Molecular structure of flavocytochrome b2 at 2.4 A resolution

The crystal structure of flavocytochrome b2 has been solved at 3.0 A resolution by the method of multiple isomorphous replacement with anomalous scattering. Area detector data from native and two heavy-atom derivative crystals were used. The phases were refined by the B.C. Wang phase-filtering procedure utilizing the 67% (v/v) solvent content of the crystals. A molecular model was built first on a minimap and then on computer graphics from a combination of maps both averaged and not averaged about the molecular symmetry axis. The structure was extended to 2.4 A resolution using film data recorded at a synchrotron and refined by the Hendrickson-Konnert procedure. The molecule, a tetramer of Mr 230,000, is located on a crystallographic 2-fold axis and possesses local 4-fold symmetry. Each subunit is composed of two domains, one binding a heme and the other an FMN prosthetic group. In subunit 1, both the cystochrome and the flavin-binding domain are visible in the electron density map. In subunit 2 the cytochrome domain is disordered. However, in the latter, a molecule of pyruvate, the product of the enzymatic reaction, is bound at the active site. The cytochrome domain consists of residues 1 to 99 and is folded in a fashion similar to the homologous soluble fragment of cytochrome b5. The flavin binding domain contains a parallel beta 8 alpha 8 barrel structure and is composed of residues 100 to 486. The remaining 25 residues form a tail that wraps around the molecular 4-fold axis and is in contact with each remaining subunit. The FMN moiety, which is located at the C-terminal end of the central beta-barrel, is mostly sequestered from solvent; it forms hydrogen bond interactions with main- and side-chain atoms from six of the eight beta-strands. The interaction of Lys349 with atoms N-1 and O-2 of the flavin ring is probably responsible for stabilization of the anionic form of the flavin semiquinone and hydroquinone and enhancing the reactivity of atom N-5 toward sulfite. The binding of pyruvate at the active site in subunit 2 is stabilized by interaction of its carboxylate group with the side-chain atoms of Arg376 and Tyr143. Residues His373 and Tyr254 interact with the keto-oxygen atom and are involved in catalysis. In contrast, four water molecules occupy the substrate-binding site in subunit 1 and Tyr143 forms a hydrogen bond to the ordered heme propionate group. Otherwise the two flavin-binding domains are identical within experimental error.(ABSTRACT TRUNCATED AT 400 WORDS)     

Evidence by NMR for mobility of the cytochrome domain within flavocytochrome b2

According to a model proposed by Gervais, M, Groudinsky, O., Risler, Y. and Labeyrie, F. ((1977) Biochem. Biophys. Res. Commun. 77, 1543-1551) flavocytochrome b2 is composed of a central flavodehydrogenase entity of 4 X 45 kDa to which are attached four cytochrome b2 globules of approx. 11 kDa that are released after proteolysis of the connective loops. A possible inherent mobility of the latter with functional significance was suspected. Proton NMR spectra at 400 MHz of the isolated and of the flavodehydrogenase-bound ferricytochrome b2 units have been compared. In the ranges downfield of +12 ppm and upfield from -4 ppm, where hyperfine-shifted heme proton resonances reside, the chemical shifts are identical for the two forms, but the linewidths are markedly broader for flavocytochrome b2. The linewidths of three heme resonances, a methyl at +19 ppm, two single protons at -6 and -8 ppm (most probably from one vinyl) and an unassigned line at -2.4 ppm, all increase by a factor of about 4. Since, in the present case, linewidths are controlled mainly by proton/proton dipolar relaxations which are caused by molecular tumbling, a change in linewidths of about 15 would be expected if the cytochrome b2 globule had no free motion relative to the flavodehydrogenase domain. The present results thus support the previous hypothesis that such a relative mobility, of unknown correlation time and amplitude, actually exists.     

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.     

Complete amino acid sequence of flavocytochrome b2 from baker's yeast

Each subunit of baker's yeast flavocytochrome b2 can be selectively cleaved by proteases into two fragments, amino-terminal fragment alpha and carboxy-terminal fragment beta. The primary structure of the former has been reported before [Ghrir, B., Becam, A. M. & Lederer, F. (1984) Eur. J. Biochem. 139, 59-74]. The amino acid sequence of the 197-residue fragment beta has now been established. The fragment was cleaved with cyanogen bromide; the three peptides thus obtained were submitted to digestions with Staphylococcus aureus V8 protease, chymotrypsin and trypsin, sometimes after succinylation. The complete fragment was also submitted to tryptic cleavage after citraconylation. Peptides were separated by thin-layer finger-printing or high-pressure liquid chromatography. They were mostly sequenced in a liquid-phase sequenator. The 511-residue amino acid sequence of the mature protein is thus completely established. Secondary structure predictions indicate an alternation of helical and extended structure, with a higher percentage of the former. Comparisons with other flavoproteins do not detect any significant sequence similarity.     

A hypothetical complex between crystalline flavocytochrome b2 and Cytochrome c

Flavocytochrome b₂ and cytochrome c are physiological electron transfer partners in yeast mitochondria. The formation of a stable complex between them has been demonstrated both in solution and in the crystalline state. On the basis of the three-dimensional structures, using molecular modeling and energy minimization, we have generated a hypothetical model for the interaction of these redox partners in the crystal lattice. General criteria such as good charge and surface complementarity, plausible orientation, and separation distance of the prosthetic groups, as well as more specific criteria such as the stoichiometry determined in the crystal, and the involvement of both domains and of more than one subunit of flavocytochrome b₂ led us to discriminate between several possible interaction sites. In the hypothetical model we present, four cytochrome c molecules interact with a tetramer of flavocytochrome b₂. The b₂ and c hemes are coplanar, with an edge-to-edge distance of 14 Å. the contact surface area is ca. 800 Ų. Several electrostatic interactions involving the flavin and the heme domains of flavocytochrome b₂ stabilize the binding of cytochrome c. © 1993 Wiley-Liss, Inc.     

High-level expression of fully active yeast flavocytochrome b2 in Escherichia coli.

Wild-type flavocytochrome b2 (L-lactate dehydrogenase) from the yeast Saccharomyces cerevisiae and three singly substituted mutant forms (F254, R349 and K376) have been expressed in the bacterium Escherichia coli. The enzyme expressed in E. coli contains the protohaem IX and flavin mononucleotide (FMN) prosthetic groups found in the enzyme isolated from yeast, has an electronic absorption spectrum identical with that of the yeast protein and an identical Mr value of 57,500 estimated by SDS/polyacrylamide-gel electrophoresis. N-Terminal amino-acid-sequence data indicate that the flavocytochrome b2 isolated from E. coli begins at position 6 (methionine) when compared with mature flavocytochrome b2 from yeast. The absence of the first five amino acid residues appears to have no effect on the enzyme-catalysed oxidation of L-lactate, since Km values for the yeast- and E. coli-expressed wild-type enzymes were identical within experimental error. The F254 mutant enzyme expressed in E. coli also showed kinetic parameters essentially the same as those found for the enzyme from yeast. The R349 and K376 mutant enzymes had no activity when expressed in either yeast or E. coli. The yield of flavocytochrome b2 from E. coli is estimated to be between 500- and 1000-fold more than from a similar wet weight of yeast (this high level of expression results in E. coli cells which are pink in colour). The increased yield has allowed us to verify the presence of FMN in the R349 mutant enzyme. The advantages of E. coli as an expression system for flavocytochrome b2 are discussed.     

New ELISA-based method for the detection of O-GlcNAc transferase activity in vitro

O-GlcNAcylation is a dynamic, reversible, post-translational modification that regulates many cellular processes. O-GlcNAc transferase (OGT) is the sole enzyme transferring N-acetylglucosamine from uridine diphosphate (UDP)-GlcNAc to selected serine/threonine residues of cytoplasm and nucleus proteins. Aberrant of OGT activity is associated with several diseases, suggesting OGT as a novel therapeutic target. In this study, we created a new enzyme linked immunosorbent assays (ELISA)-based method for detection of OGT activity. First, casein kinase II (CKII), a well-known OGT substrate, was coated onto ELISA plate. Second, the GlcNAc transferred by OGT from UDP-GlcNAc to CKII was detected using an antibody to O-GlcNAc and then the horseradish peroxidase (HRP)-labeled secondary antibody. At last, 3,3′,5,5′-tetramethylbenzidine (TMB), the substrate of HRP, was used to detect the O-GlcNAcylation level of CKII which reflected the activity of OGT. Based on a series of optimization experiments, the RL2 antibody was selected for O-GlcNAc detection and the concentrations of CKII, OGT, and UDP-GlcNAc were determined in this study. ST045849, a commercial OGT inhibitor, was used to verify the functionality of the system. Altogether, this study showed a method that could be applied to detect OGT activity and screen OGT inhibitors.     

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.     

Baker's yeast flavocytochrome b2. A mechanistic study of the dehydrohalogenation reaction

It has been shown that reduced flavocytochrome b2 not only catalyzes reduction of bromopyruvate [P. Urban, P.M. Alliel and F. Lederer (1983) Eur. J. Biochem. 134, 275-281] but also transforms it into pyruvate in a reductive elimination process. The dehydrohalogenation reaction also takes place when oxidized enzyme acts on bromolactate, but the reaction is more difficult to observe under these conditions because of its low efficiency compared to the normal oxidative process. The maximal rates of pyruvate production from bromopyruvate and chloropyruvate differ by a factor of less than 10, whereas elimination from fluoropyruvate cannot be detected. These results support a mechanism in which the dehydrohalogenation reaction takes place from a carbanion intermediate of the normal reductive-oxidative pathway.     

Inactivation of flavocytochrome b2 with fluoropyruvate. Reaction at the active-site histidine

Fluoropyruvate inactivated oxidized flavocytochrome b2 (baker's yeast L-lactate dehydrogenase) in a biphasic process yielding convex semilog plots of residual activity versus time. At each reagent concentration, rate constants k1 and k2 for the two phases could be calculated by simulation studies using one of the schemes proposed by Ray and Koshland [J. Biol. Chem. (1961) 236, 1973-1979]: E----E1 (fully active)----E2 (inactive). When plotted as a function of reagent concentration, the values of k2, but not those of k1, showed a saturation effect. Inactivation was slowed down by D-lactate, a competitive inhibitor, and completely prevented by enzyme reduction. While no enzyme chemical modification could be demonstrated for the first step, the inactivation event of the second step could be ascribed to alkylation of a histidine belonging to proteolytic fragment beta of the enzyme. The only histidine present in the fragment sequence is His-373. In the enzyme three-dimensional structure [Xia et al. (1987) Proc. Natl Acad. Sci. USA 84, 2629-2633] His-373 is well located, close to the cofactor, to play the role of the active-site base required by the chemical mechanism. Alternative chemical interpretations of the kinetic scheme are discussed, so is the difference between flavocytochrome b2 inactivation by fluoropyruvate and bromopyruvate.     

Crystallographic study of the complex between sulfite and bakers' yeast flavocytochrome b2

The complex between Saccharomyces cerevisiae flavocytochrome b2 and the sulfite anion has been analyzed by x-ray diffraction. A map of the difference in electron density between the complex and the native protein has been computed. One positive peak of electron density is visible at the active site of each of the two subunits in the asymmetric unit, very close to the N-5 of the flavin. The molecular fragment SO3(2-) can account for the shape of this difference in electron density. A third peak is visible in the subunit containing pyruvate, the reaction product. It is a peak of negative electron density localized at the position where the pyruvate usually is in the native form. These results are interpreted on the basis of the mechanism defined in solution for the reaction between flavins and sulfite.     

Intermolecular hydrogen transfer catalyzed by a flavodehydrogenase, bakers' yeast flavocytochrome b2

Bakers' yeast flavocytochrome b2 is a flavin-dependent L-2-hydroxy acid dehydrogenase which also exhibits transhydrogenase activity. When a reaction takes place between [2-3H]lactate and a halogenopyruvate, tritium is found in water and at the halogenolactate C2 position. When the halogenopyruvate undergoes halide ion elimination, tritium is also found at the C3 position of the resulting pyruvate. The amount tau of this intermolecular tritium transfer depends on the initial keto acid-acceptor concentration. At infinite acceptor concentration, extrapolation yields a maximal transfer of 97 +/- 11%. This indicates that the hydroxy acid-derived hydrogen resides transiently on enzyme monoprotic heteroatoms and that exchange with bulk solvent occurs only at the level of free reduced enzyme. Using a minimal kinetic scheme, the rate constant for hydrogen exchange between Ered and solvent is calculated to be on the order of 10(2) M-1 S-1, which leads to an estimated pK approximately equal to 15 for the ionization of the substrate-derived proton while on the enzyme. It is suggested that this hydrogen could be shared between the active site base and Flred N5 anion. It is furthermore shown that some tritium is incorporated into the products when the transhydrogenation is carried out in tritiated water. Finally, with [2-2H]lactate-reduced enzyme, a deuterium isotope effect is observed on the rate of bromopyruvate disappearance. Extrapolation to infinite bromopyruvate concentration yields DV = 4.4. An apparent inverse isotope effect is determined for bromide ion elimination. These results strengthen the idea that oxidoreduction and elimination pathways involve a common carbanionic intermediate.     

An EPR study of the interactions between heme and flavin in yeast flavocytochrome b2

E.P.R. experiments and spin-lattice relaxation time measurements have been performed on Flavocytochrome b ₂in the range 10 K to 100 K, to obtain information on the distance between the two prosthetic groups of the protein, flavin and heme. We have used the stabilization effect of pyruvate on the semiquinone form of the flavin, to compare the E.P.R. spectral shape and the relaxation properties of the radical when the heme is either in the ferrous form or in the ferric form. When the heme is ferric, no significant increase of the line broadening or enhancement of the relaxation rate of the radical can be detected in the range 10 K to 100 K. From these results, a minimum intercentre distance of 18 to 20 Å can be estimated.     

Changing the heme ligation in flavocytochrome b 2: substitution of histidine-66 by cysteine

Substitution by cysteine of one of the heme iron axial ligands (His66) of flavocytochrome b2 (L-lactate:cytochrome c oxidoreductase from Saccharomyces cerevisiae) has resulted in an enzyme (H66C-b2) which remains a competent L-lactate dehydrogenase (kcat 272+/-6 s(-1), L-lactate KM 0.60+/-0.06 mM, 25 degrees C, I 0.10, Tris-HCl, pH 7.5) but which has no cytochrome c reductase activity. As a result of the mutation, the reduction potential of the heme was found to be -265+5 mV, over 240 mV more negative than that of the wild-type enzyme, and therefore unable to be reduced by L-lactate. Surface-enhanced resonance Raman spectroscopy indicates similarities between the heme of H66C-b2 and those of cytochromes P450, with a nu4 band at 1,345 cm(-1) which is indicative of cysteine heme-iron ligation. In addition, EPR spectroscopy yields g-values at 2.33, 2.22 and 1.94, typical of low-spin ferric cytochromes P450, optical spectra show features between 600 and 900 nm which are characteristic of sulfur coordination of the heme iron, and MCD spectroscopy shows a blue-shifted NIR CT band relative to the wild-type, implying that the H66C-b2 heme is P450-like. Interestingly, EPR evidence also suggests that the second histidine heme-iron ligand (His43) is displaced in the mutant enzyme.     

Location of a cytochrome c binding site on the surface of flavocytochrome b 2

Saccharomyces cerevisiae flavocytochrome b ₂ couples the oxidation of L-lactate to the reduction of cytochrome c. The second-order rate constant for cytochrome c reduction by flavocytochrome b ₂ depends on the rate of complex formation and is sensitive to ionic strength. Mutations in the heme domain of flavocytochrome b ₂ (Glu63→Lys, Asp72→Lys and the double mutation Glu63→Lys:Asp72→Lys) have significant effects on the reaction with cytochrome c, implicating these residues in complex formation. This kinetic information has been used to guide molecular modelling studies, which are consistent with there being no one single best-configuration. Rather, there is a set of possible complexes in which the docking-face of cytochrome c can approach flavocytochrome b ₂ in a variety of orientations. Four cytochromes c can be accommodated on the flavocytochrome b ₂ tetramer, with each cytochrome c forming interactions with only one flavocytochrome b ₂ subunit. All the models involve residues 72 and 63 on flavocytochrome b ₂ but in addition predict that Glu237 may also be important for complex formation. These acidic residues interact with the basic residues 13, 27 and 79 on cytochrome c. Through this triangle of interactions runs a possible σ-tunnelling pathway for electron transfer. This pathway starts with the imidazole ring of His66 (a ligand to the heme-iron of flavocytochrome b ₂) and ends with the ring of Pro68, which is in van der Waals contact with the cytochrome c heme. In total, the edge-to-edge "through space" distance from the imidazole ring of His66 to the C3C pyrrole ring of cytochrome c is 13.1?Å.     

Influence of oxygen on the synthesis of flavocytochrome b2 by the yeast Hansenula anomala

Summary Control of oxygen concentration in the culture medium during growth of the yeast Hansenula anomala on l-lactate as sole carbon source allows induction of the synthesis of flavocytochrome b2 or l-lactate cytochrome-c oxydoreductase (E.C. 1.1.2.3.). This phenomenon is accompanied by an important change in the yeast doubling time.     

Binding of Cibacron Blue F3GA to flavocytochrome b2 from baker's yeast.

1. Flavin-free cytochrome b2 has been prepared by rapid Sephadex filtration at acid pH. The method, which yields an apo-enzyme with high reconstitution potential and has several advantages over previously used procedures, is described in detail. 2. Flavin-free cytochrome b2 thus prepared is retained by blue-dextran-bound Sepharose. It can be eluted by an increase in ionic strength, by dilute ethylene glycol and specifically by low concentrations of FMN. The holoenzyme is not retarded at all. 3. Both flavin-free and holocytochrome b2 bind Cibacron blue F3GA with appearance of distinct difference spectra. Cibacron blue is an inhibitor for the holoenzyme, it shows mixed type inhibition with respect to lactate. 4. It is concluded that there are two types of binding sites for Cibacron blue F3GA on flavocytochrome b2. Both possess ionic and hydrophobic character; one of them, which is the flavin binding site, is only available in the absence of the cofactor. Taken together these results may mean that the enzyme possesses a local flavin-binding structure similar to the 'dinucleotide fold'.     

About the pKa of the active-site histidine in flavocytochrome b2 (yeast L-lactate dehydrogenase).

Flavocytochrome b2 or L-lactate dehydrogenase from yeasts catalyzes the oxidation of L-lactate at the expense of monoelectronic acceptors such as cytochrome c, its physiological partner. When incubated in the presence of both L-lactate and a keto acid, the enzyme catalyzes a transhydrogenation reaction wherein only the flavin is involved. During this reaction, the substrate alpha-hydrogen is transferred not only to the solvent but also in part to the keto acid, which acts as reverse substrate. Thus, when bound to the reduced enzyme, this hydrogen is sticky. In the context of a carbanion mechanism, it resides on Nepsilon of His373, the active site base. We have shown before that a correlation between the amount of intermolecular hydrogen transfer from [2-3H] lactate and the keto acid reverse substrate concentration enables the determination of the first-order rate constant, kHe, for exchange of the substrate-derived protein-bound hydrogen with bulk solvent (Urban P, Lederer F, 1985, J Biol Chem 260:11115-11122). In this work, we show that the exchange with the solvent appears to be independent of the phosphate buffer concentration in the range from 40 to 500 mM. It is thus probable that exchange occurs directly with water molecules. The second-order rate constant for exchange is then 0.16 (+/-0.03) M(-1) s(-1). Using the Eigen equation, this figure yields a pKa of 9.1+/-0.1 for His373 in the reduced enzyme, compared to a probable value of 6.0 or less in the oxidized enzyme (Suzuki H, Ogura YC, 1970, J Biochem 67:291-295). The mechanistic significance of these results is discussed.