Photoinduced electron transfer between cytochrome c peroxidase and horse cytochrome c labeled at specific lysines with (dicarboxybipyridine)(bisbipyridine)ruthenium(II)

The reactions of yeast cytochrome c peroxidase with horse cytochrome c derivatives labeled at specific lysine amino groups with (dicarboxybipyridine)(bisbipyridine)ruthenium(II) [Ru(II)] were studied by flash photolysis. All of the derivatives formed complexes with cytochrome c peroxidase compound I (CMPI) at low ionic strength (2 mM sodium phosphate, pH 7). Excitation of Ru(II) to Ru(II*) with a short laser flash resulted in electron transfer to the ferric heme group in cytochrome c, followed by electron transfer to the radical site in CMPI. This reaction was biphasic and the rate constants were independent of CMPI concentration, indicating that both phases represented intracomplex electron transfer from the cytochrome c heme to the radical site in CMPI. The rate constants of the fast phase were 5200, 19,000, 55,000, and 14,300 s-1 for the derivatives modified at lysines 13, 25, 27, and 72, respectively. The rate constants of the slow phase were 260, 520, 200, and 350 s-1 for the same derivatives. These results suggest that there are two binding orientations for cytochrome c on CMPI. The binding orientation responsible for the fast phase involves a geometry that supports rapid electron transfer, while that for the slow phase allows only slow electron transfer. Increasing the ionic strength up to 40 mM increased the rate constant of the slow phase and decreased that of the fast phase. A single intracomplex electron transfer phase with a rate constant of 2800 s-1 was observed for the lysine 72 derivative at this ionic strength. When a series of light flashes was used to titrate CMPI to CMPII, the reaction between the cytochrome c derivative and the Fe(IV) site in CMPII was observed. The rate constants for this reaction were 110, 250, 350, and 140 s-1 for the above derivatives measured in low ionic strength buffer.     

Kinetics of reaction of (nitrotyrosyl)cytochrome c with ligands.

The reaction of [nitrotyrosyl]cytochrome c with ligands was studied by stopped-flow techniques. At pH 7.0 the reaction with imidazole shows two distinct phases, one fast phase being concentration-dependent and a slow phase being concentration-independent. The results are consistent with the existence of two forms of [nitrotyrosyl]cytochrome c in solutions [Schejter et al. (1970) Biochemistry 9, 5118-5122]; form I, the smaller fraction, seems to be responsible for the slow first-order process.     

Chromous ion reduction of mammalian cytochrome oxidase and some of its derivatives.

The reduction of cytochrome c oxidase by Cr2+, followed by means of stopped-flow spectrophotometry, exhibits two phases: the faster Cr2+-concentration-dependent reaction has an initial rate constant of 1.1 X 10(4)M-1-S-1, but reaches a rate limit at high concentration of reductant; the slower phase is concentration-independent with a rate of 0.3S-1. The activation energies of the fast and the slow processes are 35 and 71 kJ/mol respectively. The reduction kinetics of the mixed-valence CO complex and the cyanide-inhibited enzyme were compared with those of the fully oxidized forms: both the liganded species have a fast phase identical with that found in the oxidized oxidase. A comparison of the kinetic difference spectra obtained for the fast phase of reduction of oxidized oxidase with those obtained on reduction of the liganded species suggests that the rapid phase arises from the reduction ofhaem a, and the slow phase from the reduction of haem a3.     

Role of specific lysine residues in binding cytochrome c2 to the Rhodobacter sphaeroides reaction center in optimal orientation for rapid electron transfer

The role of specific lysine residues in facilitating electron transfer from Rhodobacter sphaeroides cytochrome c2 to the Rb. sphaeroides reaction center was studied by using six cytochrome c2 derivatives each labeled at a single lysine residue with a carboxydinitrophenyl group. The reaction of native cytochrome c2 at low ionic strength has a fast phase with a half-time of 0.6 microseconds that has been assigned to the reaction of bound cytochrome c2 [Overfield, R.E., Wraight, C.A., & DeVault, D. (1979) FEBS Lett. 105, 137]. Modification of lysine-55 did not affect the half-time of this phase but decreased the apparent binding constant by a factor of 2. The derivatives modified at lysines-10, -88, -95, -97, -99, -105, and -106 surrounding the heme crevice did not show any detectable fast phase but only slow second-order phases due to the reaction of solution cytochrome c2. These lysines thus appear to be involved in binding cytochrome c2 to the reaction center in an optimal orientation for electron transfer. The involvement of lysines-95 and -97 is especially significant, since they are located in an extra loop comprising residues 89-98 that is not present in eukaryotic cytochrome c. The reactions of horse cytochrome c derivatives modified at single lysine amino groups with trifluoroacetyl or [(trifluoromethyl)phenyl]carbamoyl were also studied. The derivatives modified at lysines-22, -55, -88, and -99 far removed from the heme crevice had nearly the same half-times for the fast phase as native cytochrome c, 6 microseconds.(ABSTRACT TRUNCATED AT 250 WORDS)     

The reaction of trimethylamine dehydrogenase with trimethylamine

The reductive half-reaction of trimethylamine dehydrogenase with its physiological substrate trimethylamine has been examined by stopped-flow spectroscopy over the pH range 6.0-11.0, with attention focusing on the fastest of the three kinetic phases of the reaction, the flavin reduction/substrate oxidation process. As in previous work with the slow substrate diethylmethylamine, the reaction is found to consist of three well resolved kinetic phases. The observed rate constant for the fast phase exhibits hyperbolic dependence on the substrate concentration with an extrapolated limiting rate constant (klim) greater than 1000 s-1 at pH above 8.5, 10 degrees C. The kinetic parameter klim/Kd for the fast phase exhibits a bell-shaped pH dependence, with two pKa values of 9.3 +/- 0.1 and 10. 0 +/- 0.1 attributed to a basic residue in the enzyme active site and the ionization of the free substrate, respectively. The sigmoidal pH profile for klim gives a single pKa value of 7.1 +/- 0. 2. The observed rate constants for both the intermediate and slow phases are found to decrease as the substrate concentration is increased. The steady-state kinetic behavior of trimethylamine dehydrogenase with trimethylamine has also been examined, and is found to be adequately described without invoking a second, inhibitory substrate-binding site. The present results demonstrate that: (a) substrate must be protonated in order to bind to the enzyme; (b) an ionization group on the enzyme is involved in substrate binding; (c) an active site general base is involved, but not strictly required, in the oxidation of substrate; (d) the fast phase of the reaction with native enzyme is considerably faster than observed with enzyme isolated from Methylophilus methylotrophus that has been grown up on dimethylamine; and (e) a discrete inhibitory substrate-binding site is not required to account for excess substrate inhibition, the kinetic behavior of trimethylamine dehydrogenase can be readily explained in the context of the known properties of the enzyme.     

Kinetic studies on mammalian cytochrome c modified with 2-hydroxy-5-hydroxy-5-nitrobenzyl bromide.

The reduction of 2-hydroxy-5-nitrobenzyl tryptophyl cytochrome c by the chromous ion was studied by stopped-flow techniques. At pH6.5 the reduction of 2-hydroxy-5-nitrobenzyl tryptophyl cytochrome c is complex, showing the presence of three distinct phases. Two chromium concentration-dependent phases are observed (1.1 X 10(5) M-1-S-1, phase 1; 1.25 X 10(4)M-1-S-1, phase 2) and one slow first-order process (0.25S-1, phase 3). A comparison of the static and kinetic difference spectra, along with the data from the reduction of the reoxidized reduced protein, suggests that the slow chromium concentration-independent phase is due to a slow conformational event after fast reduction of the NO2 group. The rates of the chromium concentration-dependent phases show a marked variation with pH above 7.5. The activation energies for the three processes were also measured at 33.2, 38.6 and 69.7 kJ-mol-1 for phases 1, 2 and 3 respectively. The reaction of reduced 2-hydroxy-5-nitrobenzyl tryptophyl cytochrome c with CO was foollowed by means of both stopped-flow and flash photolysis. The combination with CO at pH 6.8 as measured in stopped-flow experiments showed two phases, one CO-dependent phase (phase 2, 2.4 X 10(2)M-1-S-1) and one CO-independent phase (phase 1, 0.015S-1). Investigation of the pH-dependence of the phases showed both the rates and amounts of each phase to be pH-invariant. CO recombination, after photolytic removal, was found to be biphasic; a CO-dependent phase (phase 2, 2.4 X 10(2)M-1-S-1) and a CO-independent phase (phase 1, 1.0s-1) were observed. A tentative model which can accommodate these observations is proposed.     

Effect of changing the detergent bound to bovine cytochrome c oxidase upon its individual electron-transfer steps

The influence of the detergent environment upon individual electron-transfer rates of cytochrome c oxidase was investigated by stopped-flow spectrophotometry. The effects of three detergents were studied: lauryl maltoside, which supports a high turnover number (TN = 350 s-1), n-dodecyl octaethylene glycol monoether (C12E8), which supports an intermediate TN (150 s-1), and Triton X-100 in which oxidase is nearly inactive (TN = 2-3 s-1). Under limited turnover conditions (cytochrome c:cytochrome c oxidase ratio = 1:1 to 8:1), the rate of oxidation of cytochrome c was measured and compared with the fast reduction of cytochrome a and its relatively slow reoxidation. Two reducing equivalents of cytochrome c were rapidly oxidized in a burst phase; the remaining two to six equivalents were oxidized more slowly, concurrent with the reoxidation of cytochrome a; i.e., the percent reduced cytochrome a reflects the percent reduced cytochrome c. With the resting enzyme, the bimolecular reaction between reduced cytochrome c and cytochrome a was rapid, was insensitive to the detergent environment, and was not the rate-limiting step in the presence of any detergent. The rate of internal electron transfer from cytochrome a to cytochrome a3 in the resting enzyme was slow and only slightly affected by the detergent environment: 1.0-1.1 s-1 in Triton X-100, 5-7 s-1 in C12E8, and 5-12 s-1 in lauryl maltoside. With the pulsed enzyme, the intramolecular electron transfer between cytochrome a and cytochrome a3 increased 4-5-fold in the lauryl maltoside enzyme but did not increase in the Triton X-100 enzyme (intermediate values were obtained with the C12E8 enzyme). We conclude that cytochrome c oxidase acquires the pulsed conformation only in those detergents that support high TN's, e.g., lauryl maltoside and C12E8, but it is locked in the resting conformation in those detergents which result in low TN's, e.g., Triton X-100.     

Conformational substates of bovine heart cytochrome c oxidase: the modified Volpe-Caughey variant

Kinetic and equilibrium binding studies using optically correlated, quantitative electron paramagnetic resonance (EPR) spectroscopy are reported for the reaction of a modified Volpe-Caughey preparation of bovine heart cytochrome c oxidase with anionic (F-, CN-) and gaseous (NO) ligands. A fast phase of cyanide and fluoride ligation can be attributed to an EPR-silent conformer(s), while the slow and medium phases of cyanide binding are correlated with the g = 12 conformer(s). Using dioxygen or ferricyanide, it is possible to modulate reciprocally the relative amounts of these two species, that together account for at least 95% of the active-site conformers of the resting form of the enzyme.     

High-pressure stopped-flow spectrometry at low temperatures

A stopped-flow instrument operating over temperature and pressure ranges of +30 to -20 degrees C and 10(-3) to 2 kbar , respectively, is described. The system has been designed so that it can be easily interfaced with many commercially available spectrophotometers of fast response time, with the aid of quartz fiber optics. The materials used for the construction are inert, metal free and the apparatus has proven to be leak free at temperatures as low as -20 degrees C under a pressure of 2 kbar . The performance of the instrument was tested by measuring the rate of reduction of cytochrome c with sodium dithionite and the 2,6-dichloroindophenol/ascorbate reaction. The dead time of the system has been evaluated to be 20, 50, and congruent to 100 ms in water at 20 degrees C, in 40% ethylene glycol/water, and at 20 degrees C and -15 degrees C, respectively. These values are rather pressure independent up to 2 kbar . Application of the bomb was demonstrated using the cytochrome c peroxidase/ethyl peroxide reaction. This process occurred in two phases and an increase in pressure decreased the rates of reactions indicating two positive volumes of activation (delta V not equal to app (fast) = 9.2 +/- 1.5 ml X mol-1; delta V not equal to app (slow) = 14 +/- 1.5 ml X mol-1, temperature 2 degrees C). The data suggest that the fast reaction could involve a hydrophobic bond, whereas the slow process could be associated with a stereochemical change of the protein. The problem of temperature equilibrium for high-pressure experiments is also discussed.     

Reactions of mercaptans with cytochrome c oxidase and cytochrome c

1. The steady-state oxidation of ferrocytochrome c by dioxygen catalyzed by cytochrome c oxidase, is inhibited non-competitively towards cytochrome c by methanethiol, ethanethiol, 1-propanethiol and 1-butanethiol with Ki values of 4.5, 91, 200 and 330 microM, respectively. 2. The inhibition constant Ki of ethanethiol is found to be constant between pH 5 and 8, which suggests that only the neutral form of the thiol inhibits the enzyme. 3. The absorption spectrum of oxidized cytochrome c oxidase in the Soret region shows rapid absorbance changes upon addition of ethanethiol to the enzyme. This process is followed by a very slow reduction of the enzyme. The fast reaction, which represents a binding reaction of ethanethiol to cytochrome c oxidase, has a k1 of 33 M-1 . s-1 and a dissociation constant Kd of 3.9 mM. 4. Ethanethiol induces fast spectral changes in the absorption spectrum of cytochrome c, which are followed by a very slow reduction of the heme. The rate constant for the fast ethanethiol reaction representing a bimolecular binding step is 50 M-1 . s-1 and the dissociation constant is about 2 mM. Addition of up to 25 mM ethanethiol to ferrocytochrome c does not cause spectral changes. 5. EPR (electron paramagnetic resonance) spectra of cytochrome c oxidase, incubated with methanethiol or ethanethiol in the presence of cytochrome c and ascorbate, show the formation of low-spin cytochrome alpha 3-mercaptide compounds with g values of 2.39, 2.23, 1.93 and of 2.43, 2.24, 1.91, respectively.     

A copper protein and a cytochrome bind at the same site on bacterial cytochrome c peroxidase

Pseudoazurin binds at a single site on cytochrome c peroxidase from Paracoccus pantotrophus with a K(d) of 16.4 microM at 25 degrees C, pH 6.0, in an endothermic reaction that is driven by a large entropy change. Sedimentation velocity experiments confirmed the presence of a single site, although results at higher pseudoazurin concentrations are complicated by the dimerization of the protein. Microcalorimetry, ultracentrifugation, and (1)H NMR spectroscopy studies in which cytochrome c550, pseudoazurin, and cytochrome c peroxidase were all present could be modeled using a competitive binding algorithm. Molecular docking simulation of the binding of pseudoazurin to the peroxidase in combination with the chemical shift perturbation pattern for pseudoazurin in the presence of the peroxidase revealed a group of solutions that were situated close to the electron-transferring heme with Cu-Fe distances of about 14 A. This is consistent with the results of (1)H NMR spectroscopy, which showed that pseudoazurin binds closely enough to the electron-transferring heme of the peroxidase to perturb its set of heme methyl resonances. We conclude that cytochrome c550 and pseudoazurin bind at the same site on the cytochrome c peroxidase and that the pair of electrons required to restore the enzyme to its active state after turnover are delivered one-by-one to the electron-transferring heme.     

Presteady-state and steady-state kinetic properties of human cytochrome c oxidase. Identification of rate-limiting steps in mammalian cytochrome c oxidase.

Human cytochrome c oxidase was purified in a fully active form from heart and skeletal muscle. The enzyme was selectively solubilised with octylglucoside and KCl from submitochondrial particles followed by ammonium sulphate fractionation. The presteady-state and steady-state kinetic properties of the human cytochrome c oxidase preparations with either human cytochrome c or horse cytochrome c were studied spectrophotometrically and compared with those of bovine heart cytochrome c oxidase. The interaction between human cytochrome c and human cytochrome c oxidase proved to be highly specific. It is proposed that for efficient electron transfer to occur, a conformational change in the complex is required, thereby shifting the initially unfavourable redox equilibrium. The very slow presteady-state reaction between human cytochrome c oxidase and horse cytochrome c suggests that, in this case, the conformational change does not occur. The proposed model was also used to explain the steady-state kinetic parameters under various conditions. At high ionic strength (I = 200 mM, pH 7.4), the kcat was highly dependent on the type of oxidase and it is proposed that the internal electron transfer is the rate-limiting step. The kcat value of the 'high-affinity' phase, observed at low ionic strength (I = 18 mM, pH 7.4), was determined by the cytochrome c/cytochrome c oxidase combination applied, whereas the Km was highly dependent only on the type of cytochrome c used. Our results suggest that, depending on the cytochrome c/cytochrome c oxidase combination, either the dissociation of ferricytochrome c or the internal electron transfer is the rate-limiting step in the 'high-affinity' phase at low ionic strength. The 'low-affinity' kcat value was not only determined by the type of oxidase used, but also by the type of cytochrome c. It is proposed that the internal electron-transfer rate of the 'low-affinity' reaction is enhanced by the binding of a second molecule of cytochrome c.     

猪心乳酸脱氢酶(H_4)在盐酸胍变性过程中失活与内源荧光变化速度的比较

本文比较了大然乳酸脱氢酶和硫酸铵稳定的乳酸脱氢酶在盐酸胍性过程式中失活与内源荧光的变化速度.酶失活表现为三相反应,即极快相,其速度常数用停流装置也无法测定;快相和慢相,1M胍变性时,此二相的一级反应速度常数分别为2.7×10~(-3)秒~(-1)和4.17×10~(-4)秒~(-1).在2M硫酸铵存在条件下,用2M胍更性时,快相和慢相的一极反应速度常数分别为6.16×10~(-3)秒~(-1)和1.88×10~(-3)秒~(-1).内源荧光强度的变化表现为二相反应,即极快相,相当酶失活的极快相,但变化幅度远小于酶失活的变化幅度;快相,相当于酶失活的快相,其速度常数为失活速度常数的1/3倍.上述结果表明,类似肌酸激酶,乳酸脱氢酶的失活速度快于酶分子整体构象的变化,相对于整个酶分子来说,活性中心的构象变化对变性剂更加敏感.     

Reaction of dioxygen with cytochrome c oxidase reduced to different degrees: indications of a transient dioxygen complex with copper-B.

The reactions of the fully reduced, three-electron-reduced, and mixed-valence cytochrome oxidase with molecular oxygen have been followed in flow-flash experiments, starting from the CO complexes, at 445 and 830 nm at pH 7.4 and 25 degrees C. With the fully reduced and the three-electron-reduced enzyme, four kinetic phases with rate constants in the range from 1 x 10(5) to 10(3) s-1 can be observed. The initial fast phase is associated with an absorbance increase at 830 nm. This is followed by an absorbance decrease (2.8 x 10(4) s-1), the amplitude of which increases with the degree of reduction of the oxidase. The third phase (6 x 10(3) s-1) displays the largest absorbance change at both wavelengths in the fully reduced enzyme and is not seen in the mixed-valence oxidase at 830 nm; a change with opposite sign but with a similar rate constant is found at 445 nm in this enzyme form. The slowest phase (10(3) s-1) is also largest in the fully reduced oxidase and not seen in the mixed-valence enzyme. It is suggested that O2 initially binds to reduced CuB and is then transferred to cytochrome a3 before electron transfer from cytochrome a/CuA takes place. The fast oxidation of cytochrome a seen with the fully reduced enzyme is suggested not to occur during natural turnover. A reaction cycle for the complete turnover of the enzyme is presented. In this cycle, the oxidase oscillates between electron input and output states of the proton pump, characterized by cytochrome a having a high and a low reduction potential, respectively.     

Essential arginine residues of creatine kinase from beef heart mitochondria

Creatine kinase from beef heart mitochondria is inactivated by 2,3-butanedione. The kinetics of inactivation of the mitochondrial enzyme is biphasic with a bend at a point corresponding to 50% inactivation. The inactivation rate constants of the first fast and the second slow phases of the reaction differ by one order of magnitude, thus suggesting the existence of two types of arginine residues, i.e. "fast" and "slow" ones, with different reactivities. The inactivation rate constant of the slow phase is very close to that for cytoplasmic creatine kinase. At saturating concentrations MgATP and MgADP afford complete protection of the slow phase of inactivation. It is assumed that the "slow" arginine is involved in the binding of metal-nucleotide substrates in the enzyme active center.     

Reduction of cytochrome c peroxidase compounds I and II by ferrocytochrome c. A stopped-flow kinetic investigation

The oxidation of yeast cytochrome c peroxidase by hydrogen peroxide produces a unique enzyme intermediate, cytochrome c peroxidase Compound I, in which the ferric heme iron has been oxidized to an oxyferryl state, Fe(IV), and an amino acid residue has been oxidized to a radical state. The reduction of cytochrome c peroxidase Compound I by horse heart ferrocytochrome c is biphasic in the presence of excess ferrocytochrome c as cytochrome c peroxidase Compound I is reduced to the native enzyme via a second enzyme intermediate, cytochrome c peroxidase Compound II. In the first phase of the reaction, the oxyferryl heme iron in Compound I is reduced to the ferric state producing Compound II which retains the amino acid free radical. The pseudo-first order rate constant for reduction of Compound I to Compound II increases with increasing cytochrome c concentration in a hyperbolic fashion. The limiting value at infinite cytochrome c concentration, which is attributed to the intracomplex electron transfer rate from ferrocytochrome c to the heme site in Compound I, is 450 +/- 20 s-1 at pH 7.5 and 25 degrees C. Ferricytochrome c inhibits the reaction in a competitive manner. The reduction of the free radical in Compound II is complex. At low cytochrome c peroxidase concentrations, the reduction rate is 5 +/- 3 s-1, independent of the ferrocytochrome c concentration. At higher peroxidase concentrations, a term proportional to the square of the Compound II concentration is involved in the reduction of the free radical. Reduction of Compound II is not inhibited by ferricytochrome c. The rates and equilibrium constant for the interconversion of the free radical and oxyferryl forms of Compound II have also been determined.     

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.     

Reversible acidic-alkaline transition of the carbon monoxide complex of cytochrome c peroxidase

The Soret absorption band of the ferrous carbon monoxide (CO) complex of cytochrome c peroxidase exhibited a blue shift from 423.7 to 420 nm upon an increase in pH from 6.5 to 8.5. The spectral change was reversible with an isosbestic point at 422 nm. The pH dependence of this spectral change gave a sigmoidal curve fitted well to a theoretical curve of a cooperative release of two protons with a pK value of 7.5, indicating the existence of the acidic and alkaline forms of the ferrous CO enzyme. Upon irradiation of light flash (100 J of power and 30-microseconds), the heme-bound CO was readily dissociated in both acidic and alkaline forms with a quantum yield of approximately unity. On the other hand, the rate of recombination of the dissociated CO with the heme iron was significantly different between these two forms; the recombination rate constants were 1.1 X 10(3) and 3.0 X 10(4) M-1 S-1 at 25 degrees C for the acidic and alkaline forms, respectively. At intermediate pH values, kinetics of recombination were biphasic, consisting of the slow and fast processes with the appropriate rate constants mentioned above. When the fraction of the fast process was plotted against pH, the pH profile coincided with the spectrophotometric pH titration curve described above. Thus, it was concluded that the acidic and alkaline forms of the enzyme were responsible for the slow and fast processes, respectively. In infrared spectroscopy, the acidic form showed a narrow CO stretching band at 1922 cm-1 with a half-band width of 12.5 cm-1, while the alkaline form exhibited a broad CO-stretching band at 1948 cm-1 with a half-band width of 33 cm-1. Significance of these results are discussed in relation to the structure of the heme vicinity on the CO complex of cytochrome c peroxidase.     

Effect of Asp-235-->Asn substitution on the absorption spectrum and hydrogen peroxide reactivity of cytochrome c peroxidase.

The spectroscopic properties of a mutant cytochrome c peroxidase, in which Asp-235 has been replaced by an asparagine residue, were examined in both nitrate and phosphate buffers between pH 4 and 10.5. The spin state of the enzyme is pH dependent, and four distinct spectroscopic species are observed in each buffer system: a predominantly high-spin Fe(III) species at pH 4, two distinct low-spin forms between pH 5 and 9, and the denatured enzyme above pH 9.3. The spectrum of the mutant enzyme at pH 4 is dependent upon specific ion effects. Increasing the pH above 5 converts the mutant enzyme to a predominantly low-spin hydroxy complex. Subsequent conversion to a second low-spin form is essentially complete at pH 7.5. The second low-spin form has the distal histidine, His-52, coordinated to the heme iron. To evaluate the effect of the changes in coordination state upon the reactivity of the enzyme, the reaction between hydrogen peroxide and the mutant enzyme was also examined as a function of pH. The reaction of CcP(MI,D235N) with peroxide is biphasic. At pH 6, the rapid phase of the reaction can be attributed to the bimolecular reaction between hydrogen peroxide and the hydroxy-ligated form of the mutant enzyme. Despite the hexacoordination of the heme iron in this form, the bimolecular rate constant is approximately 22% that of pentacoordinate wild-type yeast cytochrome c peroxidase. The bimolecular reaction of the mutant enzyme with peroxide exhibits the same pH dependence in nitrate-containing buffers that has been described for the wild-type enzyme, indicating a loss of reactivity with the protonation of a group with an apparent pKa of 5.4. This observation eliminates Asp-235 as the source for this heme-linked ionization and strengthens the hypothesis that the pKa of 5.4 is associated with His-52. The slower phase of the reaction between peroxide and the mutant enzyme saturates at high peroxide concentration and is attributed to conversion of unreactive to reactive forms of the enzyme. The fraction of enzyme which reacts via the slow phase is dependent upon both pH and specific ion effects.     

The catalytic mechanism of Pseudomonas cytochrome c peroxidase

The catalytic mechanism of Pseudomonas cytochrome c peroxidase has been studied using rapid-scan spectrometry and stopped-flow measurements. The reaction of the totally ferric form of the enzyme with H₂O₂ was slow and the complex formed was inactive in the peroxidatic cycle, whereas partially reduced enzyme formed highly reactive intermediates with hydrogen peroxide. Rapid-scan spectrometry revealed two different spectral forms, one assignable to Compound I and the other to Compound II as found in the reaction cycle of other peroxidases. The formation of Compound I was rapid approaching that of diffusion control. The stoichiometry of the peroxidation reaction, deduced from the formation of oxidized electron donor, indicates that both the reduction of Compound I to Compound II and the conversion of Compound II to resting (partially reduced) enzyme are one-electron steps. It is concluded that the reaction mechanism generally accepted for peroxidases is applicable also to Pseudomonas cytochrome c peroxidase, the intramolecular source of one electron in Compound I formation, however, being reduced heme c.