The crystal structures of Klebsiella pneumoniae acetolactate synthase with enzyme-bound cofactor and with an unusual intermediate

Acetohydroxyacid synthase (AHAS) and acetolactate synthase (ALS) are thiamine diphosphate (ThDP)-dependent enzymes that catalyze the decarboxylation of pyruvate to give a cofactor-bound hydroxyethyl group, which is transferred to a second molecule of pyruvate to give 2-acetolactate. AHAS is found in plants, fungi, and bacteria, is involved in the biosynthesis of the branched-chain amino acids, and contains non-catalytic FAD. ALS is found only in some bacteria, is a catabolic enzyme required for the butanediol fermentation, and does not contain FAD. Here we report the 2.3-A crystal structure of Klebsiella pneumoniae ALS. The overall structure is similar to AHAS except for a groove that accommodates FAD in AHAS, which is filled with amino acid side chains in ALS. The ThDP cofactor has an unusual conformation that is unprecedented among the 26 known three-dimensional structures of nine ThDP-dependent enzymes, including AHAS. This conformation suggests a novel mechanism for ALS. A second structure, at 2.0 A, is described in which the enzyme is trapped halfway through the catalytic cycle so that it contains the hydroxyethyl intermediate bound to ThDP. The cofactor has a tricyclic structure that has not been observed previously in any ThDP-dependent enzyme, although similar structures are well known for free thiamine. This structure is consistent with our proposed mechanism and probably results from an intramolecular proton transfer within a tricyclic carbanion that is the true reaction intermediate. Modeling of the second molecule of pyruvate into the active site of the enzyme with the bound intermediate is consistent with the stereochemistry and specificity of ALS.     

Reaction of 2-thio-FAD-reconstituted p-hydroxybenzoate hydroxylase with hydrogen peroxide. Formation of a covalent flavin-protein linkage

Hydrogen peroxide reacts with 2-thio-FAD-reconstituted p-hydroxybenzoate hydroxylase to yield a long wavelength intermediate (lambda max = 360, 620 nm) which can be isolated in stable form on removal of excess H2O2. The blue flavin derivative slowly decays in a second peroxide-dependent reaction to yield a new flavin product lacking long wavelength absorbance (lambda max = 408, 472 nm). This final peroxide-modified enzyme binds p-hydroxybenzoate with a 10-fold lower affinity than does the native enzyme; furthermore, substrate binding leads to the inhibition of enzyme reduction by NADPH. Trichloroacetic acid treatment of the final peroxide-modified enzyme results in the quantitative conversion of the bound flavin to free FAD. However, gel filtration of the modified enzyme in guanidine hydrochloride at neutral pH leads to the co-elution of protein and modified flavin. The nondenatured peroxide product reacts rapidly with hydroxylamine to yield 2-NHOH-substituted FAD. These observations indicate that the secondary reaction of peroxide with the blue intermediate from 2-thio-FAD p-hydroxybenzoate hydroxylase results in the formation of an acid-labile covalent flavin-protein linkage within the enzyme active site, involving the flavin C-2 position.     

Mutagenesis of the redox-active disulfide in mercuric ion reductase: catalysis by mutant enzymes restricted to flavin redox chemistry

Mercuric reductase, a flavoenzyme that possess a redox-active cystine, Cys135Cys140, catalyzes the reduction of Hg(II) to Hg(0) by NADPH. As a probe of mechanism, we have constructed mutants lacking a redox-active disulfide by eliminating Cys135 (Ala135Cys140), Cys140 (Cys135Ala140), or both (Ala135Ala140). Additionally, we have made double mutants that lack Cys135 (Ala135Cys139Cys140) or Cys140 (Cys135Cys139Ala140) but introduce a new Cys in place of Gly139 with the aim of constructing dithiol pairs in the active site that do not form a redox-active disulfide. The resulting mutant enzymes all lack redox-active disulfides and are hence restricted to FAD/FADH2 redox chemistry. Each mutant enzyme possesses unique physical and spectroscopic properties that reflect subtle differences in the FAD microenvironment. These differences are manifested in a 23-nm range in enzyme-bound FAD lambda max values, an 80-nm range in thiolate to flavin charge-transfer absorbance maxima, and a ca. 100-mV range in FAD reduction potential. Preliminary evidence for the Ala135Cys139Cys140 mutant enzyme suggests that this protein forms a disulfide between the two adjacent Cys residues. Hg(II) titration experiments that correlate the extent of charge-transfer quenching with Hg(II) binding indicate that the Ala135Cys140 protein binds Hg(II) with substantially less avidity than does the wild-type enzyme. All mutant mercuric reductases catalyze transhydrogenation and oxygen reduction reactions through obligatory reduced flavin intermediates at rates comparable to or greater than that of the wild-type enzyme. For these activities, there is a linear correlation between log kappa cat and enzyme-bound FAD reduction potential. In a sensitive Hg(II)-mediated enzyme-bound FADH2 reoxidation assay, all mutant enzymes were able to undergo at least one catalytic event at rates 50-1000-fold slower than that of the wild-type enzyme. We have also observed the reduction of Hg(II) by free FADH2. In multiple-turnover assays which monitored the production of Hg(0), two of the mutant enzymes were observed to proceed through at least 30 turnovers at rates ca. 1000-fold slower than that of wild-type mercuric reductase. We conclude that the Cys135 and Cys140 thiols serve as Hg(II) ligands that orient the Hg(II) for subsequent reduction by a reduced flavin intermediate.     

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.     

Elucidating the specificity of binding of sulfonylurea herbicides to acetohydroxyacid synthase

Acetohydroxyacid synthase (AHAS, EC 2.2.1.6) is the target for the sulfonylurea herbicides, which act as potent inhibitors of the enzyme. Chlorsulfuron (marketed as Glean) and sulfometuron methyl (marketed as Oust) are two commercially important members of this family of herbicides. Here we report crystal structures of yeast AHAS in complex with chlorsulfuron (at a resolution of 2.19 A), sulfometuron methyl (2.34 A), and two other sulfonylureas, metsulfuron methyl (2.29 A) and tribenuron methyl (2.58 A). The structures observed suggest why these inhibitors have different potencies and provide clues about the differential effects of mutations in the active site tunnel on various inhibitors. In all of the structures, the thiamin diphosphate cofactor is fragmented, possibly as the result of inhibitor binding. In addition to thiamin diphosphate, AHAS requires FAD for activity. Recently, it has been reported that reduction of FAD can occur as a minor side reaction due to reaction with the carbanion/enamine of the hydroxyethyl-ThDP intermediate that is formed midway through the catalytic cycle. Here we report that the isoalloxazine ring has a bent conformation that would account for its ability to accept electrons from the hydroxyethyl intermediate. Most sequence and mutation data suggest that yeast AHAS is a high-quality model for the plant enzyme.     

Biosynthesis of covalently bound flavin: isolation and in vitro flavinylation of the monomeric sarcosine oxidase apoprotein

The covalently bound FAD in native monomeric sarcosine oxidase (MSOX) is attached to the protein by a thioether bond between the 8alpha-methyl group of the flavin and Cys315. Large amounts of soluble apoenzyme are produced by controlled expression in a riboflavin-dependent Escherichia coli strain. A time-dependent increase in catalytic activity is observed upon incubation of apoMSOX with FAD, accompanied by the covalent incorporation of FAD to approximately 80% of the level observed with the native enzyme. The spectral and catalytic properties of the reconstituted enzyme are otherwise indistinguishable from those of native MSOX. The reconstitution reaction exhibits apparent second-order kinetics (k = 139 M(-)(1) min(-)(1) at 23 degrees C) and is accompanied by the formation of a stoichiometric amount of hydrogen peroxide. A time-dependent reduction of FAD is observed when the reconstitution reaction is conducted under anaerobic conditions. The results provide definitive evidence for autoflavinylation in a reaction that proceeds via a reduced flavin intermediate and requires only apoMSOX and FAD. Flavinylation of apoMSOX is not observed with 5-deazaFAD or 1-deazaFAD, an outcome attributed to a decrease in the acidity of the 8alpha-methyl group protons. Covalent flavin attachment is observed with 8-nor-8-chloroFAD in an aromatic nucleophilic displacement reaction that proceeds via a quininoid intermediate but not a reduced flavin intermediate. The reconstituted enzyme contains a modified cysteine-flavin linkage (8-nor-8-S-cysteinyl) as compared with native MSOX (8alpha-S-cysteinyl), a difference that may account for its approximately 10-fold lower catalytic activity.     

Characterization of acetohydroxyacid synthase from Mycobacterium tuberculosis and the identification of its new inhibitor from the screening of a chemical library

Acetohydroxyacid synthase (AHAS) is a thiamin diphosphate- (ThDP-) and FAD-dependent enzyme that catalyzes the first common step in the biosynthetic pathway of the branched-amino acids such as leucine, isoleucine, and valine. The genes of AHAS from Mycobacterium tuberculosis were cloned, and overexpressed in E. coli and purified to homogeneity. The purified AHAS from M. tuberculosis is effectively inhibited by pyrazosulfuron ethyl (PSE), an inhibitor of plant AHAS enzyme, with the IC(50) (inhibitory concentration 50%) of 0.87 microM. The kinetic parameters of M. tuberculosis AHAS were determined, and an enzyme activity assay system using 96-well microplate was designed. After screening of a chemical library composed of 5600 compounds using the assay system, a new class of AHAS inhibitor was identified with the IC(50) in the range of 1.8-2.6 microM. One of the identified compounds (KHG20612) further showed growth inhibition activity against various strains of M. tuberculosis. The correlation of the inhibitory activity of the identified compound against AHAS to the cell growth inhibition activity suggested that AHAS might be served as a target protein for the development of novel anti-tuberculosis therapeutics.     

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.     

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.     

Reconstitution of UDP-galactopyranose mutase with 1-deaza-FAD and 5-deaza-FAD: analysis and mechanistic implications

The galactofuranose moiety found in many surface constituents of microorganisms is derived from UDP-D-galactopyranose (UDP-Galp) via a unique ring contraction reaction catalyzed by a FAD-dependent UDP-Galp mutase. When the enzyme is reduced by sodium dithionite, its catalytic efficiency increases significantly. Since the overall transformation exhibits no net change in the redox state of the parties involved, how the enzyme-bound FAD plays an active role in the reaction mechanism is puzzling. In this paper, we report our study of the catalytic properties of UDP-Galp mutase reconstituted with deaza-FADs. It was found that the mutase reconstituted with FAD or 1-deazaFAD has comparable activity, while that reconstituted with 5-deazaFAD is catalytically inactive. Because 5-deazaFAD is restricted to net two-electron process, yet FAD and 1-deazaFAD can undergo concerted two-electron as well as stepwise one-electron redox reactions, the above results support a radical mechanism for the mutase catalyzed reaction. In addition, the activity of the mutase reconstituted with FAD was found to increase considerably at high pHs. These observations have allowed us to propose a new mechanism involving one-electron transfer from the reduced FAD to an oxocarbenium intermediate generated by C-1 elimination of UDP to give a hexose radical and a flavin semiquinone. Subsequent radical recombination leads to a coenzyme-substrate adduct which may play a central role to facilitate the opening and recyclization of the galactose ring. A deprotonation step, accompanied or followed the electron transfer step, to increase the nucleophilicity of the flavin radical anion may account for the activity enhancement at pH > 8.     

Crystal structure of yeast acetohydroxyacid synthase: a target for herbicidal inhibitors

Acetohydroxyacid synthase (AHAS; EC 4.1.3.18) catalyzes the first step in branched-chain amino acid biosynthesis. The enzyme requires thiamin diphosphate and FAD for activity, but the latter is unexpected, because the reaction involves no oxidation or reduction. Due to its presence in plants, AHAS is a target for sulfonylurea and imidazolinone herbicides. Here, the crystal structure to 2.6 A resolution of the catalytic subunit of yeast AHAS is reported. The active site is located at the dimer interface and is near the proposed herbicide-binding site. The conformation of FAD and its position in the active site are defined. The structure of AHAS provides a starting point for the rational design of new herbicides.     

Biochemical evidence for multiple forms of acetohydroxy acid synthase in Spirulina platensis

Two isoforms of acetohydroxy acid synthase (AHAS), the first enzyme of the branched-chain amino acids biosynthetic pathway, were detected in cell-free extracts of the cyanobacterium Spirulina platensis and separated both by ion-exchange chromatography and by hydrophobic interaction. Several biochemical properties of the two putative isozymes were analysed and it was found that they differ for pH optimum, FAD requirement for both activity and stability, and for heat lability. The results were partially confirmed with the characterization of the enzyme extracted from a recombinant Escherichia coli strain transformed with one subcloned S. platensis coli strain transformed with one subcloned S. platensis AHAS gene. The approximate molecular mass of both AHAS activities, estimated by gel filtration, indicates that they are distinct isozymes and not different oligomeric species or aggregates of identical subunits.Abbreviations AHAS acetohydroxy acid synthase - DEAE cellulose diethylaminoethyl cellulose - DTT dithiothreitol - FAD flavin adenine dinucleotide - TPP thiamine pyrophosphate     

Flavin redox chemistry precedes substrate chlorination during the reaction of the flavin-dependent halogenase RebH

The flavin-dependent halogenase RebH catalyzes chlorination at the C7 position of tryptophan as the initial step in the biosynthesis of the chemotherapeutic agent rebeccamycin. The reaction requires reduced FADH(2) (provided by a partner flavin reductase), chloride ion, and oxygen as cosubstrates. Given the similarity of its sequence to those of flavoprotein monooxygenases and their common cosubstrate requirements, the reaction of FADH(2) and O(2) in the halogenase active site was presumed to form the typical FAD(C4a)-OOH intermediate observed in monooxygenase reactions. By using stopped-flow spectroscopy, formation of a FAD(C4a)-OOH intermediate was detected during the RebH reaction. This intermediate decayed to yield a FAD(C4a)-OH intermediate. The order of addition of FADH(2) and O(2) was critical for accumulation of the FAD(C4a)-OOH intermediate and for subsequent product formation, indicating that conformational dynamics may be important for protection of labile intermediates formed during the reaction. Formation of flavin intermediates did not require tryptophan, nor were their rates of formation affected by the presence of tryptophan, suggesting that tryptophan likely does not react directly with any flavin intermediates. Furthermore, although final oxidation to FAD occurred with a rate constant of 0.12 s(-)(1), quenched-flow kinetic data showed that the rate constant for 7-chlorotryptophan formation was 0.05 s(-)(1) at 25 degrees C. The kinetic analysis establishes that substrate chlorination occurs after completion of flavin redox reactions. These findings are consistent with a mechanism whereby hypochlorite is generated in the RebH active site from the reaction of FADH(2), chloride ion, and O(2).     

Peroxide modification of monoalkylated glutathione reductase. Stabilization of an active-site cysteine-sulfenic acid

Hydrogen peroxide reacts with two-electron reduced glutathione reductase (GR EH2 species) to give the native oxidized enzyme (E) without detectable intermediates. Prior alkylation of the EH2 interchange thiol with iodoacetamide, however, dramatically changes both the course and overall rate of the peroxide reaction. This oxidation, monitored spectrally, is characterized by an intermediate (EHRint) with enhanced long wavelength absorbance extending to 800 nm. This species decays in a second peroxide-dependent phase to an enzyme form (EHRox) easily distinguished from E. Quenching experiments with catalase allow the isolation of a stable mixture consisting of 36% monoalkylated GR (EHR), 60% EHRint, and 4% EHRox; NADPH titration and anaerobic dithiothreitol addition lead to quantitative reduction of EHRint to EHR, and there is an increase in thiol titer of 0.8-SH/FAD on NADPH reduction. Of the four titratable thiols present in EHR, 2.7 are lost on oxidation to EHRox and 0.7-0.8 mol of cysteic acid/FAD is formed. On the basis of these and other observations, we conclude that alkylation of the EH2 interchange thiol, which blocks disulfide formation, allows peroxide reaction at the remaining charge-transfer thiol to proceed via a stabilized cysteine-sulfenic acid intermediate (EHRint), which undergoes further oxidation to the corresponding cysteic acid (EHRox).     

The active site of hydroxynitrile lyase from Prunus amygdalus: Modeling studies provide new insights into the mechanism of cyanogenesis

The FAD-dependent hydroxynitrile lyase from almond (Prunus amygdalus, PaHNL) catalyzes the cleavage of R-mandelonitrile into benzaldehyde and hydrocyanic acid. Catalysis of the reverse reaction-the enantiospecific formation of alpha-hydroxynitriles--is now widely utilized in organic syntheses as one of the few industrially relevant examples of enzyme-mediated C-C bond formation. Starting from the recently determined X-ray crystal structure, systematic docking calculations with the natural substrate were used to locate the active site of the enzyme and to identify amino acid residues involved in substrate binding and catalysis. Analysis of the modeled substrate complexes supports an enzymatic mechanism that includes the flavin cofactor as a mere "spectator" of the reaction and relies on general acid/base catalysis by the conserved His-497. Stabilization of the negative charge of the cyanide ion is accomplished by a pronounced positive electrostatic potential at the binding site. PaHNL activity requires the FAD cofactor to be bound in its oxidized form, and calculations of the pKa of enzyme-bound HCN showed that the observed inactivation upon cofactor reduction is largely caused by the reversal of the electrostatic potential within the active site. The suggested mechanism closely resembles the one proposed for the FAD-independent, and structurally unrelated HNL from Hevea brasiliensis. Although the actual amino acid residues involved in the catalytic cycle are completely different in the two enzymes, a common motif for the mechanism of cyanogenesis (general acid/base catalysis plus electrostatic stabilization of the cyanide ion) becomes evident.     

Characterization of acetohydroxyacid synthase I from Escherichia coli K-12 and identification of its inhibitors

The first step in branched-chain amino acid biosynthesis is catalyzed by acetohydroxyacid synthase (EC 2.2.1.6). This reaction involves decarboxylation of pyruvate followed by condensation with either an additional pyruvate molecule or with 2-oxobutyrate. The enzyme requires three cofactors, thiamine diphosphate (ThDP), a divalent ion, and flavin adenine dinucleotide (FAD). Escherichia coli contains three active isoenzymes, and acetohydroxyacid synthase I (AHAS I) large subunit is encoded by the ilvB gene. In this study, the ilvB gene from E. coli K-12 was cloned into expression vector pETDuet-1, and was expressed in E. coli BL21 (DH3). The purified protein was identified on a 12% SDS-PAGE gel as a single band with a mass of 65 kDa. The optimum temperature, buffer, and pH for E. coli K-12 AHAS I were 37 °C, potassium phosphate buffer, and 7.5. Km values for E. coli K-12 AHAS I binding to pyruvate, Mg(+2), ThDP, and FAD were 4.15, 1.26, 0.2 mM, and 0.61 μM respectively. Inhibition of purified AHAS I protein was determined with herbicides and new compounds.     

Phenol hydroxylase from Bacillus thermoglucosidasius A7, a two-protein component monooxygenase with a dual role for FAD

A novel phenol hydroxylase (PheA) that catalyzes the first step in the degradation of phenol in Bacillus thermoglucosidasius A7 is described. The two-protein system, encoded by the pheA1 and pheA2 genes, consists of an oxygenase (PheA1) and a flavin reductase (PheA2) and is optimally active at 55 degrees C. PheA1 and PheA2 were separately expressed in recombinant Escherichia coli BL21(DE3) pLysS cells and purified to apparent homogeneity. The pheA1 gene codes for a protein of 504 amino acids with a predicted mass of 57.2 kDa. PheA1 exists as a homodimer in solution and has no enzyme activity on its own. PheA1 catalyzes the efficient ortho-hydroxylation of phenol to catechol when supplemented with PheA2 and FAD/NADH. The hydroxylase activity is strictly FAD-dependent, and neither FMN nor riboflavin can replace FAD in this reaction. The pheA2 gene codes for a protein of 161 amino acids with a predicted mass of 17.7 kDa. PheA2 is also a homodimer, with each subunit containing a highly fluorescent FAD prosthetic group. PheA2 catalyzes the NADH-dependent reduction of free flavins according to a Ping Pong Bi Bi mechanism. PheA2 is structurally related to ferric reductase, an NAD(P)H-dependent reductase from the hyperthermophilic Archaea Archaeoglobus fulgidus that catalyzes the flavin-mediated reduction of iron complexes. However, PheA2 displays no ferric reductase activity and is the first member of a newly recognized family of short-chain flavin reductases that use FAD both as a substrate and as a prosthetic group.     

Bacterial sarcosine oxidase: identification of novel substrates and a biradical reaction intermediate

Corynebacterial sarcosine oxidase contains both covalently and noncovalently bound FAD and forms complexes with various heterocyclic carboxylic acids (D-proline and 2-furoic, 2-pyrrolecarboxylic, and 2-thiophenecarboxylic acids). 2-Furoic acid, a competitive inhibitor with respect to sarcosine, selectively perturbs the absorption spectrum of the noncovalent flavin, suggesting that the enzyme has a single sarcosine binding site near the noncovalent flavin. Several heterocyclic amines have been identified as new substrates for the enzyme. Similar reactivity is observed with L-proline and L-pipecolic acid whereas L-2-azetidine-carboxylic acid is less reactive. Turnover with L-proline is slow (TN = 4.4 min-1) as compared with sarcosine (TN = 1000 min-1). Anaerobic reduction of the enzyme with heterocyclic amine substrates at pH 8.0 occurs as a biphasic reaction. A similar long-wavelength intermediate is formed in the initial fast phase of each reaction and then decays in a slower second phase to yield 1,5-dihydroFAD. The slow phase is not kinetically significant during aerobic turnover at pH 8.0 and is absent when the anaerobic reactions are conducted at pH 7.0. EPR and other studies at pH 7.0 show that the long-wavelength species is a half-reduced form of the enzyme (1 electron/substrate-reducible flavin) containing 0.9 mol of flavin radical/mol of substrate-reducible flavin. This biradical intermediate exhibits an absorption spectrum similar to that expected for a 50:50 mixture of red anionic and blue neutral flavin radicals. A similar long-wavelength species is observed during titration of the enzyme with sarcosine and other reductants. Studies with L-proline suggest that reduction of the enzyme involves initial transfer of two electrons to the noncovalent flavin. The covalent flavin is not required and can be complexed with sulfite without affecting the rate of electron transfer. The initial half-reduced form of the enzyme appears to be rapidly converted to the biradical form via comproportionation of the reduced noncovalent flavin with the oxidized covalent flavin.     

L-amino-acid oxidase from the Malayan pit viper Calloselasma rhodostoma. Comparative sequence analysis and characterization of active and inactive forms of the enzyme.

Here we report the cDNA-deduced amino-acid sequence of L-amino-acid oxidase (LAAO) from the Malayan pit viper Calloselasma rhodostoma, which shows 83% identity to LAAOs from the Eastern and Western diamondback rattlesnake (Crotalus adamanteus and Crotalus atrox, respectively). Phylogenetic comparison of the FAD-dependent ophidian LAAOs to FAD-dependent oxidases such as monoamine oxidases, D-amino-acid oxidases and tryptophan 2-monooxygenases reveals only distant relationships. Nevertheless, all LAAOs share a highly conserved dinucleotide-binding fold with monoamine oxidases, tryptophan 2-monooxygenases and various other proteins that also may have a requirement for FAD. In order to characterize Ca. rhodostoma LAAO biochemically, the enzyme was purified from snake venom to apparent homogeneity. It was found that the enzyme undergoes inactivation by either freezing or increasing the pH to above neutrality. Both inactivation processes are fully reversible and are associated with changes in the UV/visible range of the flavin absorbance spectrum. In addition, the spectral characteristics of the freeze-and pH-induced inactivated enzyme are the same, indicating that the flavin environments are similar in the two inactive conformational forms. Monovalent anions, such as Cl(-), prevent pH-induced inactivation. LAAO exhibits typical flavoprotein oxidase properties, such as thermodynamic stabilization of the red flavin semiquinone radical and formation of a sulfite adduct. The latter complex as well as the complex with the competitive substrate inhibitor, anthranilate, were only formed with the active form of the enzyme indicating diminished accessibility of the flavin binding site in the inactive form(s) of the enzyme.     

Mechanistic studies of choline oxidase with betaine aldehyde and its isosteric analogue 3,3-dimethylbutyraldehyde

Choline oxidase catalyzes the four-electron oxidation of choline to glycine betaine via two sequential FAD-dependent reactions in which betaine aldehyde is formed as an intermediate. The chemical mechanism for the oxidation of choline catalyzed by choline oxidase was recently elucidated by using kinetic isotope effects [Fan, F., and Gadda, G. (2005) J. Am. Chem. Soc. 127, 2067-2074]. In this study, the oxidation of betaine aldehyde has been investigated by using spectroscopic and kinetic analyses with betaine aldehyde and its isosteric analogue 3,3-dimethylbutyraldehyde. The pH dependence of the kcat/Km and kcat values with betaine aldehyde showed that a catalytic base with a pKa of approximately 6.7 is required for betaine aldehyde oxidation. Complete reduction of the enzyme-bound flavin was observed in a stopped-flow spectrophotometer upon anaerobic mixing with betaine aldehyde or choline at pH 8, with similar k(red) values > or = 48 s(-1). In contrast, only 10-26% of the enzyme-bound flavin was reduced by 3,3-dimethylbutyraldehyde between pH 6 and 10. Furthermore, this compound acted as a competitive inhibitor versus choline. NMR spectroscopic analyses indicated that betaine aldehyde exists predominantly (99%) as a diol form in aqueous solution. In contrast, the thermodynamic equilibrium for 3,3-dimethylbutyraldehyde favors the aldehyde (> or = 65%) over the hydrated form in the pH range from 6 to 10. The keto species of 3,3-dimethylbutyraldehyde is reactive toward enzymic nucleophiles, as suggested by the kinetic data with NAD+-dependent yeast aldehyde dehydrogenase. The data presented suggest that choline oxidase utilizes the hydrated species of the aldehyde as substrate in a mechanism for aldehyde oxidation in which hydride transfer is triggered by an active site base.