Comparison of the processes involved in reduction by the substrate for two homologous flavocytochromes b2 from different species of yeast.

A detailed study of the electron exchanges involved between FMN and haem b2 groups within flavocytochrome b2 of yeast Hansenula anomala (H-enzyme) was performed. The results were compared with those for the homologous enzyme of yeast Saccharomyces cerevisiae (Sx-enzyme) re-investigated at 5 degrees C. The mid-point reduction potentials of FMN and haem were determined by two complementary methods: potentiometric titration with substrate, L-lactate, in the presence of dye mediators with quantification of the reduced species performed by spectrophotometry at suitable wavelengths; anaerobic titration of the enzyme by its substrate by monitoring the e.p.r. signals of the semiquinone and Fe3+ species. Values of Em,7 = -19, -23 and -45 V were determined respectively from the data for the three redox systems Ho/Hr, Fo/Fsq and Fsq/Fr in the H-enzyme instead of +6, -44 and -57 mV respectively in the Sx-enzyme [Capeillère-Blandin, Bray, Iwatsubo & Labeyrie (1975) Eur. J. Biochem. 54, 549-566]. Parallel e.p.r rapid-freezing and absorbance stopped-flow studies allowed determination of the time courses of the various redox species during their reduction by L-lactate. The flavin and the haem reduction time courses were biphasic. In the initial fast phase the reduction of flavin monitored by absorbance measurements is accomplished with a rate constant kF = 360 s-1. The reduction of the haem lags the reduction of flavin with a rate constant kH = 170 s-1. The appearance of flavin free radical is slower than the reduction in flavin absorbance and occurs with a rate constant close to that of the reduction of the haem. At saturating L-lactate concentration the initial rapid phase (up to 15 ms) involved in the overall turnover can be adequately simulated with a two-step reaction scheme. The main difference between the enzymes lies especially at the level of the first step of electron exchange between bound lactate and flavin, which for the H-enzyme is no longer the rate-limiting step in the haem reduction and becomes 8-fold faster than in the Sx-enzyme. Consequently in the H-enzyme for the following step, the intramolecular transfer from flavin hydroquinone to oxidized haem, a reliable evaluation of the rate constants becomes possible. Preliminary values are k+2 = 380 s-1 and k-2 = 120 s-1 at 5 degrees C.(ABSTRACT TRUNCATED AT 400 WORDS)     

Flavocytochrome b2: simulation studies of the electron-transfer reactions among the prosthetic groups.

Simulation studies by digital computer were undertaken in order to test and clarify the interpretations deduced from experimental data concerning the electron transfer mechanism from L-lactate to flavocytochrome b2, which were presented in a preceding paper in this journal. The reaction scheme proposed as the "best" one is composed of 7 steps. It allows the best fitting of the time courses established for the oxidized flavin (Flox), the flavin semiquinone (Flsq), the fully reduced flavin (Flred), and the reduced haem (Hred); it can be extended to 1 s. This scheme also allows a good simulation of the general shape of preequilibrium titration curves obtained at a 200-ms reaction time for Hred and Flsq, and a valuable simulation of the reduction electron paramagnetic resonance time course established for Hred and Flsq at low lactate concentration. The agreement between experimental and simulated curves led to an estimation of some rate constants experimentally unknown, relative (in particular) to the electron exchange between flavin and haem and between couples of flavins. Another interest of these stimulation studies was to point out the obligatory involvement of a slow final step to perform the flavocytochrome b2 full reduction; this step could be controlled by some conformational change of the protein.     

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)     

Regulation of dehydrogenases/one-electron transferases by modification of flavin redox potentials. Effect of product binding on semiquinone stabilization in yeast flavocytochrome b2

Spectroscopic and potentiometric measurements have been carried out, at room temperature, during anaerobic titrations of Hansenula anomala L-lactate cytochrome c oxidoreductase (or flavocytochrome b2) both in the presence and in the absence of pyruvate (the physiological reaction product). Under the same conditions, the flavin spectral contribution was estimated and the flavosemiquinone proportion was directly determined by electron paramagnetic resonance measurements. In the present study, we show the visible light absorption and paramagnetic characteristics of the flavin radical at 18 degrees C and also the dramatic effect of pyruvate on the redox potential of each monoelectronic couple of the flavin. Thermodynamic stabilization of the semiquinone form, in the presence of pyruvate, is interpreted as a mode of regulation of flavocytochrome b2 activity. Taking into account that analogous controls have been observed with two other flavoenzymes belonging to this class of dehydrogenases/one-electron transferases, we suggest that redox potential modulation could be a type of regulation effective for the whole class of enzymes in which a semiquinone is an obligate intermediate.     

Isolation of the flavodehydrogenase domain of Hansenula anomala flavocytochrome b2 after mild proteolysis by an H. anomala proteinase

The protomeric chain of Hansenula anomala flavocytochrome b2 was previously shown to be built as the covalent association of two functional domains: an L-lactate dehydrogenase domain and a cytochrome c reductase domain, joined together by a proteolytically sensitive zone. This paper concerns the specific cleavage of this latter zone with a H. anomala proteinase(s) preparation and the purification of the resulting L-lactate dehydrogenase moiety of the molecule with at least 25% recovery, (i.e. one order of magnitude more than for the previously published method). A preliminary characterization of this dehydrogenase domain indicates that it is a tetramer (Mr = 4 x 39000) containing FMN as expected and not heme. It has high L-lactate:ferricyanide oxidoreductase activity (about 70% that of the whole flavocytochrome b2) and the same Km for L(+)-lactate as flavocytochrome b2, but it has no L-lactate:cytochrome c oxidoreductase activity. Its flavin semiquinone is stabilized in the presence of pyruvate as in flavocytochrome b2. The subcellular origin of the H. anomala proteinase in the preparation has not yet been elucidated.     

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.     

Sulfite binding to a flavodehydrogenase, cytochrome b2 from baker's yeast.

Baker's yeast L-lactate dehydrogenase (flavocytochrome b2) is a typical flavodehydrogenase, in that it accepts two electrons from the substrate but has a monoelectronic acceptor. Yet it forms a red semiquinone [Capeillère Blandin et al. Eur. J. Biochem. 54, 549--566 (1975)] and it is shown in this paper that it forms a reversible covalent complex with sulfite (Kd = 1.4 muM). This complex can be observed by difference spectroscopy and provides a convenient tool for visualizing the flavin chromophore, usually hidden behind the intense heme absorbance. A number of anions (D-lactate, oxalate and pyruvate) are inhibitors of the enzymatic reaction and induce spectral perturbations of the flavin spectrum. It is concluded that probably two positive charges exist at the active site: one which stabilizes the red semiquinone and one which attracts organic anions and sulfite. It is also concluded that the correlation between reactivity with sulfite and reactivity with oxygen among flavo-proteins may not be as general as previously proposed [Massey et al. J. Biol. Chem. 244, 3999--4006 (1969)].     

Potentiometric and further kinetic characterization of the flavin-binding domain of Saccharomyces cerevisiae flavocytochrome b2. Inhibition by anions binding in the active site

Saccharomyces cerevisiae flavocytochrome b2 (L-lactate:cytochrome c oxido reductase, EC 1.1.2.3) is a homotetramer, with FMN and protoheme IX binding on separate domains. The flavin-binding domains form the enzyme tetrameric core, while the cytochrome b2 domains appear to be mobile around a hinge region (Xia, Z. X., and Mathews, F. S. (1990) J. Mol. Biol. 212, 867-863). The enzyme catalyzes electron transfer from L-lactate to cytochrome c, or to nonphysiological acceptors such as ferricyanide, via FMN and heme b2. The kinetics of this multistep reaction are complex. In order to clarify some of its aspects, the tetrameric FMN-binding domain (FDH domain) has been independently expressed in Escherichia coli (Balme, A., Brunt, C. E., Pallister, R., Chapman, S. K., and Reid, G. A. (1995) Biochem. J. 309, 601-605). We present here an additional characterization of this domain. In our hands, it has essentially the same ferricyanide reductase activity as the holo-enzyme. The comparison of the steady-state kinetics with ferricyanide as acceptor and of the pre-steady-state kinetics of flavin reduction, as well as the kinetic isotope effects of the reactions using L-2-[2H]lactate, indicates that flavin reduction is the limiting step in lactate oxidation. During the oxidation of the reduced FDH domain by ferricyanide, the oxidation of the semiquinone is much faster than the oxidation of two-electron-reduced flavin. This order of reactivity is reversed during flavin to heme b2 transfer in the holo-enzyme. Potentiometric studies of the protein yielded a standard redox potential for FMN at pH 7.0, E(o)7, of -81 mV, a value practically identical to the published value of -90 mV for FMN in holo-flavocytochrome b2. However, as expected from the kinetics of the oxidative half-reaction, the FDH domain was characterized by a significantly destabilized flavin semiquinone state compared with holo-enzyme, with a semiquinone formation constant K of 1.25-0.64 vs 33.5, respectively (Tegoni, M., Silvestrini, M. C., Guigliarelli, B., Asso, M., and Bertrand, P. (1998) Biochemistry, 37, 12761-12771). As in the holo-enzyme, the semiquinone state in the FDH domain is significantly stabilized by the reaction product, pyruvate. We also studied the inhibition exerted in the steady and pre steady states by the reaction product pyruvate and by anions (bromide, chloride, phosphate, acetate), with respect to both flavin reduction and reoxidation. The results indicate that these compounds bind to the oxidized and the two-electron-reduced forms of the FDH domain, and that excess L-lactate also binds to the two-electron-reduced form. These findings point to the existence of a common or strongly overlapping binding site. A comparison of the effect of the anions on WT and R289K holo-flavocytochromes b2 indicates that invariant R289 belongs to this site. According to literature data, it must also be present in other members of the family of L-2-hydroxy acid-oxidizing enzymes.     

Adrenodoxin reductase and adrenodoxin. Mechanisms of reduction of ferricyanide and cytochrome c.

Adrenodoxin reductase, the flavoprotein moiety of the adrenal cortex mitochondrial steroid hydroxylating system, participates in adrenodoxin-dependent cytochrome c and adrenodoxin-independent ferricyanide reduction, with NADPH as electron donor for both of these 1-electron reductions. For ferricyanide reduction, adrenodoxin reductase cycles between oxidized and 2-electron-reduced forms, reoxidation proceeding via the neutral flavin (FAD) semiquinone form (Fig. 9). Addition of adrenodoxin has no effect upon the kinetic parameters of flavoprotein-catalyzed ferricyanide reduction. For cytochrome c reduction, the adrenodoxin reductase-adrenodoxin 1:1 complex has been shown to be the catalytically active species (Lambeth, J. D., McCaslin, D. R., and Kamin, H. (1976) J. Biol. Chem. 251, 7545-7550). Present studies, using stopped flow techniques, have shown that the 2-electron-reduced form of the complex (produced by reaction with 1 eq of NADPH) reacts rapidly with 1 eq of cytochrome c (k approximately or equal to 4.6 s-1), but only slowly with a second cytochrome c (k = 0.1 to 0.3 s-1). However, when a second NADPH is included, two more equivalents of cytochrome are reduced rapidly. Thus, the adrenodoxin reductase-adrenodoxin complex appears to cycle between 1- and 3-electron reduced states, via an intermediate 2-electron-containing form produced by reoxidation by cytochrome (Fig. 10). For ferricyanide reduction by adrenodoxin reductase, the fully reduced and semiquinone forms of flavin each transfer 1 electron at oxidation-reduction potentials which differ by approximately 130 mV. However, adrenodoxin in a complex with adrenodoxin reductase allows electrons of constant potential to be delivered from flavin to cytochrome c via the iron sulfur center...     

Cytochrome b2, an electron carrier between flavocytochrome b2 and cytochrome c. Rapid kinetic characterization of the electron-transfer parameters with ionic-strength-dependence.

The oxidation-reduction properties of free cytochrome b2 isolated by controlled proteolysis from flavocytochrome b2, i.e. the flavodehydrogenase-bound cytochrome b2, were investigated by using stopped-flow spectrophotometry. The rapid kinetics of the reduction of cytochrome b2 by flavocytochrome b2 in the presence of L-lactate are reported. The self-exchange rate constant between reduced cytochrome b2 bound to the flavodehydrogenase and free cytochrome b2 was determined to be 10(5) M-1 X S-1 at 5 degrees C, I 0.2 and pH 7.0. The specific electron-transfer reaction between reduced cytochrome b2 and cytochrome c was also studied, giving an apparent second-order rate constant of 10(7) M-1 X S-1 at 5 degrees C, I 0.2 and pH 7.0. This electron-exchange rate is slightly modulated by ionic strength, following the Debye-Hückel relationship with a charge factor Z1Z2 = -1.9. Comparison of these data with those for the reduction of cytochrome c by flavodehydrogenase-bound cytochrome b2 [Capeillère-Blandin (1982) Eur. J. Biochem. 128, 533-542] leads to the conclusion that the intramolecular electron exchange between haem b2 and haem c within the reaction complex occurs at a rate very similar to that determined experimentally in presence of the flavodehydrogenase domain. The low reaction rate observed with free cytochrome b2 is ascribed to the low stability of the reaction complex formed between free cytochrome b2 and cytochrome c.     

The reactivity of chicken liver xanthine dehydrogenase with molecular oxygen

The reaction of 6-electron reduced chicken liver xanthine dehydrogenase (XDH) with molecular oxygen was studied using both stopped flow and steady-state turnover techniques at pH 7.8, 4 degrees C. Oxidation of fully reduced XDH proceeded via four phases, three of which were detected with the stopped flow spectrophotometer. The fastest phase was second order in oxygen (1900 M-1 s-1), resulted in the appearance of flavin semiquinone and yielded no superoxide. The next phase was also second order in oxygen (260 M-1 s-1), involved the loss of flavin semiquinone and yielded, on average, 1 mol of superoxide/mol of XDH oxidized. The last 2 electron equivalents were located in the iron-sulfur centers. They were released one equivalent at a time in the form of superoxide. Steady-state kinetics were found to be critically dependent on temperature and oxygen concentration. When these factors were carefully controlled, both the xanthine-oxygen and NADH-oxygen reductase reactions gave linear Lineweaver-Burk plots. The xanthine-oxygen data yielded a turnover number of 43 min-1, which was 42% of that for xanthine-NAD turnover. During turnover, with xanthine and O2, 40-44% of the electron equivalents introduced by xanthine appeared as superoxide. Reduced pyridine nucleotides, NAD and 3-aminopyridine adenine dinucleotide, dramatically reduced the formation of superoxide at levels which did not seriously inhibit oxygen reactivity.     

Extreme pKa displacements at the active sites of FMN-dependent alpha-hydroxy acid-oxidizing enzymes.

Flavocytochrome b2 (or L-lactate dehydrogenase) from baker's yeast is thought to operate by the initial formation of a carbanion, as do the evolutionarily related alpha-hydroxy acid-oxidizing FMN-dependent oxidases. Previous work has shown that, in the active site of the unligated reduced flavocytochrome b2, the group that has captured the substrate alpha-proton has a high pKapp, calculated to lie around 15 through the use of Eigen's equation. A detailed inspection of the now known three-dimensional structure of the enzyme leads to the conclusion that the high pKa belongs to His 373, an active site group that plays the role of general base in the forward reaction and of general acid in the reverse direction. Moreover, consideration of the kinetics of proton transfer during the catalytic cycle suggests that the pKa of the reduced FMN N5 position should be lowered by several pH units compared to its pKa of 20 or more when free. The features of the three-dimensional structure possibly responsible for these pK shifts are analyzed; they are proposed to consist of a network of hydrogen bonds with the solvent and of a mutual electrostatic stabilization of anionic reduced flavin and the imidazolium ion. Finally, it is suggested that similar pK shifts affect the active sites of the alpha-hydroxy acid-oxidizing flavooxidases, which are homologous to flavocytochrome b2. The functional significance of these pK shifts in terms of catalysis and semiquinone stabilization is discussed.     

Purification and properties of the flavoenzyme D-lactate dehydrogenase from Megasphaera elsdenii.

A pyridine nucleotide independent D-lactate dehydrogenase has been purified to apparent homogeneity from the anaerobic bacterium Megasphaera elsdenii. The enzyme has a molecular weight of 105 000 by sedimentation equilibrium analysis with a subunit molecular weight of 55 000 by sodium dodecyl sulfate gel electrophoresis and is thus probably a dimer of identical subunits. It contains approximately 1 mol of FAD and 1 g-atom of Zn2+ per mol of protein subunit, and the flavin exhibits a fluorescence 1.7 times that of free FAD. An earlier purification [Brockman, H. L., & Wood, W. A. (1975 J. Bacteriol. 124, 1454--1461] results in substantial loss of the enzyme's zinc, which is required for catalytic activity. The new purification yields greater than 5 times the amount of enzyme previously isolated. The enzyme is specific for D-lactate, and no inhibition is observed with L-lactate. Surprisingly, the enzyme has a significant oxidase activity, which depends on the ionic strength. Vmax values of 190 and 530 min-1 were obtained at a gamma/2 of 0.224 and 0.442, respectively. Except for this atypically high oxygen reactivity, D-lactate dehydrogenase resembles other flavoenzyme dehydrogenases in that the flavin does not react with sulfite, the tryptophan content is low, and a neutral blue semiquinone is formed upon photochemical reduction. The enzyme flavin is reduced either by dithionite, by oxalate plus catalytic 5-deazaflavin in the presence of light, or by D-lactate. Two electrons per flavin were consumed in a dithionite titration, implyine with varying ratios of D-lactate and pyruvate, an Em7 of -0.219 +/- 0.007 V at 20 degrees C was calculated for the flavin. The enzyme requires dithiothreitol for stability. Rapid inactivation results when the enzyme is incubated with a substoichiometric level of Cu2+. This inactivation can be reversed by dithiothreitol. It is proposed that the enzyme possesses a pair of cysteine residues capable of facile disulfide formation.     

Origin of the transient electron paramagnetic resonance signals in DNA photolyase

DNA photolyase repairs pyrimidine dimer lesions in DNA through light-induced electron donation to the dimer. During isolation of the enzyme, the flavin cofactor necessary for catalytic activity becomes one-electron-oxidized to a semiquinone radical. In the absence of external reducing agents, the flavin can be cycled through the semiquinone radical to the fully reduced state with light-induced electron transfer from a nearby tryptophan residue. This cycle provides a convenient means of studying the process of electron transfer within the protein by using transient EPR. By studying the excitation wavelength dependence of the time-resolved EPR signals we observe, we show that the spin-polarized EPR signal reported earlier from this laboratory as being initiated by semiquinone photochemistry actually originates from the fully oxidized form of the flavin cofactor. Exciting the semiquinone form of the flavin produces two transient EPR signals: a fast signal that is limited by the time response of the instrument and a slower signal with a lifetime of approximately 6 ms. The fast component appears to correlate with a dismutation reaction occurring with the flavin. The longer lifetime process occurs on a time scale that agrees with transient absorption data published earlier; the magnetic field dependence of the amplitude of this kinetic component is consistent with redox chemistry that involves electron transfer between flavin and tryptophan. We also report a new procedure for the rapid isolation of DNA photolyase.     

A temperature-jump study of the electron transfer reactions in Hansenula anomala flavocytochrome b2

Temperature-jump experiments on flavocytochrome b2 were carried out at different levels of heme reduction at pH 7.0 and 6.0, and as a function of pyruvate concentration. The relaxation, corresponding to an increase in the concentration of reduced heme, is in no case a simple process. AtpH 7.0 the mean reciprocal relaxation time is 1/tau* = 190 s-1, independent of enzyme concentration, wavelength of observation and percentage of heme reduction. Flavin semiquinone has been identified as the major electron donor to the heme in this process. At the same pH the presence of pyruvate in the millimolar concentration range increases the relaxation rate and affects its amplitude. The latter effect could be accounted for by a change in redox equilibria between heme and flavin upon pyruvate binding. At pH 6.0 the relaxation pattern depends more clearly on the level of heme reduction. A rapid process (tau-1 = 2500 s-1), predominant at high percentages of reduced heme, has been assigned to the reduction of heme by flavin hydroquinone, while the slower process (tau-1 = 350 s-1), essentially the only one present at or below 50% of heme reduction, has been ascribed to the reduction of heme by flavin semiquinone. These results are discussed in relation to the catalytic mechanism of the enzyme.     

The role of the C-terminal tail of flavocytochrome b2.

A flavocytochrome b2 (L-lactate dehydrogenase) mutant was constructed in which the C-terminal tail (23 amino acid residues) had been deleted (Gly-489----Stop). This tail appears to form many intersubunit contacts in the tetrameric wild-type protein, and it was expected that its removal might lead to the formation of monomeric flavocytochrome b2. The isolated tail-deleted mutant enzyme (TD-b2), however, was found to be tetrameric (Mr 220,000). TD-b2 shows Km and kcat. values (at 25 degrees C and pH 7.5) of 0.96 +/- 0.06 mM and 165 +/- 6 s-1 respectively compared with 0.49 +/- 0.04 mM and 200 +/- 10 s-1 for the wild-type enzyme. The kinetic isotope effect with [2-2H]lactate as substrate seen for TD-b2, with ferricyanide as electron acceptor, was essentially the same as that observed for the wild-type enzyme. TD-b2 exhibited loss of activity during turnover in a biphasic process. The rate of the faster of the two phases was dependent on L-lactate concentration and at saturating concentrations showed a first-order deactivation rate constant, kf(deact.), of 0.029 s-1 (at 25 degrees C and pH 7.5). The slower phase, however, was independent of L-lactate concentration and gave a first-order deactivation rate constant, ks(deact.), of 0.01 s-1 (at 25 degrees C and pH 7.5). This slower phase was found to correlate with dissociation of FMN, which is one of the prosthetic groups of the enzyme. Thus fully deactivated TD-b2, which was also tetrameric, was found to be completely devoid of FMN. Much of the original activity of TD-b2 could be recovered by re-incorporation of FMN. Thus the C-terminal tail of flavocytochrome b2 appears to be required for the structural integrity of the enzyme around the flavin active site even though the two are well separated in space.     

Flavin and heme structures in lactate:cytochrome c oxidoreductase: a resonance Raman study

Resonance Raman spectra of Hansenula anomala L-lactate:cytochrome c oxidoreductase (or flavocytochrome b2), of its cytochrome b2 core, and of a bis(imidazole) iron-protoporphyrin complex were obtained at the Soret preresonance from the oxidized and reduced forms. Raman contributions from both the isoalloxazine ring of flavin mononucleotide (FMN) and the heme b2 were observed in the spectra of oxidized flavocytochrome b2. Raman diagrams showing frequency differences of selected FMN modes between aqueous and proteic environments were drawn for various flavoproteins. These diagrams were closely similar for flavocytochrome b2 and for flavodoxins. This showed that the FMN structure must be very similar in both types of proteins, despite their very different proteic pockets. However, the electron density at this macrocycle was found to be higher in flavocytochrome b2 than in these electron transferases. No significant difference was observed between the heme structures in flavocytochrome b2 and in cytochrome b2 core. The porphyrin center-N(pyrrole) distances in the oxidized and reduced heme b2 were estimated to be 1.990 and 2.022 A from frequencies of porphyrin skeletal modes, respectively. The frequency of the vinyl stretching mode of protoporphyrin was found to be very affected in resonance Raman spectra of flavocytochrome b2 and of cytochrome b2 core (1634-1636 cm-1) relative to those observed in the spectra of iron-protoporphyrin [bis(imidazole)] complexes (1620 cm-1). These specificities were interpreted as reflecting a near coplanarity of the vinyl groups of heme b2 with the pyrrole rings to which they are attached. The low-frequency regions of resonance Raman indicated that the iron atoms of the four hemes b2 are in the porphyrin plane whatever their oxidation state. The histidine-Fe-histidine symmetric stretching mode was located at 205 cm-1 in the spectra of flavocytochrome b2 and of cytochrome b2 core. It was insensitive to the iron oxidation state and indicated strong Fe-His bonds in both states.     

One-electron reduction of hepatic NADH-cytochrome b5 reductase as studied by pulse radiolysis

The reduction of flavin in hepatic NADH-cytochrome b5 reductase by the hydrated electron (eaq-) was investigated by pulse radiolysis. The eaq- reduced the flavin of NADH-cytochrome b5 reductase to form the red semiquinone between pH 5 and 9. The spectrum of the red semiquinone differs from that of enzyme reduced by dithionite in the presence of NAD+. After the first phase of the reduction, conversion of the red to blue semiquinone was observed at acidic pH. Resulting products are the blue (neutral) or red (anionic) semiquinone or a mixture of the two forms. The pK value for this flavin radical was approximately 6.3. Subsequently, the semiquinone form reacted by dismutation to form the oxidized and the fully reduced forms of the enzyme with a rate constant of 1 x 10(3) M-1 s-1 at pH 7.1. In the presence of NAD+, eaq- reacted with NAD+ to yield NAD(.). Subsequently, NAD. transferred an electron to NAD+-bound oxidized enzyme to form the blue and red semiquinone or mixture of the two forms of the enzyme, where pK value of this flavin radical was approximately 6.3. The blue semiquinone obtained at acidic pH was found to convert to the red semiquinone with a first order rate constant of 90 s-1, where the rates were not affected by pH or the concentration of NAD+. The final product is NAD+-bound red semiquinone of the enzyme.     

Chromatium flavocytochrome c: kinetics of reduction of the heme subunit, and the flavocytochrome c-mitochondrial cytochrome c complex

The kinetics of reduction of Chromatium vinosum flavocytochrome c heme subunit by exogenous flavin neutral semiquinones generated by laser flash photolysis have been investigated. Unlike the holoprotein, the isolated heme subunit was appreciably reactive with lumiflavin neutral semiquinone. The measured rate constant for the reaction (2.7 X 10(7) M-1 S-1) was comparable to those of c-type cytochromes having similar redox potentials. The ionic strength dependence of the reaction with FMN neutral radical indicated that the heme subunit had a small negative charge at the site of reduction. Taken together, these results suggest that the active site of the heme subunit is buried on complexation with the flavin subunit in the holoprotein. Horse cytochrome c formed a strong complex with Chromatium, but not Chlorobium, flavocytochrome c. Possible physiological electron acceptors such as HiPIP, cytochrome c', and cytochrome c-555 apparently did not bind to the flavocytochromes c. The rate constant for reduction by lumiflavin radical of horse cytochrome c complexed to flavocytochrome c was about twofold smaller than for reduction of horse cytochrome c alone. Flavocytochrome c was itself unreactive with exogenous flavin semiquinones. The ionic strength dependence of the reduction of the complex by FMN radical was also smaller than for horse cytochrome c in the absence of flavocytochrome c. Sulfite, which forms an adduct with the protein-bound FAD (FAD is bound in an 8-alpha-S-cysteinyl linkage), did not affect the reduction of horse cytochrome c in its complex with flavocytochrome c. We conclude that horse cytochrome c is reduced directly by exogenous flavins in its complex with flavocytochrome c, although the kinetics are slightly modified. These results are not unlike observations made with complexes of mitochondrial cytochrome c with cytochrome oxidase or cytochrome b5.     

Electron transfer chain reaction of the extracellular flavocytochrome cellobiose dehydrogenase from the basidiomycete Phanerochaete chrysosporium

Cellobiose dehydrogenase (CDH) is an extracellular flavocytochrome containing flavin and b-type heme, and plays a key role in cellulose degradation by filamentous fungi. To investigate intermolecular electron transfer from CDH to cytochrome c, Phe166, which is located in the cytochrome domain and approaches one of propionates of heme, was mutated to Tyr, and the thermodynamic and kinetic properties of the mutant (F166Y) were compared with those of the wild-type (WT) enzyme. The mid-point potential of heme in F166Y was measured by cyclic voltammetry, and was estimated to be 25 mV lower than that of WT at pH 4.0. Although presteady-state reduction of flavin was not affected by the mutation, the rate of subsequent electron transfer from flavin to heme was halved in F166Y. When WT or F166Y was reduced with cellobiose and then mixed with cytochrome c, heme re-oxidation and cytochrome c reduction occurred synchronously, suggesting that the initial electron is transferred from reduced heme to cytochrome c. Moreover, in both enzymes the observed rate of the initial phase of cytochrome c reduction was concentration dependent, whereas the second phase of cytochrome c reduction was dependent on the rate of electron transfer from flavin to heme, but not on the cytochrome c concentration. In addition, the electron transfer rate from flavin to heme was identical to the steady-state reduction rate of cytochrome c in both WT and F166Y. These results clearly indicate that the first and second electrons of two-electron-reduced CDH are both transferred via heme, and that the redox reaction of CDH involves an electron-transfer chain mechanism in cytochrome c reduction.