductase.     

Studies of Pseudomonas aeruginosa azurin mutants: cavities in beta-barrel do not affect refolding speed

Pseudomonas aeruginosa azurin is a blue-copper protein with a Greek-key fold. Removal of copper produces an apoprotein with the same structure as holoazurin. To address the effects on thermodynamic stability and folding dynamics caused by small cavities in a beta-barrel, we have studied the behavior of the apo-forms of wild-type and two mutant (His-46-Gly and His-117-Gly) azurins. The equilibrium- and kinetic-folding and unfolding reactions appear as two-state processes for all three proteins. The thermodynamic stability of the two mutants is significantly decreased as compared with the stability of wild-type azurin, in accord with cavities in or near the hydrophobic interior having an overall destabilizing effect. Large differences are also found in the unfolding rates: the mutants unfold much faster than wild-type azurin. In contrast, the folding-rate constants are almost identical for the three proteins and closely match the rate-constant predicted from the native-state topology of azurin. We conclude that the topology is more important than equilibrium stability in determining the folding speed of azurin.     

The significance of the flexible loop in the azurin (Az-iso2) from the obligate methylotroph Methylomonas sp. strain J

The obligate methylotroph Methylomonas sp. strain J produces two azurins (Az-iso1 and Az-iso2) as candidates for electron acceptor from methylamine dehydrogenase (MADH) in the electron-transfer process involving the oxidation of methylamine to formaldehyde and ammonia. The X-ray crystallographic study indicated that Az-iso2 gives two types of crystals (form I and form II) with polyethylene glycol (PEG4000) and ammonium sulfate as the precipitants, respectively. Comparison between the two Az-iso2 structures in forms I and II reveals the remarkable structural changes at the top surface of the molecule around the copper atom. Az-iso2 possesses Gly43 instead of Val43 or Ala43, which is unique among all other azurins around the copper ligand His46, inducing the remarkable structural change in the loop region from Gly37 to Gly43. When the structure of Az-iso2 is superimposed on that of amicyanin in the ternary complex composed of MADH, amicyanin, and cytochrome c(551), the loop of Az-iso2 deeply overlaps with the light subunit of MADH. However, the Az-iso2 molecule is probably able to avoid any steric hindrance with the cognate MADH to form the complex for intermolecular electron-transfer reaction, since the loop containing Gly43 is flexible. We discuss why the electron-transfer activity of Az-iso2 is fivefold higher than that of Az-iso1.     

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     

Electron transfer from quinohemoprotein alcohol dehydrogenase to blue copper protein azurin in the alcohol oxidase respiratory chain of Pseudomonas putida HK5.

A blue copper protein was purified together with a type II quinohemoprotein alcohol dehydrogenase (ADH IIB) from the soluble fraction of Pseudomonas putida HK5 grown on n-butanol. The purified blue copper protein was shown to be azurin, on the basis of several properties such as its absorption maximum (623 nm), its low molecular mass (17 500 Da), its acidic nature (pI of 4.1), its relatively high redox potential (306 mV), the presence of an intramolecular disulfide bond, and N-terminal amino acid sequence homology with respect to azurins from other sources, especially from P. putida NCIB 9869 and Pseudomonas fluorescens. Direct electron transfer from ADH IIB to azurin was shown to occur at a rate of 48-70 s-1. The apparent Km value of ADH IIB for azurin, determined by steady-state kinetics, was decreased several-fold by increasing the ionic strength. Furthermore, the extent of fluorescence quenching of ADH IIB due to the interaction with azurin was increased by increasing the ionic strength, but the binding constant for binding between ADH IIB and azurin was unchanged. The redox potential of azurin was increased 12 mV by incubation with ADH but not vice versa. Furthermore, the redox potential gap between ADH and azurin was increased from 102 to 126 mV by increasing the ionic strength. It is conceivable that a hydrophobic interaction is involved in the electron transfer between both proteins, and it is also suggested that the electron transfer may occur by a freely reversible on and off binding process but may not be related to the global binding process of both proteins. Thus, the results presented here strongly suggest that azurin works as an electron-transfer mediator in a PQQ-dependent alcohol oxidase respiratory chain in P. putida HK5.     

Gated electron transfers and electron pathways in azurin: a NMR dynamic study at multiple fields and temperatures

Dynamic properties of electron transfer pathways in a small blue copper cupredoxin are explored using an extensive 15N NMR relaxation study of reduced Pseudomonas aeruginosa azurin at four magnetic fields (500-900 MHz) and at two temperatures chosen well below the melting point of the protein. Following a careful model-free analysis, several protein regions with different dynamic regimes are identified. Nanosecond time-scale mobility characterizes various residues of the hydrophobic surface patch believed to mark the natural entry point for electrons, notably the surface-exposed copper-ligand His117. These findings are consistent with a gated electron transfer process according to the "dynamic docking" model. Residues 47-49 along intramolecular pathways of electrons show rigidity that is remarkably conserved when increasing the temperature. Three different conformational exchange processes were observed in the millisecond range, one near the only disulfide bridge in the molecule and two near the copper ion. The latter two processes are consistent with previous data such as crystal structures at various pH values and NMR relaxation dispersion experiments; they may indicate an additional gated electron transfer mechanism at slower time-scales.     

Role of the active-site cysteine of Pseudomonas aeruginosa azurin. Crystal structure analysis of the CuII(Cys112Asp) protein

Replacement of the cysteine at position 112 of Pseudomonas aeruginosa azurin with an aspartic acid residue results in a mutant (Cys112Asp) protein that retains a strong copper-binding site. Cu^II(Cys112Asp) azurin can be reduced by excess [Ru^II(NH₃)₆]²⁺, resulting in a Cu^I protein with an electronic absorption spectrum very similar to that of wild-type Cu^I azurin. Cys112Asp azurin exhibits reversible interprotein electron-transfer reactivity with P. aeruginosa cytochrome c ₅₅₁ (μ?=?0.1?M sodium phosphate (pH?7.0);E°(Cu^II/I)?=?180 mV vs NHE); this redox activity indicates that electrons can still enter and exit the protein through the partially solvent-exposed imidazole ring of His117. The structure of Cu^II(Cys112Asp) azurin at 2.4-Å resolution shows that the active-site copper is five coordinate: the pseudo-square base of the distorted square-pyramidal structure is defined by the imidazole N^δ atoms of His46 and His117 and the oxygen atoms of an asymmetrically-bound bidentate carboxylate group of Asp112; the apical position is occupied by the oxygen atom of the backbone carbonyl group of Gly45. The Cu^II–Asp112 interaction is distinguished by an approximately 1.2-Å displacement of the metal center from the plane defined by the Asp112 carboxylate group.     

The structural role of the copper-coordinating and surface-exposed histidine residue in the blue copper protein azurin

Copper K-edge extended X-ray absorption fine structure (EXAFS) spectroscopy and (15)N NMR relaxation studies were performed on samples of a variant azurin in which the surface-exposed histidine ligand of the copper atom (His117) has been replaced by glycine. The experiments were performed to probe the structure of the active site and the protein dynamics. The cavity in the protein structure created by the His-->Gly replacement could be filled by external ligands, which can either restore the spectroscopic properties of the original type-1 copper site or create a new type-2 copper site. The binding of external ligands occurs only when the copper atom is in its oxidised state. In the reduced form, the binding is abolished. From the EXAFS experiments, it is concluded that for the oxidised type-1 copper sites the protein plus external ligand (L) provide an NSS*L donor set deriving from His46, Cys112, Met121 and the external ligand. The type-2 copper site features an S(N/O)(3) donor set in which the S-donor derives from Cys112, one N-donor from His46 and the remaining two N or O donors from one or more external ligands. Upon reduction of the type-1 as well as the type-2 site, the external ligand drops out of the copper site and the coordination reduces to 3-fold with an SS*N donor set deriving from His46, Cys112 and Met121. The Cu-S(delta)(Met) distance is reduced from about 3.2 to 2.3 A. Analysis of the NMR data shows that the hydrophobic patch around His117 has gained fluxionality when compared to wild-type azurin, which may explain why the His117Gly variant is able to accommodate a variety of external ligands of different sizes and with different chelating properties. On the other hand, the structure and dynamics of the beta-sandwich, which comprises the main body of the protein, is only slightly affected by the mutation. The unusually high reduction potential of the His117Gly azurin is discussed in light of the present results.     

Insights into redox partner interactions and substrate binding in nitrite reductase from Alcaligenes xylosoxidans: crystal structures of the Trp138His and His313Gln mutants

Dissimilatory nitrite reductase catalyses the reduction of nitrite to nitric oxide within the key biological process of denitrification. We present biochemical and structural results on two key mutants, one postulated to be important for the interaction with the partner protein and the other for substrate entry. Trp138, adjacent to one of the type-1 Cu ligands, is one of the residues surrounding a small depression speculated to be important in complex formation with the physiological redox partners, azurin I and II. Our data reveal that the Trp138His mutant is fully active using methyl viologen as an artificial electron donor, but there is a large decrease in activity using azurin I. These observations together with its crystal structure at a high resolution of 1.6 A confirm the importance of Trp138 in electron transfer and thus in productive interaction with azurin. A "hydrophobic pocket" on the protein surface has been identified as the channel through which nitrite may be guided to the catalytic type-2 Cu site. Glu133 and His313 at the opening of the pocket are conserved among most blue and green copper nitrite reductases (CuNiRs). The failure to soak the substrate into our high-resolution crystal form of native and mutant CuNiRs has been linked to the observation of an extraneous poly(ethylene glycol) (PEG) molecule interacting with His313. We present the crystal structure of His313Gln and the substrate-bound mutant at high resolutions of 1.65 and 1.72 A, respectively. The observation of the substrate-bound structure for the His313Gln mutant and inhibitory studies with PEG establishes the role of the hydrophobic pocket as the port of substrate entry.     

Crystal structure analysis of oxidized Pseudomonas aeruginosa azurin at pH 5.5 and pH 9.0. A pH-induced conformational transition involves a peptide bond flip

The X-ray crystal structure of recombinant wild-type azurin from Pseudomonas aeruginosa was determined by difference Fourier techniques using phases derived from the structure of the mutant His35Leu. Two data sets were collected from a single crystal of oxidized azurin soaked in mother liquor buffered at pH 5.5 and pH 9.0, respectively. Both data sets extend to 1.93 A resolution. The two pH forms were refined independently to crystallographic R-factors of 17.6% (pH 5.5) and 17.5% (pH 9.0). The conformational transition previously attributed to the protonation/deprotonation of residue His35 (pKa(red) = 7.3, pKa(ox) = 6.2), which lies in a crevice of the protein close to the copper binding site, involves a concomitant Pro36-Gly37 main-chain peptide bond flip. At the lower pH, the protonated imidazole N delta 1 of His35 forms a strong hydrogen bond with the carbonyl oxygen from Pro36, while at alkaline pH the deprotonated N delta 1 acts as an acceptor of a weak hydrogen bond from HN Gly37. The structure of the remainder of the azurin molecule, including the copper binding site, is not significantly affected by this transition.     

Structure of azurin from Alcaligenes denitrificans refinement at 1.8 A resolution and comparison of the two crystallographically independent molecules

The structure of the blue copper protein azurin, from Alcaligenes denitrificans, has been refined crystallographically by restrained least-squares methods. The final crystallographic R value for 21,980 observed reflections to 1.8 A (1 A = 0.1 nm) resolution is 0.157. The asymmetric unit of the crystal contains two independent azurin molecules, the model for which comprises 1973 protein atoms, together with three SO2-4 ions, and 281 water molecules. Comparison of the two molecules shows very high correspondence. For 125 out of 129 residues (excluding only the chain termini, residues 1 to 2 and 128 to 129) the root-mean-square (r.m.s.) deviation in main-chain atom positions is 0.27 A. For other structural parameters r.m.s. deviations are also low; torsion angles 6.5 degrees, hydrogen bond lengths 0.12 A, bonds to copper 0.04 A and bond angles at the copper 3.9 degrees. The only significant differences are at the chain termini and in several loops. Some of these can be attributed to crystal packing effects, others to genuine structural microheterogeneity. Refinement has confirmed that the copper co-ordination is best described as distorted trigonal planar, with strong in-plane bonds to His46 N delta 1, His117 N delta 1 and Cys112 S gamma, and much weaker axial interactions with Met121 S delta and Gly45 C = O. Two N-H...S hydrogen bonds characterize Cys112 S gamma as a thiolate (S-) sulphur and may influence the visible absorption maximum. Atoms in and around the copper site have very low mobility, whereas the most mobile regions of the molecule are the chain termini and some of the connecting loops between secondary structure elements, especially those at the "southern" end, remote from the copper site. Main-chain to side-chain hydrogen bonds supply important stabilizing interactions at the "northern" end. Surface features include the hydrophobic patch around His117, probably important for electron transfer, the SO2-4 site at His83, and the general absence of ion pairs, despite the presence of many charged amino acid residues. The 281 water molecules include 182 that occur as approximately twofold-related pairs. There are no internal water molecules. The water sites common to both azurin molecules include those in surface pockets and some in intermolecular contact regions. They are characterized by relatively low thermal parameters and numerous protein contacts.     

Probing electron transfer reactions between two azurins from Alcaligenes xylosoxidans GIFU 1051 with optically active Ru complexes as molecular recognition probes: Importance of the 43rd residue

Electron transfer reactions between optically-active Ru^II/III complexes incorporating (S)-/(R)-amino acids, and the two azurins, azurin-1 (az-1Cu) and azurin-2 (az-2Cu) isolated from Alcaligenes xylosoxidans GIFU 1051, have been studied to probe molecular recognition sites on the two azurins. The Ru^II/III complexes are K[Ru^II(L)(bpy)] and [Ru^III(L)(bpy)], and have a tripodal ligand (L) derived from the (S)-/(R)-amino acids, which are in turn exchanged for other functional substituent groups, such as (S)-/(R)-phenylalanine, -leucine, -valine, -alanine, and -glutamic acid (L = (S)-/(R)-BCMPA, -BCMLE, -BCMVA, -BCMAL, and -BCMGA). In the oxidation reaction of az-1Cu^I promoted by the Ru^III complexes, the kinetic parameters exhibited enantio- and stereo-selectivities, while the same reaction of az-2Cu^I was less enantio- and stereo-selective. These differences suggest that the processes of formation of the activated states are different for the two azurins. On the other hand, such a difference has not been observed for az-1 and az-2 with respect to the reduction reactions promoted by both azurins Cu^II by the Ru^II complexes within the experimental error. This suggests that the neutrality of the Ru complexes is important for precise molecular recognition of azurins. His117 has been proposed as the electron transfer site. The local structures in the vicinity of the His117 side chain in the two azurins, are essentially identical with the exception of the 43rd residue, Val43 and Ala43 for az-1 and az-2, respectively. Electron transfer reactions between Ru^III complexes and a mutant azurin, V43A-az-1, were also carried out. Interestingly, the activation parameters estimated were very similar to those of az-2, indicating that the 43rd residue acts as the electron transfer site in azurins and provides rationalization for the different mechanisms of az-1 and az-2 in redox reactions.     

Ionic strength and pH dependence of the reaction between plastocyanin and Photosystem 1. Evidence of a rate-limiting conformational change

The electron-transfer reaction between spinach wild-type plastocyanin (Pc(WT)) two site-directed mutants, Pc(Thr79His) and Pc(Lys81His), and spinach Photosystem 1 particles, has been studied as a function of protein concentration, ionic strength and pH by using laser-flash absorption spectroscopy. The kinetic data are interpreted using the simplest possible three-step model, involving a rate-limiting conformational change preceding intracomplex electron transfer. The three proteins show similar concentration, pH and ionic strength dependencies. The effects of ionic strength and pH on the reaction indicate a strong influence of complementary charges on complex formation and stabilization. Studies with apoprotein support the opinion that the hydrophobic patch is critical for an productive interaction with the reaction center of Photosystem 1. Together with earlier site-directed mutagenesis studies, the absence of a detectable Photosystem 1 reaction in the presence of reduced azurin, stellacyanin, cytochrome c and cytochrome c₅₅₁, demonstrates the existence of a high level of specificity in the protein-protein interface in the formation of an efficient electron-transfer complex.     

If space is provided,bulky modification on the rim of azurin's beta-barrel results in folded protein

Pseudomonas aeruginosa azurin is a blue-copper protein with a beta-barrel fold. Here we report that, at conditions where thermal unfolding of apo-azurin is reversible, the reaction occurs in a single step with a transition midpoint (T(m)) of 69 degrees C (pH 7). The active-site mutation His117Gly creates a cavity in the beta-barrel near the surface but does not perturb the overall fold (T(m) of 64 degrees C, pH 7). Oxidation of the active-site cysteine (Cysteine-112) in wild-type azurin, which occurs readily at higher temperatures, results in a modified protein that cannot adopt a native-like structure. In sharp contrast, Cysteine-112 oxidation in His117Gly azurin yields a modified apo-azurin that appears folded and displays cooperative, reversible unfolding (T(m) approximately 55 degrees C, pH 7). We conclude that azurin's beta-barrel is a rigid structural element that constrains the structure of its surface; a bulky modification can only be accommodated if complementary space is provided.     

Myrothecium verrucaria bilirubin oxidase and its mutants for potential copper ligands

Bilirubin oxidase (EC:1.3.3.5) purified from a culture medium of Myrothecium verrucaria MT-1 (authentic enzyme) catalyzes the oxidation of bilirubin to biliverdin in vitro and recombinant enzyme (wild type) was obtained by using an overexpression system of the bilirubin oxidase gene with Aspergillus oryzae harboring an expression vector. The absorption and ESR spectra showed that both bilirubin oxidases are multicopper oxidases containing type 1, type 2, and type 3 coppers similar to laccase, ascorbate oxidase, and ceruloplasmin. Site-directed mutagenesis has been performed for the possible ligands of each type of copper. In some mutants, Cys457 --> Val, Ala, His94 --> Val, and His134.136 --> Val, type 1 and type 2 copper centers were perturbed completely and the enzyme activity was completely lost. Differing from the holoenzyme, these mutants showed type 3 copper signals. However, the optical and magnetic properties characteristic of type 1 copper were retained even by mutating one of the type 1 copper ligands, i.e., a mutant, Met467 --> Gly, showed a weak but apparent enzyme activity. A double mutant His456.458 --> Val had only type 1 Cu, showing a blue band at 600 nm (epsilon = 1.6 x 10(3)) and an ESR signal with very narrow hyperfine splitting (A parallel = 7.2 x 10(-)3 cm-1). Since the type 2 and type 3 coppers are not present, the mutant did not show enzyme activity. These results strongly imply that the peculiar sequence in bilirubin oxidase, His456-Cys457-His458, forms an intramolecular electron-transfer pathway between the type 1 copper site and the trinuclear center composed of the type 2 and type 3 copper sites.