Crystal structure of cytochrome c peroxidase compound I

We have compared the 2.5-A crystal structure of yeast cytochrome c peroxidase (CCP) with that of its semistable two-equivalent oxidized intermediate, compound I, by difference Fourier and least-squares refinement methods. Both structures were observed at -15 degrees C. The difference Fourier map reveals that formation of compound I causes only small positional adjustments of a few tenths of an angstrom. The map's most pronounced feature is a pair of positive and negative peaks bracketing the heme iron position. Least-squares refinement shows that the iron atom moves about 0.2 A toward the distal side of the heme. No significant difference density is evident near the side chains of Trp-51 or Met-172, each of which has been proposed to be the site of the electron paramagnetic resonance (EPR) active radical in compound I. However, the second most prominent feature of difference density is a negative peak near the side chain of Thr-180, which, according to the results of least-squares refinement, moves by 0.15 A in the direction of Met-230. These observations, together with the results of mutagenesis experiments [Fishel, L. A., Villafranca, J. E., Mauro, J. M., & Kraut, J. (1987) Biochemistry 26, 351-360; Goodin, D. B., Mauk, A. G., & Smith, M. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 1295-1299] in which Trp-51 and Met-172 have been replaced without loss of the EPR radical signal in compound I, lead us to consider the possibility that the radical site lies within a cluster composed of the side chains of Met-230, Met-231, and Trp-191.(ABSTRACT TRUNCATED AT 250 WORDS)     

X-ray structures of recombinant yeast cytochrome c peroxidase and three heme-cleft mutants prepared by site-directed mutagenesis

The 2.2-A X-ray structure for CCP(MI), a plasmid-encoded form of Saccharomyces cerevisiae cytochrome c peroxidase (CCP) expressed in Escherichia coli [Fishel, L.A., Villafranca, J. E., Mauro, J. M., & Kraut, J. (1987) Biochemistry 26, 351-360], has been solved, together with the structures of three specifically designed single-site heme-cleft mutants. The structure of CCP(MI) was solved by using molecular replacement methods, since its crystals grow differently from the crystals of CCP isolated from bakers' yeast used previously for structural solution. Small distal-side differences between CCP(MI) and bakers' yeast CCP are observed, presumably due to a strain-specific Thr-53----Ile substitution in CCP(MI). A Trp-51----Phe mutant remains pentacoordinated and exhibits only minor distal structural adjustments. The observation of a vacant sixth coordination site in this structure differs from the results of solution resonance Raman studies, which predict hexacoordinated high-spin iron [Smulevich, G., Mauro, J.M., Fishel, L. A., English, A. M., Kraut, J., & Spiro, T. G. (1988) Biochemistry 27, 5477-5485]. The coordination behavior of this W51F mutant is apparently altered in the presence of a precipitating agent, 30% 2-methyl-2,4-pentanediol. A proximal Trp-191----Phe mutant that has substantially diminished enzyme activity and altered magnetic properties [Mauro, J. M., Fishel, L. F., Hazzard, J. T., Meyer, T. E., Tollin, G., Cusanovich, M. A., & Kraut, J. (1988) Biochemistry 27, 6243-6256] accommodates the substitution by allowing the side chain of Phe-191, together with the segment of backbone to which it is attached, to move toward the heme. This relatively large (ca. 1 A) local perturbation is accompanied by numerous small adjustments resulting in a slight overall compression of the enzyme's proximal domain; however, the iron coordination sphere is essentially unchanged. This structure rules out a major alteration in protein conformation as a reason for the dramatically decreased activity of the W191F mutant. Changing proximal Asp-235 to Asn results in two significant localized structural changes. First, the heme iron moves toward the porphyrin plane, and distal water 595 now clearly resides in the iron coordination sphere at a distance of 2.0 A. The observation of hexacoordinated iron for the D235N mutant is in accord with previous resonance Raman results. Second, the indole side chain of Trp-191 has flipped over as a result of the mutation; the tryptophan N epsilon takes part in a new hydrogen bond with the backbone carbonyl oxygen of Leu-177.(ABSTRACT TRUNCATED AT 400 WORDS)     

Crystal structure of nitric oxide inhibited cytochrome c peroxidase

We have collected X-ray diffraction data from a crystal of cytochrome c peroxidase (CCP) complexed with the inhibitor nitric oxide to a resolution of 2.55 A. A difference Fourier map shows density indicating the NO ligand is bound to the heme iron at the sixth coordination site in a bent configuration. Structural adjustments were determined by least-squares refinement that yielded an agreement residual of R = 0.18. The orientation of the ligand, tilting toward Arg-48, causes adjustment in the position of this nearby polar side chain. As a model for the substrate hydrogen peroxide, this geometry is consistent with the suggestion that Arg-48 serves to polarize the O-O peroxide bond to promote heterolytic cleavage of the bond [Poulos, T. L., & Kraut, J. (1980) J. Biol. Chem. 255, 8199-8205]. Strong difference density is also observed near residues 190-194, especially around the indole ring of Trp-191. The density indicates movement of the indole ring away from the proximal His-175 imidazole ring by about 0.25 A, which appears to cause perturbation of the neighboring residues. The response of Trp-191 on the proximal side of the heme to binding nitric oxide on the distal side probably results from delocalization of the electron density of the ligand. Relevant to this is the recent finding that a mutant in which Trp-191 is replaced by phenylalanine has dramatically reduced activity, less than 0.05% of the parent activity [Mauro, J. M., Fishel, L. A., Hazzard, J. T., Meyer, T. E., Tollin, G., Cusanovich, M. A., & Kraut, J. (1988) Biochemistry 27, 6243-6256].(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of electrostatics and salt bridges in stabilizing the compound I radical in ascorbate peroxidase

Cytochrome c (CcP) and ascorbate peroxidase (APX) are heme peroxidases which have very similar active site structures yet differ substantially in the properties of compound I, the intermediate formed upon reaction with peroxides. Although both peroxidases have a tryptophan in the proximal heme pocket, Trp191 in CcP and Trp179 in APX, only Trp191 in CcP forms a stable cation radical while APX forms the more traditional porphyrin pi-cation radical. Previous work [Barrows, T. P., et al. (2004)Biochemistry 43, 8826-8834] has shown that converting three methionine residues in the cytochrome c peroxidase (CcP) proximal heme pocket to the corresponding residues in APX dramatically decreased the stability of the Trp191 radical in CcP compound I. On the basis of these results, we reasoned that replacing the analogous residues at positions 160, 203, and 204 in APX with methionine should stabilize a Trp179 radical in APX compound I. Steady- and transient-state kinetics of this mutant (designated APX3M) show a significant destabilization of the native porphyrin pi-radical, while electron paramagnetic resonance (EPR) studies show an increase in the intensity of the signal at g = 2.006 with characteristics consistent with formation of a Trp radical. This hypothesis was tested by replacing Trp179 with Phe in the APX3M background. The EPR spectrum of this mutant was very similar to that of the CcP W191G mutant which is known to form a tyrosine radical. Previously published theoretical studies [Guallar, V., et al. (2003) Proc. Natl. Acad. Sci. U.S.A. 100, 6998-7002] suggest that electrostatic shielding of the heme propionates also plays a role in the stability of the porphyrin radical. Arg172 in APX hydrogen bonds with one of the heme propionates. Replacing Arg172 with an asparagine residue in the APX3M background generates a mutant which no longer forms the full complement of the compound I porphyrin pi-radical. These results suggest that the electrostatics of the proximal pocket and the shielding of propionate groups by salt bridges are critical factors controlling the location of a stable compound I radical in heme peroxidases.     

Electrostatic control of the tryptophan radical in cytochrome c peroxidase

Previously a K(+)-binding site, analogous to that found in ascorbate peroxidase (APX), was engineered into cytochrome c peroxidase (CcP) to test the hypothesis that the bound K(+) influences the stability of the Trp191 cation radical formed during the CcP catalytic cycle (Bonagura et al., (1996) Biochemistry 35, 6107 and Bonagura et al., (1999) Biochemistry 38, 5528). Characterization of this mutant, designated CcPK2, showed that the stability of the Trp191 cation radical is dependent on the occupancy of the engineered K(+) site and that the Trp191 radical was much less stable in this mutant than in wild-type CcP. The mutations Met230Leu, Met231Gln, and Met172Ser have now been constructed on the CcPK2 mutant template to test if the Met residues also contribute to the stabilization of the Trp191 cation radical. Crystal structures show that the mutations affect only the local structure near the sites of mutation. Removal of these electronegative residues located less than 8 A from the Trp radical results in a further destabilization of the Trp radical. The characteristic EPR signal associated with the Trp radical is significantly narrowed and is characteristic of a tyrosine radical signal. Double-mixing stopped-flow experiments, where the delay time between the formation of CcP compound I and its mixing with horse heart ferrocytochrome c is varied, show that the stability of the Trp radical decreases as the Met residues are removed from the proximal cavity. When taken together, these results demonstrate a strong correlation between the experimentally determined stability of the Trp191 radical, the enzyme activity, and the calculated electrostatic stabilization of the Trp191 radical.     

Role of configurational gating in intracomplex electron transfer from cytochrome c to the radical cation in cytochrome c peroxidase.

Electron transfer within complexes of cytochrome c (Cc) and cytochrome c peroxidase (CcP) was studied to determine whether the reactions are gated by fluctuations in configuration. Electron transfer in the physiological complex of yeast Cc (yCc) and CcP was studied using the Ru-39-Cc derivative, in which the H39C/C102T variant of yeast iso-1-cytochrome c is labeled at the single cysteine residue on the back surface with trisbipyridylruthenium(II). Laser excitation of the 1:1 Ru-39-Cc-CcP compound I complex at low ionic strength results in rapid electron transfer from RuII to heme c FeIII, followed by electron transfer from heme c FeII to the Trp-191 indolyl radical cation with a rate constant keta of 2 x 10(6) s-1 at 20 degrees C. keta is not changed by increasing the viscosity up to 40 cP with glycerol and is independent of temperature. These results suggest that this reaction is not gated by fluctuations in the configuration of the complex, but may represent the elementary electron transfer step. The value of keta is consistent with the efficient pathway for electron transfer in the crystalline yCc-CcP complex, which has a distance of 16 A between the edge of heme c and the Trp-191 indole [Pelletier, H., and Kraut, J. (1992) Science 258, 1748-1755]. Electron transfer in the complex of horse Cc (hCc) and CcP was examined using Ru-27-Cc, in which hCc is labeled with trisbipyridylruthenium(II) at Lys-27. Laser excitation of the Ru-27-Cc-CcP complex results in electron transfer from RuII to heme c FeII with a rate constant k1 of 2.3 x 10(7) s-1, followed by oxidation of the Trp-191 indole to a radical cation by RuIII with a rate constant k3 of 7 x 10(6) s-1. The cycle is completed by electron transfer from heme c FeII to the Trp-191 radical cation with a rate constant k4 of 6.1 x 10(4) s-1. The rate constant k4 decreases to 3.4 x 10(3) s-1 as the viscosity is increased to 84 cP, but the rate constants k1 and k3 remain the same. The results are consistent with a gating mechanism in which the Ru-27-Cc-CcP complex undergoes fluctuations between a major state A with the configuration of the hCc-CcP crystalline complex and a minor state B with the configuration of the yCc-CcP complex. The hCc-CcP complex, state A, has an inefficient pathway for electron transfer from heme c to the Trp-191 indolyl radical cation with a distance of 20.5 A and a predicted value of 5 x 10(2) s-1 for k4A. The observed rate constant k4 is thus gated by the rate constant ka for conversion of state A to state B, where the rate of electron transfer k4B is expected to be 2 x 10(6) s-1. The temperature dependence of k4 provides activation parameters that are consistent with the proposed gating mechanism. These studies provide evidence that configurational gating does not control electron transfer in the physiological yCc-CcP complex, but is required in the nonphysiological hCc-CcP complex.     

Reaction of bovine cytochrome c oxidase with hydrogen peroxide produces a tryptophan cation radical and a porphyrin cation radical

Oxidized bovine cytochrome c oxidase reacts with hydrogen peroxide to generate two electron paramagnetic resonance (EPR) free radical signals (Fabian, M., and Palmer, G. (1995) Biochemistry 34, 13802-13810). These radicals are associated with the binuclear center and give rise to two overlapped EPR signals, one signal being narrower in line width (DeltaHptp = 12 G) than the other (DeltaHptp = 45 G). We have used electron nuclear double resonance (ENDOR) spectrometry to identify the two different chemical species giving rise to these two EPR signals. Comparison of the ENDOR spectrum associated with the narrow signal with that of compound I of horseradish peroxidase (formed by reaction of that enzyme with hydrogen peroxide) demonstrates that the two species are virtually identical. The chemical species giving rise to the narrow signal is therefore identified as an exchange-coupled porphyrin cation radical similar to that formed in horseradish peroxidase compound I. Comparison of the ENDOR spectrum of compound ES (formed by the reaction of hydrogen peroxide with cytochrome c peroxidase) with that of the broad signal indicates that the chemical species giving rise to the broad EPR signal in cytochrome c oxidase is probably an exchange coupled tryptophan cation radical. This is substantiated using H(2)O/D(2)O solvent exchange experiments where the ENDOR difference spectrum of the broad EPR signal of cytochrome c oxidase shows a feature consistent with hyperfine coupling to the exchangeable N(1) proton of a tryptophan cation radical.     

Yeast cytochrome c peroxidase: mutagenesis and expression in Escherichia coli show tryptophan-51 is not the radical site in compound I

Using oligonucleotide-directed site-specific mutagenesis, we have constructed a system for the mutation and expression of yeast cytochrome c peroxidase (CCP, EC 1.11.1.5) in Escherichia coli and applied it to test the hypothesis that Trp-51 is the locus of the free radical observed in compound I of CCP [Poulos, T. L., & Kraut, J. (1980) J. Biol. Chem. 255, 8199-8205]. The system was created by substituting a CCP gene modified by site-directed mutagenesis, CCP(MI), for the fol gene in a vector previously used for mutagenesis and overexpression of dihydrofolate reductase. E. coli transformed with the resulting plasmid produced the CCP(MI) enzyme in large quantities, more than 15 mg/L of cell culture, of which 10% is holo- and 90% is apo-CCP(MI). The apoenzyme was easily converted to holoenzyme by the addition of bovine hemin. Purified CCP(MI) has the same catalytic activity and spectra as bakers' yeast CCP. A mutation has been made in CCP(MI), Trp-51 to Phe. The Phe-51 mutant protein CCP(MI,F51) is fully active, and the electron paramagnetic resonance (EPR) spectrum, at 89 K, of its oxidized intermediate, compound I, displays a strong sharp resonance at g = 2.004, which is very similar to the signal observed for compound I of both bakers' yeast CCP and CCP(MI). However, UV-visible and EPR spectroscopy revealed that the half-life of CCP(MI,F51) compound I at 23 degrees C is only 1.4% of that observed for the compound I forms of CCP(MI) or bakers' yeast CCP. Thus, Trp-51 is not necessary for the formation of the free radical observed in compound I but appears to exert a significant influence on its stability.     

Detection of an oxyferryl porphyrin pi-cation-radical intermediate in the reaction between hydrogen peroxide and a mutant yeast cytochrome c peroxidase. Evidence for tryptophan-191 involvement in the radical site of compound I

Peroxide oxidation of a mutant cytochrome c peroxidase, in which Trp-191 has been replaced by Phe through site-directed mutagenesis, produces an oxidized intermediate whose stable UV/visible absorption spectrum is very similar to that of compound I of the native yeast enzyme. This spectrum is characteristic of an oxyferryl, Fe(IV), heme. Stopped-flow studies reveal that the reaction between the mutant enzyme and hydrogen peroxide is biphasic with the transient formation of an intermediate whose absorption spectrum is quite distinct from that of either the native ferric enzyme or the final product. Rapid spectral scanning of the intermediate provides a spectrum characteristic of an oxyferryl porphyrin pi-cation-radical species. At pH 6, 100 mM ionic strength, and 25 degrees C, the rate constant for formation of the oxyferryl pi-cation radical has a lower limit of 6 X 10(7) M-1 s-1 and the rate of conversion of the transient intermediate to the final oxidized product is 51 +/- 4 s-1. Evidence is presented indicating that Trp-191 either is the site of the radical in CcP compound I or is intimately involved in formation of the radical.     

Electron transfer between cytochromec and cytochromec peroxidase

The reaction between cytochromec (CC) and cytochromec peroxidase (CcP) is a very attractive system for investigating the fundamental mechanism of biological electron transfer. The resting ferric state of CcP is oxidized by hydrogen peroxide to compound I (CMPI) containing an oxyferryl heme and an indolyl radical cation on Trp-191. CMPI is sequentially reduced to CMPII and then to the resting state CcP by two molecules of CC. In this review we discuss the use of a new ruthenium photoreduction technique and other rapid kinetic techniques to address the following important questions: (1) What is the initial electron acceptor in CMPI? (2) What are the true rates of electron transfer from CC to the radical cation and to the oxyferryl heme? (3) What are the binding domains and pathways for electron transfer from CC to the radical cation and the oxyferryl heme? (4) What is the mechanism for the complete reaction under physiological conditions?     

Chloroperoxidase compound I: Electron paramagnetic resonance and M?ssbauer studies

The green primary compound of chloroperoxidase was prepared by freeze-quenching the enzyme after rapid mixing with a 5-fold excess of peracetic acid. The electron paramagnetic resonance (EPR) spectra of these preparations consisted of at least three distinct signals that could be assigned to native enzyme, a free radical, and the green compound I as reported earlier. The absorption spectrum of compound I was obtained through subtraction of EPR signals measured under passage conditions. The signal is well approximated by an effective spin Seff = 1/2 model with g = 1.64, 1.73, 2.00 and a highly anisotropic line width. M?ssbauer difference spectra of compound I samples minus native enzyme showed well-resolved magnetic splitting at 4.2 K, an isomer shift delta Fe = 0.15 mm/s, and quadrupole splitting delta EQ = 1.02 mm/s. All data are consistent with the model of an exchange-coupled spin S = 1 ferryl iron and a spin S' = 1/2 porphyrin radical. As a result of the large zero field splitting, D, of the ferryl iron and of intermediate antiferromagnetic exchange, S.J.S'.J approximately 1.02 D, the system consists of three Kramers doublets that are widely separated in energy. The model relates the EPR and M?ssbauer spectra of the ground doublet to the intrinsic parameters of the ferryl iron, D/k = 52 K, E/D congruent to 0.035, and A perpendicular (gn beta n) = 20 T, and the porphyrin radical.(ABSTRACT TRUNCATED AT 250 WORDS)     

Redesign of cytochrome c peroxidase into a manganese peroxidase: role of tryptophans in peroxidase activity.

Trp191Phe and Trp51Phe mutations have been introduced into an engineered cytochrome c peroxidase (CcP) containing a Mn(II)-binding site reported previously (MnCcP; see Yeung, B. K.-S., et al. (1997) Chem. Biol. 5, 215-221). The goal of the present study is to elucidate the role of tryptophans in peroxidase activity since CcP contains both Trp51 and Trp191 while manganese peroxidase (MnP) contains phenylalanine residues at the corresponding positions. The presence of Trp191 in CcP allows formation of a unique high-valent intermediate containing a ferryl oxo and tryptophan radical called compound I'. The absence of a tryptophan residue at this position in MnP is the main reason for the formation of an intermediate called compound I which contains a ferryl oxo and porphyrin pi-cation radical. In this study, we showed that introduction of the Trp191Phe mutation to MnCcP did not improve MnP activity (specific activity: MnCcP, 0.750 micromol min-1 mg-1; MnCcP(W191F), 0.560 micromol min-1 mg-1. k(cat)/K(m): MnCcP, 0.0517 s-1 mM-1; MnCcP(W191F), 0.0568 s-1 mM-1) despite the fact that introduction of the same mutation to WTCcP caused the formation of a transient compound I (decay rate, 60 s-1). However, introducing both the Trp191Phe and Trp51Phe mutations not only resulted in a longer lived compound I in WTCcP (decay rate, 18 s-1), but also significantly improved MnP activity in MnCcP (MnCcP(W51F, W191F): specific activity, 8.0 micromol min-1 mg-1; k(cat)/K(m), 0. 599 s-1 mM-1). The increase in activity can be attributed to the Trp51Phe mutation since MnCcP(W51F) showed significantly increased MnP activity relative to MnCcP (specific activity, 3.2 micromol min-1 mg-1; k(cat)/K(m), 0.325 s-1 mM-1). As with MnP, the activity of MnCcP(W51F, W191F) was found to increase with decreasing pH. Our results demonstrate that, while the Trp191Phe and Trp51Phe mutations both play important roles in stabilizing compound I, only the Trp51Phe mutation contributes significantly to increasing the MnP activity because this mutation increases the reactivity of compound II, whose oxidation of Mn(II) is the rate-determining step in the reaction mechanism.     

Direct probing of copper active site and free radical formed during bicarbonate-dependent peroxidase activity of bovine and human copper, zinc-superoxide dismutases. Low-temperature electron paramagnetic resonance and electron nuclear double resonance studies

Using X-band electron paramagnetic resonance (EPR) and electron nuclear double resonance (ENDOR) spectroscopy at liquid helium temperatures, the Cu(II) coordination geometry at the active site of bovine and human copper,zinc-superoxide dismutases (bSOD1 and hSOD1) treated with H(2)O(2) and bicarbonate (HCO(3)(-)) was examined. The time course EPR of wild type human SOD1 (WT hSOD1), W32F hSOD1 mutant (tryptophan 32 substituted with phenylalanine), and bSOD1 treated with H(2)O(2) and HCO(3)(-) shows an initial reduction of active site Cu(II) to Cu(I) followed by its oxidation back to Cu(II) in the presence of H(2)O(2). However, HCO(3)(-) induced a Trp-32-derived radical from WT hSOD1 but not from bSOD1. The mutation of Trp-32 by phenylalanine totally eliminated the Trp-32 radical signal generated from W32F hSOD1 treated with HCO(3)(-) and H(2)O(2). Further characterization of the free radical was performed by UV irradiation of WT hSOD1 and bSOD1 that generated tryptophanyl and tyrosyl radicals. Both proton ((1)H) and nitrogen ((14)N) ENDOR studies of bSOD1 and hSOD1 in the presence of H(2)O(2) revealed a change in the geometry of His-46 (or His-44) and His-48 (or His-46) coordinated to Cu(II) at the active site of WT hSOD1 and bSOD1, respectively. However, in the presence of HCO(3)(-) and H(2)O(2), both (1)H and (14)N ENDOR spectra were almost identical to those derived from native bSOD1. We conclude that HCO(3)(-)-derived oxidant does not alter significantly the Cu(II) active site geometry and histidine coordination to Cu(II) in SOD1 as does H(2)O(2) alone; however, the oxidant derived from HCO(3)(-) (i.e. carbonate anion radical) reacts with surface-associated Trp-32 in hSOD1 to form the corresponding radical.     

Tryptophan-191----phenylalanine, a proximal-side mutation in yeast cytochrome c peroxidase that strongly affects the kinetics of ferrocytochrome c oxidation

On the basis of X-ray structural information, it was previously proposed that tryptophan-191 of yeast cytochrome c peroxidase (CCP) may be important in determining the spectroscopic and catalytic properties of the enzyme [Edwards, S. L., Xuong, Ng. H., Hamlin, R. C., & Kraut, J. (1987) Biochemistry 26, 1503-1511]. By use of site-directed mutagenesis and an Escherichia coli expression system, a mutant phenylalanine-191 (F191) CCP was prepared in order to examine the effects of altering the H-bonding and pi-pi interactions that occur between Trp-191 and the iron-coordinated proximal His-175 in the parent enzyme. The F191 mutant enzyme exhibits a dramatic decrease (approximately 3000-fold at pH 7) in V0/e for catalysis of peroxide-dependent ferrocytochrome c oxidation, while V0/e for oxidation of ferrocyanide is decreased only 4.6-fold compared to that of the parent. The Fe3+/Fe2+ Em,7 and the stability of the oxyferryl center in the H2O2-oxidized mutant enzyme are relatively unaffected by the mutation, but the species responsible for a radical-like signal centered at g = 2.00 has been destabilized approximately 100-fold with respect to spontaneous decay. Steady-state kinetic assays as well as transient-state laser flash photolysis experiments utilizing flavin semiquinones as reductants indicate that the mutant CCP forms a complex with cytochrome c but the oxyferryl center in the oxidized enzyme is no longer able to be rapidly reduced by ferrocytochrome c. The most likely reasons for this kinetic behavior are either that new steric constraints exist in the mutant which impede relaxation of the iron center to the resting ferric state or that the indole ring of Trp-191 is important in a specific interprotein electron-transfer pathway that exists between the heme centers of CCP and cytochrome c.     

Radical formation at Tyr39 and Tyr153 following reaction of yeast cytochrome c peroxidase with hydrogen peroxide

The formation of yeast cytochrome c peroxidase (CcP) compound I has been recognized for many years to be associated with formation of two protein-centered radicals. One of these radical sites is located at Trp191 and is directly involved in catalytic oxidation of ferrocytochrome c (Sivaraja, M., Goodin, D. B., Smith, M., Hoffman, B. M. (1989) Science 245, 738-740). The second radical has been proposed to arise from one or more tyrosyl residues of CcP. However, the tyrosyl residue (or residues) capable of forming this radical has not been identified, and the functional role of this radical remains poorly understood. In the present work, this issue has been addressed through the combined use of the spin-trapping reagent 2-methyl-2-nitrosopropane and peptide mapping by electrospray mass spectrometry to identify Tyr39 and Tyr153 as two tyrosyl residues that are capable of forming radical centers upon reaction of CcP with hydrogen peroxide. The implications of this observation to the catalytic mechanism of CcP are addressed with reference to the three-dimensional structure of CcP.     

Small substrates and cytochrome c are oxidized at different sites of cytochrome c peroxidase.

Modeling studies suggest that electrons are transferred from cytochrome c to cytochrome c peroxidase (CcP) with cytochrome c predominantly bound at a site facing the gamma-meso edge of the CcP prosthetic heme group (Poulos, T.L., and Kraut, J. (1980) J. Biol. Chem. 255, 10322-10330). As shown here, guaiacol and ferrocyanide are oxidized at a different site of CcP. Thus, the oxidations of cytochrome c and guaiacol are differentially inactivated by phenylhydrazine and sodium azide. The loss of guaiacol oxidation activity correlates with covalent binding of 1 equivalent of [14C]phenylhydrazine to the protein, whereas the slower loss of cytochrome c activity correlates with the appearance of a 428-nm absorbance maximum attributed to the formation of a sigma-phenyl-iron heme complex. The delta-meso-phenyl and 8-hydroxymethyl derivatives of heme are formed as minor products. Catalytic oxidation of azide to the azidyl radical results in inactivation of CcP and formation of delta-meso-azidoheme. Reconstitution of apo-CcP with delta-meso-azido-, -ethyl-, and -(2-phenylethyl)heme yields holoproteins that give compound I species with H2O2 and exhibit 80, 59, and 31%, respectively, of the control kcat value for cytochrome c oxidation but little or no guaiacol or ferrocyanide oxidizing activity. Conversely, CcP reconstituted with gamma-meso-ethylheme is fully active in the oxidation of guaiacol and ferrocyanide but only retains 27% of the cytochrome c oxidizing activity. These results indicate that guaiacol and ferrocyanide are primarily oxidized near the delta-meso-heme edge rather than, like cytochrome c, at a surface site facing the gamma-meso edge.     

Role of the low-affinity binding site in electron transfer from cytochrome C to cytochrome C peroxidase

The interaction of yeast iso-1-cytochrome c (yCc) with the high- and low-affinity binding sites on cytochrome c peroxidase compound I (CMPI) was studied by stopped-flow spectroscopy. When 3 microM reduced yCc(II) was mixed with 0.5 microM CMPI at 10 mM ionic strength, the Trp-191 radical cation was reduced from the high-affinity site with an apparent rate constant >3000 s(-1), followed by slow reduction of the oxyferryl heme with a rate constant of only 10 s(-1). In contrast, mixing 3 microM reduced yCc(II) with 0.5 microM preformed CMPI *yCc(III) complex led to reduction of the radical cation with a rate constant of 10 s(-1), followed by reduction of the oxyferryl heme in compound II with the same rate constant. The rate constants for reduction of the radical cation and the oxyferryl heme both increased with increasing concentrations of yCc(II) and remained equal to each other. These results are consistent with a mechanism in which both the Trp-191 radical cation and the oxyferryl heme are reduced by yCc(II) in the high-affinity binding site, and the reaction is rate-limited by product dissociation of yCc(III) from the high-affinity site with apparent rate constant k(d). Binding yCc(II) to the low-affinity site is proposed to increase the rate constant for dissociation of yCc(III) from the high-affinity site in a substrate-assisted product dissociation mechanism. The value of k(d) is <5 s(-1) for the 1:1 complex and >2000 s(-1) for the 2:1 complex at 10 mM ionic strength. The reaction of horse Cc(II) with CMPI was greatly inhibited by binding 1 equiv of yCc(III) to the high-affinity site, providing evidence that reduction of the oxyferryl heme involves electron transfer from the high-affinity binding site rather than the low-affinity site. The effects of CcP surface mutations on the dissociation rate constant indicate that the high-affinity binding site used for the reaction in solution is the same as the one identified in the yCc*CcP crystal structure.     

Electron paramagnetic and electron nuclear double resonance of the hydrogen peroxide compound of cytochrome c peroxidase

We have collected electron paramagnetic resonance (EPR) and electron nuclear double resonance (ENDOR) spectra from the hydrogen peroxide compound of yeast cytochrome c peroxidase, termed ES, employing EPR microwave frequencies of 9.6 and 11.6 GHz. We have measured and analyzed the temperature dependence of the spin-lattice relaxation rate (1/T1) of the paramagnetic center of ES over the temperature range 1.9 to 4 K. In addition, an upper bound to exchange coupling between the ferryl heme and EPR-visible centers of ES has been calculated and expressions for the dipolar interaction between a ferryl heme and a free radical have been derived. These results all confirm that the EPR signal of ES is not associated with an aromatic amino acid radical, and in particular not with a tryptophanyl radical. This conclusion has led us to consider an explanation of the EPR signal in terms of a nucleophilically stabilized methionyl radical.     

Electron paramagnetic resonance and electron nuclear double resonance spectroscopic identification and characterization of the tyrosyl radicals in prostaglandin H synthase 1

The tyrosyl radicals generated in reactions of ethyl hydrogen peroxide with both native and indomethacin-pretreated prostaglandin H synthase 1 (PGHS-1) were examined by low-temperature electron paramagnetic resonance (EPR) and electron nuclear double resonance (ENDOR) spectroscopies. In the reaction of peroxide with the native enzyme at 0 degrees C, the tyrosyl radical EPR signal underwent a continuous reduction in line width and lost intensity as the incubation time increased, changing from an initial, 35-G wide doublet to a wide singlet of slightly smaller line width and finally to a 25-G narrow singlet. The 25-G narrow singlet produced by self-inactivation was distinctly broader than the 22-G narrow singlet obtained by indomethacin treatment. Analysis of the narrow singlet EPR spectra of self-inactivated and indomethacin-pretreated enzymes suggests that they reflect conformationally distinct tyrosyl radicals. ENDOR spectroscopy allowed more detailed characterization by providing hyperfine couplings for ring and methylene protons. These results establish that the wide doublet and the 22-G narrow singlet EPR signals arise from tyrosyl radicals with different side-chain conformations. The wide-singlet ENDOR spectrum, however, is best accounted for as a mixture of native wide-doublet and self-inactivated 25-G narrow-singlet species, consistent with an earlier EPR study [DeGray et al. (1992) J. Biol. Chem. 267, 23583-23588]. We conclude that a tyrosyl residue other than the catalytically essential Y385 species is most likely responsible for the indomethacin-inhibited, narrow-singlet spectrum. Thus, this inhibitor may function by redirecting radical formation to a catalytically inactive side chain. Either radical migration or conformational relaxation at Y385 produces the 25-G narrow singlet during self-inactivation. Our ENDOR data also indicate that the catalytically active, wide-doublet species is not hydrogen bonded, which may enhance its reactivity toward the fatty-acid substrate bound nearby.     

The role of redox-active amino acids on compound I stability, substrate oxidation, and protein cross-linking in yeast cytochrome C peroxidase.

The role of two tryptophans (Trp51 and Trp191) and six tyrosines (Tyr36, Tyr39, Tyr42, Tyr187, Tyr229, and Tyr236) in yeast cytochrome c peroxidase (CcP) has been probed by site-directed mutagenesis. A series of sequential mutations of these redox-active amino acid residues to the corresponding, less oxidizable residues in lignin peroxidase (LiP) resulted in an increasingly more stable compound I, with rate constants for compound I decay decreasing from 57 s(-1) for CcP(MI, W191F) to 7 s(-1) for CcP(MI, W191F,W51F,Y187F,Y229F,Y236F,Y36F,Y39E,Y42F). These results provide experimental support for the proposal that the stability of compound I depends on the number of endogenous oxidizable amino acids in proteins. The higher stability of compound I in the variant proteins also makes it possible to observe its visible absorption spectroscopic features more clearly. The effects of the mutations on oxidation of ferrocytochrome c and 2,6-dimethoxyphenol were also examined. Since the first mutation in the series involved the change of Trp191, a residue that plays a critical role in the electron transfer pathway between CcP and cyt c, the ability to oxidize cyt c was negligible for all mutant proteins. On the other hand, the W191F mutation had little effect on the proteins' ability to oxidize 2,6-dimethoxyphenol. Instead, the W51F mutation resulted in the largest increase in the k(cat)/K(M), from 2.1 x 10(2) to 5.0 x 10(3) M(-1) s(-1), yielding an efficiency that is comparable to that of manganese peroxidase (MnP). The effect in W51F mutation can be attributed to the residue's influence on the stability and thus reactivity of the ferryl oxygen of compound II, whose substrate oxidation is the rate-determining step in the reaction mechanism. Finally, out of all mutant proteins in this study, only the variant containing the Y36F, Y39E, and Y42F mutations was found to prevent covalent protein cross-links in the presence of excess hydrogen peroxide and in the absence of exogenous reductants. This finding marks the first time a CcP variant is incapable of forming protein cross-links and confirms that one of the three tyrosines must be involved in the protein cross-linking.