Carbon-13 and nitrogen-15 nuclear-magnetic-resonance investigation on Desulfovibrio vulgaris flavodoxin

Desulfovibrio vulgaris apoflavodoxin has been reconstituted with 15N and 13C-enriched riboflavin 5'-phosphate. For the first time all carbon atoms of the isoalloxazine ring of the protein-bound prosthetic group have been investigated. The reconstituted protein was studied in the oxidized and in the two-electron-reduced state. The results are interpreted in terms of specific interactions between the apoprotein and the prosthetic group, and the chemical structure of protein-bound FMN. In the oxidized state weak hydrogen bonds exist between the apoprotein and the N(5), N(3) and O(4 alpha) atoms of FMN. The N(1) and O(2 alpha) atoms of FMN form strong hydrogen bonds. The isoalloxazine ring of FMN is strongly polarized and the N(10) atom shows an increased sp2 hybridisation compared to that of free FMN in aqueous solution. The N(3)-H group is not accessible to bulk solvent, as deduced from the coupling constant of the N(3)-H group. In the reduced state the hydrogen bond pattern is similar to that in the oxidized state and in addition a strong hydrogen bond is observed between the N(5)-H group of FMN and the apoprotein. The reduced prosthetic group possesses a coplanar structure and is ionized. The N(3)-H and N(5)-H groups are not accessible to solvent water. Two-electron reduction of the protein leads to a large electron density increase in the benzene subnucleus of bound FMN compared to that in free FMN. The results are discussed in relation to the published crystallographic data on the protein.     

Nuclear magnetic resonance studies of the old yellow enzyme. 1. 15N NMR of the enzyme recombined with 15N-labeled flavin mononucleotides

The apoenzyme of NADPH oxidoreductase, 'old yellow enzyme', was reconstituted with specifically 15N-labeled flavin mononucleotide and investigated by 15N NMR spectroscopy in the oxidized and reduced state. The results indicate that in the oxidized state a hydrogen bond is formed between the N(5) atom and the apoprotein. In addition, hydrogen bonds exist between the N(1) and N(3) atoms of FMN and the apoprotein. The resonance position of N(10) indicates that this atom is somewhat sp3-hybridized, i.e. lifted out of the molecular plane of the isoalloxazine ring system. In the reduced state the N(1) atom is negatively charged and the N(3) atom forms a hydrogen bond with the apoprotein. The N(10) atom in protein-bound FMN exhibits about the same hybridization state as in free anionic reduced FMN, i.e. it is located in the plane of the isoalloxazine ring. The chemical shift of the N(5) resonance indicates that this atom is almost completely sp3-hybridized. This interpretation can also be derived from the 15N(5)-1H coupling constant. Among the flavoproteins thus far studied by NMR techniques, old yellow enzyme is the only protein that shows a conformation of the reduced prosthetic group with the N(5) atom lifted out of the molecular plane. The isoelectric focussing properties of old yellow enzyme and a new easy method for the preparation of the apoprotein are also reported.     

Nuclear magnetic resonance studies of the old yellow enzyme. 2. 13C NMR of the enzyme recombined with 13C-labeled flavin mononucleotides

The apoenzyme of NADPH oxidoreductase, 'old yellow enzyme', was reconstituted with selectively 13C-enriched flavin mononucleotides and investigated by 13C NMR spectroscopy. The 13C NMR results confirm the results obtained by 15N NMR spectroscopy and yield additional information about the coenzyme-apoenzyme interaction. A strong deshielding of the C(2) and C(4) atoms of enzyme-bound FMN both in the oxidized and reduced state is observed, which is supposed to be induced by hydrogen-bond formation between the protein and the two carbonyl groups at C(2) and C(4) of the isoalloxazine ring system. The chemical shifts of all 13C resonances of the flavin in the two-electron-reduced state indicate that the N(5) atom is sp3-hybridized. From 31P NMR measurements it is concluded that the FMN phosphate group is not accessible to bulk solvent. The unusual 31P chemical shift of FMN in old yellow enzyme seems to indicate a different binding mode of the FMN phosphate group in this enzyme as compared to the flavodoxins. The 13C and 15N NMR data on the old-yellow-enzyme--phenolate complexes show that the atoms of the phenolate are more deshielded whereas the atoms of the enzyme-bound isoalloxazine ring are more shielded upon complexation. A non-linear correlation exists between the chemical shifts of the N(5) and the N(10) atoms and the pKa value of the phenolate derivative bound to the protein. Since the chemical shifts of N(5), N(10) and C(4a) are influenced most on complexation it is suggested that the phenolate is bound near the pyrazine ring of the isoalloxazine system. 15N NMR studies on the complex between FMN and 2-aminobenzoic acid indicate that the structure of this complex differs from that of the old-yellow-enzyme--phenolate complexes.     

13C, 15N, and 31P NMR studies on 6-hydroxy-L-nicotine oxidase from Arthrobacter oxidans

The interaction between the apoprotein of 6-hydroxy-L-nicotine oxidase from Arthrobacter oxidans and the prosthetic group FAD has been investigated by 13C, 15N, and 31P NMR techniques. The FAD prosthetic group was selectively enriched in 13C and 15N isotopes by adding isotopically labeled riboflavin derivatives to the growth medium of riboflavin-requiring mutant cells. In the oxidized state the chemical shift of the C(7) and C(8) atoms indicates that the xylene moiety of the isoalloxazine ring is embedded in a hydrophobic environment. The polarization of the isoalloxazine ring as a whole is, however, much more comparable to that of free flavin in a polar and protic environment than to free flavin in an apolar environment. The polarization of the ring system can be ascribed to strong hydrogen bonds between the apoprotein and the two carbonyl groups. The binding of the competitive inhibitor, 6-hydroxy-D-nicotine, influences the resonances of the C(4a) and the N(5) atoms strongly. It is suggested that these shifts are due to a strong hydrogen-bonding interaction between the N(5) atom and the inhibitor. On reduction all resonances, except those of the C(10a) and the N(1) atoms, shift upfield, indicating the increased electron density in the ring system. In the dithionite-reduced enzyme, the ring system is bent at the N(5) position. Due to the bending of the N(5) atom and the sp2 hybridized N(10) atom, electron density from the N(10) atom is reallocated at the C(4) carbonyl group. In contrast, in the substrate-reduced enzyme the N(5) atom is almost completely sp2 hybridized, yielding a rather planar isoalloxazine ring.(ABSTRACT TRUNCATED AT 250 WORDS)     

Flavin-protein interactions in flavocytochrome b2 as studied by NMR after reconstitution of the enzyme with 13C- and 15N-labelled flavin.

A new procedure was devised for reversibly removing the flavin from flavocytochrome b2. It allowed reconstitution with selectively enriched 13C- and 15N-labelled FMN for an NMR analysis of the chemical shifts of the enriched positions as well as that of 31P. From these measurements, it was possible to deduce information about the hydrogen-bonding pattern of FMN in the protein, the hybridization states of the nitrogen atoms and (in part) the pi-electron distribution. The carbonyl groups at C(2) and C(4) and the nitrogen atoms N(1) and N(5) form hydrogen bonds to the apoenzyme in both redox states. Nevertheless, according to 15N-chemical shifts, the bond from the protein to N(3) is very weak in both redox states, whereas that to N(5) is strong for the oxidized state, and is weakened upon flavin reduction. On the other hand, the 13C-NMR results indicate that the C(2) and C(4) carbonyl oxygens form stronger hydrogen bonds with the enzyme than most other flavoproteins in both redox states. From coupling constant measurements it is shown that the N(3) proton is not solvent accessible. Although no N-H coupling constant could be measured for N(5) in the reduced state due to lack of resolution, N(5) is clearly protonated in flavocytochrome b2 as in all other known flavoproteins. With respect to N(10), it is more sp3-hybridized in the oxidized state than in free FMN, whereas the other nitrogen atoms show a nearly planar structure. In the reduced state, N(5) and N(10) in bound FMN are both more sp3-hybridized than in free FMN, but N(5) exhibits a higher degree of sp3-hybridization than N(10), which is only slightly shifted out of the isoalloxazine plane. In addition, two-electron reduction of the enzyme leads to anion formation on N(1), as indicated by its 15N-chemical shift of N(1) and characteristic upfield shifts of the resonances of C(2), C(4) and C(4a) compared to the oxidized state, as observed for most flavoproteins. 31P-NMR measurements show that the phosphate geometry has changed in enzyme bound FMN compared to the free flavin in water, indicating a strong interaction of the phosphate group with the apoenzyme.     

Crystal structure of oxidized flavodoxin from a red alga Chondrus crispus refined at 1.8 A resolution. Description of the flavin mononucleotide binding site.

In order to describe the detailed conformation of the oxidized flavodoxin from a eukaryotic red alga, Chondrus crispus, the crystal structure has been refined by a restrained least-squares method. The crystallographic R factor is 0.168 for 13,899 reflections with F greater than 2 sigma F between 6.0 and 1.8 A resolution. The refined model includes 173 amino acid residues, flavin mononucleotide (FMN) and 110 water molecules. The root-mean-square deviation in bond lengths from ideal values is 0.015 A, and the mean co-ordinate error is estimated to be 0.2 A. The FMN is located at the periphery of the molecule. The orientation of the isoalloxazine ring is such that the C-7 and C-8 methyl groups are exposed to solvent and the pyrimidine moiety is buried in the protein. Three peptide segments, T8-T13, T55-T58 and D94-C103, are involved in FMN binding. The first segment of T8-T13 enfolds the phosphate group of the FMN. The three oxygen atoms in the phosphate group form extensive hydrogen bonds with amide groups of the main chain and the O gamma atoms of the side-chains in this segment. T55 O and W56 N epsilon 1 in the second segment form hydrogen bonds with O-2 in the ribityl moiety and one of the oxygen atoms in the phosphate group, respectively. The O gamma H of T58 forms a hydrogen bond with the N-5 atom in the isoalloxazine ring, which is expected to be protonated in the semiquinone form. The third segment is in contact with the isoalloxazine ring. It appears that the hydrogen bond acceptor of the NH of Asp94 in the third segment is O-2 rather than N-1 in the isoalloxazine ring. The isoalloxazine ring is flanked by the side-chains of Trp56 and Tyr98; it forms an angle of 38 degrees with the indole ring of Trp56 and is almost parallel to the benzene ring of Tyr98. The environment of the phosphate group is conserved as in other flavodoxins whereas that of the isoalloxazine ring differs. The relationship between the hydrogen bond to the N-5 in the ring and the redox potential for the oxidized/semiquinone couple is discussed.     

13C-NMR studies on the reaction intermediates of porcine kidney D-amino acid oxidase reconstituted with 13C-enriched flavin adenine dinucleotide

The 13C-NMR spectra of the reaction intermediates of D-amino acid oxidase (DAO) were measured with DAO reconstituted with FAD in which the 2-, 4-, 4a-, and 10a-positions of the isoalloxazine moiety were selectively 13C-enriched. The reaction intermediates used include charge-transfer complexes of the oxidized DAO with substrate intermediates and those of the reduced enzyme with substrate intermediates. For the former type of complex, the reaction intermediates with beta-cyano-D-alanine (D-BCNA) and D-proline were used, while for the latter the purple intermediates with D-alanine and D-proline were chosen. The 13C-resonances of 2-13C in the reaction intermediates with D-BCNA and D-proline were downfield-shifted by about 1 ppm relative to the free oxidized DAO. The 4-13C signal for the DAO-D-BCNA intermediate was observed at 1.2 ppm upfield from that of the oxidized DAO, though that for DAO-D-proline intermediate showed no shift. These results suggest modulation of the hydrogen bondings at C(2) = 0 and/or C(4) = 0 in these reaction intermediates. Comparison of the 13C-resonances of reduced DAO with those of free reduced FMN in the neutral and anionic forms indicate that FAD in reduced DAO is in the anionic reduced form. The 4a-13C resonance of reduced DAO is upfield-shifted by about 3 ppm from that of free reduced anionic FMN. Comparison of the 13C-resonances for the purple intermediates with those of reduced FMN and reduced DAO indicate unequivocally that FAD in the purple intermediate is in the anionic reduced state. The 4a-13C resonances for the purple intermediates were substantially upfield-shifted (by 2.4 ppm with D-alanine and 1.9 ppm with D-proline) relative to reduced DAO. This indicates that the electron density, and hence the nucleophilicity, of the 4a-carbon is elevated in the purple intermediate relative to free reduced DAO. This leads to a model in which the oxidative half reaction proceeds via the reaction of molecular oxygen at the 4a-position of the reduced FAD in the purple intermediate. This provides a rational molecular basis for the oxidative half reaction by way of the purple intermediate prior to product release rather than by way of free reduced enzyme after product release.     

Interaction of muscle glycogen phosphorylase B with flavin-adenine dinucleotide and its analogs

The inhibition of rabbit skeletal muscle glycogen phosphorylase b by FAD and its analogues with substitutes in the position 8 has been studied. The value of half-saturation, [I]0,5, for inhibitors increases in the following order: FAD (44 microM), 8 alpha-hydroxy-FAD (60 microM), 8-dimethylamino (nor)-FAD (69 microM), 8 alpha-(N-acetyl-L-cystein-S-yl)-FAD (106 microM). From the comparison of these values with those obtained earlier for FMN analogues, it follows that in the case of FAD the half-saturation value is less sensitive to modification of the position 8 in the flavin isoalloxazine ring. The existence of the glycogen phosphorylase b FAD-complex has been proved by the spectrophotometry and sedimentation methods. The positions of maxima of optical absorption of the enzyme-bound FAD in the 300-500 nm region are identical with corresponding positions for FMN. FAD has been shown to hinder the AMP-induced transition of dimeric form of the enzyme to tetrameric one.     

A hydrogen peroxide-forming NADH oxidase that functions as an alkyl hydroperoxide reductase in Amphibacillus xylanus

The Amphibacillus xylanus NADH oxidase, which catalyzes the reduction of oxygen to hydrogen peroxide with beta-NADH, can also reduce hydrogen peroxide to water in the presence of free flavin adenine dinucleotide (FAD) or the small disulfide-containing Salmonella enterica AhpC protein. The enzyme has two disulfide bonds, Cys128-Cys131 and Cys337-Cys340, which can act as redox centers in addition to the enzyme-bound FAD (K. Ohnishi, Y. Niimura, M. Hidaka, H. Masaki, H. Suzuki, T. Uozumi, and T. Nishino, J. Biol. Chem. 270:5812-5817, 1995). The NADH-FAD reductase activity was directly dependent on the FAD concentration, with a second-order rate constant of approximately 2.0 x 10(6) M(-1) s(-1). Rapid-reaction studies showed that the reduction of free flavin occurred through enzyme-bound FAD, which was reduced by NADH. The peroxidase activity of NADH oxidase in the presence of FAD resulted from reduction of peroxide by free FADH(2) reduced via enzyme-bound FAD. This peroxidase activity was markedly decreased in the presence of oxygen, since the free FADH(2) is easily oxidized by oxygen, indicating that this enzyme system is unlikely to be functional in aerobic growing cells. The A. xylanus ahpC gene was cloned and overexpressed in Escherichia coli. When the NADH oxidase was coupled with A. xylanus AhpC, the peroxidase activity was not inhibited by oxygen. The V(max) values for hydrogen peroxide and cumene hydroperoxide reduction were both approximately 150 s(-1). The K(m) values for hydrogen peroxide and cumene hydroperoxide were too low to allow accurate determination of their values. Both AhpC and NADH oxidase were induced under aerobic conditions, a clear indication that these proteins are involved in the removal of peroxides under aerobic growing conditions.     

pH-induced changes in activity and conformation of NADH oxidase from Thermus thermophilus

Thermus thermophilus NADH oxidase (NOX) activity exhibits a bell-shaped pH-dependency with the maximal rate at pH 5.2 and marked inhibition at lower pH. The first pH transition, from pH 7.2 to pH 5.2, results in more than a 2-fold activity increase with protonation of a group with pKa=6.1+/-0.1. The difference in fluorescence of the free and enzyme-bound flavin strongly indicates that the increase in enzyme activity in a pH-dependent manner is related to a protein-cofactor interaction. Only one amino acid residue, His75, has an intrinsic pKa approximately 6.0 and is localized in proximity (<10 A) to N5-N10 of the isoalloxazine ring and, therefore, is able to participate in such an interaction. Solvent acidification leads to the second pH transition from pH 5.2 to 2.0 that results in complete inhibition of the enzyme with protonation of a group with an apparent pKa=4.0+/-0.1. Inactivation of NOX activity at low pH is not caused by large conformational changes in the quaternary structure as judged by intrinsic viscosity and sedimentation velocity experiments. NOX exists as a dimer even as an apoprotein at acidic conditions. There is a strong coupling between the fluorescence of the enzyme-bound flavin and the intrinsic tryptophans, as demonstrated by energy transfer between Trp47 and the isoalloxazine ring of flavin adenine dinucleotide (FAD). The pH-induced changes in intrinsic tryptophan and FAD fluorescence indicate that inhibition of the FAD-binding enzyme at low pH is related to dissociation of the flavin cofactor, due to protonation of its adenine moiety.     

Crystal structure of reduced thioredoxin reductase from Escherichia coli: structural flexibility in the isoalloxazine ring of the flavin adenine dinucleotide cofactor

Catalysis by thioredoxin reductase (TrxR) from Escherichia coli requires alternation between two domain arrangements. One of these conformations has been observed by X-ray crystallography (Waksman G, Krishna TSR, Williams CH Jr, Kuriyan J, 1994, J Mol Biol 236:800-816). This form of TrxR, denoted FO, permits the reaction of enzyme-bound reduced FAD with a redox-active disulfide on TrxR. As part of an investigation of conformational changes and intermediates in catalysis by TrxR, an X-ray structure of the FO form of TrxR with both the FAD and active site disulfide reduced has been determined. Reduction after crystallization resulted in significant local conformation changes. The isoalloxazine ring of the FAD cofactor, which is essentially planar in the oxidized enzyme, assumes a 34 degree "butterfly" bend about the N(5)-N(10) axis in reduced TrxR. Theoretical calculations reported by others predict ring bending of 15-28 degrees for reduced isoalloxazines protonated at N(1). The large bending in reduced TrxR is attributed in part to steric interactions between the isoalloxazine ring and the sulfur of Cys138, formed by reduction of the active site disulfide, and is accompanied by changes in the positions and interactions of several of the ribityl side-chain atoms of FAD. The bending angle in reduced TrxR is larger than that for any flavoprotein in the Protein Data Bank. Distributions of bending angles in published oxidized and reduced flavoenzyme structures are different from those found in studies of free flavins, indicating that the protein environment has a significant effect on bending.     

Electrostatic control of the isoalloxazine environment in the two-electron reduced states of yeast glutathione reductase

The resonance Raman spectra of the oxidized and two-electron reduced forms of yeast glutathione reductase are reported. The spectra of the oxidized enzyme indicate a low electron density for the isoalloxazine ring. As far as the two-electron reduced species are concerned, the spectral comparison of the NADPH-reduced enzyme with the glutathione- or dithiothreitol-reduced enzyme shows significant frequency differences for the flavin bands II, III, and VII. The shift of band VII was correlated with a change in steric or electronic interaction of the hydroxyl group of a conserved Tyr with the N(10)-C(10a) portion of the isoalloxazine ring. Upward shifts of bands II and III observed for the glutathione- or dithiothreitol-reduced enzyme indicate both a slight change in isoalloxazine conformation and a hydrogen bond strengthening at the N(1) and/or N(5) site(s). The formation of a mixed disulfide intermediate tends to slightly decrease the frequency of bands II, III, X, XI, and XIV. To account for the different spectral features observed for the NADPH- and glutathione-reduced species, several possibilities have been examined. In particular, we propose a hydrogen bonding modulation at the N(5) site of FAD through a variable conformation of an ammonium group of a conserved Lys residue. Changes in N(5)(flavin)-protein interaction in the two-electron reduced forms of glutathione reductase are discussed in relation to a plausible mechanism of the regulation of the enzyme activity via a variable redox potential of FAD.     

Elucidations of the Catalytic Cycle of NADH-Cytochrome b5 Reductase by X-ray Crystallography: New Insights into Regulation of Efficient Electron Transfer

NADH-Cytochrome b₅ reductase (b5R), a flavoprotein consisting of NADH and flavin adenine dinucleotide (FAD) binding domains, catalyzes electron transfer from the two-electron carrier NADH to the one-electron carrier cytochrome b₅ (Cb5). The crystal structures of both the fully reduced form and the oxidized form of porcine liver b5R were determined. In the reduced b5R structure determined at 1.68 Å resolution, the relative configuration of the two domains was slightly shifted in comparison with that of the oxidized form. This shift resulted in an increase in the solvent-accessible surface area of FAD and created a new hydrogen-bonding interaction between the N5 atom of the isoalloxazine ring of FAD and the hydroxyl oxygen atom of Thr66, which is considered to be a key residue in the release of a proton from the N5 atom. The isoalloxazine ring of FAD in the reduced form is flat as in the oxidized form and stacked together with the nicotinamide ring of NAD⁺. Determination of the oxidized b5R structure, including the hydrogen atoms, determined at 0.78 Å resolution revealed the details of a hydrogen-bonding network from the N5 atom of FAD to His49 via Thr66. Both of the reduced and oxidized b5R structures explain how backflow in this catalytic cycle is prevented and the transfer of electrons to one-electron acceptors such as Cb5 is accelerated. Furthermore, crystallographic analysis by the cryo-trapping method suggests that re-oxidation follows a two-step mechanism. These results provide structural insights into the catalytic cycle of b5R.     

Spectroscopic and kinetic properties of recombinant choline oxidase from Arthrobacter globiformis

Choline oxidase catalyzes the four-electron oxidation of choline to glycine betaine, with molecular oxygen acting as primary electron acceptor. Recently, the recombinant enzyme expressed in Escherichia coli was purified to homogeneity and shown to contain FAD in a mixture of oxidized and anionic semiquinone redox states [Fan et al. (2003) Arch. Biochem. Biophys., in press]. In this study, methods have been devised to convert the enzyme-bound flavin semiquinone to oxidized FAD and vice versa, allowing characterization of the resulting forms of choline oxidase. The enzyme-bound oxidized flavin showed typical UV-vis absorbance peaks at 359 and 452 nm (with epsilon(452) = 11.4 M(-1) cm(-1)) and emitted light at 530 nm (with lambda(ex) at 452 nm). The affinity of the enzyme for sulfite was high (with a K(d) value of approximately 50 microM at pH 7 and 15 degrees C), suggesting the presence of a positive charge near the N(1)C(2)=O locus of the flavin. The enzyme-bound anionic flavin semiquinone was unusually insensitive to oxygen or ferricyanide at pH 8 and showed absorbance peaks at 372 and 495 nm (with epsilon(372) = 19.95 M(-1) cm(-1)), maximal fluorescence emission at 454 nm (with lambda(ex) at 372 nm), circular dichroic signals at 370 and 406 nm, and an ESR peak-to-peak line width of 13.9 G. Both UV-vis absorbance studies on the enzyme under turnover with choline and steady-state kinetic data with either choline or betaine aldehyde were consistent with the flavin semiquinone being not involved in catalysis. The pH dependence of the kinetic parameters at varying concentrations of both choline and oxygen indicated that a catalytic base is required for choline oxidation but not for oxygen reduction and that the order of the kinetic steps involving substrate binding and product release is not affected by pH.     

A comparative carbon-13, nitrogen-15, and phosphorus-31 nuclear magnetic resonance study on the flavodoxins from Clostridium MP, Megasphaera elsdenii, and Azotobacter vinelandii

The flavodoxins from Megasphaera elsdenii, Clostridium MP, and Azotobacter vinelandii were studied by 13C, 15N, and 31P NMR techniques by using various selectivity enriched oxidized riboflavin 5'-phosphate (FMN) derivatives. It is shown that the pi electron distribution in protein-bound flavin differs from that of free flavin and depends also on the apoflavoprotein used. In the oxidized state Clostridium MP and M. elsdenii flavodoxins are very similar with respect to specific hydrogen bond interaction between FMN and the apoprotein and the electronic structure of flavin. A. vinelandii flavodoxin differs from these flavodoxins in both respects, but it also differs from Desulfovibrio vulgaris flavodoxin. The similarities between A. vinelandii and D. vulgaris flavodoxins are greater than the similarities with the other two flavodoxins. The differences in the pi electron distribution in the FMN of reduced flavodoxins from A. vinelandii and D. vulgaris are even greater, but the hydrogen bond patterns between the reduced flavins and the apoflavodoxins are very similar. In the reduced state all flavodoxins studied contain an ionized prosthetic group and the isoalloxazine ring is in a planar conformation. The results are compared with existing three-dimensional data and discussed with respect to the various possible mesomeric structures in protein-bound FMN. The results are also discussed in light of the proposed hypothesis that specific hydrogen bonding to the protein-bound flavin determines the specific biological activity of a particular flavoprotein.     

Studies on the structure and mechanism of Streptococcus faecium L-alpha-glycerophosphate oxidase

An FAD-containing L-alpha-glycerophosphate oxidase has been purified to homogeneity from Streptococcus faecium. The purified protein exists as a dimer (subunit Mr = 65,000); each subunit contains 1 mol of FAD. The enzyme contains no iron, as determined by atomic absorption spectroscopy. The alpha-glycerophosphate oxidase reacts reversibly with sulfite to form a covalent N(5) adduct; it preferentially binds the anionic form of the native oxidized FAD, and it also stabilizes the p-quinonoid form of 8-mercapto-FAD. The enzyme shows an unusually high reactivity with ferricyanide in the absence of oxygen; however, there is no evidence for any superoxide ion (O2-.) generation under standard assay conditions. Dithionite titrations of the enzyme reveal an unusual pH dependence for the stabilization of the flavin semiquinone; only at pH 8.5 does significant anionic semiquinone accumulate. L-alpha-Glycerophosphate rapidly reduces the enzyme-bound FAD; in addition, a small amount of catalytically insignificant red semiquinone appears under these conditions. The 5-deaza-FAD-reconstituted enzyme is also reduced by substrate, strongly suggesting that a radical mechanism is not involved in the oxidation of alpha-glycerophosphate. Furthermore, nitroethane anion reduces the native enzyme; this observation suggests that an electron transfer mechanism involving a substrate carbanion is possible with this enzyme.     

13C-NMR studies of porcine kidney D-amino acid oxidase reconstituted with 13C-enriched flavin adenine dinucleotide. Effects of competitive inhibitors

D-Amino acid oxidase (DAO) from porcine kidney was reconstituted with FAD's which were enriched with 13C at the 2-, 4-, 4a-, and 10a-positions of the isoalloxazine moiety, and 13C-NMR spectra of the reconstituted DAO were measured in the absence and presence of various competitive inhibitors. When compared to the corresponding chemical shifts of FMN at infinite dilution (Moonen, C.T.W. et al. (1984) Biochemistry 23, 4859-4867), the resonances of C(2), C(4), C(4a), and C(10a) of FAD bound to apoDAO were all shifted to higher field. However, when the reconstituted DAO was complexed with o-, m-, p-aminobenzoate, or benzoate, each of the four 13C-signals underwent a different change in chemical shift. In these changes we observed no characteristics which distinguish DAO-aminobenzoate complexes from DAO-benzoate complex, even though o-, m-, and p-aminobenzoates are known to form charge-transfer complexes with DAO. The signals due to 2- and 4-13C were more sensitive to the formation of the inhibitor-DAO complexes than those of the other carbon atoms. These findings suggest the modulation of the hydrogen bonds at the oxygen atoms of C(2) = O and C(4) = O with the protein moiety as the result of the inhibitor-binding.     

Hydrogen-1, carbon-13, and nitrogen-15 NMR spectroscopy of Anabaena 7120 flavodoxin: assignment of beta-sheet and flavin binding site resonances and analysis of protein-flavin interactions

Sequence-specific 1H and 13C NMR assignments have been made for residues that form the five-stranded parallel beta-sheet and the flavin mononucleotide (FMN) binding site of oxidized Anabaena 7120 flavodoxin. Interstrand nuclear Overhauser enhancements (NOEs) indicate that the beta-sheet arrangement is similar to that observed in the crystal structure of the 70% homologous long-chain flavodoxin from Anacystis nidulans [Smith et al. (1983) J. Mol. Biol. 165, 737-755]. A total of 62 NOEs were identified: 8 between protons of bound FMN, 29 between protons of the protein in the flavin binding site, and 25 between protons of bound FMN and protons of the protein. These constraints were used to determine the localized solution structure of the FMN binding site. The electronic environment and conformation of the protein-bound flavin isoalloxazine ring were investigated by determining 13C chemical shifts, one-bond 13C-13C and 15N-1H coupling constants, and three-bond 13C-1H coupling constants. The carbonyl edge of the flavin ring was found to be slightly polarized. The xylene ring was found to be nonplanar. Tyrosine 94, located adjacent to the flavin isoalloxazine ring, was shown to have a hindered aromatic ring flip rate.     

Xanthine oxidase-catalyzed reductive debromination of 6-(bromomethyl)-9H-purine with concomitant covalent modification of the FAD prosthetic group

Bovine milk xanthine oxidase was potently inhibited by 6-(bromomethyl)-9H-purine in a time-dependent process with O2 as the electron acceptor. If the enzyme were assayed with phenazene ethosulfate as an electron acceptor, 6-(bromomethyl)-9H-purine was not an inhibitor. The rate of formation of inhibited enzyme increased with increasing concentrations of 6-(halomethyl)-9H-purine, decreased with increasing concentrations of O2, and increased in the presence of xanthine. The inhibited enzyme regained activity nonactinically at pH 7 with a t1/2 of 31 h. The optical difference spectrum between native enzyme and inhibited enzyme suggested that the enzyme-bound FAD was modified. This conclusion was confirmed by demonstrating that activity was restored to the inhibited enzyme if the enzyme-bound flavin was removed by treatment with CaCl2 and the resulting apoenzyme was reconstituted with FAD. Aerobically, 6-(bromomethyl)-9H-purine was oxidized by the enzyme to a species having a UV spectrum consistent with hydroxylation of the purine ring to form a urate analogue. Anaerobically, the enzyme reduced 6-(bromomethyl)-9H-purine to 6-methylpurine with 1 mol of enzyme being completely inhibited after reduction of 23 mol of 6-(bromomethyl)-9H-purine. Thus, 6-(bromomethyl)-9H-purine was not only oxidized by xanthine oxidase but was also reduced by the enzyme in a reaction that partitioned between formation of 6-methylpurine and inhibition of the enzyme by modification of the enzyme-bound flavin. Similar results were found when 6-(chloromethyl)-9H-purine was the inhibitor.     

para-Hydroxybenzoate hydroxylase containing 6-hydroxy-FAD is an effective enzyme with modified reaction mechanisms

The flavin prosthetic group (FAD) of p-hydroxybenzoate hydroxylase (EC 1.14.13.2) from Pseudomonas fluorescens, was replaced by 6-hydroxy-FAD (an extra hydroxyl group on the carbon at position 6 of the isoalloxazine ring of FAD). The catalytic cycle of this modified enzyme was analyzed and compared to the function of native (FAD) enzyme. Transient state kinetic analyses of the multiple changes in the chemical state of the flavin were the principal methods used to probe the mechanism. Four known substrates of the native enzyme were used to probe the reaction. With the natural substrate, p-hydroxybenzoate, the 6-hydroxy-FAD enzyme activity was 12-15% of native enzyme, due to a slower release of product from the enzyme, and less than one product molecule was formed per NADPH oxidized, due to an increased rate of nonproductive decomposition of the transient peroxyflavin essential to the catalytic pathway. More extensive changes in mechanism were observed with the substrates, 2,4-dihydroxybenzoate and p-aminobenzoate. The results suggest that, during catalysis, when the reduced state of FAD is ready for oxygen reaction, the substrate is located below and close to the C-4a/N-5 edge of the isoalloxazine ring. The nature of the high extinction, transient state of flavin, formed upon transfer of oxygen to substrate is discussed. It is not a flavin cation, and is unlikely to be an oxygen-substituted analogue of N-3/C-4 dihydroflavin.