Reduction kinetics of the four hemes of cytochrome c3 from Desulfovibrio vulgaris by flash photolysis.

The reduction of the tetraheme cytochrome c3 (from Desulfovibrio vulgaris, strains Miyazaki F and Hildenbourough) by flavin semiquinone and reduced methyl viologen follows a monophasic kinetic profile, even though the four hemes do not have equivalent reduction potentials. Rate constants for reduction of the individual hemes are obtained subsequent to incrementally reducing the cytochrome by phototitration. The dependence of each rate constant on the reduction potential difference between the heme and the reductant can be described by outer sphere electron transfer theroy. Thus, the very low reduction potentials of the cytochrome c3 hemes compensate for the very large solvent accessibility of the hemes. The relative rate constants for electron transfer to the four hemes of cytochrome c3 are consistent with the assignments of reduction potential to hemes previously made by Park et al. (Park, J.-S., Kano, K., Niki, S. and Akutsu, H. (1991) FEBS Lett. 285, 149-151) using NMR techniques. The ionic strength dependence of the observed rate constant for reduction by the methyl viologen radical cation indicates that ionic strength substantially alters the structure and/or the heme reduction potentials of the cytochrome. This result is confirmed by reduction with a neutral flavin species (5-deazariboflavin semiquinone) in which the reactivity of the highest potential heme decreases and the reactivity of the lowest potential heme increases at high (500 mM) ionic strength, and by the sensitivity of heme methyl resonances to ionic strength as observed by 1H-NMR. These unusual ionic strength-dependent effects may be due to a combination of structural changes in the cytochrome and alterations of the electrostatic fields at elevated ionic strengths.     

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.     

Transient formation of ubisemiquinone radical and subsequent electron transfer process in the Escherichia coli cytochrome bo

To elucidate a unique mechanism for the quinol oxidation in the Escherichia coli cytochrome bo, we applied pulse radiolysis technique to the wild-type enzyme with or without a single bound ubiquinone-8 at the high-affinity quinone binding site (Q(H)), using N-methylnicotinamide (NMA) as an electron mediator. With the ubiquinone bound enzyme, the reduction of the oxidase occurred in two phases as judged from kinetic difference spectra. In the faster phase, the transient species with an absorption maximum at 440 nm, a characteristic of the formation of ubisemiquinone anion radical, appeared within 10 micros after pulse radiolysis. In the slower phase, a decrease of absorption at 440 nm was accompanied by an increase of absorption at 428 and 561 nm, characteristic of the reduced form. In contrast, with the bound ubiquinone-8-free wild-type enzyme, NMA radicals directly reduced hemes b and o, though the reduction yield was low. These results indicate that a pathway for an intramolecular electron transfer from ubisemiquinone anion radical at the Q(H) site to heme b exists in cytochrome bo. The first-order rate constant of this process was calculated to be 1.5 x 10(3) s(-1) and is comparable to a turnover rate for ubiquinol-1. The rate constant for the intramolecular electron transfer decreased considerably with increasing pH, though the yields of the formation of ubisemiquinone anion radical and the subsequent reduction of the hemes were not affected. The pH profile was tightly linked to the stability of the bound ubisemiquinone in cytochrome bo [Ingledew, W. J., Ohnishi, T., and Salerno, J. C. (1995) Eur. J. Biochem. 227, 903-908], indicating that electron transfer from the bound ubisemiquinone at the Q(H) site to the hemes slows down at the alkaline pH where the bound ubisemiquinone can be stabilized. These findings are consistent with our previous proposal that the bound ubiquinone at the Q(H) site mediates electron transfer from the low-affinity quinol oxidation site in subunit II to low-spin heme b in subunit I.     

Evidence for two different electron transfer pathways in the same enzyme, nitrate reductase A from Escherichia coli.

In order to clarify the role of cytochrome in nitrate reductase we have performed spectrophotometric and stopped-flow kinetic studies of reduction and oxidation of the cytochrome hemes with analogues of physiological quinones, using menadione as an analogue of menaquinone and duroquinone as an analogue of ubiquinone, and comparing the results with those obtained with dithionite. The spectrophotometric studies indicate that reduction of the cytochrome hemes varies according to the analogue of quinone used, and in no cases is it complete. Stopped-flow kinetics of heme oxidation by potassium nitrate indicates that there are two distinct reactions, depending on whether the hemes were previously reduced by menadiol or by duroquinol. These results, and those of spectrophotometric studies of a mutant lacking the highest-potential [Fe-S] cluster, allow us to propose a two-pathway electron transfer model for nitrate reductase A from Escherichia coli.     

Transient kinetic studies of heme reduction in Escherichia coli nitrate reductase A (NarGHI) by menaquinol

We have studied the transient kinetics of quinol-dependent heme reduction in Escherichia coli nitrate reductase A (NarGHI) by the menaquinol analogue menadiol using the stopped-flow method. Four kinetic phases are observed in the reduction of the hemes. A transient species, likely to be associated with a semiquinone radical anion, is observed with kinetics that correlates with one of the phases. The decay of the transient species and the formation of the second reduction phase of the hemes can be fitted to a double-exponential equation giving similar rate constants, k(1) = 9.24 +/- 0.9 s(-1) and k(2) = 0.22 +/- 0.02 s(-1) for the decay of the transient species, and k(1) = 9.23 +/- 0.9 s(-1) and k(2) = 0.22 +/- 0.02 s(-1) for the formation of the reduction phase. The quinol-binding-site inhibitors 2-n-heptyl-4-hydroxyquinoline-N-oxide (HOQNO) and stigmatellin have significant and different inhibitory effects on the reduction kinetics. The kinetics of heme reduction in NarI expressed in the absence of the NarGH catalytic dimer (NarI(DeltaGH) exhibits only two kinetic phases, and the decay of the transient species also correlates kinetically with the second reduction phase of the hemes. We have also studied nitrate-dependent heme reoxidation following quinol-dependent heme reduction using a sequential stopped-flow method. HOQNO elicits a much stronger inhibitory effect than stigmatellin on the reoxidation of the hemes. On the basis of our results, we propose schemes for the mechanism of NarGHI reduction by menaquinol and reoxidation by nitrate.     

Redox tuning of the catalytic activity of soluble fumarate reductases from Shewanella

Many enzymes involved in bioenergetic processes contain chains of redox centers that link the protein surface, where interaction with electron donors or acceptors occurs, to a secluded catalytic site. In numerous cases these redox centers can transfer only single electrons even when they are associated to catalytic sites that perform two-electron chemistry. These chains provide no obvious contribution to enhance chemiosmotic energy conservation, and often have more redox centers than those necessary to hold sufficient electrons to sustain one catalytic turnover of the enzyme. To investigate the role of such a redox chain we analyzed the transient kinetics of fumarate reduction by two flavocytochromes c₃ of Shewanella species while these enzymes were being reduced by sodium dithionite. These soluble monomeric proteins contain a chain of four hemes that interact with a flavin adenine dinucleotide (FAD) catalytic center that performs the obligatory two electron–two proton reduction of fumarate to succinate. Our results enabled us to parse the kinetic contribution of each heme towards electron uptake and conduction to the catalytic center, and to determine that the rate of fumarate reduction is modulated by the redox stage of the enzyme, which is defined by the number of reduced centers. In both enzymes the catalytically most competent redox stages are those least prevalent in a quasi-stationary condition of turnover. Furthermore, the electron distribution among the redox centers during turnover suggested how these enzymes can play a role in the switch between respiration of solid and soluble terminal electron acceptors in the anaerobic bioenergetic metabolism of Shewanella.     

Stopped-flow and rapid-scan studies of the redox behavior of cytochrome aco from facultative alkalophilic Bacillus

Cytochrome aco purified from an alkalophilic bacterium grown at pH 10 contains hemes a, b, and c as prosthetic groups, and their redox behavior was examined by using stopped-flow and rapid-scan techniques. Under anaerobic conditions the reduction of both heme a and c moieties with dithionite proceeded exponentially but with different rates, usually the former being reduced about 4 times faster than the latter. The reduction of protoheme was much slower, and a time-difference spectrum for this species was of a high spin type with absorption peaks at 433, 557, and 609 nm. Only the protoheme combined with CO, fulfilling the criteria for cytochrome o. Potentiometric titrations determined a midpoint potential of c heme to be 95 mV at pH 7.0 and 25 degrees C and suggested the presence of two forms of a heme with midpoint potentials of 250 and 323 mV. Cytochrome aco utilizes ascorbate plus N,N,N',N'-tetramethyl-p-phenylenediamine (TMPD) to reduce oxygen relatively rapidly without added cytochrome c (Qureshi, M. H., Yumoto, I., Fujiwara, T., Fukumori, Y., Yamanaka, T. (1990) J. Biochem. 107, 480-485). During the steady state, however, heme a stayed almost fully reduced in contrast to a partial reduction of heme c. Even after exhaustion of the dissolved oxygen the extent of reduction of heme c was 60-70% that attained by the dithionite reduction. When ascorbate plus TMPD-reduced cytochrome aco was exposed to oxygen the reduced heme c was oxidized rapidly whereas the oxidation of reduced a heme was negligibly slow. The full reduction of heme a during the steady state and its extremely slow oxidation rendered participation of heme a in the oxidase reaction less likely. A novel peak appearing transiently around 567 nm during the reaction was tentatively ascribed to an intermediate form of protoheme, or o heme, which was thus supposed to react directly with molecular oxygen. These results suggest strongly that the main electron transfer pathway would be c----o----oxygen. A possible role of a in regulating the electron flow through the main pathway and its functional relationship to a heme in the aa3-type cytochrome oxidase were discussed.     

Comparative study of the reaction kinetics of cytochrome P-450 reduction by NADPH-cytochrome P-450 reductase and dithionite

The reactions of NADPH- or dithionite-dependent reduction of cytochrome P-450 were studied using a stopped flow technique. It was found that the kinetic curves for both reactions may be fitted by a sum of the two exponents. The arrhenius plots for the fast phase rate constants are linear for both reactions. On the contrary, the breaks on the corresponding plots for the slow phase rate constants are observed at 22 and 33 degrees C for cytochrome P-450 reduction by dithionite and at 31 degrees C for NADPH-dependent reduction of cytochrome P-450. The coincidence of the values of the rate constants and activation energy (56 +/- 5 kJ/mol) for the fast phase of NADPH-dependent reduction of cytochrome P-450 with values of catalytic constants and activation energy for demethylation of tertiary amines suggests that the first electron transfer process from NADPH-cytochrome P-450 reductase to cytochrome P-450 may be the rate-limiting step. A diverse character of the kinetic parameters for the two cytochrome P-450 reduction reactions is indicative of different nature of biphasity of these processes.     

Purification, redox and spectroscopic properties of the tetraheme cytochrome c isolated from Rubrivivax gelatinosus.

The tetraheme cytochrome c subunit of the Rubrivivax gelatinosus reaction center was isolated in the presence of octyl beta-D-thioglucoside by ammonium sulfate precipitation and solubilization at pH 9 in a solution of Deriphat 160. Several biochemical properties of this purified cytochrome were characterized. In particular, it forms small oligomers and its N-terminal amino acid is blocked. In the presence or absence of diaminodurene, ascorbate and dithionite, different oxidation/reduction states of the isolated cytochrome were studied by absorption, EPR and resonance Raman spectroscopies. All the data show two hemes quickly reduced by ascorbate, one heme slowly reduced by ascorbate and one heme only reduced by dithionite. The quickly ascorbate-reduced hemes have paramagnetic properties very similar to those of the two low-potential hemes of the reaction center-bound cytochrome (gz = 3.34), but their alpha band is split with two components peaking at 552 nm and 554 nm in the reduced state. Their axial ligands did not change, being His/Met and His/His, as indicated by the resonance Raman spectra. The slowly ascorbate-reduced heme and the dithionite-reduced heme are assigned to the two high-potential hemes of the bound cytochrome. Their alpha band was blue-shifted at 551 nm and the gz values decreased to 2.96, although the axial ligations (His/Met) were conserved. It was concluded that the estimated 300 mV potential drop of these hemes reflected changes in their solvent accessibility, while the reduction in gz indicates an increased symmetry of their cooordination spheres. These structural modifications impaired the cytochrome's essential function as the electron donor to the photooxidized bacteriochlorophyll dimer of the reaction center. In contrast to its native state, the isolated cytochrome was unable to reduce efficiently the reaction center purified from a Rubrivivax gelatinosus mutant in which the tetraheme was absent. Despite the conformational changes of the cytochrome, its four hemes are still divided into two groups with a pair of low-potential hemes and a pair of high-potential hemes.     

Cooperativity in the dissociation of nitric oxide from hemoglobin.

The dissociation of nitric oxide from hemoglobin, from isolated subunits of hemoglobin, and from myoglobin has been studied using dithionite to remove free nitric oxide. The reduction of nitric oxide by dithionite has a rate of 1.4 X 10(3) M-1 S-1 at 20 degrees in 0.05 M phosphate, pH 7.0, which is small compared with the rate of recombination of hemoglobin with nitric oxide (25 X 10(6) M-1 S-1 (Cassoly, R., and Gibson, Q. H. (1975) J. Mol. Biol. 91, 301-313). The rate of NO combination with chains and myoglobin was found to be 24 X 10(6) M-1 S-1 and 17 X 10(6) M-1 S-1, respectively. Hence, the observed progress curve of the dissociation of nitric oxide is dependent upon the dithionite concentration and the total heme concentration. Addition of excess carbon monoxide to the dissociation mixture reduces the free heme yielding a single exponential process for chains and for myoglobin which is dithionite and heme concentration independent over a wide range of concentrations. The rates of dissociation of nitric oxide from alpha chains, from beta chains, and from myoglobin are 4.6 X 10(-5) S-1, 2.2 X 10(-5) S-1, and 1.2 X 10(4) S-1, respectively, both in the presence and in the absence of carbon monoxide at 20 degrees in 0.05 M phosphate, pH 7.0. Analogous heme and dithionite concentration dependence is found for the dissociation of nitric oxide from tetrameric hemoglobin. The reaction is cooperative, the intrinsic rate constants for the dissociation of the 1st and 4th molecules of NO differing about 100-fold. With hemoglobin, replacement of NO by CO at neutral pH is biphasic in phosphate buffers. The rate of the slow phase is 1 X 10(-5) S-1 and is independent of pH. The amplitude of the fast phase increases with lowering of pH. By analogy with the treatment of the HbCO + NO reaction given by Salhany et al. (Salhany, J.M., Ogawa, S., and Shulman, R.G. (1975) Biochemistry 14, 2180-2190), the fast phase is attributed to the dissociation of NO from T state molecules and the slow phase to dissociation from R state molecules. Analysis of the data gives a pH-independent value of 0.01 for the allosteric constant c (c = Kr/Kt where Kr and Kt are the dissociation constants for NO from the R and T states, respectively) and pH-dependent values of L (2.5 X 10(7) at pH 7 in 0.05 M phosphate buffer). The value of c is considerably greater than that for O2 and CO. Studies of the difference spectrum induced in the Soret region by inositol hexaphosphate are also reported. This spectrum does not arise directly from the change of conformation between R and T states. The results show that if the equilibrium binding curve for NO could be determined experimentally, it would show cooperativity with Hill's n at 50% saturation of about 1.6.     

In vitro kinetics of reduction of cytochrome c554 isolated from the reaction center of the green phototrophic bacterium, Chloroflexus aurantiacus

The photochemical reaction center in the green bacterium Chloroflexus aurantiacus is similar to that found in purple phototrophic bacteria and interacts with a multiheme membrane-bound cytochrome. We have examined the kinetics of reduction of the pure solubilized reaction center cytochrome by laser flash photolysis of solutions containing lumiflavin or FMN. Reduction by lumiflavin semiquinone followed single exponential kinetics and the observed rate constant (kobs) was linearly dependent on protein concentration (k = 1.8 X 10(7) M-1s-1 heme-1). This result suggests either that the four hemes have similar reduction rate constants which cannot be resolved or that there are large differences in rate constant and only the most reactive heme (or hemes) was observed under these conditions. To determine the relative reactivities of the four hemes, we varied the extent of heme reduction at a single total protein concentration. As the hemes were progressively reduced by steady-state illumination prior to laser flash photolysis, kobs for the reaction with fully reduced lumiflavin decreased nonlinearly. Second-order rate constants for the four hemes were assigned by nonlinear least-squares analysis of kobs vs oxidized heme concentration data. The second-order rate constants obtained in this way for the highest and lowest potential hemes differed by a factor of about 20, which is larger than expected for c-type cytochromes based on redox potential alone (a factor of about 3 would be expected). This is interpreted as being due to differences in steric accessibility. Relative to the highest potential heme, which is as reactive as a typical c-type cytochrome, we estimated a steric effect of approximately twofold for heme 2, and steric effects of approximately fivefold for hemes 3 and 4. Using fully reduced FMN as reductant of oxidized cytochrome, ionic strength effects indicate a minus-minus interaction, with approximately a -2 charge near the site of reduction of the highest potential heme.     

Chemical and kinetic reaction mechanisms of quinohemoprotein amine dehydrogenase from Paracoccus denitrificans

Quinohemoprotein amine dehydrogenase (QHNDH) possesses a cysteine tryptophylquinone (CTQ) prosthetic group that catalyzes the oxidative deamination of primary amines. In addition to CTQ, two heme c cofactors are present in QHNDH that mediate the transfer of the substrate-derived electrons from CTQ to an external electron acceptor. Steady-state kinetic assays yielded relatively small k(cat) values (<6 s(-1)), and the rate-limiting step appears to be the interprotein electron transfer from heme in QHNDH to the external electron acceptor. Transient kinetic studies of the CTQ-dependent reduction of heme in QHNDH by amine substrates yielded different rate constants for different substrates (72, 190, and 162 s(-1) for methylamine, butylamine, and benzylamine, respectively). Deuterium kinetic isotope effect (KIE) values of 5.3, 3.9, and 8.5 were observed, respectively, for the reactions of methylamine, butylamine, and benzylamine. These results suggest that the abstraction of a proton from the alpha-methylene group of the substrate, which occurs concomitant with CTQ reduction, is the rate-limiting step in the CTQ-dependent reduction of hemes in QHNDH by these amine substrates. In contrast, the reaction of 2-phenylethylamine with QHNDH does not exhibit a significant KIE ((H)k(3)/(D)k(3) = 1.05) and exhibits a much smaller rate constant of 16 s(-1). This suggests that for 2-phenylethylamine, the rate-limiting step in the single-turnover reaction is either hydrolysis of the imine reaction intermediate from CTQ or product release prior to intraprotein electron transfer. Analysis of the products of the reactions of QHNDH with chiral deuterated 2-phenylethylamines demonstrated that the enzyme abstracts the pro-S proton of the substrate in a highly stereospecific manner. Inspection of the crystal structure of phenylhydrazine-inhibited QHNDH suggests that Asp33(gamma) is the residue that performs the proton abstraction. On the basis of these results, kinetic and chemical reaction mechanisms for QHNDH are proposed and discussed in the context of the crystal structure of the enzyme.     

Redox-Bohr and other cooperativity effects in the nine-heme cytochrome C from Desulfovibrio desulfuricans ATCC 27774: crystallographic and modeling studies

The nine-heme cytochrome c is a monomeric multiheme cytochrome found in Desulfovibrio desulfuricans ATCC 27774. The polypeptide chain comprises 296 residues and wraps around nine hemes of type c. It is believed to take part in the periplasmic assembly of proteins involved in the mechanism of hydrogen cycling, receiving electrons from the tetraheme cytochrome c3. With the purpose of understanding the molecular basis of electron transfer processes in this cytochrome, we have determined the crystal structures of its oxidized and reduced forms at pH 7.5 and performed theoretical calculations of the binding equilibrium of protons and electrons in these structures. This integrated study allowed us to observe that the reduction process induced relevant conformational changes in several residues, as well as protonation changes in some protonatable residues. In particular, the surroundings of hemes I and IV constitute two areas of special interest. In addition, we were able to ascertain the groups involved in the redox-Bohr effect present in this cytochrome and the conformational changes that may underlie the redox-cooperativity effects on different hemes. Furthermore, the thermodynamic simulations provide evidence that the N- and C-terminal domains function in an independent manner, with the hemes belonging to the N-terminal domain showing, in general, a lower redox potential than those found in the C-terminal domain. In this way, electrons captured by the N-terminal domain could easily flow to the C-terminal domain, allowing the former to capture more electrons. A notable exception is heme IX, which has low redox potential and could serve as the exit path for electrons toward other proteins in the electron transfer pathway.     

Reactions catalyzed by the heme domain of inducible nitric oxide synthase: evidence for the involvement of tetrahydrobiopterin in electron transfer

The heme domain (iNOS(heme)) of inducible nitric oxide synthase (iNOS) was expressed in Escherichia coli and purified to homogeneity. Characterization of the expressed iNOS(heme) shows it to behave in all respects like full-length iNOS. iNOS(heme) is isolated without bound pterin but can be readily reconstituted with (6R)-5,6,7,8-tetrahydro-L-biopterin (H(4)B) or other pterins. The reactivity of pterin-bound and pterin-free iNOS(heme) was examined, using sodium dithionite as the reductant. H(4)B-bound iNOS(heme) catalyzes both steps of the NOS reaction, hydroxylating arginine to N(G)-hydroxy-L-arginine (NHA) and oxidizing NHA to citrulline and *NO. Maximal product formation (0.93 plus minus 0.12 equiv of NHA from arginine and 0.83 plus minus 0.08 equiv of citrulline from NHA) requires the addition of 2 to 2.5 electron equiv. Full reduction of H(4)B-bound iNOS(heme) with dithionite also requires 2 to 2.5 electron equiv. These data together demonstrate that fully reduced H(4)B-bound iNOS(heme) is able to catalyze the formation of 1 equiv of product in the absence of electrons from dithionite. Arginine hydroxylation requires the presence of a bound, redox-active tetrahydropterin; pterin-free iNOS(heme) or iNOS(heme) reconstituted with a redox-inactive analogue, 6(R,S)-methyl-5-deaza-5,6,7,8-tetrahydropterin, did not form NHA under these conditions. H(4)B has an integral role in NHA oxidation as well. Pterin-free iNOS(heme) oxidizes NHA to citrulline, N(delta)-cyanoornithine, an unidentified amino acid, and NO(-). Maximal product formation (0.75 plus minus 0.01 equiv of amino acid products) requires the addition of 2 to 2.5 electron equiv, but reduction of pterin-free iNOS(heme) requires only 1 to 1.5 electron equiv, indicating that both electrons for the oxidation of NHA by pterin-free iNOS(heme) are derived from dithionite. These data provide strong evidence that H(4)B is involved in electron transfer in NOS catalysis.     

Rapid electron transfer between monomers when the cytochrome bc1 complex dimer is reduced through center N

We have obtained evidence for electron transfer between cytochrome b subunits of the yeast bc(1) complex dimer by analyzing pre-steady state reduction of cytochrome b in the presence of center P inhibitors. The kinetics and extent of cytochrome b reduced by quinol in the presence of variable concentrations of antimycin decreased non-linearly and could only be fitted to a model in which electrons entering through one center N can equilibrate between the two cytochrome b subunits of the bc(1) complex dimer. The b(H) heme absorbance in a bc(1) complex inhibited at center P and preincubated with substoichiometric concentrations of antimycin showed a red shift upon the addition of substrate, which indicates that electrons from the uninhibited center N in one monomer are able to reach the b(H) heme at the antimycin-blocked site in the other. The extent of cytochrome b reduction by variable concentrations of menaquinol could only be fitted to a kinetic model that assumes electron equilibration between center N sites in the dimer. Kinetic simulations showed that non-rate-limiting electron equilibration between the two b(H) hemes in the dimer through the two b(L) hemes is possible upon reduction through one center N despite the thermodynamically unfavorable b(H) to b(L) electron transfer step. We propose that electron transfer between cytochrome b subunits minimizes the formation of semiquinone-ferrocytochrome b(H) complexes at center N and favors ubiquinol oxidation at center P by increasing the amount of oxidized cytochrome b.     

Thermodynamic redox behavior of the heme centers of cbb3 heme-copper oxygen reductase from Bradyrhizobium japonicum

A comprehensive study of the thermodynamic redox behavior of the hemes from the cbb3 oxygen reductase from Bradyrhizobium japonicum was performed. This enzyme is a member of the C-type heme-copper oxygen reductase superfamily and has three subunits with six redox centers: four low-spin hemes and a high-spin heme and one copper ion, composing the site where oxygen is reduced. In this analysis, the visible spectra and redox properties of the five heme centers were deconvoluted. Their redox profiles and the pH dependence of the midpoint reduction potentials (redox-Bohr effect) were investigated. The reference reduction potentials (defined for a state where all centers are reduced) and homotropic interaction potentials were determined in the framework of a model of pairwise interacting redox centers. At pH 7.7, the reference reduction potentials for the three hemes c are 390, 300, and 220 mV, with low interaction potentials between them, weaker than -15 mV. For hemes b and b3, reference reduction potentials of 375 and 290 mV, respectively, were obtained; these two redox centers show an interaction potential weaker than -60 mV. The midpoint reduction potentials of all five hemes are pH-dependent. The study of these thermodynamic parameters is important in understanding the coupling mechanism of the redox and chemical processes during oxygen reduction. The analysis of the thermodynamic redox behavior of the cbb3 oxygen reductase contributes to the investigation of the mechanism of electron transfer and proton translocation by heme-copper oxygen reductases in general and indicates a thermodynamic coupling for the electron and proton transfer mechanisms.     

Reduction by dithionite ion of adducts of metmyoglobin with imidazole, pyridine, and derivatives

The rate and equilibrium constants for the information of a number of metmyoglobin species Mb+X (X = imidazole, imidazole-H-, 1-methylimidazole, 2-methylimidazole, 4-nitroimidazole, 2-methyl-5-nitroimidazole, pyridine, 2-, 3-, and 4-picoline) and the rates of their reduction by dithionite have been measured at 25 degrees. Several different kinds of kinetic behavior for the reduction were observed. In all cases, a rate constant for direct reaction of Mb+X with SO2- can be assessed. The data strongly support attack of SO2- on the ligand, followed by electron transfer through the pi system to the metal ion.     

Mechanism of bovine liver S-adenosylhomocysteine hydrolase. Steady-state and pre-steady-state kinetic analysis

The kinetic mechanism of S-adenosylhomocysteine hydrolase was investigated by stopped-flow spectrofluorometry at pH 7.0 and 25 degrees C. Pre-steady-state kinetic steps were identified with chemical steps proposed for the mechanism of this enzyme (Palmer, J.L., and Abeles, R.H. (1979) J. Biol. Chem. 254, 1217-1226). The steady-state kinetic constants for the hydrolysis or synthesis of S-adenosylhomocysteine were in good agreement with those values calculated from the pre-steady-state rate constants. The equilibrium constant for dehydration of 3'-ketoadenosine to 3'-keto-4',5'-dehydroadenosine on the enzyme was 3. The analogous equilibrium constant for addition of L-homocysteine to S-3'-keto-4',5'-dehydroadenosylhomocysteine on the enzyme was 0.3. The elimination of H2O from adenosine in solution had an equilibrium constant of 1.4 (aH2O = 1). Thus, the equilibrium constants for these elimination reactions on the enzyme were probably not perturbed significantly from those in solution. The equilibrium constant for the reduction of enzyme-bound NAD+ by adenosine was 8, and the analogous constant for the reduction of the enzyme by S-adenosylhomocysteine was 4. The equilibrium constant for the reduction of NAD+ by a secondary alcohol in solution was 5 x 10(-5) at pH 7.0. Consequently, the reduction of enzyme-bound NAD+ by adenosine was 10(5)-fold more favorable than the reduction of free NAD+. The magnitude of the first-order rate constants for the interconversion of enzyme-bound intermediates varied over a relatively small range (3-80 s-1). Similarly, the magnitude of the equilibrium constants among enzyme-bound intermediates varied over a narrow range (0.3-10). These results were consistent with the overall reversibility of the reaction.     

Nanosecond time-resolved absorption studies of human oxyhemoglobin photolysis intermediates.

The time-resolved spectra of photoproducts from ligand photodissociation of oxyhemoglobin are measured in the Soret spectral region for times from 10 ns to 320 microseconds after laser photolysis. Four processes are detected at a heme concentration of 80 microM: a 38-ns geminate recombination, a 137-ns tertiary relaxation, and two bimolecular processes for rebinding of molecular oxygen. The pseudo-first-order rate constants for rebinding to the alpha and beta subunits of hemoglobin are 3.2 x 10(4) s-1 (31 microseconds lifetime) and 9.4 x 10(4) s-1 (11 microseconds lifetime), respectively. The significance of kinetic measurements made at different heme concentrations is discussed in terms of the equilibrium compositions of hemoglobin tetramer and dimer mixtures. The rebinding rate constants for alpha and beta chains are observed to be about two times slower in the dimer than in the tetramer, a finding that appears to support the observation of quaternary enhancement in equilibrium ligand binding by hemoglobin tetramers.     

An analysis of the reaction kinetics of the hexahaem nitrite reductase of the anaerobic rumen bacterium Wolinella succinogenes.

The reduction kinetics of both the resting and redox-cycled forms of the nitrite reductase from the anaerobic rumen bacterium Wolinella succinogenes were studied by stopped-flow reaction techniques. Single-turnover reduction of the enzyme by dithionite occurs in two kinetic phases for both forms of the enzyme. When the resting form of the enzyme is subjected to a single-turnover reduction by dithionite, the slower of the two kinetic phases exhibits a hyperbolic dependence of the rate constant on the square root of the reductant concentration, the limiting value of which (approximately 4 s-1) is assigned to a slow internal electron-transfer process. In contrast, when the redox-cycled form of the enzyme is reduced by dithionite in a single-turnover experiment, both kinetic phases exhibit linear dependences of the rate on the square root of dithionite concentration, with associated rate constants of 150 M-1/2.s-1 and 6 M-1/2.s-1. Computer simulations of both the reduction processes shows that no unique set of rate constants can account for the kinetics of both forms, although the kinetics of the redox-cycled species is consistent with a much enhanced rate of internal electron transfer. Under turnover conditions the time course for reduction of the enzyme, in the presence of millimolar levels of nitrite and 100 mM-dithionite, is extremely complex. A working model for the mechanism of the turnover activity of the enzyme is proposed which very closely describes the reaction kinetics over a wide range of substrate concentrations, as shown by computer simulation. The similarity in the action of the nitrite reductase enzyme and mammalian cytochrome c oxidase is commented upon.