Complex-formation between cytochrome c and cytochrome c peroxidase. Kinetic studies

1. The kinetics of ferrocytochrome c peroxidation by yeast peroxidase are described. Kinetic differences between the older and more recent preparations of the enzyme most probably arise from differences in intrinsic turnover rates. 2. The time-courses of cytochrome c peroxidation by the enzyme follow essentially first-order kinetics in phosphate buffer. Deviations from first-order kinetics occur in acetate buffer, and are due to a higher enzymic turnover rate in this medium accompanied by a greater tendency to autocatalytic peroxidation of cytochrome c. 3. The kinetics of ferrocytochrome c peroxidation by yeast peroxidase are interpreted in terms of a mechanism postulating formation of reversible complexes between the peroxidase and both reduced and oxidized cytochrome c. Formation of these complexes is inhibited at high ionic strengths and by polycations. 4. Oxidized cytochrome c can act as a competitive inhibitor of ferrocytochrome c peroxidation by peroxidase. The K(i) for ferricytochrome c is approximately equal to the K(m) for ferrocytochrome c and thus probably accounts for the observed apparent first-order kinetics even at saturating concentrations of ferrocytochrome c. 5. The results are discussed in terms of a possible analogy between the oxidations of cytochrome c catalysed by yeast peroxidase and by mammalian cytochrome oxidase.     

pH titration study of cytochrome c peroxidase and apocytochrome c peroxidase.

A pH titration study of cytochrome c peroxidase and apocytochrome c peroxidase was carried out at 25 degrees C and 0.1 M ionic strength. The net charge on cytochrome c peroxidase due to proton association and dissociation varies from +32 at pH 2 to --50.2 at pH 12, while that of apocytochrome c peroxidase varies between +24.5 at pH 3 to --48 at pH 12. The apoprotein tented to aggregate below pH 3. Between pH 4 and 8, the titration behavior of both the native enzyme and the apoenzyme are consistent with the semi-empirical Linderstr?m-Lang theory. Between pH 9 and 12, the titration behavior of both the holo- and apoproteins suggest they assume a more extended conformation which reduces the electrostatic interaction charged groups on the surface. In the acid region, between pH 4 and 3, a similar transition occurs in which the protein expands 40% based on the electrostatic factor of the Linderstr?m-Lang theory.     

The reaction between reduced azurin and oxidized cytochrome c peroxidase from Pseudomonas aeruginosa

The reaction between ferric Pseudomonas cytochrome c peroxidase and reduced azurin was investigated by static titration, rapid scan, and stopped flow techniques as well as circular dichroism measurements. Kinetics of the reduction of the enzyme under pseudo-first order conditions reveals a biphasic logarithmic curve indicating that the reaction between enzyme and azurin is complex and comprises of two reactions, one rapid and a slower one. The relative portion of the fast phase from the overall reaction increases with increasing azurin concentration. Kinetic results can be explained by postulating the presence of two different enzyme forms which are slowly interconvertible. Both enzymatic forms form a complex with reduced azurin. The electron transfer between proteins occurs within the molecular complex of azurin and the peroxidase.     

Proton nuclear magnetic resonance characterization of the oxidized intermediates of cytochrome c peroxidase

Oxidation of cytochrome c peroxidase with hydrogen peroxide to form the initial oxidized intermediate, cytochrome c peroxidase compound I, drastically alters the proton hyperfine nmr spectrum. In contrast to studies of horseradish peroxidase, where the spectrum of horseradish peroxidase compound I is similar to that of the native protein, cytochrome c peroxidase compound I exhibits only broad resonances near 17 and 30 ppm from 2,2-dimethyl-2-silapentane-5-sulfonate. No unique resonances attributable to cytochrome c peroxidase compound II could be identified. These results define the molecular conditions for which resolved hyperfine resonances of the iron(IV) states of heme proteins may be observed when the data presented here are compared with the data from horseradish peroxidase. Oxidation of cytochrome c peroxidase while it is complexed to ferricytochrome c reveals that the heme resonances of cytochrome c are not influenced by the oxidation state of cytochrome c peroxidase.     

Complex-formation between cytochrome c and cytochrome c peroxidase. Equilibrium and titration studies

1. Physical studies of complex-formation between cytochrome c and yeast peroxidase are consistent with kinetic predictions that these complexes participate in the catalytic activity of yeast peroxidase towards ferrocytochrome c. Enzyme-ferricytochrome c complexes have been detected both by the analytical ultracentrifuge and by column chromatography, whereas an enzyme-ferrocytochrome c complex was demonstrated by column chromatography. Estimated binding constants obtained from chromatographic experiments were similar to the measured kinetic values. 2. The physicochemical study of the enzyme-ferricytochrome c complex, and an analysis of its spectrum and reactivity, suggest that the conformation and reactivity of neither cytochrome c nor yeast peroxidase are grossly modified in the complex. 3. The peroxide compound of yeast cytochrome c peroxidase was found to have two oxidizing equivalents accessible to cytochrome c but only one readily accessible to ferrocyanide. Several types of peroxide compound, differing in available oxidizing equivalents and in reactivity with cytochrome c, seem to be formed by stoicheiometric amounts of hydrogen peroxide. 4. Fluoride combines not only with free yeast peroxidase but also with peroxidase-peroxide and accelerates the decomposition of the latter compound. The ligand-catalysed decomposition provides evidence for one-electron reduction pathways in yeast peroxidase, and the reversible binding of fluoride casts doubt upon the concept that the peroxidase-peroxide intermediate is any form of peroxide complex. 5. A mechanism for cytochrome c oxidation is proposed involving the successive reaction of two reversibly bound molecules of cytochrome c with oxidizing equivalents associated with the enzyme protein.     

Monooxygenase activity of cytochrome c peroxidase.

Recombinant cytochrome c peroxidase (CcP) and a W51A mutant of CcP, in contrast to other classical peroxidases, react with phenylhydrazine to give sigma-bonded phenyl-iron complexes. The conclusion that the heme iron is accessible to substrates is supported by the observation that CcP and W51A CcP oxidize thioanisole to the racemic sulfoxide with quantitative incorporation of oxygen from H2O2. Definitive evidence for an open active site is provided by stereoselective epoxidation by both enzymes of styrene, cis-beta-methylstyrene, and trans-beta-methylstyrene. trans-beta-methylstyrene yields exclusively the trans-epoxide, but styrene yields the epoxide and phenylacetaldehyde, and cis-beta-methylstyrene yields both the cis- and trans-epoxides and 1-phenyl-2-propanone. The sulfoxide, stereoretentive epoxides, and 1-phenyl-2-propanone are formed by ferryl oxygen transfer mechanisms because their oxygen atom derives from H2O2. In contrast, the oxygen in the trans-epoxide from the cis-olefin derives primarily from molecular oxygen and is probably introduced by a protein cooxidation mechanism. cis-[1,2-2H]-1-Phenyl-1-propene is oxidized to [1,1-2H]-1-phenyl-2-propanone without a detectable isotope effect on the epoxide:ketone product ratio. The phenyl-iron complex is not formed and substrate oxidation is not observed when the prosthetic group is replaced by delta-meso-ethylheme. CcP thus has a sufficiently open active site to form a phenyl-iron complex, to oxidize thioanisole to the sulfoxide, and to epoxidize styrene and beta-methylstyrene. The results indicate that a ferryl (Fe(IV) = O)/protein radical pair can be coupled to achieve two-electron oxidations. The unique ability of CcP to catalyze monooxygenation reactions does not conflict with its peroxidase function because cytochrome c is oxidized at a distinct surface site (DePillis, G. D., Sishta, B. P., Mauk, A. G., and Ortiz de Montellano, P. R. (1991) J. Biol. Chem. 266, 19334-19341).     

Two sites of interaction of anions with cytochrome a in oxidized bovine cytochrome c oxidase

An interaction between cytochrome a in oxidized cytochrome c oxidase (CcO) and anions has been characterized by EPR spectroscopy. Those anions that affect the EPR g = 3 signal of cytochrome a can be divided into two groups. One group consists of halides (Cl-, Br-, and I-) and induces an upfield shift of the g = 3 signal. Nitrogen-containing anions (CN-, NO2-, N3-, NO3-) are in the second group and shift the g = 3 signal downfield. The shifts in the EPR spectrum of CcO are unrelated to ligand binding to the binuclear center. The binding properties of one representative from each group, azide and chloride, were characterized in detail. The dependence of the shift on chloride concentration is consistent with a single binding site in the isolated oxidized enzyme with a Kd of approximately 3 mm. In mitochondria, the apparent Kd was found to be about four times larger than that of the isolated enzyme. The data indicate it is the chloride anion that is bound to CcO, and there is a hydrophilic size-selective access channel to this site from the cytosolic side of the mitochondrial membrane. An observed competition between azide and chloride is interpreted by azide binding to three sites: two that are apparent in the x-ray structure plus the chloride-binding site. It is suggested that either Mg2+ or Arg-438/Arg-439 is the chloride-binding site, and a mechanism for the ligand-induced shift of the g = 3 signal is proposed.     

Formation and photolability of low-spin ferrous cytochrome c peroxidase at alkaline pH.

The ferrous form of native cytochrome c peroxidase (CCP) is known to undergo a reversible transition when titrated over the pH range of 7.00-9.70. This transition produces a conversion from a pentacoordinate high-spin to a hexacoordinate low-spin heme active site and is clearly apparent in the heme optical absorption spectra. Here, we report the characterization of this transition and its effect upon the local heme environment using various optical spectroscopies. The formation of hexacoordinate low-spin heme is interpreted to involve the binding of His-52 at the distal site after the perturbation of the extensive H-bonded network within and around the heme pocket of CCP(II) at alkaline pH. Interestingly, CD investigations of CCP(II) in the far-UV and Soret regions indicate the dissappearance of a single high-spin species and the existence of at least two low-spin species of CCP(II) as the pH is raised above 7.90. Furthermore, transient resonance Raman experiments demonstrate that the hexacoordinate low-spin species can be photolyzed within 10-ns laser pulses, producing a species similar to the low-pH (high-spin) form of CCP(II) at alkaline pH. However, the extent of photolysis is quite pH dependent, with a maximum photodissociation yield at pH = 8.50.     

Cocrystals of yeast cytochrome c peroxidase and horse heart cytochrome c

Yeast cytochrome c peroxidase and horse heart cytochrome c have been cocrystallized in a form suitable for x-ray diffraction studies and the structure determined at 3.3 A. The asymmetric unit contains a dimer of the peroxidase which was oriented and positioned in the unit cell using molecular replacement techniques. Similar attempts to locate the cytochrome c molecules were unsuccessful. The peroxidase dimer model was subjected to eight rounds of restrained parameters least squares refinement after which the crystallographic R factor was 0.27 at 3.3 A. Examination of a 2Fo-Fc electron density map showed large "empty" regions between peroxidase dimers with no indication of cytochrome c molecules. Electrophoretic analysis of the crystals demonstrated the presence of the peroxidase and cytochrome c in an approximate equal molar ratio. Therefore, while cytochrome c molecules are present in the unit cell they are orientationally disordered and occupy the space between peroxidase dimers.     

Purification and properties of a cross-linked complex between cytochrome c and cytochrome c peroxidase.

Cytochrome c (horse heart) was covalently linked to yeast cytochrome c peroxidase by using the cleavable bifunctional reagent dithiobis-succinimidyl propionate in 5 mM-sodium phosphate buffer, pH 7.0. A cross-linked complex of molecular weight 48 000 was purified in approx. 10% yield from the reaction mixture, which contained 1 mol of cytochrome c and 1 mol of cytochrome c peroxidase/mol. Of the total 40 lysine residues, four to six were blocked by the cross-linking agent. Dithiobis-succinimidylpropionate can also cross-link cytochrome c to ovalbumin, but cytochrome c peroxidase is the preferred partner for cytochrome c in a mixture of the three proteins. The cytochrome c cross-linked to the peroxidase can be rapidly reduced by free cytochrome c-557 from Crithidia oncopelti, and the equilibrium obtained can be used to calculate a mid-point oxidation-reduction potential for the cross-linked cytochrome of 243 mV. Mitochondrial NADH-cytochrome c reductase will reduce the bound cytochrome only very slowly, but the rate of reduction by ascorbate at high ionic strength approaches that for free cytochrome c. Bound cytochrome c reduced by ascorbate can be re-oxidized within 10s by the associated peroxidase in the presence of equimolar H2O2. In the standard peroxidase assay the cross-linked complex shows 40% of the activity of the free peroxidase. Thus the intrinsic ability of each partner in the complex to take part in electron transfer is retained, but the stable association of the two proteins affects access of reductants.     

The cytochrome c peroxidase of Paracoccus denitrificans.

The size, visible absorption spectra, nature of haem and haem content suggest that the cytochrome c peroxidase of Paracoccus denitrificans is related to that of Pseudomonas aeruginosa. However, the Paracoccus enzyme shows a preference for cytochrome c donors with a positively charged 'front surface' and in this respect resembles the cytochrome c peroxidase from Saccharomyces cerevisiae. Paracoccus cytochrome c-550 is the best electron donor tested and, in spite of an acidic isoelectric point, has a markedly asymmetric charge distribution with a strongly positive 'front face'. Mitochondrial cytochromes c have a much less pronounced charge asymmetry but are basic overall. This difference between cytochrome c-550 and mitochondrial cytochrome c may reflect subtle differences in their electron transport roles. A dendrogram of cytochrome c1 sequences shows that Rhodopseudomonas viridis is a closer relative of mitochondria than is Pa. denitrificans. Perhaps a mitochondrial-type cytochrome c peroxidase may be found in such an organism.     

A hypothetical model of the cytochrome c peroxidase . cytochrome c electron transfer complex

A hypothetical three-dimensional model of the cytochrome c peroxidase . tuna cytochrome c complex is presented. The model is based on known x-ray structures and supported by chemical modification and kinetic data. Cytochrome c peroxidase contains a ring of aspartate residues with a spatial distribution on the molecular surface that is complementary to the distribution of highly conserved lysines surrounding the exposed edge of the cytochrome c heme crevice, namely lysines 13, 27, 72, 86, and 87. These lysines are known to play a functional role in the reaction with cytochrome c peroxidase, cytochrome oxidase, cytochrome c1, and cytochrome b5. A hypothetical model of the complex was constructed with the aid of a computer-graphics display system by visually optimizing hydrogen bonding interactions between complementary charged groups. The two hemes in the resulting model are parallel with an edge separation of 16.5 A. In addition, a system of inter- and intramolecular pi-pi and hydrogen bonding interactions forms a bridge between the hemes and suggests a mechanism of electron transfer.     

Engineering ascorbate peroxidase activity into cytochrome c peroxidase

Cytochrome c peroxidase (CCP) and ascorbate peroxidase (APX) have very similar structures, and yet neither CCP nor APX exhibits each other's activities with respect to reducing substrates. APX has a unique substrate binding site near the heme propionates where ascorbate H-bonds with a surface Arg and one heme propionate (Sharp et al. (2003) Nat. Struct. Biol. 10, 303-307). The corresponding region in CCP has a much longer surface loop, and the critical Arg residue that is required for ascorbate binding in APX is Asn in CCP. In order to convert CCP into an APX, the ascorbate-binding loop and critical arginine were engineered into CCP to give the CCP2APX mutant. The mutant crystal structure shows that the engineered site is nearly identical to that found in APX. While wild-type CCP shows no APX activity, CCP2APX catalyzes the peroxidation of ascorbate at a rate of approximately 12 min (-1), indicating that the engineered ascorbate-binding loop can bind ascorbate.     

Leishmania major peroxidase is a cytochrome c peroxidase

Leishmania major peroxidase (LmP) exhibits both ascorbate and cytochrome c peroxidase activities. Our previous results illustrated that LmP has a much higher activity against horse heart cytochrome c than ascorbate, suggesting that cytochrome c may be the biologically important substrate. To elucidate the biological function of LmP, we have recombinantly expressed, purified, and determined the 2.08 ? crystal structure of L. major cytochrome c (LmCytc). Like other types of cytochrome c, LmCytc has an electropositive surface surrounding the exposed heme edge that serves as the site of docking with redox partners. Kinetic assays performed with LmCytc and LmP show that LmCytc is a much better substrate for LmP than horse heart cytochrome c. Furthermore, unlike the well-studied yeast system, the reaction follows classic Michaelis-Menten kinetics and is sensitive to an increasing ionic strength. Using the yeast cocrystal as a control, protein-protein docking was performed using Rosetta to develop a model for the binding of LmP and LmCytc. These results suggest that the biological function of LmP is to act as a cytochrome c peroxidase.     

The binding of porphyrin cytochrome c to yeast cytochrome c peroxidase. A fluorescence study of the number of sites and their sensitivity to salt

Porphyrin c, the iron-free derivative of cytochrome c, is a reasonably good model for cytochrome c binding to cytochrome c peroxidase (CcP). It binds with the same stoichiometry but only one-quarter as tightly as cytochrome c. CcP (resting, FeIII) and CcP X CN can both bind up to two molecules of porphyrin c. The binding of the first porphyrin c is tight (kd = 1 X 10(-9) M, pH 6, ionic strength mu = 0, 4 degrees C) and results in quenching of the porphyrin c fluorescence. The binding is sensitive to ionic strength. The binding of the second porphyrin c is looser (Kd unknown) and does not result in quenching of the porphyrin fluorescence. The binding of porphyrin c to the cyano form and the resting forms of CcP cannot be distinguished by our methods. ES is the first acceptor of electrons from c(II) and can bind at least two molecules of porphyrin c. The binding of the first porphyrin c is extremely tight, results in substantial quenching and is insensitive to ionic strength. The binding of porphyrin c to the loose site (Kd = 2 X 10(-9) M, pH 6, 4 degrees C, mu = 0) results, unlike the resting and cyano forms, in quenching of fluorescence of the second porphyrin c. The binding of the second porphyrin c to ES is sensitive to ionic strength. The calculated distances between porphyrin c and the hemes of CcP(FeIII) and ES are approximately 2.5 nm.