Kinetic comparison of reduction and intramolecular electron transfer in milk xanthine oxidase and chicken liver xanthine dehydrogenase by laser flash photolysis

A comparative study using laser flash photolysis of the kinetics of reduction and intramolecular electron transfer among the redox centers of chicken liver xanthine dehydrogenase and of bovine milk xanthine oxidase is described. The photogenerated reductant, 5-deazariboflavin semiquinone, reacts with the dehydrogenase (presumably at the Mo center) in a second-order manner, with a rate constant (k = 6 x 10(7) M-1 s-1) similar to that observed with the oxidase [k = 3 x 10(7) M-1 s-1; Bhattacharyya et al. (1983) Biochemistry 22, 5270-5279]. In the case of the dehydrogenase, neutral FAD radical formation is found to occur by intramolecular electron transfer (kobs = 1600 s-1), presumably from the Mo center, whereas with the oxidase the flavin radical forms via a bimolecular process involving direct reduction by the deazaflavin semiquinone (k = 2 x 10(8) M-1 s-1). Biphasic rates of Fe/S center reduction are observed with both enzymes, which are due to intramolecular electron transfer (kobs approximately 100 s-1 and kobs = 8-11 s-1). Intramolecular oxidation of the FAD radical in each enzyme occurs with a rate constant comparable to that of the rapid phase of Fe/S center reduction. The methylviologen radical, generated by the reaction of the oxidized viologen with 5-deazariboflavin semiquinone, reacts with both the dehydrogenase and the oxidase in a second-order manner (k = 7 x 10(5) M-1 s-1 and 4 x 10(6) M-1 s-1, respectively). Alkylation of the FAD centers results in substantial alterations in the kinetics of the reaction of the viologen radical with the oxidase but not with the dehydrogenase. These results suggest that the viologen radical reacts directly with the FAD center in the oxidase but not in the dehydrogenase, as is the case with the deazaflavin radical. The data support the conclusion that the environments of the FAD centers differ in the two enzymes, which is in accord with other studies addressing this problem from a different perspective [Massey et al. (1989) J. Biol. Chem. 264, 10567-10573]. In contrast, the rate constants for intramolecular electron transfer among the Mo, FAD, and Fe/S centers in the two enzymes (where they can be determined) are quite similar.     

Laser flash photolysis studies of the reduction kinetics of NADPH:cytochrome P-450 reductase

The reduction kinetics of NADPH:cytochrome P-450 reductase have been investigated by the laser flash photolysis technique, using the semiquinone of 5-deazariboflavin (5-dRfH.) as the reductant. Transients observed at 470 nm at neutral pH indicated that the oxidized reductase was reduced via second-order kinetics with a rate constant of 6.8 X 10(7) M-1 s-1. The second-order rate constant corresponding to the formation of the protein-bound semiquinone (measured at 585 nm) was essentially the same as that obtained at 470 nm (7.1 X 10(7) M-1 s-1). Subsequent to this rapid formation of protein-bound semiquinone, a partial exponential decay was observed at 585 nm. The rate of this decay remained invariant with protein concentration between pH 5.0 and 7.0, and a first-order rate constant of 70 s-1 was obtained for this process. This is assigned to intramolecular electron transfer from FADH. to FMN. Prior reduction of the enzyme to the one-electron level led to a decrease in both the second-order rate constant for reduction (2 X 10(7) M-1 s-1) and the first-order intraflavin electron transfer rate constant (15 s-1). The protein-bound FAD moiety of FMN-depleted reductase was reduced by 5-dRfH. with a second-order rate constant that was identical with that observed with the native enzyme (6.9 X 10(7) M-1 s-1). However, with this species no significant decay of the FAD semiquinone was observed at 585 nm following its rapid formation, consistent with the above assignment of this kinetic process.(ABSTRACT TRUNCATED AT 250 WORDS)     

Electron transfer process in cytochrome bd-type ubiquinol oxidase from Escherichia coli revealed by pulse radiolysis

Cytochrome bd is a two-subunit ubiquinol oxidase in the aerobic respiratory chain of Escherichia coli and binds hemes b558, b595, and d as the redox metal centers. Taking advantage of spectroscopic properties of three hemes which exhibit distinct absorption peaks, we investigated electron transfer within the enzyme by the technique of pulse radiolysis. Reduction of the hemes in the air-oxidized, resting-state enzyme, where heme d exists in mainly an oxygenated form and partially an oxoferryl and a ferric low-spin forms, occurred in two phases. In the faster phase, radiolytically generated N-methylnicotinamide radicals simultaneously reduced the ferric hemes b558 and b595 with a second-order rate constant of 3 x 10(8) M-1 s-1, suggesting that a rapid equilibrium occurs for electron transfer between two b-type hemes long before 10 micros. In the slower phase, an intramolecular electron transfer from heme b to the oxoferryl and the ferric heme d occurred with the first-order rate constant of 4.2-5.6 x 10(2) s-1. In contrast, the oxygenated heme d did not exhibit significant spectral change. Reactions with the fully oxidized and hydrogen peroxide-treated forms demonstrated that the oxidation and/or ligation states of heme d do not affect the heme b reduction. The following intramolecular electron transfer transformed the ferric and oxoferryl forms of heme d to the ferrous and ferric forms, respectively, with the first-order rate constants of 3.4 x 10(3) and 5.9 x 10(2) s-1, respectively.     

Chromatium vinosum cytochrome c-552. Reduction by photoreduced flavins and intramolecular electron transfer

Cytochrome c-552 from Chromatium vinosum is an unusual heme protein in that it contains two hemes and one flavin per molecule. To investigate whether intramolecular electron transfer occurs in this protein, we have studied its reduction by external photoreduced flavin by using pulsed-laser excitation. This approach allows us to measure reduction kinetics on the mirosecond time scale. Both fully reduced lumiflavin and lumiflavin semiquinone radical reduce cytochrome c-552 with second-order rate constants of approximately 1.4 x 10(6) M-1s-1 and 1.9 x 10(8) M-1 s-1, respectively. Kinetic and spectral data and the results of similar studies with riboflavin indicate that both the flavin and heme moieties of cytochrome c-552 are reduced simultaneously on a millisecond time scale, with the transient formation of a protein-bound flavin anion radical. This is suggested to be due to rapid intramolecular electron transfer. Further, steric restrictions play an important role in the reduction reaction. Studies were conducted on the redox processes following photolysis of CO-ferrocytochrome c-552 in which the flavin was partly oxidized to resolve the kinetics of electron transfer between the heme and flavin of cytochrome c-552. Based on these results, we conclude that intramolecular electron transfer from ferrous heme to oxidized flavin occurs with a first-order rate constant of greater than 1.4 x 10(6) s-1.     

Laser flash photolysis study of intermolecular and intramolecular electron transfer in trimethylamine dehydrogenase

Laser flash photolysis has been used to investigate the kinetics of reduction of trimethylamine dehydrogenase by substoichiometric amounts of 5-deazariboflavin semiquinone, and the subsequent intramolecular electron transfer from the FMN cofactor to the Fe4S4 center. The initial reduction event followed second-order kinetics (k = 1.0 x 10(8) M-1 s-1 at pH 7.0 and 6.4 x 10(7) M-1 s-1 at pH 8.5) and resulted in the formation of the neutral FMN semiquinone and the reduced iron-sulfur cluster (in a ratio of approximately 1:3). Following this, a slower, protein concentration independent (and thus intramolecular) electron transfer was observed corresponding to FMN semiquinone oxidation and iron-sulfur cluster reduction (k = 62 s-1 at pH 7.0 and 30 s-1 at pH 8.5). The addition of the inhibitor tetramethylammonium chloride to the reaction mixture had no effect on these kinetic properties, suggesting that this compound exerts its effect on the reduced form of the enzyme. Treatment of the enzyme with phenylhydrazine, which introduces a phenyl group at the 4a-position of the FMN cofactor, decreased both the rate constant for reduction of the protein and the extent of FMN semiquinone production, while increasing the amount of iron-sulfur center reduction, consistent with the results obtained with the native enzyme. Experiments in which the kinetics of reduction of the enzyme were determined during various stages of partial reduction were also consistent with these results, and further indicated that the FMN semiquinone form of the enzyme is more reactive toward the deazariboflavin reductant than is the oxidized FMN.(ABSTRACT TRUNCATED AT 250 WORDS)     

Laser flash photolysis studies of the kinetics of electron-transfer reactions of Saccharomyces flavocytochrome b2: evidence for conformational gating of intramolecular electron transfer induced by pyruvate binding

The kinetics of reduction of the flavocytochrome from Saccharomyces cerevisiae by exogenous deazaflavin semiquinones have been investigated by using laser flash photolysis. Direct reduction by deazaflavin semiquinone of both the b2 heme and the FMN cofactor occurred via second-order kinetics with similar rate constants (9 x 10(8) M-1 s-1). A slower, monoexponential, phase of FMN reoxidation was also observed, concurrent with a slow phase of heme reduction. The latter accounted for approximately 20-25% of the total heme absorbance change. Both of these slow phases were protein concentration dependent, yielding identical second-order rate constants (1.1 x 10(7) M-1 s-1), and were interpreted as resulting from intermolecular electron transfer from the FMN semiquinone on one protein molecule to an oxidized heme on a second molecule. Consistent with this conclusion, no slow phase of heme reduction was observed with deflavo-flavocytochrome b2. Upon the addition of pyruvate (but not D-lactate or oxalate), the second-order rate constant for heme reduction was unaffected, but direct reduction of the FMN cofactor was no longer observed. Reduction of the heme cofactor was followed by a slower partial reoxidation, which occurred concomitantly with a monoexponential phase of FMN reduction. Both processes were protein concentration independent and were interpreted as the result of intramolecular electron transfer from reduced b2 heme to oxidized FMN. Potentiometric titrations of the flavocytochrome in the absence and presence of pyruvate demonstrated that the thermodynamic driving force for electron transfer from FMN to heme is much greater in the absence of pyruvate. Despite this, intramolecular electron transfer was only observed in the presence of pyruvate. This result is interpreted in terms of a conformational change induced by pyruvate binding which permits electron transfer between the cofactors. The rate constant for intramolecular electron transfer in the presence of pyruvate was dependent on ionic strength, suggesting the occurrence of electrostatic effects which influence this process.     

Direct measurement of intramolecular electron transfer between type I and type III copper centers in the multi-copper enzyme ascorbate oxidase and its type II copper-depleted and cyanide-inhibited forms

Transient kinetics of reduction of zucchini squash ascorbate oxidase (AO) by lumiflavin semiquinone have been studied by using laser flash photolysis. Second-order kinetics were obtained for reduction of the type I copper with a rate constant of 2.7 X 10(7) M-1 s-1, which is comparable to that obtained with other blue copper proteins such as plastocyanin. Following reduction, the type I copper was reoxidized in a protein concentration independent (i.e., intramolecular) reaction (kobs = 160 s-1). Comparison with literature values for limiting rate constants in transient single-turnover kinetic experiments suggests that intramolecular electron transfer probably is the rate-limiting step in enzyme catalysis. The extent of reoxidation of type I copper was approximately 55%, which is consistent with the approximately equal redox potentials of the type I and type III copper centers. Neither azide nor fluoride caused any significant changes in kinetics, although they are enzyme inhibitors and are thought to bind to the type II copper. In contrast, cyanide caused a concentration-dependent decrease in the extent of intramolecular electron transfer (with no change in rate constant), and decreased the rate constant for reduction of the type I copper by a factor of 2. The apparent dissociation constant for cyanide (0.2-0.4 mM) is similar to that reported for inhibition of enzyme activity. Removal of the type II copper from AO only marginally affected the kinetics of electron transfer to type I copper (k = 3.2 x 10(7) M-1 s-1) and slightly increased the extent but did not alter the rate constant of intramolecular electron transfer.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ionic strength dependence of the kinetics of electron transfer from bovine mitochondrial cytochrome c to bovine cytochrome c oxidase.

The effect of ionic strength on the one-electron reduction of oxidized bovine cytochrome c oxidase by reduced bovine cytochrome c has been studied by using flavin semiquinone reductants generated in situ by laser flash photolysis. In the absence of cytochrome c, direct reduction of the heme a prosthetic group of the oxidase by the one-electron reductant 5-deazariboflavin semiquinone occurred slowly, despite a driving force of approximately +1 V. This is consistent with a sterically inaccessible heme a center. This reduction process was independent of ionic strength from 10 to 100 mM. Addition of cytochrome c resulted in a marked increase in the amount of reduced oxidase generated per laser flash. Reduction of the oxidase at the heme a site was monophasic, whereas oxidation of cytochrome c was multiphasic, the fastest phase corresponding in rate constant to the reduction of the heme a. During the fast kinetic phase, 2 equiv of cytochrome c was oxidized per heme a reduced. We presume that the second equivalent was used to reduce the Cua center, although this was not directly measured. The first-order rate-limiting process which controls electron transfer to the heme a showed a marked ionic strength effect, with a maximum rate constant occurring at mu = 110 mM (1470 s-1), whereas the rate constant obtained at mu = 10 mM was 630 s-1 and at mu = 510 mM was 45 s-1. There was no effect of "pulsing" the enzyme on this rate-limiting one-electron transfer process. These results suggest that there are structural differences in the complex(es) formed between mitochondrial cytochrome c and cytochrome c oxidase at very low and more physiologically relevant ionic strengths, which lead to differences in electron-transfer rate constants.     

Control of electron transfer by the electrochemical potential gradient in cytochrome-c oxidase reconstituted into phospholipid vesicles

The kinetics of electron transfer between cytochrome-c oxidase and ruthenium hexamine has been characterized using the native enzyme or its cyanide complex either solubilized by detergent (soluble cytochrome oxidase) or reconstituted into artificial phospholipid vesicles (cytochrome oxidase-containing vesicles). Ru(NH3)2+6 (Ru(II] reduces oxidized cytochrome a, following (by-and-large) bimolecular kinetics; the second order rate constant using the cyanide complex of the enzyme is 1.5 x 10(6) M-1 s-1, for the enzyme in detergent, and slightly higher for COV. In the case of COV the kinetics are not affected by the addition of ionophores. Upon mixing fully reduced cytochrome oxidase with oxygen (in the presence of excess reductants), the oxidation leading to the pulsed enzyme is followed by a steady state phase and (eventually) by complete re-reduction. When the concentrations of dioxygen and oxidase are sufficiently low (micromolar range), the time course of oxidation can be resolved by stopped flow at room temperature, yielding an apparent bimolecular rate constant of 5 x 10(7) M-1 s-1. After exhaustion of oxygen and end of steady state, re-reduction of the pulsed enzyme by the excess Ru(II) is observed; the concentration dependence shows that the rate of re-reduction is limited at 3 s-1 in detergent; this limiting value is assigned to the intramolecular electron transfer process from cytochrome a-Cua to the binuclear center. Using the reconstituted enzyme, the internal electron transfer step is sensitive to ionophores, increasing from 2-3 to 7-8 s-1 upon addition of valinomycin and carbonyl cyanide m-chlorophenylhydrazone. This finding indicates for the first time an effect of the electrochemical potential across the membrane on the internal electron transfer rate; the results are compared with expectations based on the hypothesis formulated by Brunori et al. (Brunori, M., Sarti, P., Colosimo, A., Antonini, G., Malatesta, F., Jones, M.G., and Wilson, M.T. (1985) EMBO J. 4, 2365-2368), and their bioenergetic relevance is discussed with reference to the proton pumping activity of the enzyme.     

Laser flash photolysis studies of electron transfer between semiquinone and fully reduced free flavins and the cytochrome c-cytochrome oxidase complex

Laser flash photolysis has been used to determine the rate constants for the reduction of bovine cytochrome oxidase and the cytochrome c-cytochrome oxidase complex by the semiquinone and fully reduced forms of various flavin analogues (FH. and FH-, respectively). Under the condition used, the reaction of FH. with free cytochrome oxidase is too slow to compete with FH. disproportionation whereas FH- reacts measurably. Both FH. and FH- are effective in reducing the complex. The reduction of heme a in the complex is shown to proceed via cytochrome c, and a limiting first-order rate is observed in the case of FH- at high complex concentrations. The data indicate that the interaction site for electron transfer to cytochrome c is the same in the complex as with the free protein, and although a tight complex exists, at least small reactants like the flavins are not sterically hindered in their access to the bound cytochrome c. Moreover, the results also establish that intramolecular electron transfer between cytochrome c and cytochrome oxidase within the complex occurs with a first-order rate constant of greater than 700 s-1. Thus, the presence of cytochrome c greatly enhances electron transfer from reduced flavins to cytochrome oxidase.     

Laser flash photolysis study of the kinetics of electron transfer reactions of flavocytochrome b2 from Hansenula anomala: further evidence for intramolecular electron transfer mediated by ligand binding.

Intramolecular electron transfer between the heme and flavin cofactors of flavocytochrome b2 is an obligatory step during the enzymatic oxidation of L-lactate and subsequent reduction of cytochrome c. Previous kinetic studies using both steady-state and transient methods have suggested that such intramolecular electron transfer is inhibited when pyruvate, the two-electron oxidation product of L-lactate, is bound at the active site of Hansenula anomala flavocytochrome b2. In contrast to this, we have recently demonstrated using laser flash photolysis that intramolecular electron transfer could be observed in the flavocytochrome b2 from Saccharomyces cerevisiae only when pyruvate was present [Walker, M., & Tollin, G. (1991) Biochemistry 30, 5546-5555], despite a large thermodynamic driving force of 100 mV and apparently favorable cofactor geometry as indicated by crystallographic studies. In the present study, we have utilized laser flash photolysis to investigate intramolecular electron transfer in the flavocytochrome b2 from H. anomala in an effort to address these apparently conflicting interpretations with respect to the influence of pyruvate on enzyme properties. The results obtained are closely comparable to those we reported using the protein from Saccharomyces. Thus, in the absence of pyruvate, bimolecular reduction of both the heme and FMN cofactors by deazaflavin semiquinone occurs (k approximately 10(9) M-1 s-1), followed by a protein concentration dependent intermolecular electron transfer from the semiquinone form of the FMN cofactor to the heme (k approximately 10(7) M-1 s-1).(ABSTRACT TRUNCATED AT 250 WORDS)     

Cytochrome oxidase from Pseudomonas aeruginosa. IV. Reaction with oxygen and carbon monoxide.

The reaction between a cytochrome oxidase from Pseudomonas aeruginosa and oxygen has been studied by a rapid mixing technique. The data indicate that the heme d1 moiety of the ascorbate-reduced enzyme is oxidized faster than the heme c component. The oxidation of heme d1 is accurately second order with respect to oxygen and has a rate constant of 5.7 - 10(4) M-1 - s-1 at 20 degrees C. The oxidation of the heme c has a first order rate constant of about 8 s-1 at infinite concentration of O2. The results indicate that the rate-limiting step is the internal transfer of electrons from heme c to heme d1. These more rapid reactions are followed by more complicated but smaller abcorbance changes whose origin is still not clear. The reaction of ascorbate-reduced oxidase with CO has also been studied and is second order with a rate constant of 1.8 - 10(4) M-1 - s-1. The initial reaction with CO is followed by a slower reaction of significantly less magnitude. The equilibrium constant for the reaction with CO, calculated as a dissociation constant from titrimetric experiments with dithionite-reduced oxidase, is about 2.3 - 10(-6) M. From these data a rate constant of 0.041 s-1 can be calculated for the dissociation of CO from the enzyme.     

Electron paramagnetic resonance of the tungsten derivative of rat liver sulfite oxidase.

Sulfite oxidase purified from livers of tungsten-treated rats has been used for EPR studies of tungsten substituted at the molybdenum site of the enzyme in a fraction of the molecules. The EPR signal of W(V) in sulfite oxidase is quite similar to that of Mo(V) in its line shape and in its sensitivity to the presence of anions such as phosphate and fluoride. Hyperfine interaction with a dissociable proton is also observed in both signals. The pH-dependent alteration in line shape exhibited by the Mo(V) EPR signal of the rat liver enzyme. Incomplete reduction of the tungsten center at pH 9 is indicated by attenuated signal intensity at this pH. The W(V) signal has g values lower than those of the Mo(V) signal, has a much broader resonance envelope, and is much less readily saturated by increasing microwave power. Kinetic studies on the reduction of the heme and tungsten centers of sulfite oxidase have shown that reduction of de-molybdo forms of sulfite oxidase by sulfite is catalyzed by the residual traces of native molybdenum-containing molecules. Reduction is accomplished by electron transfer involving intermolecular heme-heme interaction. The W(V) signal is generated only after all the heme centers are reduced. The rate and extent of heme reduction at pH 9 are the same as at pH 7. Studies on the reoxidation of W(V) and reduced heme by O2 and by cytochrome c suggest that the cytochrome b5 of sulfite oxidase is the site of electron transfer to cytochrome c, whereas oxidase activity is the property of the molybdenum center. It appears that the tungsten center in sulfite oxidase is incapable of oxidizing sulfite.     

Comparison of the kinetics of reduction and intramolecular electron transfer in electrostatic and covalent complexes of ferredoxin-NADP+ reductase and flavodoxin from Anabaena PCC 7119

The kinetics of reduction and intracomplex electron transfer in electrostatically stabilized and covalently crosslinked complexes between ferredoxin-NADP+ reductase (FNR) and flavodoxin (Fld) from the cyanobacterium Anabaena PCC 7119 were compared using laser flash photolysis. The second-order rate constant for reduction by 5-deazariboflavin semiquinone (dRfH) of FNR within the electrostatically stabilized complex at 10 mM ionic strength (4.0 X 10(8) M-1 s-1) was identical to that for free FNR. This suggests that the FAD cofactor of FNR is not sterically hindered upon complex formation. A lower limit of approximately 7000 s-1 was estimated for the first-order rate constant for intracomplex electron transfer from FNRred to Fldox under these conditions. In contrast, for the covalently crosslinked complex, a smaller second-order rate constant (2.1 X 10(8) M-1 s-1) was obtained for the reduction of FNR by dRfH within the complex, suggesting that some steric hindrance of the FAD cofactor of FNR occurs due to crosslinking. A limiting rate constant of 1000 s-1 for the intracomplex electron transfer reaction was obtained for the covalent complex, which was unaffected by changes in ionic strength. The substantially diminished limiting rate constant, relative to that of the electrostatic complex, may reflect either a suboptimal orientation of the redox cofactors within the covalent complex or a required structural reorganization preceding electron transfer which is not allowed once the proteins have been covalently linked. Thus, although the covalent complex is biochemically competent, it is not a quantitatively precise model for the catalytically relevant intermediate along the reaction pathway.     

The oxidation of Pseudomonas cytochrome c-551 oxidase by potassium ferricyanide.

Stopped-flow kinetics were made of the reaction between ascorbate-reduced Pseudomonas cytochrome oxidase and potassium ferricyanide under both N2 and CO atmospheres. Under N2 three kinetic processes were observed, two being dependent on ferricyanide concentration, with second-order rate constants of 9.6 X 10(4)M-1.s-1 and 1.5 X 10(4)M-1.s-1, whereas the other was concentration-independent, with a first-order rate constant of 0.17 +/- 0.03s-1. Measurements of their kinetic difference spectra have allowed the fastest and second-fastest phases of the reaction to be assigned to direct bimolecular reactions of ferricyanide with the haem c and haem d, moieties of the enzyme respectively. Under CO, the second-order rate constant for the reaction of the haem c was, at 1.3 X 10(5)M-1.s-1, slightly enhanced over the rate in a N2 atmosphere, but the reaction velocity of the haem d1 component was greatly decreased, being apparently limited to that of the rates of CO dissociation from the molecule (0.15s-1 and 0.03s-1). The results are compared with those obtained during a previous study of the reaction of reduced Pseudomonas cytochrome oxidase with oxidized azurin.     

Ligand binding by the chlorocruorin from Eudistylia vancouverii.

Carbon monoxide chlorocruorin from Eudistylia vancouverii shows three distinct first-order relaxations with rates of 2.9 x 10(9) s-1, 6.5 x 10(7) s-1, and 3.2 x 10(6) s-1 (geminate reactions) and three second-order relaxations with rates of 4.7 x 10(6) M-1 s-1, 7 x 10(5) M-1 s-1, and 7 x 10(4) M-1 s-1, when studied by flash photolysis. The amplitudes of the second-order reactions depend on the extent of photolysis. This may be due to relaxation from the liganded (R) to the unliganded (T) conformation following photolysis and suggests that the combination rates contribute to cooperativity. In a stopped-flow experiment only the slowest phase with a rate of 7 x 10(4) M-1 s-1 is observed. It is assigned to binding to the T-state protein. Fragments of the native protein containing 12 and 4 hemes react like the holoprotein suggesting that the tetramer is a major cooperative unit. Oxygen binding shows three geminate relaxations with rates of 2.5 x 10(10) s-1, 3.5 x 10(7) s-1, and 4.5 x 10(6) s-1, and two second-order rates of 1.5 x 10(7) M-1 s-1 and 1 x 10(6) M-1 s-1. The amplitudes of the second-order phases do not correlate with the extent of photolysis. The results with the two ligands are consistent with an allosteric transition fast enough to compete with a rebinding rate of 500 s-1 in the R to T direction (CO rebinding) but not fast enough to compete with oxygen rebinding. There is significant heterogeneity in the R-state kinetics, but the T-state reaction is homogeneous.     

Electron transfer rates and equilibrium within cytochrome c oxidase.

Intramolecular electron transfer (ET) between the CuA center and heme a in bovine cytochrome c oxidase was investigated by pulse radiolysis. CuA, the initial electron acceptor, was reduced by 1-methyl nicotinamide radicals in a diffusion-controlled reaction, as monitored by absorption changes at 830 nm. After the initial reduction phase, the 830 nm absorption was partially restored, corresponding to reoxidation of the CuA center. Concomitantly, the absorption at 445 nm and 605 nm increased, indicating reduction of heme a. The rate constants for heme a reduction and CuA reoxidation were identical within experimental error and independent of the enzyme concentration. This demonstrates that a fast intramolecular electron equilibration is taking place between CuA and heme a. The rate constants for CuA --> heme a ET and the reverse (heme a --> CuA) process were found to be 13 000 s-1 and 3700 s-1, respectively, at 25 degrees C and pH 7.4. This corresponds to an equilibrium constant of 3.4 under these conditions. Thermodynamic and activation parameters of the ET reactions were determined. The significance of these results, particularly the observed low activation barriers, are discussed within the framework of the known three-dimensional structure, ET pathways and reorganization energies.     

Laser-flash-photolysis studies of p-cresol methylhydroxylase. Electron-transfer properties of the flavin and haem components.

p-Cresol methylhydroxylase, a heterodimer consisting of one flavoprotein subunit and one cytochrome c subunit, may be resolved into its subunits, and the holoenzyme may then be fully reconstituted from the pure subunits. In the present study we have characterized the reduction kinetics of the intact enzyme and its subunits, by using exogenous 5-deazariboflavin semiquinone radical generated in the presence of EDTA by the laser-flash-photolysis technique. Under anaerobic conditions the 5-deazariboflavin semiquinone radical reacts rapidly with the native enzyme with a rate constant approaching that of a diffusion-controlled reaction (k = 2.8 X 10(9) M-1 X s-1). Time-resolved difference spectra at pH 7.6 indicate that both flavin and haem are reduced initially by the deazariboflavin semiquinone radical, followed by an additional slower intramolecular electron transfer (k = 220 s-1) from the endogenous neutral flavin semiquinone radical to the oxidized haem moiety of the native enzyme. During the steady-state photochemical titration of the native enzyme at pH 7.6 with deazariboflavin semiquinone radical generated by light-irradiation the haem appeared to be reduced before the protein-bound flavin and was followed by the formation of the protein-bound anionic flavin radical. This result suggests that the redox potential of the haem is higher than that of the flavin, and that deprotonation of the flavin neutral radical occurred during the photochemical titration. Reduction kinetics of the flavoprotein and cytochrome subunits were also investigated by laser-flash photolysis. The protein-bound flavin of the isolated flavin subunit was reduced rapidly by the deazariboflavin semiquinone radical (k = 2.2 X 10(9) M-1 X s-1), as was the haem of the pure cytochrome c subunit (k = 3.7 X 10(9) M-1 X s-1). Flash-induced difference spectra obtained for the flavoprotein and cytochrome subunits at pH 7.6 were consistent with the formation of neutral flavin semiquinone radical and reduced haem, respectively. Investigation of the kinetic properties of the neutral flavin semiquinone radical of the flavoprotein subunit at pH 7.6 and at longer times (up to 5s) were consistent with a slow first-order deprotonation reaction (k = 1 s-1) of the neutral radical to its anionic form.     

Reduction of cytochrome oxidase by 5,10-dihydro-5-methylphenazine: kinetic parameters from rapid-scanning stopped-flow experiments

The kinetics of the reduction of resting cytochrome oxidase and of its cyanide complex by 5,10-dihydro-5- methylphenazine (MPH) have been characterized by rapid-scan and fixed-wavelength stopped-flow spectrophotometry in the Soret, visible, and near-IR spectral regions. In this study, we focused on a form of the resting enzyme that is characterized by a Soret absorption maximum at 424 nm. These experiments complement earlier work on the reduction of a 418 nm absorbing form of the resting enzyme [ Halaka , F.G., Babcock , G. T., & Dye, J. L. (1981) J. Biol. Chem. 256, 1084-1087]. The reduction of cytochrome a is accomplished in a second-order reaction with a rate constant of 3 X 10(5) M-1 s-1. The reduction of the 830-nm absorber, Cua, is closely coupled to but lags the reduction of cytochrome a; we have resolved a rate constant of about 20 s-1 for the copper reduction. The reduction of cytochrome a proceeds with a rate constant that is nearly independent of the spectral properties of the resting enzyme and of the ligation state of cytochrome a3. The reduction of cytochrome a3 occurs by slow, intramolecular electron transfer. We have resolved two phases for this process that have rate constants of approximately 0.2 s-1 and approximately 0.02 s-1 for both the 418- and 424-nm forms of the resting enzyme. It appears, therefore, that spectroscopic heterogeneity at the cytochrome a3 site in the resting enzyme exerts very little influence on the kinetics of the anaerobic reduction of the oxidase metal centers. From this we conclude that the rate of electron transfer to the a3 site is probably controlled by the protein conformation and not primarily by local factors within the a3 environment.     

The radical chemistry of milk xanthine oxidase as studied by radiation chemistry techniques

The kinetics of electron transfer within the molybdoflavoenzyme xanthine oxidase has been investigated using the technique of pulse radiolysis. Subsequent to one-electron reduction of native enzyme at 20 degrees C in 20 mM pyrophosphate buffer, pH 8.5, using the CO-.2 species as reductant, a spectral change is observed having a rate constant of approximately 290 s-1. From its wavelength dependence, this spectral change is assigned to the transfer of an electron from flavin semiquinone (formed on reaction with the CO2-. species) to one of the iron-sulfur centers of the enzyme in an intramolecular equilibration process. The value for this rate constant agrees well with the 330 s-1 observed in previous stopped-flow pH-jump experiments carried out at 25 degrees C (Hille, R., and Massey, V. (1986) J. Biol. Chem. 261, 1241-1247). Experimental results with fully reduced enzyme reacting with the radiolytically generated N.3 species also support the conclusion that the equilibration of reducing equivalents among the oxidation-reduction centers of xanthine oxidase is a rapid process. Evidence is also found that xanthine oxidase possesses an unusually reactive disulfide bond that is reduced rapidly by radiolytically generated radicals. The ramifications of the present results with regard to the interpretation of experiments involving chemically reactive radical species, generated either by photolysis or radiolysis, are discussed.