The homologous tryptophan critical for cytochrome c peroxidase function is not essential for ascorbate peroxidase activity

The crystal structures of ascorbate peroxidase (APX) and cytochrome c peroxidase (CCP) show that the active site structures are nearly identical. Both enzymes contain a His-Asp-Trp catalytic triad in the proximal pocket. The proximal Asp residue hydrogen bonds with both the His proximal heme ligand and the indole ring nitrogen of the proximal Trp. The Trp is stacked parallel to and in contact with the proximal His ligand. This Trp is known to be the site of free radical formation in CCP compound I and also is essential for activity. However, APX forms a porphyrin radical and not a Trp-centered radical, even though the His-Asp-Trp triad structure is the same in both peroxidases. We found that conversion of the proximal Trp to Phe has no effect on APX enzyme activity and that the mutant crystal structure shows that changes in the structure are confined to the site of mutation. This indicates that the paths of electron transfer in CCP and APX are distinctly different. The Trp-to-Phe mutant does alter the stability of the APX compound I porphyrin radical, by a factor of two. Electrostatic calculations and modeling studies show that a potassium cation located about 8?Å from the proximal Trp in APX, but absent in CCP, makes a significant contribution to the stability of a cation Trp radical. This underscores the importance of long-range electrostatic effects in enzyme catalyzed reactions.     

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.     

Cation-induced stabilization of the engineered cation-binding loop in cytochrome c peroxidase (CcP)

We have previously shown that the K(+) site found in the proximal heme pocket of ascorbate peroxidase (APX) could be successfully engineered into the closely homologous cytochrome c peroxidase (CcP) [Bonagura et al., (1996) Biochemistry 35, 6107-6115; Bonagura et al. (1999) Biochemistry 38, 5538-5545]. In addition, specificity could be switched to binding Ca(2+) as found in other peroxidases [Bonagura et al. (1999) J. Biol. Chem. 274, 37827-37833]. The introduction of a proximal cation-binding site also promotes conversion of the Trp191 containing cation-binding loop from a "closed" to an "open" conformer. In the present study we have changed a crucial hinge residue of the cation-binding loop, Asn195, to Pro which stabilizes the loop, albeit, only in the presence of bound K(+). The crystal structure of this mutant, N195PK2, has been refined to 1.9 A. As predicted, introduction of this crucial hinge residue stabilizes the cation-binding loop in the presence of the bound K(+). As in earlier work, the characteristic EPR signal of Trp191 cation radical becomes progressively weaker with increasing [K(+)] and the lifetime of the Trp191 radical also has been considerably shortened in this mutant. This mutant CcP exhibits reduced enzyme activity, which could be titrated to lower levels with increasing [K(+)] when horse heart cytochrome c is the substrate. However, with yeast cytochrome c as the substrate, the mutant was as active as wild-type at low ionic strength, but 40-fold lower at high ionic strength. We attribute this difference to a change in the rate-limiting step as a function of ionic strength when yeast cytochrome c is the substrate.     

Crystal structure of Leishmania major peroxidase and characterization of the compound i tryptophan radical

The parasitic protozoa Leishmania major produces a peroxidase (L. major peroxidase; LmP) that exhibits activities characteristic of both yeast cytochrome c peroxidase (CCP) and plant cytosolic ascorbate peroxidase (APX). One common feature is a key Trp residue, Trp(208) in LmP and Trp(191) in CCP, that is situated adjacent to the proximal His heme ligand in CCP, APX, and LmP. In CCP, Trp(191) forms a stable cationic radical after reaction with H(2)O(2) to form Compound I; in APX, the radical is located on the porphyrin ring. In order to clarify the role of Trp(208) in LmP and to further probe peroxidase structure-function relationships, we have determined the crystal structure of LmP and have studied the role of Trp(208) using electron paramagnetic resonance spectroscopy (EPR), mutagenesis, and enzyme kinetics. Both CCP and LmP have an extended section of β structure near Trp(191) and Trp(208), respectively, which is absent in APX. This region provides stability to the Trp(191) radical in CCP. EPR of LmP Compound I exhibits an intense and stable signal similar to CCP Compound I. In the LmP W208F mutant, this signal disappears, indicating that Trp(208) forms a stable cationic radical. In LmP conversion of the Cys(197) to Thr significantly weakens the Compound I EPR signal and dramatically lowers enzyme activity. These results further support the view that modulation of the local electrostatic environment controls the stability of the Trp radical in peroxidases. Our results also suggest that the biological role of LmP is to function as a cytochrome c peroxidase.     

The effects of an engineered cation site on the structure, activity, and EPR properties of cytochrome c peroxidase

Earlier work [Bonagura et al. (1996) Biochemistry 35, 6107] showed that the K+ site found in the proximal pocket of ascorbate peroxidase (APX) could be engineered into cytochrome c peroxidase (CCP). Binding of K+ at the engineered site results in a loss in activity and destabilization of the CCP compound I Trp191 cationic radical owing to long-range electrostatic effects. The engineered CCP mutant crystal structure has been refined to 1.5 A using data obtained at cryogenic temperatures which provides a more detailed basis for comparison with the naturally occurring K+ site in APX. The characteristic EPR signal associated with the Trp191 radical becomes progressively weaker as K+ is added, which correlates well with the loss in enzyme activity as [K+] is increased. These results coupled with stopped-flow studies support our earlier conclusions that the loss in activity and EPR signal is due to destabilization of the Trp191 cationic radical.     

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.     

New insights into the heme cavity structure of catalase-peroxidase: a spectroscopic approach to the recombinant synechocystis enzyme and selected distal cavity mutants

Catalase-peroxidases (KatGs) are heme peroxidases with homology to yeast cytochrome cperoxidase (CCP) and plant ascorbate peroxidases (APXs). KatGs exhibit a peroxidase activity of broad specificity and a high catalase activity, which strongly depends on the presence of a distal Trp as part of the conserved amino acid triad Arg-Trp-His. By contrast, both CCP and APX do not have a substantial catalase activity despite the presence of the same triad. Thus, to elucidate structure-function relationships of catalase-peroxidases (for which no crystal structure is available at the moment), we performed UV-Vis and resonance Raman studies of recombinant wild-type KatG from the cyanobacterium SynechocystisPCC 6803 and the distal side variants (His123-->Gln, Glu; Arg119-->Ala, Asn; Trp122-->Phe, Ala). The distal cavity of KatG is very similar to that of the other class I peroxidases. A H-bond network involving water molecules and the distal Trp, Arg, and His is present, which connects the distal and proximal sides of the heme pocket. However, distal mutation not only affects the heme Fe coordination state and perturbs the proximal Fe-Im bond, as previously observed for other peroxidases, but also alters the stability of the heme architecture. The charge of the distal residues appears particularly important for maintaining the heme architecture. Moreover, the Trp plays a significant role in the distal H-bonding, much more pronounced than in CCP. The relevance of these findings for the catalase activity of KatG is discussed in light of the complete loss of catalase activity in the distal Trp mutants.     

Role of proximal methionine residues in Leishmania major peroxidase

The active site architecture of Leishmania major peroxidase (LmP) is very similar with both cytochrome c peroxidase and ascorbate peroxidase. We utilized point mutagenesis to investigate if the conserved proximal methionine residues (Met248 and Met249) in LmP help in controlling catalysis. Steady-state kinetics of methionine mutants shows that ferrocytochrome c oxidation is <2% of wild type levels without affecting the second order rate constant of first phase of Compound I formation, while the activity toward a small molecule substrate, guaiacol or iodide, increases. Our diode array stopped-flow spectral studies show that the porphyrin π-cation radical of Compound I in mutant LmP is more stable than wild type enzyme. These results suggest that the electronegative sulfur atoms of the proximal pocket are critical factors for controlling the location of a stable Compound I radical in heme peroxidases and are important in the oxidation of ferrocytochrome c.     

The crystal structure of lignin peroxidase at 1.70 A resolution reveals a hydroxy group on the cbeta of tryptophan 171: a novel radical site formed during the redox cycle

The crystal structure of lignin peroxidase (LiP) from the white rot fungus Phanerochaete chrysosporium was refined to an R-factor of 16.2 % utilizing synchrotron data in the resolution range from 10 to 1.7 A. The final model comprises all 343 amino acid residues, 370 water molecules, the heme, four carbohydrates, and two calcium ions. Lignin peroxidase shows the typical peroxidase fold and the heme has a close environment as found in other peroxidases. During refinement of the LiP model an unprecedented modification of an amino acid was recognized. The surface residue tryptophan 171 in LiP is stereospecifically hydroxylated at the Cbeta atom due to an autocatalytic process. We propose that during the catalytic cycle of LiP a transient radical at Trp171 occurs that is different from those previously assumed for this type of peroxidase. Recently, the existence of a second substrate-binding site centered at Trp171 has been reported, by us which is different from the "classical heme edge" site found in other peroxidases. Here, we report evidence for a radical formation at Trp171 using spin trapping, which supports the concept of Trp171 being a redox active amino acid and being involved in the oxidation of veratryl alcohol. On the basis of our current model, an electron pathway from Trp171 to the heme is envisaged, relevant for the oxidation of veratryl alcohol and possibly lignin. Beside the opening leading to the heme edge, which can accommodate small aromatic substrate molecules, a smaller channel giving access to the distal heme pocket was identified that is large enough for molecules such as hydrogen peroxide. Furthermore, it was found that in LiP the bond between the heme iron and the Nepsilon2 atom of the proximal histidine residue is significantly longer than in cytochrome c peroxidase (CcP). The weaker Fe-N bond in LiP renders the heme more electron deficient and destabilizes high oxidation states, which could explain the higher redox potential of LiP as compared to CcP.     

Role of tryptophan-208 residue in cytochrome c oxidation by ascorbate peroxidase from Leishmania major-kinetic studies on Trp208Phe mutant and wild type enzyme

Ascorbate peroxidase from L. Major (LmAPX) is a functional hybrid between cytochrome c peroxidase (CCP) and ascorbate peroxidase (APX). We utilized point mutagenesis to investigate if a conserved proximal tryptophan residue (Trp208) among Class I peroxidase helps in controlling catalysis. The mutant W208F enzyme had no effect on both apparent dissociation constant of the enzyme-cytochrome c complex and K(m) value for cytochrome c indicating that cytochrome c binding affinity to the enzyme did not alter after mutation. Surprisingly, the mutant was 1000 times less active than the wild type in cytochrome c oxidation without affecting the second order rate constant of compound I formation. Our diode array stopped-flow spectral studies showed that the substrate unbound wild type enzyme reacts with H(2)O(2) to form compound I (compound II type spectrum), which was quite different from that of compound I in W208F mutant as well as horseradish peroxidase (HRP). The spectrum of the compound I in wild type LmAPX showed a red shift from 409 nm to 420 nm with equal intensity, which was broadly similar to those of known Trp radical. In case of compound I for W208F mutant, the peak in the Soret region was decreased in heme intensity at 409 nm and was not shifted to 420 nm suggesting this type of spectrum was similar to that of the known porphyrin pi-cation radical. In case of an enzyme-H(2)O(2)-ascorbate system, the kinetic for formation and decay of compound I and II of a mutant enzyme was almost identical to that of a wild type enzyme. Thus, the results of cytochrome c binding, compound I formation rate and activity assay suggested that Trp208 in LmAPX was essential for electron transfer from cytochrome c to heme ferryl but was not indispensable for ascorbate or guaiacol oxidation.     

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.     

The tuberculosis prodrug isoniazid bound to activating peroxidases

Isoniazid (INH, isonicotinic acid hydrazine) is one of only two therapeutic agents effective in treating tuberculosis. This prodrug is activated by the heme enzyme catalase peroxidase (KatG) endogenous to Mycobacterium tuberculosis but the mechanism of activation is poorly understood, in part because the binding interaction has not been properly established. The class I peroxidases ascorbate peroxidase (APX) and cytochrome c peroxidase (CcP) have active site structures very similar to KatG and are also capable of activating isoniazid. We report here the first crystal structures of complexes of isoniazid bound to APX and CcP. These are the first structures of isoniazid bound to any activating enzymes. The structures show that isoniazid binds close to the delta-heme edge in both APX and CcP, although the precise binding orientation varies slightly in the two cases. A second binding site for INH is found in APX at the gamma-heme edge close to the established ascorbate binding site, indicating that the gamma-heme edge can also support the binding of aromatic substrates. We also show that in an active site mutant of soybean APX (W41A) INH can bind directly to the heme iron to become an inhibitor and in a different mode when the distal histidine is replaced by alanine (H42A). These structures provide the first unambiguous evidence for the location of the isoniazid binding site in the class I peroxidases and provide rationalization of isoniazid resistance in naturally occurring KatG mutant strains of M. tuberculosis.     

Mechanisms of compound I formation in heme peroxidases

The formation of compound I is the first step in the reaction mechanism of plant heme peroxidases. This intermediate stores two oxidizing equivalents from hydrogen peroxide as an oxyferryl iron center and a radical, either on the porphyrin ring or on a tryptophan residue. Site-directed mutagenesis has proved to be a most useful tool for the identification of the intermediates involved and the resulting nature of the compound I formed. Although there is no doubt that an acid-base mechanism operates in heme peroxidase during the formation of compound I, the roles of several distal pocket residues are currently the subject of intensive research. It is now generally accepted that the conserved distal histidine in the active site of heme peroxidases is the acid-base catalyst that promotes the heterolytic cleavage of hydrogen peroxide. Other residues, such as the distal arginine and asparagine, participate in a range of roles assisting catalysis by the distal histidine. Recent advances in the elucidation of the mechanism at the molecular level are discussed. Another aspect related to the nature of compound I is the location of the radical center. Novel radical species have been detected in the reactions of ascorbate peroxidase, lignin peroxidase and several mutants of horseradish peroxidase. Detailed kinetic and spectroscopic studies of these radical species have provided important insights about the factors that control porphyrin-protein radical exchange. The wide range of data being obtained on compound I will lead to an understanding of its vital function in peroxidase catalysis and the physiological roles played by these enzymes.     

Engineering the proximal heme cavity of catalase-peroxidase

Catalase-peroxidases (KatGs) are prokaryotic heme peroxidases with homology to yeast cytochrome c peroxidase (CCP) and plant ascorbate peroxidases (APXs). KatGs, CCP and APXs contain identical amino acid triads in the heme pocket (distal Arg/Trp/His and proximal His/Trp/Asp), but differ dramatically in their reactivities towards hydrogen peroxide and various one-electron donors. Only KatGs have high catalase activity in addition to a peroxidase activity of broad specificity. Here, we investigated the effect of mutating the conserved proximal triad on KatG catalysis. With the exception of W341F, all variants (H290Q, W341A, D402N, D402E) exhibited a catalase activity <1% of wild-type KatG and spectral properties indicating alterations in heme coordination and spin states. Generally, the peroxidase activity was much less effected by these mutations. Compared with wild-type KatG the W341F variant had a catalase and halogenation activity of about 40% and an even increased overall peroxidase activity. This variant, for the first time, allowed to monitor the hydrogen peroxide mediated transitions of ferric KatG to compound I and back to the resting enzyme. Compound I reduction by aromatic one-electron donors (o-dianisidine, pyrogallol, aniline) was not influenced by exchanging Trp by Phe. The findings are discussed in comparison with the data known from CCP and APX and a reaction mechanism for the multifunctional activity of the W341F variant is suggested.     

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.     

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.     

Characterization of the hydrogen peroxide-enzyme reaction for two cytochrome c peroxidase mutants

The bimolecular reaction between Escherichia coli-produced cytochrome-c peroxidase (CcP(MI)) and hydrogen peroxide is identical to that of native yeast cytochrome-c peroxidase (CcP) and hydrogen peroxide in the neutral pH region. Both enzymes have pH-independent bimolecular rate constants of 46 microM-1.s-1 for the reaction with hydrogen peroxide. A second mutant enzyme, E. coli-produced cytochrome-c peroxidase mutant with phenylalanine at position 191 (CcP(MI, F191)), has a pH-independent bimolecular rate constant for the hydrogen peroxide reaction of 65 microM-1.s-1, 40% larger than for CcP or CcP(MI). The initial peroxide-oxidation product of CcP(MI, F191) is an oxyferryl porphyrin pi-cation radical intermediate in contrast to the oxyferryl amino-acid radical intermediate formed upon oxidation of CcP or CcP(MI) with hydrogen peroxide. The reactions of all three enzymes with hydrogen peroxide are pH-dependent in KNO3-containing buffers. The reactions are influenced by an ionizable group, which has an apparent pKa of 5.4 in all three enzymes. The enzymes react with hydrogen peroxide when the ionizable group is unprotonated. Both CcP(MI) and CcP(MI, F191) have slightly smaller pH stability regions compared to CcP as assessed by the hydrogen peroxide titer and spectral analysis. The alteration in structural stability must be attributed to differences in the primary sequence between CcP and CcP(MI) which occur at positions -2, -1, 53 and 152.     

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?     

Effect of active site and surface mutations on the reduction potential of yeast cytochrome c peroxidase and spectroscopic properties of the oxidized and reduced enzyme

The reduction potentials of 22 yeast cytochrome c peroxidase (CcP) mutants were determined at pH 7.0 in order to determine the effect of both heme pocket and surface mutations on the Fe(III)/Fe(II) redox couple of CcP, as well as to determine the range in redox potentials that could be obtained through point mutations in the enzyme. Spectroscopic properties of the Fe(III) and Fe(II) forms of the mutant enzymes are also reported. The mutations include variants in the distal and proximal heme pockets as well as on the enzyme surface and involve single, double, and triple point mutations. A spectrochemical redox titration technique used in this study gave an E(0') value of -189 mV for yeast CcP compared to a previously reported value of -194 mV determined by potentiometry [C.W. Conroy, P. Tyma, P.H. Daum, J.E. Erman, Biochim. Biophys. Acta 537 (1978) 62-69]. Both positive and negative shifts in the reduction potential from that of the wild-type enzyme were observed, spanning a range of 113 mV. The His-52-->Asn mutation gave the most negative potential, -259 mV, while a triple mutant in which the three distal pocket residues, Arg-48, Trp-51, and His-52, were all converted to leucine residues gave the most positive potential, -146 mV.     

Apolar distal pocket mutants of yeast cytochrome c peroxidase: Hydrogen peroxide reactivity and cyanide binding of the TriAla,TriVal, and TriLeu variants

Three yeast cytochrome c peroxidase (CcP) variants with apolar distal heme pockets have been constructed. The CcP variants have Arg48, Trp51, and His52 mutated to either all alanines, CcP(triAla), all valines, CcP(triVal), or all leucines, CcP(triLeu). The triple mutants have detectable enzymatic activity at pH 6 but the activity is less than 0.02% that of wild-type CcP. The activity loss is primarily due to the decreased rate of reaction between the triple mutants and H₂O₂ compared to wild-type CcP. Spectroscopic properties and cyanide binding characteristics of the triple mutants have been investigated over the pH stability region of CcP, pH 4 to 8. The absorption spectra indicate that the CcP triple mutants have hemes that are predominantly five-coordinate, high-spin at pH 5 and six-coordinate, low-spin at pH 8. Cyanide binding to the triple mutants is biphasic indicating that the triple mutants have two slowly-exchanging conformational states with different cyanide affinities. The binding affinity for cyanide is reduced at least two orders of magnitude in the triple mutants compared to wild-type CcP and the rate of cyanide binding is reduced by four to five orders of magnitude. Correlation of the reaction rates of CcP and 12 distal pocket mutants with H₂O₂ and HCN suggests that both reactions require ionization of the reactants within the distal heme pocket allowing the anion to bind the heme iron. Distal pocket features that promote substrate ionization (basic residues involved in base-catalyzed substrate ionization or polar residues that can stabilize substrate anions) increase the overall rate of reaction with H₂O₂ and HCN while features that inhibit substrate ionization slow the reactions.