Expression, purification, characterization, and solution nuclear magnetic resonance study of highly deuterated yeast cytochrome C peroxidase with enhanced solubility.

Here we present the preparation, biophysical characterization, and nuclear magnetic resonance (NMR) spectroscopy study of yeast cytochrome c peroxidase (CcP) constructs with enhanced solubility. Using a high-yield Escherichia coli expression system, we routinely produced uniformly labeled [(2)H,(13)C,(15)N]CcP samples with high levels of deuterium incorporation (96-99%) and good yields (30-60 mg of pure protein from 1 L of bacterial culture). In addition to simplifying the purification procedure, introduction of a His tag at either protein terminus dramatically increases its solubility, allowing preparation of concentrated, stable CcP samples required for multidimensional NMR spectroscopy. Using a range of biophysical techniques and X-ray crystallography, we demonstrate that the engineered His tags neither perturb the structure of the enzyme nor alter the heme environment or its reactivity toward known ligands. The His-tagged CcP constructs remain catalytically active yet exhibit differences in the interaction with cytochrome c, the physiological binding partner, most likely because of steric occlusion of the high-affinity binding site by the C-terminal His tag. We show that protein perdeuteration greatly increases the quality of the double- and triple-resonance NMR spectra, allowing nearly complete backbone resonance assignments and subsequent study of the CcP by heteronuclear NMR spectroscopy.

Investigation of the electron transport chain to and the catalytic activity of the diheme cytochrome c peroxidase CcpA of Shewanella oneidensis.

Bacterial diheme c-type cytochrome peroxidases (BCCPs) catalyze the periplasmic reduction of hydrogen peroxide to water. The gammaproteobacterium Shewanella oneidensis produces the peroxidase CcpA under a number of anaerobic conditions, including dissimilatory iron-reducing conditions. We wanted to understand the function of this protein in the organism and its putative connection to the electron transport chain to ferric iron. CcpA was isolated and tested for peroxidase activity, and its structural conformation was analyzed by X-ray crystallography. CcpA exhibited in vitro peroxidase activity and had a structure typical of diheme peroxidases. It was produced in almost equal amounts under anaerobic and microaerophilic conditions. With 50 mM ferric citrate and 50 µM oxygen in the growth medium, CcpA expression results in a strong selective advantage for the cell, which was detected in competitive growth experiments with wild-type and ΔccpA mutant cells that lack the entire ccpA gene due to a markerless deletion. We were unable to reduce CcpA directly with CymA, MtrA, or FccA, which are known key players in the chain of electron transport to ferric iron and fumarate but identified the small monoheme ScyA as a mediator of electron transport between CymA and BCCP. To our knowledge, this is the first detailed description of a complete chain of electron transport to a periplasmic c-type cytochrome peroxidase. This study furthermore reports the possibility of establishing a specific electron transport chain using c-type cytochromes.

Reaction of N-hydroxyguanidine with the ferrous-oxy state of a heme peroxidase cavity mutant: a model for the reactions of nitric oxide synthase.

Yeast cytochrome c peroxidase was used to construct a model for the reactions catalyzed by the second cycle of nitric oxide synthase. The R48A/W191F mutant introduced a binding site for N-hydroxyguanidine near the distal heme face and removed the redox active Trp-191 radical site. Both the R48A and R48A/W191F mutants catalyzed the H2O2 dependent conversion of N-hydroxyguanidine to N-nitrosoguanidine. It is proposed that these reactions proceed by direct one-electron oxidation of NHG by the Fe(+4)O center of either Compound I (Fe(+4)=O, porph+(.)) or Compound ES (Fe(+4)=O, Trp+(.)). R48A/W191F formed a Fe(+2)O2 complex upon photolysis of Fe(+2)CO in the presence of O2, and N-hydroxyguanidine was observed to react with this species to produce products, distinct from N-nitrosoguanidine, that gave a positive Griess reaction for nitrate+nitrite, a positive Berthelot reaction for urea, and no evidence for formation of NO(.). It is proposed that HNO and urea are produced in analogy with reactions of nitric oxide synthase in the pterin-free state.

Characterization of a covalently linked yeast cytochrome c-cytochrome c peroxidase complex: evidence for a single, catalytically active cytochrome c binding site on cytochrome c peroxidase.

A covalent complex between recombinant yeast iso-1-cytochrome c and recombinant yeast cytochrome c peroxidase (rCcP), in which the crystallographically defined cytochrome c binding site [Pelletier, H., and Kraut, J. (1992) Science 258, 1748-1755] is blocked, was synthesized via disulfide bond formation using specifically engineered cysteine residues in both yeast iso-1-cytochrome c and yeast cytochrome c peroxidase [Papa, H. S., and Poulos, T. L. (1995) Biochemistry 34, 6573-6580]. Previous studies on similar covalent complexes, those that block the Pelletier-Kraut crystallographic site, have demonstrated that samples of the covalent complexes have detectable activities that are significantly lower than those of wild-type yCcP, usually in the range of approximately 1-7% of that of the wild-type enzyme. Using gradient elution procedures in the purification of the engineered peroxidase, cytochrome c, and covalent complex, along with activity measurements during the purification steps, we demonstrate that the residual activity associated with the purified covalent complex is due to unreacted CcP that copurifies with the covalent complex. Within experimental error, the covalent complex that blocks the Pelletier-Kraut site has zero catalytic activity in the steady-state oxidation of exogenous yeast iso-1-ferrocytochrome c by hydrogen peroxide, demonstrating that only ferrocytochrome c bound at the Pelletier-Kraut site is oxidized during catalytic turnover.

Ca2+ and the bacterial peroxidases: the cytochrome c peroxidase from Pseudomonas stutzeri.

The production of cytochrome c peroxidase (CCP) from Pseudomonas ( Ps.) stutzeri (ATCC 11607) was optimized by adjusting the composition of the growth medium and aeration of the culture. The protein was isolated and characterized biochemically and spectroscopically in the oxidized and mixed valence forms. The activity of Ps. stutzeri CCP was studied using two different ferrocytochromes as electron donors: Ps. stutzeri cytochrome c(551) (the physiological electron donor) and horse heart cytochrome c. These electron donors interact differently with Ps. stutzeri CCP, exhibiting different ionic strength dependence. The CCP from Paracoccus ( Pa.) denitrificans was proposed to have two different Ca(2+) binding sites: one usually occupied (site I) and the other either empty or partially occupied in the oxidized enzyme (site II). The Ps. stutzeri enzyme was purified in a form with tightly bound Ca(2+). The affinity for Ca(2+) in the mixed valence enzyme is so high that Ca(2+) returns to it from the EGTA which was added to empty the site in the oxidized enzyme. Molecular mass determination by ultracentrifugation and behavior on gel filtration chromatography have revealed that this CCP is isolated as an active dimer, in contrast to the Pa. denitrificans CCP which requires added Ca(2+) for formation of the dimer and also for activation of the enzyme. This is consistent with the proposal that Ca(2+) in the bacterial peroxidases influences the monomer/dimer equilibrium and the transition to the active form of the enzyme. Additional Ca(2+)does affect both the kinetics of oxidation of horse heart cytochrome c (but not cytochrome c(551)) and higher aggregation states of the enzyme. This suggests the presence of a superficial Ca(2+)binding site of low affinity.

Cloning, overproduction and characterization of cytochrome c peroxidase from the purple phototrophic bacterium Rhodobacter capsulatus.

The bacterial cytochrome c peroxidase (BCCP) from Rhodobacter capsulatus was purified as a recombinant protein from an Escherichia coli clone over-expressing the BCCP structural gene. BCCP from Rb. capsulatus oxidizes the Rhodobacter cytochrome c2 and reduces hydrogen peroxide, probably functioning as a detoxification mechanism. The enzyme binds two haem c groups covalently. The gene encoding BCCP from Rb. capsulatus was cloned through the construction of a 7-kb subgenomic clone. In comparison with the protein sequence, the sequence deduced from the gene has a 21-amino-acid N-terminal extension with the characteristics of a signal peptide. The purified recombinant enzyme showed the same physico-chemical properties as the native enzyme. Spectrophotometric titration established the presence of a high-potential (Em=+270 mV) and a low-potential haem (between -190 mV and -310 mV) as found in other BCCPs. The enzyme was isolated in the fully oxidized but inactive form. It binds calcium tightly and EGTA treatment of the enzyme was necessary to show calcium activation of the mixed valence enzyme. This activation is associated with the formation of a high-spin state at the low-potential haem. BCCP oxidizes horse ferrocytochrome c better than the native electron donor, cytochrome c2; the catalytic activities ('turnover number') are 85 800 min(-1) and 63 600 min(-1), respectively. These activities are the highest ever found for a BCCP.

Expression, purification, characterization, and NMR studies of highly deuterated recombinant cytochrome c peroxidase.

Two forms of extensively deuterated S. cerevisiae cytochrome c peroxidase (CcP; EC 1.11.1.5) have been overexpressed in E. coli by growth in highly deuterated medium. One of these ferriheme enzyme forms (recDCcP) was produced using >97% deuterated growth medium and was determined to be approximately 84% deuterated. The second form [recD(His)CcP] was grown in the same highly deuterated medium that had been supplemented with excess histidine (at natural hydrogen isotope abundance) and was also approximately 84% deuterated. This resulted in direct histidine incorporation without isotope scrambling. Both of these enzymes along with the corresponding recombinant native CcP (recNATCcP), which was expressed in a standard medium with normal hydrogen isotope abundance, consisted of 294 amino acid polypeptide chains having the identical sequence to the yeast-isolated enzyme, without any N-terminal modifications. Comparative characterizations of all three enzymes have been carried out for the resting-state, high-spin forms and in the cyanide-ligated, low-spin forms. The primary physical methods employed were electrophoresis, UV-visible spectroscopy, hydrogen peroxide reaction kinetics, mass spectrometry, and (1)H NMR spectroscopy. The results indicate that high-level deuteration does not significantly alter CcP's reactivity or spectroscopy. As an example of potential NMR uses, recDCcPCN and recD(His)CcPCN have been used to achieve complete, unambiguous, stereospecific (1)H resonance assignments for the heme hyperfine-shifted protons, which also allows the heme side chain conformations to be assessed. Assigning these important active-site protons has been an elusive goal since the first NMR spectra on this enzyme were reported 18 years ago, due to a combination of the enzyme's comparatively large size, paramagnetism, and limited thermal stability.

Yeast cytochrome c peroxidase expression in Escherichia coli and rapid isolation of various highly pure holoenzymes.

A more efficient 2-day isolation and purification method for recombinant yeast cytochrome c peroxidase produced in Escherichia coli is presented. Two types of recombinant "wild-type" CcP have been produced and characterized, the recombinant nuclear gene sequence and the 294-amino-acid original protein sequence. These two sequences constitute the majority of the recombinant "native" or wild-type CcP currently in production and from which all recombinant variants now derive. The enzymes have been subjected to extensive physical characterizations, including sequencing, UV-visible spectroscopy, HPLC, gel electrophoresis, kinetic measurements, NMR spectroscopy, and mass spectrometry. Less extensive characterization data are also presented for recombinant, perdeuterated CcP, an enzyme produced in >95% deuterated medium. All of these results indicate that the purified recombinant wild-type enzymes are functionally and spectroscopically identical to the native, yeast-isolated wild-type enzyme. This improved method uses standard chromatography to produce highly purified holoenzyme in a more efficient manner than previously achieved. Two methods for assembling the holoenzyme are described. In one, exogenous heme is added at lysis, while in the other heme biosynthesis is stimulated in E. coli. A primary reason for developing this method has been the need to minimize loss of precious, isotope-labeled enzyme and, so, this method has also been used to produce both the perdeuterated and the (15)N-labeled enzyme, as well as several variants.

A cytochrome c peroxidase from Pseudomonas nautica 617 active at high ionic strength: expression, purification and characterization.

Cytochrome c peroxidase was expressed in cells of Pseudomonas nautica strain 617 grown under microaerophilic conditions. The 36.5 kDa dihaemic enzyme was purified to electrophoretic homogeneity in three chromatographic steps. N-terminal sequence comparison showed that the Ps. nautica enzyme exhibits a high similarity with the corresponding proteins from Paracoccus denitrificans and Pseudomonas aeruginosa. UV-visible spectra confirm calcium activation of the enzyme through spin state transition of the peroxidatic haem. Monohaemic cytochrome c(552) from Ps. nautica was identified as the physiological electron donor, with a half-saturating concentration of 122 microM and allowing a maximal catalytic centre activity of 116,000 min(-1). Using this cytochrome the enzyme retained the same activity even at high ionic strength. There are indications that the interactions between the two redox partners are mainly hydrophobic in nature.

Characterization of cytochrome c-556 from the purple phototrophic bacterium Rhodobacter capsulatus as a cytochrome-c peroxidase.

A cytochrome c-556 was purified from Rhodobacter capsulatus and the complete amino acid sequence was determined. It contains 328 amino acid residues and two typical heme-binding sites at cysteine residues 54 and 57 and at residues 200 and 203. It is homologous to the family of bacterial cytochrome c peroxidases (BCCP) with 69% identity to Paracoccus denitrificans BCCP and 60% identity to Pseudomonas aeruginosa BCCP for which there is a three-dimensional structure. There is lesser similarity to the mauG gene products from methylotrophic bacteria which are thought to be involved in biosynthesis of the quinone cofactor of methylamine dehydrogenase. Translated genes from Escherichia coli and Helicobacter pylori are also related to the bacterial cytochrome c peroxidases. The divergence of this family of proteins is reflected in the fact that the reported sixth heme ligands are not conserved, except in Pseudomonas, Rhodobacter and Paracoccus. This suggests that homologs of BCCP may fold differently and/or may not have the same enzymatic activity as the prototypic protein from Ps. aeruginosa. We found that the Rb. capsulatus BCCP is active with both Rb. capsulatus cytochrome c2 and with horse cytochrome c as substrates (Km values 60 microm and 6 microm, respectively). The turnover number was 40 s(-1) and the Km for peroxide was 33 microm. We have thus confirmed that the Rb. capsulatus protein is a cytochrome c peroxidase.

Cytochrome c peroxidase from a methylotrophic yeast: physiological role and isolation.

Mutant strains of the methylotrophic yeast Hansenula polymorpha defective in catalase (cat) and in glucose repression of alcohol oxidase synthesis (gcr1) have been isolated following multiple UV mutagenesis steps. One representative gcr1 cat mutant C-105 grows during batch cultivation in a glucose/methanol medium. However, growth is preceded by a prolonged lag period. C-105 and other gcr1 cat mutants do not grow on methanol medium without an alternative carbon source. A large collection of second-site suppressor catalase-defective (scd) revertants were isolated with restored ability for methylotrophic growth (Mth+) in the absence of catalase activity. These Mth+ gcr1 cat scd strains utilize methanol as a sole source of carbon and energy, although biomass yields are reduced relative to the wild-type strain. In contrast to the parental C-105 strain, H2O2 does not accumulate in the methanol medium of the revertants. We show that restoration of methylotrophic growth in the suppressor strains is strongly correlated with increased levels of the alternative H2O2-destroying enzyme, cytochrome c peroxidase. Cytochrome c peroxidase from cell-free extracts of one of the scd revertants has been purified to homogeneity and crystallized.

Cytochrome c peroxidase from Methylococcus capsulatus Bath.

A bacterial cytochrome c peroxidase was purified from the obligate methanotroph Methylococcus capsulatus Bath in either the fully oxidized or the half reduced form depending on the purification procedure. The cytochrome was a homo-dimer with a subunit mol mass of 35.8 kDa and an isoelectric point of 4.5. At physiological temperatures, the enzyme contained one high-spin, low-potential (Em7 = -254 mV) and one low-spin, high-potential (Em7 = +432 mM ) heme. The low-potential heme center exhibited a spin-state transition from the penta-coordinated, high-spin configuration to a low-spin configuration upon cooling the enzyme to cryogenic temperatures. Using M. capsulatus Bath ferrocytochrome c555 as the electron donor, the KM and Vmax for peroxide reduction were 510 +/- 100 nM and 425 +/- 22 mol ferrocytochrome c555 oxidized min-1 (mole cytochrome c peroxidase)-1, respectively.

A single histidine is required for activity of cytochrome c peroxidase from Paracoccus denitrificans.

The diheme cytochrome c peroxidase from Paracoccus denitrificans was modified with the histidine-specific reagent diethyl pyrocarbonate. At low excess of reagent, 1 mol of histidine was modified in the oxidized enzyme, and modification was associated with loss of the ability to form the active state. With time, the modification reversed, and the ability to form the active state was recovered. The agreement between the spectrophotometric measurement of histidine modification and radioactive incorporation using a radiolabeled reagent indicated little modification of other amino acids. However, the reversal of histidine modification observed spectrophotometrically was not matched by loss of radioactivity, and we propose a slow transfer of the ethoxyformyl group to an unidentified amino acid. The presence of CN- bound to the active peroxidatic site of the enzyme led to complete protection of the essential histidine from modification. Limited subtilisin treatment of the native enzyme followed by tryptic digest of the C-terminal fragment (residues 251-338) showed that radioactivity was located in a peptide containing a single histidine at position 275. We propose that this conserved residue, in a highly conserved region, is central to the function of the active mixed-valence state.

Crystallization and preliminary crystallographic analysis of cytochrome c553 peroxidase from Nitrosomonas europaea.

The di-heme peroxidase (cytochrome c553 peroxidase) from Nitrosomonas europaea has been crystallized in a form suitable for high-resolution X-ray structure determination. A complete data set was obtained to 2.5A and the data were indexed in space group P2(1) with a = 88.79 A, b = 55.93 A, c = 144.37 A, beta = 103.87 degrees. The self-rotation function indicates one homodimer per asymmetric unit.

Altering substrate specificity at the heme edge of cytochrome c peroxidase.

Two mutants of cytochrome c peroxidase (CCP) are reported which exhibit unique specificities toward oxidation of small substrates. Ala-147 in CCP is located near the delta-meso edge of the heme and along the solvent access channel through which H2O2 is thought to approach the active site. This residue was replaced with Met and Tyr to investigate the hypothesis that small molecule substrates are oxidized at the exposed delta-meso edge of the heme. X-ray crystallographic analyses confirm that the side chains of A147M and A147Y are positioned over the delta-meso heme position and might therefore modify small molecule access to the oxidized heme cofactor. Steady-state kinetic measurements show that cytochrome c oxidation is enhanced 3-fold for A147Y relative to wild type, while small molecule oxidation is altered to varying degrees depending on the substrate and mutant. For example, oxidation of phenols by A147Y is reduced to less than 20% relative to the wild-type enzyme, while Vmax/e for oxidation of other small molecules is less affected by either mutation. However, the "specificity" of aniline oxidation by A147M, i.e., (Vmax/e)/Km, is 43-fold higher than in wild-type enzyme, suggesting that a specific interaction for aniline has been introduced by the mutation. Stopped-flow kinetic data show that the restricted heme access in A147Y or A147M slows the reaction between the enzyme and H202, but not to an extent that it becomes rate limiting for the oxidation of the substrates examined. The rate constant for compound ES formation with A147Y is 2.5 times slower than wild-type CCP. These observations strongly support the suggestion that small molecule oxidations occur at sites on the enzyme distinct from those utilized by cytochrome c and that the specificity of small molecule oxidation can be significantly modulated by manipulating access to the heme edge. The results help to define the role of alternative electron transfer pathways in cytochrome c peroxidase and may have useful applications in improving the specificity of peroxidase with engineered function.

Circular dichroism studies of the binding of mammalian and non-mammalian cytochromes c to cytochrome c oxidase, cytochrome c peroxidase, and polyanions.

The effects of binding of Candida krusei, Drosophila melanogaster, horse, human, and rat cytochromes c to beef cytochrome c oxidase (ferrocytochrome c: oxygen oxidoreductase, EC 1.9.3.1) and yeast cytochrome c peroxidase (ferricytochrome c: hydrogen-peroxide oxidoreductase, EC 1.11.1.5) on their circular dichroism spectra were determined. The binding to cytochrome oxidase results in a positive increase in the ellipticities of the positive and negative Cotton effects at 404 nm and 417 nm of cytochrome c. The horse, human, and rat cytochromes c display less of an increase in the ellipticity of the positive Cotton effect at 404 nm, but more of a positive change in the negative Cotton effect at 417 nm than the C. krusei or D. melanogaster proteins. Interaction with yeast cytochrome c peroxidase elicits only a positive change in the ellipticity of the positive Cotton effect at 404 nm. No significant change is observed in the negative Cotton effect at 417 nm. Rat cytochrome c variants with a phenylalanine in place of tyrosine-67 and/or an alanine in place of proline-30 all display circular dichroism spectral changes upon binding to cytochrome c oxidase or cytochrome c peroxidase identical to those of the unaltered protein. The increase in ellipticity at 404 nm upon binding occurs even though replacement of tyrosine-67 results in the loss of the positive Cotton effect at this position. Polyglutamate and phosvitin complexes of cytochrome c show changes in the circular dichroism spectrum similar to those observed with cytochrome c peroxidase. However, the magnitudes of the spectral changes were considerably less. A model is proposed in which the main cause of the circular dichroism spectral changes observed upon complexation arise from the exclusion of solvent from the exposed front heme edge. According to this model, the exclusion of solvent changes the relative asymmetry of the environment of the electronic transitions of the heme prosthetic group of cytochrome c, resulting in observed circular dichroic effects.

A di-heme cytochrome c peroxidase from Nitrosomonas europaea catalytically active in both the oxidized and half-reduced states.

A di-c-heme containing cytochrome (cytochrome c553 peroxidase) has been isolated from the chemoautotrophic bacterium Nitrosomonas europaea. Sequence analysis of the N terminus and the two heme-containing peptides generated by digestion of the enzyme with trypsin show 40% homology overall to sequences reported for the di-heme peroxidase from Pseudomonas aeruginosa (Rönnberg, M., Kalkkinen, N., and Ellfolk, N. (1989) FEBS Lett. 250, 175-178). At room temperature and pH 7.0, one heme is low spin with Em7 = +450 mV and the other is high spin with Em7 = -260 mV. EPR spectra show a mixture of high spin and low spin signals at cryogenic temperatures. Anionic ligands (CN-, N3-, F-, CNO-) bind so as to perturb the high spin heme when cytochrome c553 peroxidase is either fully oxidized (FeLS3+:FeHS3+) or half-reduced (FeLS2+:FeHS3+). The EPR signal of the high potential, low spin heme in fully oxidized enzyme is unperturbed by the presence of the ligands. Furthermore, each ligand results in similar characteristic EPR signals for either oxidation state of the peroxidase. Both the fully oxidized and half-reduced oxidation states of cytochrome c553 peroxidase are catalytically active as evidenced by the enzyme's ability to oxidize horse heart cytochrome c in the presence of H2O2, as well as by optical changes associated with the addition of H2O2 to the peroxidase. In the presence of stoichiometric amounts of H2O2, the half-reduced enzyme is rapidly oxidized and the fully oxidized enzyme shows a significant decrease in absorbance in the Soret region of the optical spectrum coupled with a lesser increase near 600-650 nm. These latter optical changes are similar to what is observed in the formation of a porphyrin cation radical. This suggests that this di-heme peroxidase may form a compound I intermediate analogous to that formed by horseradish peroxidase.

Derivatization of yeast cytochrome c peroxidase with pentaammineruthenium(III).

Cytochrome c peroxidase (CCP) was derivatized using aquopentaammineruthenium(II) [a5RuIIH2O] resulting in stable, covalently-linked derivatives that were purified by cation-exchange FPLC. Spectrophotometric determination of a5RuHis:heme ratios allowed identification of two derivatives containing one a5RuHis per CCP molecule. The histidine-specific reagent, diethyl pyrocarbonate (DEPC), which reacted with three histidine residues in native CCP (6, 60, 96) at pH 7, reacted with only two histidines in both a5RuHisCCP species. X-ray crystallography showed that a5Ru is coordinated to His60 in one derivative [Fox et al. (1990) J. Am. Chem. Soc. 112, 7426]; HPLC and mass spectral analysis of the tryptic peptides of the other derivative identified a peptide (MW = 1469 Da) corresponding to residues 1-12 of CCP plus a5Ru, indicating His6 as the site of modification. Mass spectral analysis of native CCP, a5RuHis60CCP, and the a5RuHis6 derivative yielded MWs of 33,536, 33,717, and 33,901 Da, respectively, revealing that a second site is ruthenated in the His6 derivative. Mass spectral analysis of a shoulder separated from the a5RuHis60CCP FPLC peak also indicated the presence of CCP with bound a5Ru (MW = 33,718 Da). Differential pulse voltammetry of this shoulder, which has negligible a5RuHis absorption, gave a peak at -68 mV (vs NHE) which is in the range expected for reduction of a5RuIII (carboxylato) complexes, as well as a peak at 42 mV due to the presence of approximately 20% a5RuHis60CCP. The extent of ruthenation at sites other than histidine was unexpected and illustrates that a5RuIIH2O is less specific for histidine than previously thought. Activity measurements and stability of enzyme intermediates were measured to further characterize the a5RuCCP species and showed that the derivatives have similar properties to native CCP.

Enhanced oxidation of aniline derivatives by two mutants of cytochrome c peroxidase at tryptophan 51.

Two hyperactive mutants of cytochrome c peroxidase (CCP), W51F and W51A, catalyze the enhanced oxidation of a number of substituted anilines. The reaction of CCP compound ES with mesidine is biphasic, while similar reactions using compound II give monophasic kinetics. These data, in addition to the ratio of the Fe4+ = O and free-radical species observed during steady-state turnover, indicate that reduction of the Trp-191 free radical of compound ES is more rapid than the reduction of the Fe4+ = O species. Transient kinetics were examined for the oxidation of eight mono-substituted anilines by CCP, W51F, and W51A. Each of the aniline derivatives were oxidized by the mutants at rates that exceeded that of the wild-type enzyme, and the rate constant for m-chloroaniline was 400-fold faster for W51F than for wild-type CCP. Variations in the rate constants for the different substrates follow a linear free-energy relationship using the Hammet substituent effect parameter sigma +, implicating electron transfer from the aniline ring in the transition state. For aniline oxidation, the free energy of activation is 3 kcal/mol lower for the mutants than for wild-type CCP, and this is due primarily to an increase in the activation entropy. These results indicate that the enhanced kinetics of W51F and W51A result from a generalized increase in enzyme reactivity characterized by an exo-entropic transition state such as dissociation of bound H2O from the Fe4+ = O center.

Preparation and kinetic studies of immobilised yeast cytochrome c peroxidase.

Yeast cytochrome c peroxidase (CcP) was purified from baker's yeast and immobilised onto a nylon membrane. The kinetics of the soluble and immobilised forms of the enzyme were investigated for the catalysed oxidation of potassium ferrocyanide in the presence of H2O2 and m-chloroperoxybenzoic acid. The pH dependence of the two forms of the enzyme differed. Although both the soluble and the immobilised enzymes showed optimal activity at pH 6.2, a different kinetic behaviour was demonstrated. Both forms of the enzyme showed similar activity toward H2O2, although when m-chloroperoxybenzoic acid was replaced as the electron acceptor, the immobilised form of the enzyme had a reduced turnover number and an increased Km. The activation energy of immobilised CcP was greater in the presence of both H2O2 [16.6 kJ mol-1] and m-chloroperoxybenzoic acid [37.9 kJ mol-1] than for soluble CcP [11.4 and 23.4 kJ mol-1, respectively]. The activities of both soluble and immobilised CcP were greatly reduced above 45 degrees C, although at higher temperatures the immobilised enzyme retained a relatively greater percentage of its maximum activity.