Generation of novel copper sites by mutation of the axial ligand of amicyanin. Atomic resolution structures and spectroscopic properties

Amicyanin from Paracoccus denitrificans is a type 1 copper protein with three strong equatorial copper ligands provided by nitrogens of His53 and His95 and the sulfur of Cys92, with an additional weak axial ligand provided by the sulfur of Met98. Met98 was replaced with either Gln or Ala. As isolated, the M98A and M98Q mutant proteins contain zinc in the active site. The zinc is then removed and replaced with copper so that the copper-containing proteins may be studied. Each of the mutant amicyanins exhibits a marked decrease in thermal stability relative to that of native amicyanin, consistent with the weaker affinity for copper. Crystal structures were obtained for the oxidized and reduced forms of M98A and M98Q amicyanins at atomic resolution (相似文献   

An amicyanin C-terminal loop mutant where the active-site histidine donor cannot be protonated

A novel blue copper protein was constructed by replacing the C-terminal loop of amicyanin (Paracoccus versutus) by the homologous loop of rusticyanin. The C-terminal loop of both amicyanin and rusticyanin contains three (His, Cys, Met) of the four copper ligands. The amicyanin mutant exhibits all spectroscopic properties normally encountered for blue copper sites. The midpoint potential (369 mV) is the highest reported value for an amicyanin mutant. Cyclic voltammetry and NMR studies of the reduced form indicate that, in contrast to wild-type amicyanin and all amicyanin mutants described so far, the C-terminal histidine ligand does not protonate in the accessible pH range (pKa<4.5).     

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performed on samples of a variant azurin in which the surface-exposed histidine ligand of the copper atom (His117) has been replaced by glycine.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.     

The crystal structure of cobalt-substituted pseudoazurin from Alcaligenes faecalis

The Cu(II) center at the active site of the blue copper protein pseudoazurin from Alcaligenes faecalis has been substituted by Co(II) via denaturing of the protein, chelation and removal of copper by EDTA and refolding of the apo‐protein, followed by addition of an aqueous solution of CoCl₂. Sitting drop vapour diffusion experiments produced green hexagonal crystals, which belong to space group P6₅, with unit cell dimensions a = b = 50.03, c = 98.80 Å. Diffraction data, collected at 291 K on a copper rotating anode X‐ray source, were phased by the anomalous signal of the cobalt atom. The structure was built automatically, fitted manually and subsequently refined to 1.86 Å resolution. The Co‐substituted protein exhibits similar overall geometry to the native structure with copper. Cobalt binds more strongly to the axial Met86‐Sδ and retains the tetrahedral arrangement with the four ligand atoms, His40‐Nδ₁, Cys78‐Sγ, His81‐Nδ₁, and 86Met‐Sδ, although the structure is less distorted than the native copper protein. The structure reported herein, is the first crystallographic structure of a Co(II)‐substituted pseudoazurin. © 2010 Wiley Periodicals, Inc. Biopolymers 95: 202–207, 2011.     

Introduction of a pi-pi interaction at the active site of a cupredoxin: characterization of the Met16Phe Pseudoazurin mutant

The Met16Phe mutant of the type 1 copper protein pseudoazurin (PACu), in which a phenyl ring is introduced close to the imidazole moiety of the His81 ligand, has been characterized. NMR studies indicate that the introduced phenyl ring is parallel to the imidazole group of His81. The mutation has a subtle effect on the position of the two S(Cys)-->Cu(II) ligand-to-metal charge transfer bands in the visible spectrum of PACu(II) and a more significant influence on their intensities resulting in a A(459)/A(598) ratio of 0.31 for Met16Phe as compared to a A(453)/A(594) ratio of 0.43 for wild-type PACu(II) at pH 8. The electron paramagnetic resonance spectrum of the Met16Phe variant is more axial than that of the wild-type protein, and the resonance Raman spectrum of the mutant exhibits subtle differences. A C(gamma)H proton of Met86 exhibits a much smaller hyperfine shift in the paramagnetic (1)H NMR spectrum of Met16Phe PACu(II) as compared to its position in the wild-type protein, which indicates a weaker axial Cu-S(Met86) interaction in the mutant. The Met16Phe mutation results in an approximately 60 mV increase in the reduction potential of PACu. The pK(a) value of the ligand His81 decreases from 4.9 in wild-type PACu(I) to 4.5 in Met16Phe PACu(I) indicating that the pi-pi contact with Phe16 stabilizes the Cu-N(His81) interaction. The Met16Phe variant of PACu has a self-exchange rate constant at pH 7.6 (25 degrees C) of 9.8 x 10(3) M(-)(1) s(-)(1) as compared to the considerably smaller value of 3.7 x 10(3) M(-)(1) s(-)(1) for the wild-type protein under identical conditions. The enhanced electron transfer reactivity of Met16Phe PACu is a consequence of a lower reorganization energy due to additional active site rigidity caused by the pi-pi interaction between His81 and the introduced phenyl ring.     

Methionine-121 coordination determines metal specificity in unfolded<Emphasis Type="Italic"> Pseudomonas aeruginosa</Emphasis> azurin

Pseudomonas aeruginosa azurin binds copper so tightly that it remains bound even upon polypeptide unfolding. Copper can be substituted with zinc without change in protein structure, and also in this complex the metal remains bound upon protein unfolding. Previous work has shown that native-state copper ligands Cys112 and His117 are two of at least three metal ligands in the unfolded state. In this study we use isothermal titration calorimetry and spectroscopic methods to test if the native-state ligand Met121 remains a metal ligand upon unfolding. From studies on a point-mutated version of azurin (Met121Ala) and a set of model peptides spanning the copper-binding C-terminal part (including Cys112, His117 and Met121), we conclude that Met121 is a metal ligand in unfolded copper-azurin but not in the case of unfolded zinc-azurin. Combination of unfolding and metal-titration data allow for determination of copper (Cu(II) and Cu(I)) and zinc affinities for folded and unfolded azurin polypeptides, respectively.     

The copper centers of tyramine β-monooxygenase and its catalytic-site methionine variants: an X-ray absorption study

Tyramine β-monooxygenase (TBM) is a member of a family of copper monooxygenases containing two noncoupled copper centers, and includes peptidylglycine monooxygenase and dopamine β-monooxygenase. In its Cu(II) form, TBM is coordinated by two to three His residues and one to two non-His O/N ligands consistent with a [Cu_M(His)₂(OH₂)₂–Cu_H(His)₃(OH₂)] formulation. Reduction to the Cu(I) state causes a change in the X-ray absorption spectroscopy (XAS) spectrum, consistent with a change to a [Cu_M(His)₂S(Met)–Cu_H(His)₃] environment. Lowering the pH to 4.0 results in a large increase in the intensity of the Cu(I)–S extended X-ray absorption fine structure (EXAFS) component, suggesting a tighter Cu–S bond or the coordination of an additional sulfur donor. The XAS spectra of three variants, where the Cu_M Met471 residue had been mutated to His, Cys, and Asp, were examined. Significant differences from the wild-type enzyme are evident in the spectra of the reduced mutants. Although the side chains of His, Cys, and Asp are expected to substitute for Met at the Cu_M site, the data showed identical spectra for all three reduced variants, with no evidence for coordination of residue 471. Rather, the K-edge data suggested a modest decrease in coordination number, whereas the EXAFS indicated an average of two His residues at each Cu(I) center. These data highlight the unique role of the Met residue at the Cu_M center, and pose interesting questions as to why replacement by the cuprophilic thiolate ligand leads to detectable activity whereas replacement by imidazole generates inactive TBM.     

The structural homology of amicyanin from Thiobacillus versutus to plant plastocyanins

The complete amino acid sequence of the blue copper protein amicyanin of Thiobacillus versutus, induced when the bacterium is grown on methylamine, has been determined as follows: QDKITVTSEKPVAAADVPADAVVVGIEKMKYLTPEVTIKAGETVYWVNGEVMPHNVA FKKGIVGEDAFRGEMMTKDQAYAITFNEAGSYDYFCTPHPFMRGKVIVE. The four copper ligand residues in this 106-residue-containing polypeptide chain are His54, Cys93, His96, and Met99. The Thiobacillus amicyanin is 52% similar to the amicyanin of Pseudomonas AM1, the only other copper protein known with the same spacing between the second histidine ligand and the methionine ligand. T. versutus amicyanin contains no cysteine bridge and is more closely related to the plant copper protein plastocyanin than to the bacterial copper protein azurin. Alignment of the two known amicyanin sequences with the consensus sequence of the plastocyanins and comparison with the known three-dimensional structure of poplar leaves plastocyanin reveals that the bacterial proteins have the same overall structure with two beta-sheets packed face to face. The major structural differences between the amicyanins and the plastocyanins appear to be located in two of the five loops that connect the six identified beta-strands of the amicyanins. The first of these two loops, connecting strands F and G, contains a ligand histidine and must have a different conformation from the same loop in the plastocyanins because it is shorter by two amino acids. Further differences occur in the loop connecting the strands D and E. This loop contains only 17 residues in amicyanin whereas the corresponding loop of plastocyanin contains 25 residues. Despite these differences the amicyanins appear much closer related to the plastocyanins than to the azurins. The present findings demonstrate that the occurrence of blue copper proteins with clearly plastocyanin-like features is not restricted to photosynthetic redox chains.     

Active site modeling in copper azurin molecular dynamics simulations

Active site modeling in molecular dynamics simulations is investigated for the reduced state of copper azurin. Five simulation runs (5 ns each) were performed at room temperature to study the consequences of a mixed electrostatic/constrained modeling for the coordination between the metal and the polypeptide chain, using for the ligand residues a set of charges that is modified with respect to the apo form of the protein by the presence of the copper ion.The results show that the different charge values do not lead to relevant effects on the geometry of the active site of the protein, as long as bond distance constraints are used for all the five ligand atoms. The distance constraint on the O atom of Gly45 can be removed without altering the active site geometry. The coordination between Cu and the other axial ligand Met121 is outlined as being flexible. Differences are found between the bonds of the copper ion with the two apparently equivalent N¹ atoms of His46 and His117.The overall findings are discussed in connection with the issue of determining a model for the active site of azurin suitable to be used in molecular dynamics simulations under unfolding conditions. Figure Model of azurin active site. Copper ligand residues are cut off at C position except Gly45, for which the portion of backbone connecting it to His46 is shown. Only polar H atoms are shown. All atoms are in standard colors (Cu in violet), and the five ligands are labeled     

Crystal structure of a novel red copper protein from Nitrosomonas europaea

Nitrosocyanin (NC) is a mononuclear red copper protein isolated from the ammonia oxidizing bacterium Nitrosomonas europaea. Although NC exhibits some sequence homology to classic blue copper proteins, its spectroscopic and electrochemical properties are drastically different. The 1.65 A resolution crystal structure of oxidized NC reveals an unprecedented trimer of single domain cupredoxins. Each copper center is partially covered by an unusual extended beta-hairpin structure from an adjacent monomer. The copper ion is coordinated by His 98, His 103, Cys 95, a single side chain oxygen of Glu 60, and a solvent molecule. In the 2.3 A resolution structure of reduced NC, His 98 shifts away from the copper ion, and the solvent molecule is not observed. The arrangement of these ligands renders the coordination geometry of the NC red copper center distinct from that of blue copper centers. In particular, the red copper center has a higher coordination number and lacks the long Cu-S(Met) and short Cu-S(Cys) bond distances characteristic of blue copper. Moreover, the red copper center is square pyramidal whereas blue copper is typically distorted tetrahedral. Analysis of the NC structure provides insight into possible functions of this new type of biological copper center.     

Site-directed mutagenesis of a possible type 1 copper ligand of bilirubin oxidase; a Met467Gln mutant shows stellacyanin-like properties

In our previous paper, we reported a mutant of recombinant Myrothecium verrucaria bilirubin oxidase, in which the Met467 residue was replaced by Gly [Shimizu, A. et al. (1999) Biochemistry 38, 3034-3042]. This mutant displayed a remarkable reduction in enzymatic activity and an evident decrease in the intensity of the absorption band around 600 nm (type 1 charge transfer transition). In this study, we report the preparation of three Met467 mutants (Met467Gln, Met467His, and Met467Arg) and characterize their enzymatic activities, midpoint potentials, and absorption and ESR spectra. Met467His and Met467Arg show no enzymatic activity and a great reduction in the intensity of the absorption band around 600 nm. Furthermore, their ESR spectra show no type 1 copper signal, but only a type 2 copper signal; however, oxidation by ferricyanide caused the type 1 copper signal to appear. On the other hand, Met467Gln as expressed shows both type 1 and type 2 copper signals in its ESR spectrum, the type 1 copper atom parameters being very different from usual blue copper proteins but very similar to those of stellacyanin. The enzymatic activity of the Met467Gln mutant for bilirubin is quite low (0.3%), but the activity for potassium ferrocyanide is similar (130%) to that of the wild type enzyme. These results indicate that Met467 is important for characterizing the features of the type 1 copper of bilirubin oxidase.     

Role of the axial ligand in type 1 Cu centers studied by point mutations of met148 in rusticyanin.

Type 1 Cu centers in cupredoxins, nitrite reductases, and multi-copper oxidases utilize the same trigonal core ligation to His-Cys-His, with a weak axial ligand generally provided by a Met sulfur. In azurin, an additional axial ligand, a carbonyl oxygen from a Gly, is present. The importance of these axial ligands and in particular the Met has been debated extensively in terms of their role in fine-tuning the redox potential, spectroscopic properties, and rack-induced or entatic state properties of the copper sites. Extensive site-directed mutagenesis of the Met ligand has been carried out in azurin, but the presence of an additional carbonyl oxygen axial ligand has made it difficult to interpret the effects of these substitutions. Here, the axial methionine ligand (Met148) in rusticyanin is replaced with Leu, Gln, Lys, and Glu to examine the effect on the redox potential, acid stability, and copper site geometry. The midpoint redox potential varies from 363 (Met148Lys) to 798 mV (Met148Leu). The acid stability of the oxidized proteins is reduced except for the Met148Gln mutant. The Gln mutant remains blue at all pH values between 2.8 and 8, and has a redox potential of 563 mV at pH 3.2. The optical and rhombic EPR properties of this mutant closely resemble those of stellacyanin, which has the lowest redox potential among single-type 1 copper proteins (185 mV). The Met148Lys mutant exhibits type 2 Cu EPR and optical spectra in this pH range. The Met148Glu mutant exhibits a type 2 Cu EPR spectrum above pH 3 and a mixture of type 1 and type 2 Cu spectra at lower pH. The Met148Leu mutant exhibits the highest redox potential ( approximately 800 mV at pH 3.2) which is similar to the values in fungal laccase and in the type 1 Cu site of ceruloplasmin where this axial ligand is also a Leu.     

The role of hydrogen bonding at the active site of a cupredoxin: the Phe114Pro azurin variant

The Phe114Pro mutation to the cupredoxin azurin (AZ) leads to a number of structural changes at the active site attributed to deletion of one of the hydrogen bonds to the Cys112 ligand, removal of the bulky phenyl group from the hydrophobic patch of the protein, and steric interactions made by the introduced Pro. The remaining hydrogen bond between the coordinating thiolate and the backbone amide of Asn47 is strengthened. At the type-1 copper site, the Cu(II)-O(Gly45) axial interaction decreases, while the metal moves out of the plane formed by the equatorial His46, Cys112, and His117 ligands, shortening the bond to the axially coordinating Met121. The resulting distorted tetrahedral geometry is distinct from the trigonal bipyramidal arrangement in the wild-type (WT) protein. The unique position of the main S(Cys) --> Cu(II) ligand-to-metal charge-transfer transition in AZ (628 nm) has shifted in the Phe114Pro variant to a value that is more typical for cupredoxins (599 nm). This probably occurs because of the removal of the Phe114-Cys112 hydrogen bond. The Phe114Pro mutation results in a 90 mV decrease in the reduction potential of AZ, and removal of the second hydrogen bond to the Cys ligand seems to be the major cause of this change. The C-terminal His117 ligand does not protonate in the reduced Phe114Pro AZ variant, which suggests that none of the structural features altered by the mutation are responsible for the absence of this effect in the WT protein. Upon reduction, the copper displaces further from the equatorial ligand plane and the Cu-S(Met121) bond length decreases. These changes are larger than those seen in the WT protein and contribute to the order of magnitude decrease in the intrinsic electron-transfer capabilities of the Phe114Pro variant.     

1H NMR study of the solution molecular and electronic structure of Escherichia coli ferricytochrome b562: evidence for S = 1/2 in equilibrium S = 5/2 spin equilibrium for intact His/Met ligation

The solution 500-MHz 1H NMR spectral parameters for ferricytochrome b562, a soluble 12-kDa electron carrier from Escherichia coli with axial His/Met coordination, are shown to be strongly influenced by protein concentration and ionic strength at low pH and 25 degrees C in a manner consistent with significant aggregation at low ionic strength. At high ionic strength a well-resolved 1H NMR spectrum reveals over 40 hyperfine-shifted resonances which arise from two isomeric species in the ratio 2:1. 2D COSY and NOESY maps at 25 degrees C for the hyperfine-shifted resonances allow the assignment of a number of axial His resonances and all heme peripheral substituent peaks. The resulting asymmetric heme contact shift patterns, together with the halving of the number of lines when reconstituting with 2-fold symmetric hemin, demonstrate the molecular basis of the solution heterogeneity to be heme orientational disorder. The strongly upfield-shifted axial Met-7 resonances, characteristic of low-spin ferricytochromes c with His/Met ligation, appear upfield only at very low temperatures. At elevated temperatures, all resonances, in particular those of the axial Met, move strongly downfield. Detailed analysis of the deviation from Curie behavior for different functional groups demonstrates the presence of a low spin in equilibrium high spin equilibrium with an intact His-Fe-Met coordination. The weaker axial field in ferricytochrome b562, relative to the purely low-spin ferricytochromes c, is attributed to a perturbed iron-Met bond. The contact shifts for a coordinated Met in the high-spin state are estimated. A link between equatorial hemin and axial ligand interactions is indicated by a differential population of the high-spin form for the two hemin orientations.     

Replacement of the axial copper ligand methionine with lysine in amicyanin converts it to a zinc-binding protein that no longer binds copper

The mutation of the axial ligand of the type I copper protein amicyanin from Met to Lys results in a protein that is spectroscopically invisible and redox inactive. M98K amicyanin acts as a competitive inhibitor in the reaction of native amicyanin with methylamine dehydrogenase indicating that the M98K mutation has not affected the affinity for its natural electron donor. The crystal structure of M98K amicyanin reveals that its overall structure is very similar to native amicyanin but that the type I binding site is occupied by zinc. Anomalous difference Fourier maps calculated using the data collected around the absorption edges of copper and zinc confirm the presence of Zn²⁺ at the type I site. The Lys98 NZ donates a hydrogen bond to a well-ordered water molecule at the type I site which enhances the ability of Lys98 to provide a ligand for Zn²⁺. Attempts to reconstitute M98K apoamicyanin with copper resulted in precipitation of the protein. The fact that the M98K mutation generated such a selective zinc-binding protein was surprising as ligation of zinc by Lys is rare and this ligand set is unique for zinc.     

Cassette mutagenesis of Met121 in azurin from Pseudomonas aeruginosa.

Cassette mutagenesis was used to exchange the suggested copper ligand Met121 in azurin to all other amino acids, and a stop codon. The mutant proteins were characterized by optical absorption spectroscopy and EPR. At low pH, all mutants exhibit the characteristics of a blue type 1 copper protein, indicating that methionine is not needed to create a blue copper site. At high pH, the Glu121 and the Lys121 mutants constitute a new form of protein-bound copper that is outside the range of type 1 copper.     

Both Met(109) and Met(112) are utilized for Cu(II) coordination by the amyloidogenic fragment of the human prion protein at physiological pH

The prion protein is a ubiquitous neuronal membrane protein. Misfolding of the prion protein has been implicated in transmissible spongiform encephalopathies (prion diseases). It has been demonstrated that the human prion protein (PrP) is capable of coordinating at least five Cu^II ions under physiological conditions; four copper binding sites can be found in the octarepeat domain between residues 61 and 91, while another copper binding site can be found in the unstructured “amyloidogenic” domain between residues 91 and 126 PrP(91-126). Herein we expand upon a previous study [J. Shearer, P. Soh, Inorg. Chem. 46 (2007) 710-719] where we demonstrated that the physiologically relevant high affinity Cu^II coordination site within PrP(91-126) is found between residues 106 and 114. It was shown that Cu^II is contained within a square planar (N/O)₃S coordination environment with one His imidazole ligand (H(111)) and one Met thioether ligand (either M(109) or M(112)). The identity of the Met thioether ligand was not identified in that study. In this study we perform a detailed investigation of the Cu^II coordination environment within the PrP fragment containing residues 106-114 (PrP(106-114)) involving optical, X-ray absorption, EPR, and fluorescence spectroscopies in conjunction with electronic structure calculations. By using derivatives of PrP(106-114) with systematic Met → Ile “mutations” we show that the Cu^II coordination environment within PrP(106-114) is actually comprised of a mixture of two major species; one Cu^II(N/O)₃S center with the M(109) thioether coordinated to Cu^II and another Cu^II(N/O)₃S center with the M(112) thioether coordinated to Cu^II. Furthermore, deletion of one or more Met residues from the primary sequence of PrP(106-114) both reduces the Cu^II affinity of the peptide by two to seven fold, and renders the resulting Cu^II metallopeptides redox inactive. The biological implications of these findings are discussed.     

Influence of loop shortening on the metal binding site of cupredoxin pseudoazurin

Atomic resolution structures of the pseudoazurin (PAZ) variant into which the shorter ligand-containing loop of amicyanin (AMI) is introduced have been determined. The mutated loop adopts a different conformation in PAZAMI than in AMI. The copper site structure is affected, with the major influence being an increased axial interaction resulting in the shortest Cu(II)-S(Met) bond observed for the cupredoxin family of electron-transfer proteins. This is accompanied by a lengthening of the important Cu-S(Cys) bond and enhanced tetragonal distortion, consistent with the influence of the PAZAMI loop contraction on the UV/vis spectrum. The change in active site geometry is the major cause of the 50 mV decrease in reduction potential. The copper site structure changes very little upon reduction, consistent with the distorted site still possessing the properties required to facilitate rapid electron transfer. The exposed His ligand on the loop protonates in the reduced protein and reasons for the increased pKa compared to that of PAZ are discussed. The area surrounding the His ligand is more hydrophobic in PAZAMI than in PAZ, while electron self-exchange, which involves homodimer formation via this surface patch, is decreased. The nature of the side chains in this region, as dictated by the sequence of the ligand-containing loop, is a more significant factor than hydrophobicity for facilitating transient protein interactions in PAZ. The structure of PAZAMI demonstrates the importance of loop-scaffold interactions for metal sites in proteins.     

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.     

Circular Thin-layer Chromatography of Oligosaccharides

The physicochemical properties and chemical constituents of the blue protein from rice bran were investigated. The blue protein was a copper-containing glycoprotein, the molecular weight of which was found to be 18,300 Daltons by the sedimentation equilibrium method assuming the partial specific volume 0.72 cm³ g^?1. The hexose and pentose contents were 5.49 and 4.01 g per 100 g protein respectively. The copper content was 0.38% which corresponded to 1.09 atoms per one molecule of the protein. The electron spin resonance spectrum showed that the copper was in a cupric state. The standard oxidation-reduction potential of the copper was found to be +275 mV at 20°C and at pH 7.39. The visible and near infrared absorption maxima were found at 450, 600 and 890 mμ, and the 450 mμ band was optically active in the optical rotatory dispersion exhibiting a large Cotton effect.