Electron transfer between azurin and cytochrone c-551 from Pseudomonas aeruginosa

Significance of the Disulfide Bridge in the Structure and Stability of Metalloprotein Azurin

Metalloproteins make up a class of proteins that incorporate metal ions into their structures, enabling them to perform essential functions in biological systems, such as catalysis and electron transport. Azurin is one such metalloprotein with copper cofactor, having a β-barrel structure with exceptional thermal stability. The copper metal ion is coordinated at one end of the β-barrel structure, and there is a disulfide bond at the opposite end. In this study, we explore the effect of this disulfide bond in the high thermal stability of azurin by analyzing both the native S-S bonded and S-S nonbonded (S-S open) forms using temperature replica exchange molecular dynamics (REMD). Similar to experimental observations, we find a 35 K decrease in denaturation temperature for S-S open azurin compared to that of the native holo form (420 K). As observed in the case of native holo azurin, the unfolding process of the S-S open form also started with disruptions of the α-helix. The free energy surfaces of the unfolding process revealed that the denaturation event of the S-S open form progresses through different sets of conformational ensembles. Subsequently, we compared the stabilities of individual β-sheet strands of both the S-S bonded and the S-S nonbonded forms of azurin. Further, we examined the contacts between individual residues for the central structures from the free energy surfaces of the S-S nonbonded form. The microscopic origin of the lowering in the denaturation temperature is further supplemented by thermodynamic analysis.

Role of Metal Cofactor in Enhanced Thermal Stability of Azurin

Metal cofactors are critical centers for different biochemical processes of metalloproteins, and often, this metal coordination renders additional structural stability. In this study, we explore the additional stability conferred by the copper ion on azurin by analyzing both the apo and holo forms using temperature replica exchange molecular dynamics (REMD) data. We find a 14 K decrease in denaturation temperature for apo (406 K) azurin relative to that of holo (420 K), indicating a copper ion-induced additional thermal stability for holo azurin. The unfolding of apo azurin begins with the melting of α-helix and β-sheet V, similar to that of holo form. β-Sheets IV, VII, and VIII are comparatively more stable than other β-strands and melt at higher temperatures. Similar to holo azurin, the strong hydrophobic interactions among the apolar residues in the protein core is the key factor that renders high stability to apo protein as well. We construct free energy surfaces at different temperatures to capture the major conformations along the unfolding basins of the protein. Using contact maps from different basins we show the changes in the interaction between different residues along the unfolding pathway. Furthermore, we compare the Cα root-mean-square fluctuations (Cα-RMSF) and B-factor of all residues of apo and holo forms to understand the flexibility of different regions. The concerted displacement of α-helix and β-sheets V and VI from the protein core is another distinction we observe for apo compared to the holo form, where β-sheet VI was relatively stable.

Molecular Insight into the High Thermal Stability of Metalloprotein Azurin

We investigate the events characterizing the steps of the unfolding pathway of blue copper metalloprotein azurin using replica exchange molecular dynamics (REMD). Our studies show that the unfolding of azurin begins with the melting of α-helix and β-sheets II and V. This is followed by the melting of other β-sheets and the exposure of hydrophobic protein core to the solvent, resulting in disruptions of its tertiary structure. Free energy surfaces constructed at different temperatures portray different basins that signify the stability of different melted structures in the unfolding process. The contact maps at different temperatures reveal that the strong hydrophobic interaction within the core of the protein is the vital force that renders high stability to this protein. Analysis of the individual β-sheets by looking into their amino acid sequence shows that β-sheets with charged side chains on the surface melt fast compared to others. The β-barrel of azurin is able to dynamically rearrange, and it helps the protein to preserve its hydrophobic core, holding back the native topology from melting fast. B-factor analysis shows that residues of β-sheets III, IV, and VII deviate less from their initial structure at the transition temperature.

Microbial-based therapy of cancer: current progress and future prospects

The use of bacteria in the regression of certain forms of cancer has been recognized for more than a century. Much effort, therefore, has been spent over the years in developing wild-type or modified bacterial strains to treat cancer. However, their use at the dose required for therapeutic efficacy has always been associated with toxicity problems and other deleterious effects. Recently, the old idea of using bacteria in the treatment of cancer has attracted considerable interest and new genetically engineered attenuated strains as well as microbial compounds that might have specific anticancer activity without side effects are being evaluated for their ability to act as new anticancer agents. This involves the use of attenuated bacterial strains and expressing foreign genes that encode the ability to convert non-toxic prodrugs to cytotoxic drugs. Novel strategies also include the use of bacterial products such as proteins, enzymes, immunotoxins and secondary metabolites, which specifically target cancer cells and cause tumor regression through growth inhibition, cell cycle arrest or apoptosis induction. In this review we describe the current knowledge and discuss the future directions regarding the use of bacteria or their products, in cancer therapy.

Loop dynamics and ligand binding kinetics in the reaction catalyzed by the Yersinia protein tyrosine phosphatase

The Yersinia protein tyrosine phosphatase (YopH) contains a loop of ten amino acids (the WPD loop) that covers the entrance of the active site of the enzyme during substrate binding. In this work the substrate mimicking competitive inhibitor p-nitrocatechol sulfate (PNC) is used as a probe of the active site. The dynamics of the WPD loop was determined by subjecting an equilibrated system containing YopH, PNC, and YopH bound to PNC to a laser induced temperature jump, and subsequently following the change in equilibrium due to the perturbation. Using this methodology the dynamics associated with substrate binding in YopH have been determined. These results indicate that substrate binding is coupled to the WPD loop motion, and WPD loop dynamics occur in the sub-millisecond time scale. The significance of these dynamic results is interpreted in terms of the catalytic cycle of the enzyme.

Single molecule recognition between cytochrome C 551 and gold-immobilized azurin by force spectroscopy

Recent developments in single molecule force spectroscopy have allowed investigating the interaction between two redox partners, Azurin and Cytochrome C 551. Azurin has been directly chemisorbed on a gold electrode whereas cytochrome c has been linked to the atomic force microscopy tip by means of a heterobifunctional flexible cross-linker. When recording force-distance cycles, molecular recognition events could be observed, displaying unbinding forces of approximately 95 pN for an applied loading rate of 10 nN/s. The specificity of molecular recognition was confirmed by the significant decrease of unbinding probability observed in control block experiments performed adding free azurin solution in the fluid cell. In addition, the complex dissociation kinetics has been here investigated by monitoring the unbinding forces as a function of the loading rate: the thermal off-rate was estimated to be approximately 14 s(-1), much higher than values commonly estimated for complexes more stable than electron transfer complexes. Results here discussed represent the first studies on molecular recognition between two redox partners by atomic force microscopy.

Pseudomonas aeruginosa cytochrome C(551): probing the role of the hydrophobic patch in electron transfer

Cytochrome c(551) from Pseudomonas aeruginosa is a monomeric redox protein of 82 amino-acid residues, involved in dissimilative denitrification as the physiological electron donor of cd(1) nitrite reductase. The distribution of charged residues on the surface of c(551) is very anisotropic: one side is richer in acidic residues whereas the other shows a ring of positive side chains, mainly lysines, located at the border of an hydrophobic patch which surrounds the heme crevice. In order to map in cytochrome c(551) the surface involved in electron transfer, we have introduced specific mutations in three residues belonging to the hydrophobic patch, namely Val23-->Asp, Pro58-->Ala and Ile59-->Glu. The effect of these mutations was analyzed studying both the self-exchange rate and the electron-transfer activity towards P. aeruginosa cd(1) nitrite reductase, the physiological partner and P. aeruginosa azurin, a copper protein often used as a model redox partner in vitro. Our results show that introduction of a negative charge in the hydrophobic patch severely hampers both homonuclear and heteronuclear electron transfer.

In vivo studies disprove an obligatory role of azurin in denitrification in Pseudomonas aeruginosa and show that azu expression is under control of rpoS and ANR

The role of the blue copper protein azurin and cytochrome C551 as the possible electron donors to nitrite reductase in the dissimilatory nitrate reduction pathway in Pseudomonas aeruginosa have been investigated. It was shown by an in vivo approach with mutant strains of P. aeruginosa deficient in one or both of these electron-transfer proteins that cytochrome C551, but not azurin, is functional in this pathway. Expression studies demonstrated the presence of azurin in both aerobic and anaerobic cultures. A sharp increase in azurin expression was observed when cultures were shifted from exponential to stationary phase. The stationary-phase sigma factor, sigma s, was shown to be responsible for this induction. In addition, one of the two promoters transcribing the azu gene was regulated by the anaerobic transcriptional regulator ANR. An azurin-deficient mutant was more sensitive to hydrogen peroxide and paraquat than the wild-type P. aeruginosa. These results suggest a physiological role of azurin in stress situations like those encountered in the transition to the stationary phase.

Electron-transfer properties of Pseudomonas aeruginosa [Lys44, Glu64]azurin

In the hydrophobic patch of azurin from Pseudomonas aeruginosa, an electric dipole was created by changing Met44 into Lys and Met64 into Glu. The effect of this dipole on the electron-transfer properties of azurin was investigated. From a spectroscopic characterization (NMR, EPR and ultraviolet-visible) it was found that both the copper site and the overall structure of the [Lys44, Glu64]azurin were not disturbed by the two mutations. A small perturbation of the active site at high pH, similar to that observed for [Lys44]azurin, occurs in the double mutant. At neutral pH the electron-self-exchange rate constant of the double mutant shows a decrease of three orders of magnitude compared with the wild-type value. The possible reasons for this decrease are discussed. Electron transfer with the proposed physiological redox partners cytochrome c551 and nitrite reductase have been investigated and the data analyzed in the Marcus framework. From this analysis it is confirmed that the hydrophobic patch of azurin is the interaction site with both partners, and that cytochrome c551 uses its hydrophobic patch and nitrite reductase a negatively charged surface area for the electron transfer.

Expression and characterization of Pseudomonas aeruginosa cytochrome c-551 and two site-directed mutants: role of tryptophan 56 in the modulation of redox properties

The gene coding for Pseudomonas aeruginosa cytochrome c-551 was expressed in Pseudomonas putida under aerobic conditions, using two different expression vectors; the more efficient proved to be pNM185, induced by m-toluate. Mature holo-(cytochrome c-551) was produced in high yield by this expression system, and was purified to homogeneity. Comparison of the recombinant wild-type protein with that purified from Ps. aeruginosa showed no differences in structural and functional properties. Trp56, an internal residue in cytochrome c-551, is located at hydrogen-bonding distance from haem propionate-17, together with Arg47. Ionization of propionate-17 was related to the observed pH-dependence of redox potential. The role of Trp56 in determining the redox properties of Ps. aeruginosa cytochrome c-551 was assessed by site-directed mutagenesis, by substitution with Tyr (W56Y) and Phe (W56F). The W56Y mutant is similar to the wild-type cytochrome. On the other hand, the W56F mutant, although similar to the wild-type protein in spectral properties and electron donation to azurin, is characterized by a weakening of the Fe-Met61 bond, as shown in the oxidized protein by the loss of the 695 nm band approx. 2 pH units below the wild-type. Moreover, in W56F, the midpoint potential and its pH-dependence are both different from the wild-type. These results are consistent with the hypothesis that hydrogen-bonding to haem propionate-17 is important in modulation of the redox properties of Ps. aeruginosa cytochrome c-551.

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.

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.

Sequential 1H NMR assignments of iron(II) cytochrome c551 from Pseudomonas aeruginosa

Sequence-specific 1H NMR resonance assignments for all but the C-terminal Lys 82 are reported for iron(II) cytochrome c551 from Pseudomonas aeruginosa at 25 degrees C and pH = 6.8. Spin systems were identified by using TOCSY and DQF-COSY spectra in 2H2O and 1H2O. Sequential assignments were made by using NOESY connectivities between adjacent amide, alpha, and beta protons. Resonances from several amino acids including His 16, Gly 24, Ile 48, and Met 61 experience strong ring-current shifts due to their placement near the heme. All heme protons, including the previously unassigned propionates, have been identified. Preliminary analysis of sequential and medium-range NOEs provides evidence for substantial amounts of helix in the solution structure. Long-range NOEs indicate that the folds in solution and crystal structures are similar. For one aromatic side chain (Tyr 27) that is close to the heme group we found a transition from hindered ring rotation at low temperature to rapid rotation at high temperature.

The structural gene for cytochrome c551 from Pseudomonas aeruginosa. The nucleotide sequence shows a location downstream of the nitrite reductase gene

The gene coding for Pseudomonas aeruginosa cytochrome c551 has been cloned and its nucleotide sequence determined. Cytochrome c551 is expressed as a 104 amino acid pre-protein from which a signal peptide of 22 amino acids is cleaved off during the translocation across the cytoplasmic membrane. The gene is located just downstream of the gene coding for nitrite reductase on the Pseudomonas aeruginosa chromosome, suggesting that these genes form an operon.

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.

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)

The pH dependence of the electron self-exchange rate of azurin from Pseudomonas aeruginosa as studied by 1H-NMR

The electron self-exchange rate of azurin from Pseudomonas aeruginosa has been measured by proton NMR as a function of temperature under various conditions of pH, buffer and ionic strength. The rate does not appear very sensitive to variations in the latter parameters. Qualitative thermodynamic compensation is observed for the entropy and enthalpy of activation, with a compensation temperature of 309 +/- 7 K, and an average exchange rate of 1.3 X 10(6) M-1 s-1. The observed high entropy of activation contributes significantly to the high exchange rate. The data are analyzed by considering an encounter complex in which two azurin molecules associate along their hydrophobic patches. Copper-to-copper electron transfer over a distance of 1.5 nm in the complex is facilitated by the favourable disposition of the His-117 ligands.

1H NMR studies of electron exchange rate of Pseudomonas aeruginosa azurin

T1 values of the His-35 C-2 proton resonance of reduced Pseudomonas aeruginosa azurin were determined at 25 degrees C and pH values 4.5, 7.3, and 9.0 in the presence of different fractional amounts of oxidized azurin. The C-2 proton of His-35 undergoes very rapid spin relaxation in oxidized azurin because of its close proximity to the paramagnetic copper. In the presence of oxidized protein, the T1 values of this proton in reduced azurin depend on the lifetime of the reduced protein. From the T1 data, the electron self-exchange rate constant for azurin was calculated to be 1.4 X 10(4) M-1 X s-1, 4.3 X 10(3) M-1 X s-1, and 6.0 X 10(3) M-1 X s-1 at pH values 4.5, 7.3, and 9, respectively. At pH 7.3, the C-2 proton of His-35 is in slow exchange between the imidazole and imidazolium forms and gives rise to two separate resonances at 9.39 and 8.00 ppm. By using these two resonances, the electron self-exchange rate constants were determined separately for the two species of azurin for which the His-35 residue is in the imidazole or the imidazolium forms; results showed that both species participate in self-exchange of electrons with equal efficiency.

Denitrification and nitrite reduction: Pseudomonas aeruginosa nitrite-reductase

Present knowledge of the different enzymatic steps of the denitrification chains in various bacteria, particularly Paracoccus denitrificans and Pseudomonas aeruginosa has been briefly reviewed. The question whether nitric oxide (NO), nitrous oxide (N2O) and other nitrogen derivatives are obligatory intermediates has been discussed. The second part is an extensive review of the structure and the function of a key enzyme in denitrification, cytochrome c551-nitrite-oxidoreductase from P. aeruginosa. Recent results on the stoichiometry of nitrite reduction have been discussed.

Conformational heterogeneity of the copper binding site in azurin. A time-resolved fluorescence study

Comparison of the fluorescence spectra and the effect of temperature on the quantum yields of fluorescence of Azurin (from Pseudomonas fluorescens ATCC-13525-2) and 3-methylindole (in methylcyclohexane solution) provides substantive evidence that the tryptophan residue in azurin is completely inaccessible to solvent molecules. The quantum yields of azurin (CuII), azurin (CuI), and apoazurin (lambda ex = 291 nm) were 0.052, 0.054, and 0.31, respectively. Other evidence indicates that there is no energy transfer from tyrosine to tryptophan in any of these proteins. The fluorescence decay behavior of each of the azurin samples was found to be invariant with emission wavelength. The fluorescences of azurin (CuII) and azurin (CuI) decay with dual exponential kinetics (tau 1 = 4.80 ns, tau 2 = 0.18 ns) while that of apoazurin obeys single exponential decay kinetics (tau = 4.90). The ratio of pre-exponentials of azurin (CuII), alpha 1/alpha 2, is found to be 0.25, and this ratio increases to 0.36 on reduction to azurin (CuI). The results are interpreted as originating from different interactions of the tryptophan with two conformers of the copper-ligand complex in azurin.

Proton NMR of the histidines of azurin from Alcaligenes faecalis: linkage of histidine-35 with redox kinetics

On the basis of redox kinetic studies, Rosen and Pecht [Rosen, P. & Pecht, I. (1976) Biochemistry 15, 775-786] postulated a slowly attained (approximately equal to 0.1 sec) conformational equilibrium between two forms of reduced azurin from the bacterium Pseudomonas aeruginosa, one form being faster in electron transfer. NMR investigations have shown that at pH 7 there are two forms of reduced azurin exchanging slowly with each other, differing in the presence or absence of a proton on the imidazole side chain of histidine-35. Rosen et al. [Rosen, P., Segal, M. & Pecht, I. (1981) Eur. J. Biochem. 120, 339-344] observed that the azurin from the bacterium Alcaligenes faecalis shows no such slowly attained equilibrium between two forms. Therefore, a 1H NMR study was carried out on this azurin with emphasis on the downfield region. A resonance was found at 7.95 ppm downfield that does not move with pH, is not seen in the oxidized protein, has the same pseudocontact shift in the Co(II) derivative as the C-2 proton of histidine-35 has in the Co(II) derivative of P. aeruginosa azurin, and, in the apoprotein, exhibits a typical protonation shift downfield at pH less than 5. Therefore, this resonance is assigned to the C-2 proton of histidine-35. The crystal structure of P. aeruginosa azurin shows that at pH 7 the imidazole side chain of histidine-35 is in a crevice within the protein, where its ring is adjacent and parallel to that of histidine-47, a copper ligand. The preceding observations combined with others show that the kinetics of some redox reactions involving azurin depend on the position of histidine-35. The implication is that there is a pathway for electron transport to the copper atom involving passage through histidine-35.

The kinetics of electron transfer between pseudomonas aeruginosa cytochrome c-551 and its oxidase

The redox reaction between cytochrome c-551 and its oxidase from the respiratory chain of pseudomonas aeruginosa was studied by rapid-mixing techniques at both pH7 and 9.1. The electron transfer in the direction of cytochrome c-551 reduction, starting with the oxidase in the reduced and CO-bound form, is monophasic, and the governing bimolecular rate constants are 1.3(+/- 0.2) x 10(7) M-1 . s-1 at pH 9.1 and 4 (+/- 1) x 10(6) M-1 . s-1 at pH 7.0. In the opposite direction, i.e. mixing the oxidized oxidase with the reduced cytochrome c-551 in the absence of O2, both a lower absorbance change and a more complex kinetic pattern were observed. With oxidized azurin instead of oxidized cytochrome c-551 the oxidation of the c haem in the CO-bound oxidase is also monophasic, and the second-order rate constant is 2 (+/- 0.7) x 10(6) M-1 . s-1 at pH 9.1. The redox potential of the c haem in the oxidase, as obtained from kinetic titrations of the completely oxidized enzyme with reduced azurin as the variable substrate, is 288 mV at pH 7.0 and 255 mV at pH 9.1. This is in contrast with the very high affinity observed in similar titrations performed with both oxidized azurin and oxidized cytochrome c-551 starting from the CO derivative of the reduced oxidase. It is concluded that: (i) azurin and cytochrome c-551 are not equally efficient in vitro as reducing substrates of the oxidase in the respiratory chain of Pseudomonas aeruginosa; (ii) CO ligation to the d1 haem in the oxidase induces a large decrease (at least 80 mV) in the redox potential of the c-haem moiety.

Electron transfer between azurin from Alcaligenes faecalis and cytochrome c551 from Pseudomonas aeruginosa

The electron transfer equilibrium and kinetics between azurin from Alcaligenes faecalis and cytochrome c551 from Pseudomonas aeruginosa have been studied. The equilibrium constant K = ([Cyt(III)] . [Az(I)])/([Cyt(II)] . [Az(II))]) = 0.5 at 25 degrees C is about seven times smaller than that observed between the cytochrome c551 and the titrations confirmed a 43-mV difference between the mid-point potentials of +266 mV and +309 mV for the Alcaligenes and Pseudomonas azurins respectively. The kinetics of the reaction between Alcaligenes azurin and Pseudomonas cytochrome c551 were investigated by the temperature-jump chemical relaxation method. Only a single relaxation mode was observed throughout the range of concentrations and temperatures examined. Thus, the slow relaxation time observed in the reaction between P. aeruginosa azurin and cytochrome c551 is not observed with the Alcaligenes azurin. The simplest mechanism that can therefore be ascribed to the investigated system is: [formula: see text]. This scheme is similar to that proposed earlier for the reaction between P. aeruginosa azurin and cytochrome c551 but does not involve the conformational transition proposed for azurin. The specific rates for the electron transfer are still fast: 1.8 x 10(6) M-1 . s-1 and 3.0 x 10(6) M-1 . s-1 respectively at 25 degrees C.

Electron transfer between horse heart and Candida krusei cytochromes c in the free and bound states

Electron transfer between horse heart and Candida krusei cytochromes c in the free and phosvitin-bound states was examined by difference spectrum and stopped-flow methods. The difference spectra in the wavelength range of 540-560 nm demonstrated that electrons are exchangeable between the cytochromes c of the two species. The equilibrium constants of the electron transfer reaction for the free and phosvitin-bound forms, estimated from these difference spectra, were close to unity at 20 degrees C in 20 mM Tris-HCl buffer (pH 7.4). The electron transfer rate for free cytochrome c was (2-3).10(4) M-1.s-1 under the same conditions. The transfer rate for the bound form increased with increase in the binding ratio at ratios below half the maximum, and was almost constant at higher ratios up to the maximum. The maximum electron exchange rate was about 2.10(6) M-1.s-1, which is 60-70 times that for the free form at a given concentration of cytochrome c. The activation energy of the reaction for the bound cytochrome c was equal to that for the free form, being about 10 kcal/mol. The dependence of the exchange rate on temperature, cytochrome c concentration and solvent viscosity suggests that enhancement of the electron transfer rate between cytochromes c on binding to phosvitin is due to increase in the collision frequency between cytochromes c concentrated on the phosvitin molecule.

The electron-transfer reaction between azurin and the cytochrome c oxidase from Pseudomonas aeruginosa

A stopped-flow investigation of the electron-transfer reaction between oxidized azurin and reduced Pseudomonas aeruginosa cytochrome c-551 oxidase and between reduced azurin and oxidized Ps. aeruginosa cytochrome c-551 oxidase was performed. Electrons leave and enter the oxidase molecule via its haem c component, with the oxidation and reduction of the haem d1 occurring by internal electron transfer. The reaction mechanism in both directions is complex. In the direction of oxidase oxidation, two phases assigned on the basis of difference spectra to haem c proceed with rate constants of 3.2 X 10(5)M-1-S-1 and 2.0 X 10(4)M-1-S-1, whereas the haem d1 oxidation occurs at 0.35 +/- 0.1S-1. Addition of CO to the reduced enzyme profoundly modifies the rate of haem c oxidation, with the faster process tending towards a rate limit of 200S-1. Reduction of the oxidase was similarly complex, with a fast haem c phase tending to a rate limit of 120S-1, and a slower phase with a second-order rate of 1.5 X 10(4)M-1-S-1; the internal transfer rate in this direction was o.25 +/- 0.1S-1. These results have been applied to a kinetic model originally developed from temperature-jump studies.

Kinetics and equilibria of the electron transfer between azurin and the hexacyanoiron (II/III) couple

The electron transfer reaction between the "blue" single copper protein azurin (from Pseudomonas aeruginosa) and the hexacyanoiron (II/III) couple has been studied. Equilibrium constants for the reduction of azurin were measured spectrophotometrically in the temperature range 5-33 degrees C (K = 1.1 X 10(-2) at 25 degrees C, deltaH degrees = 10.9 kcal/mol, 0.1 M potassium phosphate, pH 7.0, I = 0.22). The enthalpy change was also determined by microcalorimetry and from the analysis of chemical relaxation amplitudes. Following a temperature-jump perturbation of this equilibrium, only a single relaxation was observed. The reciprocal of the relaxation time increased linearly as oxidized azurin was reacted with increasing amounts of ferrocyanide, yet reached saturation when reduced azurin was titrated with ferricyanide. This behavior as well as the analysis of the relaxation amplitudes led to the following scheme for this system: see article. At 25 degrees C the rate constants for the electron transfer were k+3=6.4s-1 and k-3=45s-1, the association constants K1=54 M-1 and K2-1=610 M-1. The activation and overall thermodynamic parameters as well as the individual thermodynamic values for the different steps were combined to construct a self-consistent energy profile for the reaction.

Some spectral and steady-state kinetic properties of Pseudomonas cytochrome oxidase

Some spectra of Pseudomonas cytochrome oxidase are reported, both for comparison with those of other workers and to illustrate the differences between the ascorbate- and dithionite-reduced forms of the enzyme. A spectrum of the reduced enzyme-CO complex, prepared in the absence of added reductants by incubation under CO, is also included. Ultracentrifugation studies yielded a value for the sedimentation coefficient (s20,w) of 7.5S, and an isoelectric point of pH6.9 was determined by isoelectric focusing. Steady-state kinetic constants of the electron donors, quinol, sodium ascorbate, reduced Pseudomonas azurin and Pseudomonas ferrocytochrome c551 were investigated giving Km values of 30mM, 4mM, 49muM and 5.6muM respectively. The two protein substrates were observed to be subject to product inhibition and the Ki for oxidized Pseudomonas azurin was evaluated at 4.9muM. Steady-state kinetics were also used to investigate the effects of the oxidation products of dithionite on the oxidase and nitrite reductase activities of Pseudomonas cytochrome oxidase. These experiments showed that whereas the oxidase activity was inhibited, the nitrite reductase activity was slightly enhanced.

A temperature-jump study of the reaction between azurin and cytochrome c oxidase from Pseudomonas aeruginosa

The electron-transfer reaction between azurin and the cytochrome oxidase from Pseudomonas aeruginosa was investigated by temperature-jump relaxation in the absence of O2 and in the presence of CO. The results show that: (i) reduced azurin exists in two forms in equilibrium, only one of which is capable of exchanging electrons with the Pseudomonas cytochrome oxidase, in agreement with M. T. Wilson, C. Greenwood, M. Brunori & E. Antonini (1975) (Biochem. J. 145, 449-457); (ii) the electron transfer between azurin and Pseudomonas cytochrome oxidase occurs within a molecular complex of the two proteins; this internal transfer becomes rate-limiting at high reagent concentrations.