Amino acid sequence of long chain alpha-hydroxy acid oxidase from rat kidney, a member of the family of FMN-dependent alpha-hydroxy acid-oxidizing enzymes

The complete amino acid sequence of rat kidney long chain alpha-hydroxy acid oxidase has been determined by microsequencing, using a number of standard enzymatic and chemical cleavages. Peptides were purified by high pressure liquid chromatography or by gel electrophoresis followed by electrotransfer. The sequence comprises 352 residues and ends with a peroxisomal targeting sequence SRL. The present work definitely establishes that hydroxy acid oxidase is a member of the family of FMN-dependent alpha-hydroxy acid-oxidizing enzymes. The family includes lactate oxidase, short chain alpha-hydroxy acid oxidase (glycolate oxidase), flavocytochrome b2, and mandelate dehydrogenase. There are altogether 45 totally conserved positions among the six sequences known. The sequence similarities are analyzed in light of the known three-dimensional structure of flavocytochrome b2 and glycolate oxidase. It is concluded that long chain hydroxy acid oxidase should be folded as a beta 8 alpha 8 barrel and should dehydrogenate alpha-hydroxy acids according to the same chemical mechanism as other enzymes of the family, in spite of a Tyr----Phe substitution at the active site.     

The crystal structure of L-lactate oxidase from Aerococcus viridans at 2.1A resolution reveals the mechanism of strict substrate recognition

L-Lactate oxidase (LOX) from Aerococcus viridans is a member of the alpha-hydroxyacid-oxidase flavoenzyme family. We have determined the three-dimensional structure of LOX and revealed the mechanism of substrate recognition. The LOX monomer structure has a typical alpha(8)/beta(8) motif commonly found in other flavin family proteins. A related enzyme, glycolate oxidase, catalyzes the oxidation of glycolate rather than lactate. Comparison of the two enzyme structures highlights the importance of five residues around the FMN prosthetic group of LOX, which act synergistically to discriminate between the l/d configurations of lactate. X-ray crystallography of LOX gave a space group I422 of unit-cell parameters a=b=191.096A, c=194.497A and alpha=beta=gamma=90 degrees with four monomers per asymmetric unit. The four independent monomers display slight structural differences around the active site. Diffraction data were collected, under cryogenic conditions to 2.1A resolution at the synchrotron facilities in Japan.     

Flavocytochrome b2: reactivity of its flavin with molecular oxygen

Flavocytochrome b2, a flavohemoprotein, catalyzes the oxidation of lactate at the expense of the physiological acceptor cytochrome c in the yeast mitochondrial intermembrane space. The mechanism of electron transfer from the substrate to monoelectronic acceptors via FMN and heme b2 has been intensively studied over the years. Each prosthetic group is bound to a separate domain, N-terminal for the heme, C-terminal for the flavin. Each domain belongs to a distinct evolutionary family. In particular, the flavodehydrogenase domain is homologous to a number of well-characterized l-2-hydroxy acid-oxidizing enzymes. Among these, some are oxidases for which the oxidative half-reaction produces hydrogen peroxide at the expense of oxygen. For bacterial mandelate dehydrogenase and flavocytochrome b2, in contrast, the oxidative half-reaction requires monoelectronic acceptors. Several crystal structures indicate an identical fold and a highly conserved active site among family members. All these enzymes form anionic semiquinones and bind sulfite, properties generally associated with oxidases, whereas electron transferases are expected to form neutral semiquinones and to yield superoxide anion. Thus, flavocytochrome b2 is a highly unusual dehydrogenase-electron transferase, and one may wonder how its flavin reacts with oxygen. In this work, we show that the separately engineered flavodehydrogenase domain produces superoxide anion in its slow reaction with oxygen. This reaction apparently also takes place in the holoenzyme when oxygen is the sole electron acceptor, because the heme domain autoxidation is also slow; this is not unexpected, in view of the heme domain mobility relative to the tetrameric flavodehydrogenase core (Xia, Z. X., and Mathews, F. S. (1990) J. Mol. Biol. 212, 837-863). Nevertheless, this reaction is so slow that it cannot compete with the normal electron flow in the presence of monoelectronic acceptors, such as ferricyanide and cytochrome c. An inspection of the available structures of family members does not provide a rationale for the difference between the oxidases and the electron transferases.     

Similarity of different β-strands flanked in loops by glycines and prolines from distinct (α/β)8-barrel enzymes: Chance or a homology?

Many (alpha/beta)8-barrel enzymes contain their conserved sequence regions at or around the beta-strand segments that are often preceded and succeeded by glycines and prolines, respectively. alpha-Amylase is one of these enzymes. Its sequences exhibit a very low degree of similarity, but strong conservation is seen around its beta-strands. These conserved regions were used in the search for similarities with beta-strands of other (alpha/beta)8-barrel enzymes. The analysis revealed an interesting similarity between the segment around the beta 2-strand of alpha-amylase and the one around the beta 4-strand of glycolate oxidase that are flanked in loops by glycines and prolines. The similarity can be further extended on other members of the alpha-amylase and glycolate oxidase subfamilies, i.e., cyclodextrin glycosyltransferase and oligo-1,6-glucosidase, and flavocytochrome b2, respectively. Moreover, the alpha-subunit of tryptophan synthase, the (alpha/beta)8-barrel enzyme belonging to the other subfamily of (alpha/beta)8-barrels, has both investigated strands, beta 2 and beta 4, similar to beta 2 of alpha-amylase and beta 4 of glycolate oxidase. The possibilities of whether this similarity exists only by chance or is a consequence of some processes during the evolution of (alpha/beta)8-barrel proteins are briefly discussed.     

Three-dimensional structure of the iron-sulfur flavoprotein trimethylamine dehydrogenase at 2.4-A resolution

The three-dimensional structure of trimethylamine dehydrogenase from the methylotrophic bacterium W3A1 has been determined to 2.4-A resolution. The enzyme is composed of two identical 83,000-dalton subunits, each of which is folded into three structural domains. The largest domain, at the NH2 terminus of the molecule, is folded as an eight-stranded parallel alpha/beta barrel. It contains the [4Fe-4S] and covalently bound FMN cofactors separated by about 4 A. The folding topology of the large domain and orientation of the FMN cofactor are very similar to those found in glycolate oxidase. The other two domains contain alpha/beta parallel beta sheet topologies with similar folding patterns. The topologies and spatial arrangements of these two domains are remarkably similar to the FAD- and NADPH-binding domains of glutathione reductase.     

Three-dimensional structures of glycolate oxidase with bound active-site inhibitors.

A key step in plant photorespiration, the oxidation of glycolate to glyoxylate, is carried out by the peroxisomal flavoprotein glycolate oxidase (EC 1.1.3.15). The three-dimensional structure of this alpha/beta barrel protein has been refined to 2 A resolution (Lindqvist Y. 1989. J Mol Biol 209:151-166). FMN dependent glycolate oxidase is a member of the family of alpha-hydroxy acid oxidases. Here we describe the crystallization and structure determination of two inhibitor complexes of the enzyme, TKP (3-Decyl-2,5-dioxo-4-hydroxy-3-pyrroline) and TACA (4-Carboxy-5-(1-pentyl)hexylsulfanyl-1,2,3-triazole). The structure of the TACA complex has been refined to 2.6 A resolution and the TKP complex, solved with molecular replacement, to 2.2 A resolution. The Rfree for the TACA and TKP complexes are 24.2 and 25.1%, respectively. The overall structures are very similar to the unliganded holoenzyme, but a closer examination of the active site reveals differences in the positioning of the flavin isoalloxazine ring and a displaced flexible loop in the TKP complex. The two inhibitors differ in binding mode and hydrophobic interactions, and these differences are reflected by the very different Ki values for the inhibitors, 16 nM for TACA and 4.8 microM for TKP. Implications of the structures of these enzyme-inhibitor complexes for the model for substrate binding and catalysis proposed from the holo-enzyme structure are discussed.     

Crystal structure analysis of recombinant rat kidney long chain hydroxy acid oxidase

Long chain hydroxy acid oxidase (LCHAO) is a member of an FMN-dependent enzyme family that oxidizes L-2-hydroxy acids to ketoacids. LCHAO is a peroxisomal enzyme, and the identity of its physiological substrate is unclear. Mandelate is the most efficient substrate known and is commonly used in the test tube. LCHAO differs from most family members in that one of the otherwise invariant active site residues is a phenylalanine (Phe23) instead of a tyrosine. We now report the crystal structure of LCHAO. It shows the same beta8alpha8 TIM barrel structure as other structurally characterized family members, e.g., spinach glycolate oxidase (GOX) and the electron transferases yeast flavocytochrome b2 (FCB2) and Pseudomonas putida mandelate dehydrogenase (MDH). Loop 4, which is mobile in other family members, is visible in part. An acetate ion is present in the active site. The flavin interacts with the protein in the same way as in the electron transferases, and not as in GOX, an unexpected observation. An interpretation is proposed to explain this difference between GOX on one hand and FCB2 and LCHAO on the other hand, which had been proposed to arise from the differences between family members in their reactivity with oxygen. A comparison of models of the substrate bound to various published structures suggests that the very different reactivity with mandelate of LCHAO, GOX, FCB2, and MDH cannot be rationalized by a hydride transfer mechanism.     

Structural conservation in parallel beta/alpha-barrel enzymes that catalyze three sequential reactions in the pathway of tryptophan biosynthesis

Three successive steps in tryptophan biosynthesis are catalyzed by single-domain proteins, each folded as a parallel beta/alpha-barrel, as observed in the crystal structures of the bienzyme (phosphoribosyl)-anthranilate isomerase:indoleglycerolphosphate synthase from Escherichia coli [Priestle, J.P., Grütter, M. G., White, J. L., Vincent, M. G., Kania, M., Wilson, E., Jardetzky, T. S., Kirschner, K., & Jansonius, J. N. (1987) Proc. Natl. Acad. Sci. U.S.A. 84, 5690-5694] and the alpha-subunit of the tetrameric bienzyme tryptophan synthase from Salmonella typhimurium [Hyde, C. C., Ahmed, S. A., Padlan, E. A., Miles, E. W., & Davies, D. R. (1988) J. Biol. Chem. 263, 17857-17871]. Recent refinement of the crystal structures of these enzymes at atomic resolution revealed that they contain a common phosphate group binding site in the beta/alpha-barrel, created by residues of the loop between beta-strand 7 and alpha-helix 7 and the N-terminus of an additional helix 8'. The close similarities of their beta/alpha-barrel structures permitted the alignment of 50-75% of their respective amino acid sequences. Considerable sequence similarity was detected in the regions spanning the phosphate binding sites, whereas the percentage of identical residues was barely significant for the remaining parts of the enzymes. These observations suggest divergent evolution of these three beta/alpha-barrel enzymes involved in tryptophan biosynthesis. The same phosphate binding site was also observed in six other beta/alpha-barrel enzymes that are functionally unrelated to those involved in tryptophan biosynthesis: triosephosphate isomerase, ribulose-1,5-bisphosphate carboxylase/oxygenase, glycolate oxidase, flavocytochrome b2, trimethylamine dehydrogenase, and tentatively also fructosebisphosphate aldolase.(ABSTRACT TRUNCATED AT 250 WORDS)     

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)     

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.     

X-ray structure of Escherichia coli pyridoxine 5'-phosphate oxidase complexed with pyridoxal 5'-phosphate at 2.0 A resolution.

Escherichia coli pyridoxine 5'-phosphate oxidase catalyzes the terminal step in the biosynthesis of pyridoxal 5'-phosphate by the FMN oxidation of pyridoxine 5'-phosphate forming FMNH(2) and H(2)O(2). Recent studies have shown that in addition to the active site, pyridoxine 5'-phosphate oxidase contains a non-catalytic site that binds pyridoxal 5'-phosphate tightly. The crystal structure of pyridoxine 5'-phosphate oxidase from E. coli with one or two molecules of pyridoxal 5'-phosphate bound to each monomer has been determined to 2.0 A resolution. One of the pyridoxal 5'-phosphate molecules is clearly bound at the active site with the aldehyde at C4' of pyridoxal 5'-phosphate near N5 of the bound FMN. A protein conformational change has occurred that partially closes the active site. The orientation of the bound pyridoxal 5'-phosphate suggests that the enzyme catalyzes a hydride ion transfer between C4' of pyridoxal 5'-phosphate and N5 of FMN. When the crystals are soaked with excess pyridoxal 5'-phosphate an additional molecule of this cofactor is also bound about 11 A from the active site. A possible tunnel exists between the two sites so that pyridoxal 5'-phosphate formed at the active site may transfer to the non-catalytic site without passing though the solvent.     

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)     

Heterotetrameric sarcosine oxidase: structure of a diflavin metalloenzyme at 1.85 A resolution

The crystal structure of heterotetrameric sarcosine oxidase (TSOX) from Pseudomonas maltophilia has been determined at 1.85 A resolution. TSOX contains three coenzymes (FAD, FMN and NAD+), four different subunits (alpha, 103 kDa; beta, 44 kDa; gamma, 21 kDa; delta, 11 kDa) and catalyzes the oxidation of sarcosine (N-methylglycine) to yield hydrogen peroxide, glycine and formaldehyde. In the presence of tetrahydrofolate, the oxidation of sarcosine is coupled to the formation of 5,10-methylenetetrahydrofolate. The NAD+ and putative folate binding sites are located in the alpha-subunit. The FAD binding site is in the beta-subunit. FMN is bound at the interface of the alpha and beta-subunits. The FAD and FMN rings are separated by a short segment of the beta-subunit with the closest atoms located 7.4 A apart. Sulfite, an inhibitor of oxygen reduction, is bound at the FMN site. 2-Furoate, a competitive inhibitor with respect to sarcosine, is bound at the FAD site. The sarcosine dehydrogenase and 5,10-methylenetetrahydrofolate synthase sites are 35 A apart but connected by a large internal cavity (approximately 10,000 A3). An unexpected zinc ion, coordinated by three cysteine and one histidine side-chains, is bound to the delta-subunit. The N-terminal half of the alpha subunit of TSOX (alphaA) is closely similar to the FAD-binding domain of glutathione reductase but with NAD+ replacing FAD. The C-terminal half of the alpha subunit of TSOX (alphaB) is similar to the C-terminal half of dimethylglycine oxidase and the T-protein of the glycine cleavage system, proteins that bind tetrahydrofolate. The beta-subunit of TSOX is very similar to monomeric sarcosine oxidase. The gamma-subunit is similar to the C-terminal sub-domain of alpha-TSOX. The delta-subunit shows little similarity with any PDB entry. The alphaA domain/beta-subunit sub-structure of TSOX closely resembles the alphabeta dimer of L-proline dehydrogenase, a heteroctameric protein (alphabeta)4 that shows highest overall similarity to TSOX.     

L-lactate 2-monooxygenase from Mycobacterium smegmatis. Cloning, nucleotide sequence, and primary structure homology within an enzyme family

L-Lactate 2-monooxygenase catalyzes the oxidation of L-lactate to acetate and carbon dioxide. The catalytic mechanism has been extensively investigated but very little is known about which amino acid residues may play a role in catalysis. As a first step toward this goal, the gene for this protein from Mycobacterium smegmatis has been cloned and sequenced. Peptide sequencing data for L-lactate 2-monooxygenase was used to construct three sets of fully redundant tetradecamer oligonucleotide probes, which were hybridized to restriction-digested M. smegmatis DNA. An approximately 3-kilobase pair PstI fragment hybridized with two of the probes. This region was subsequently isolated and cloned into Escherichia coli. From this size-fractionated gene bank, a 3.1-kilobase pair genomic DNA fragment was isolated by colony hybridization to two of the oligonucleotide probes. The complete gene for L-lactate 2-monooxygenase was contained on this fragment as shown by DNA sequencing of the whole insert. The DNA sequence codes for a mature protein that is 393 amino acids in length with a subunit molecular weight of 43,072 (including the FMN). The protein sequence shows impressive homology with the primary structures of two mechanistically related proteins, yeast flavocytochrome b2 (Lederer, F., Cortial, S., Becam, A.-M., Haumont, P.-Y., and Perez, L. (1985) Eur. J. Biochem. 152, 419-428; Guiard, B. (1985) EMBO J. 4, 3265-3272) and spinach glycolate oxidase (Volkita, M., and Somerville, C. R. (1987) J. Biol. Chem. 262, 15825-15828; Cederlund, E., Lindqvist, Y., Soderlund, G., Br?ndén, C.-I., and Jornvall, H. (1988) Eur. J. Biochem. 173, 523-530). For each residue proposed from the crystal structure of glycolate oxidase to be involved in catalysis (Lindqvist, Y., and Br?ndén, C.-I. (1989) J. Biol. Chem. 264, 3624-3628), an identical residue was found in a homologous position in lactate oxidase. Furthermore, most of these residues occur in regions whose sequences are highly conserved between lactate oxidase, flavocytochrome b2, and glycolate oxidase.     

Cofactor assisted gating mechanism in the active site of NADH oxidase from Thermus thermophilus

NADH oxidase (NOX) from Thermus thermophilus is a member of a structurally homologous flavoprotein family of nitroreductases and flavin reductases. The importance of local conformational dynamics in the active site of NOX has been recently demonstrated. The enzyme activity was increased by 250% in the presence of 1 M urea with no apparent perturbation of the native structure of the protein. The present in silico results correlate with the in vitro data and suggest the possible explanation about the effect of urea on NOX activity at the molecular level. Both, X-ray structure and molecular dynamics (MD) simulations, show open conformation of the active site represented by approximately 0.9 nm distance between the indole ring of Trp47 and the isoalloxazine ring of FMN412. In this conformation, the substrate molecule can bind in the active site without sterical restraints. MD simulations also indicate more stable conformation of the active site called "closed" conformation. In this conformation, Trp47 and the isoalloxazine ring of FMN412 are so close to each other (approximately 0.5 nm) that the substrate molecule is unable to bind between them without perturbing this conformation. The open/close transition of the active site between Trp47 and the flavin ring is accompanied by release of the "tightly" bound water molecule from the active site--cofactor assisted gating mechanism. The presence of urea in aqueous solutions of NOX prohibits closing of the active site and even unlocks the closed active site because of the concomitant binding of a urea molecule in the active site cavity. The binding of urea in the active site is stabilized by formation of one/two persistent hydrogen bonds involving the carbonyl group of the urea molecule. Our report represents the first MD study of an enzyme from the novel flavoprotein family of nitroreductases and flavin reductases. The common occurrence of aromatic residues covering the active sites in homologous enzymes suggests the possibility of a general gating mechanism and the importance of local dynamics within this flavoprotein family.     

Organization of the multiple coenzymes and subunits and role of the covalent flavin link in the complex heterotetrameric sarcosine oxidase

Heterotetrameric (alphabetagammadelta) sarcosine oxidase from Corynebacterium sp. P-1 (cTSOX) contains noncovalently bound FAD and NAD(+) and covalently bound FMN, attached to beta(His173). The beta(His173Asn) mutant is expressed as a catalytically inactive, labile heterotetramer. The beta and delta subunits are lost during mutant enzyme purification, which yields a stable alphagamma complex. Addition of stabilizing agents prevents loss of the delta but not the beta subunit. The covalent flavin link is clearly a critical structural element and essential for TSOX activity or preventing FMN loss. The alpha subunit was expressed by itself and purified by affinity chromatography. The alpha and beta subunits each contain an NH(2)-terminal ADP-binding motif that could serve as part of the binding site for NAD(+) or FAD. The alpha subunit and the alphagamma complex were each found to contain 1 mol of NAD(+) but no FAD. Since NAD(+) binds to alpha, FAD probably binds to beta. The latter could not be directly demonstrated since it was not possible to express beta by itself. However, FAD in TSOX from Pseudomonas maltophilia (pTSOX) exhibits properties similar to those observed for the covalently bound FAD in monomeric sarcosine oxidase and N-methyltryptophan oxidase, enzymes that exhibit sequence homology with beta. A highly conserved glycine in the ADP-binding motif of the alpha(Gly139) or beta(Gly30) subunit was mutated in an attempt to generate NAD(+)- or FAD-free cTSOX, respectively. The alpha(Gly139Ala) mutant is expressed only at low temperature (t(optimum) = 15 degrees C), but the purified enzyme exhibited properties indistinguishable from the wild-type enzyme. The much larger barrier to NAD(+) binding in the case of the alpha(Gly139Val) mutant could not be overcome even by growth at 3 degrees C, suggesting that NAD(+) binding is required for TSOX expression. The beta(Gly30Ala) mutant exhibited subunit expression levels similar to those of the wild-type enzyme, but the mutation blocked subunit assembly and covalent attachment of FMN, suggesting that both processes require a conformational change in beta that is induced upon FAD binding. About half of the covalent FMN in recombinant preparations of cTSOX or pTSOX is present as a reversible covalent 4a-adduct with a cysteine residue. Adduct formation is not prevented by mutating any of the three cysteine residues in the beta subunit of cTSOX to Ser or Ala. Since FMN is attached via its 8-methyl group to the beta subunit, the FMN ring must be located at the interface between beta and another subunit that contains the reactive cysteine residue.     

Structure and mechanism of Escherichia coli pyridoxine 5'-phosphate oxidase

Escherichia coli pyridoxine 5'-phosphate oxidase (PNPOx) catalyzes the oxidation of either pyridoxine 5'-phosphate (PNP) or pyridoxamine 5'-phosphate (PMP), forming pyridoxal 5'-phosphate (PLP). This reaction serves as the terminal step in the de novo biosynthesis of PLP in E. coli and as a part of the salvage pathway of this coenzyme in both E. coli and mammalian cells. Recent studies have shown that in addition to the active site, PNPOx contains a noncatalytic site that binds PLP tightly. The crystal structures of PNPOx with one and two molecules of PLP bound have been determined. In the active site, the PLP pyridine ring is stacked almost parallel against the re-face of the middle ring of flavin mononucleotide (FMN). A large protein conformational change occurs upon binding of PLP. When the protein is soaked with excess PLP an additional molecule of this cofactor is bound about 11 A from the active site. A possible tunnel exists between the two sites. Site mutants were made of all residues at the active site that make interactions with the substrate. Stereospecificity studies showed that the enzyme is specific for removal of the proR hydrogen atom from the prochiral C4' carbon of PMP. The crystal structure and the stereospecificity studies suggest that the pair of electrons on C4' of the substrate are transferred to FMN as a hydride ion.     

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.     

Phosphate group binding "cup" of PLP-dependent and non-PLP-dependent enzymes: leitmotif and variations

Pyridoxal-5'-phosphate (PLP) is widely used by many enzymes in reactions where amino acids are interconverted. Whereas the role of the pyridoxal ring in catalysis is well understood, the functional role of the single phosphate group in PLP has been less studied. Here we construct unambiguous connection diagrams that describe the interactions among the three non-ester phosphate oxygen atoms of PLP and surrounding atoms from the protein binding site and from water molecules, the so-called phosphate group binding "cup". These diagrams provide a simple means to identify common recognition motifs for the phosphate group in both similar and different protein folds. Diagrams were constructed and compared in the cases of five newly determined structures of PLP-dependent transferases (fold type I enzymes) and, additionally, two non-PLP protein complexes (indole-3-glycerol phosphate synthase (IGPS) with bound indole-3-glycerol phosphate (IGP) and old yellow enzyme (OYE) with bound flavin mononucleotide (FMN)). A detailed comparison of the diagrams shows that three positions out of ten in the structure of the phosphate group binding "cup" contain invariant atoms, while seven others are occupied by conserved atom types. This level of similarity was also observed in the fold type III (TIM beta/alpha-barrel) enzymes that bind three different ligands: PLP, IGP and FMN.