Properties and catalytic function of the two nonequivalent flavins in sarcosine oxidase

Sarcosine oxidase from Corynebacterium sp. U-96 contains 1 mol of noncovalently bound flavin and 1 mol of covalently bound flavin per mole of enzyme. Anaerobic titrations of the enzyme with either sarcosine or dithionite show that both flavins are reducible and that two electrons per flavin are required for complete reduction. Absorption increases in the 510-650-nm region, attributed to the formation of a blue neutral flavin radical, are observed during titration of the enzyme with dithionite or substrate, during photochemical reduction of the enzyme, and during reoxidation of substrate-reduced enzyme. Fifty percent of the enzyme flavin forms a reversible, covalent complex with sulfite (Kd = 1.1 X 10(-4) M), accompanied by a complete loss of catalytic activity. Sulfite does not prevent reduction of the sulfite-unreactive flavin by sarcosine but does interfere with the reoxidation of reduced enzyme by oxygen. The stability of the sulfite complex is unaffected by excess acetate (an inhibitor competitive with sarcosine) or by removal of the noncovalent flavin to form a semiapoprotein preparation where 75% of the flavin reacts with sulfite (Kd = 9.4 X 10(-5) M) while only 3% remains reducible with sarcosine. The results indicate that oxygen and sulfite react with the covalently bound flavin and suggest that sarcosine is oxidized by the noncovalently bound flavin.     

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.     

Kinetic studies on the reaction mechanism of sarcosine oxidase

A sarcosine oxidase (sarcosine: oxygen oxidoreductase (demethylating), EC 1.5.3.1) isolated from Corynebacterium sp. U-96 contains both covalently bound FAD and noncovalently bound FAD. The noncovalent FAD reacts with sarcosine, the covalent FAD with molecular oxygen (Jorns, M.S. (1985) Biochemistry 24, 3189-3194). To clarify the reaction mechanism of the enzyme, kinetic investigations were performed by the stopped-flow method as well as by analysis of the overall reaction. The absorption spectrum of the enzyme in the steady state was very similar to that of the oxidized enzyme, and no intermediate enzyme species, such as a semiquinoid flavin, was detected. The rate for anaerobic reduction of the noncovalently bound FAD and the covalently bound FAD by sarcosine were 31 and 6.7 s-1, respectively. The latter value was smaller than the value of respective Vmax/e0 obtained by the overall reaction kinetics (Vmax/e0: the maximum velocity per enzyme concentration). Both rate constants for oxidation of the two FADs by molecular oxygen were 100 s-1. A reaction scheme of sarcosine oxidase is proposed to account for the data obtained; 70% of the enzyme functions via a fully reduced enzyme, and 30% of the enzyme goes along a side-path, without forming the fully reduced enzyme. In addition, it is suggested that the reactivity of noncovalently bound FAD with sarcosine is affected by the oxidation-reduction state of the covalently bound FAD, in contrast to the reactivity of the covalently bound FAD with molecular oxygen, which is independent of the oxidation-reduction state of the noncovalently bound FAD.     

Structure of the flavocoenzyme of two homologous amine oxidases: monomeric sarcosine oxidase and N-methyltryptophan oxidase

Monomeric sarcosine oxidase (MSOX) and N-methyltryptophan oxidase (MTOX) are homologous enzymes that catalyze the oxidative demethylation of sarcosine (N-methylglycine) and N-methyl-L-tryptophan, respectively. MSOX is induced in various bacteria upon growth on sarcosine. MTOX is an E. coli enzyme of unknown metabolic function. Both enzymes contain covalently bound flavin. The covalent flavin is at the FAD level as judged by electrospray mass spectrometry. The data provide the first evidence that MTOX is a flavoprotein. The following observations indicate that 8alpha-(S-cysteinyl)FAD is the covalent flavin in MSOX from Bacillus sp. B-0618 and MTOX. FMN-containing peptides, prepared by digestion of MSOX or MTOX with trypsin, chymotrypsin, and phosphodiesterase, exhibited absorption and fluorescence properties characteristic of an 8alpha-(S-cysteinyl)flavin and could be bound to apo-flavodoxin. The thioether link in the FMN-containing peptides was converted to the sulfone by performic acid oxidation, as judged by characteristic absorbance changes and an increase in flavin fluorescence. The sulfone underwent a predicted reductive cleavage reaction upon treatment with dithionite, releasing unmodified FMN. Cys315 was identified as the covalent FAD attachment site in MSOX from B. sp. B-0618, as judged by the sequence obtained for a flavin-containing tryptic peptide (GAVCMYT). Cys315 aligns with a conserved cysteine in MSOX from other bacteria, MTOX (Cys308) and pipecolate oxidase, a homologous mammalian enzyme known to contain covalently bound flavin. There is only one conserved cysteine found among these enzymes, suggesting that Cys308 is the covalent flavin attachment site in MTOX.     

Kinetics of electron entry, exit, and interflavin electron transfer during catalysis by sarcosine oxidase.

Sarcosine oxidase contains 1 mol of covalently bound plus 1 mol of noncovalently bound FAD per active site. The first phase of the anaerobic reduction of the enzyme with sarcosine converts oxidized enzyme to an equilibrium mixture of two-electron-reduced forms (EH2) and occurs at a rate (2700 min-1, pH 8.0) similar to that determined for the maximum rate of aerobic turnover in steady-state kinetic studies (2600 min-1). The second phase of the anaerobic half-reaction converts EH2 to the four-electron-reduced enzyme (EH4) and occurs at a rate (k = 350 min-1) which is 7-fold slower than aerobic turnover. Reaction of EH2 with oxygen is 1.7-fold faster (k = 4480 min-1) than aerobic turnover and 13-fold faster than the anaerobic conversion of EH2 to EH4. The results suggest that the enzyme cycles between fully oxidized and two-electron-reduced forms during turnover with sarcosine. The long wavelength absorbance observed for EH2 is attributable to a flavin biradical (FADH.FAD.-) which is generated in about 50% yield at pH 8.0 and in nearly quantitative yield at pH 7.0. The rate of biradical formation is determined by the rate of electron transfer from sarcosine to the noncovalent flavin since electron equilibration between the two flavins (k = 750 s-1 or 45,000 min-1, pH 8.0) is nearly 20-fold faster, as determined in pH-jump experiments. Only two of the three possible isoelectronic forms of EH2 are likely to transfer electrons to oxygen since the reaction is known to occur at the covalent flavin. However, equilibration among EH2 forms is probably maintained during reoxidation, consistent with the observed monophasic kinetics, since interflavin electron transfer is 10-fold faster than electron transfer to oxygen.     

芽胞杆菌BSD-8肌氨酸氧化酶的纯化与性质

对一株从土壤中分离到的芽胞杆菌Bacillus sp.BSD-8菌株所产生的热稳定性较高的肌氨酸氧化酶进行纯化,并对该酶的特性进行了研究。通过硫酸铵分级沉淀、DEAE-纤维素离子交换柱、Toyopearl疏水层析柱和Sephadex G-75分子筛层析,使酶提纯25倍,比活力达到5.3U/mg。研究了纯化后的酶的生化特性,确定了该酶的主要特性:该酶为黄素蛋白,与黄素以非共价键的方式结合,由单一亚基组成,其亚基分子量为51kDa。酶的最适反应温度及pH分别为60℃与8.5。该酶在60℃及pH8.0~10.0条件下稳定。以Lineveaver-Burk作图法求得该酶米氏常数Km值为3.1mmol/L。Ag+、Hg2+、SDS及Tween80对该酶有强抑制作用,而Tween20和Triton X-100对酶活性无影响。该肌氨酸氧化酶在耐热性质上比以前所报道的肌氨酸氧化酶有很大的提高,在酶法肌酐测定应用中有明显的优势。     

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.     

Covalent flavinylation of monomeric sarcosine oxidase: identification of a residue essential for holoenzyme biosynthesis

FAD in monomeric sarcosine oxidase (MSOX) is covalently linked to the protein by a thioether linkage between its 8alpha-methyl group and Cys315. Covalent flavinylation of apoMSOX has been shown to proceed via an autocatalytic reaction that requires only FAD and is blocked by a mutation of Cys315. His45 and Arg49 are located just above the si-face of the flavin ring, near the site of covalent attachment. His45Ala and His45Asn mutants contain covalently bound FAD and exhibit catalytic properties similar to wild-type MSOX. The results rule out a significant role for His45 in covalent flavinylation or sarcosine oxidation. In contrast, Arg49Ala and Arg49Gln mutants are isolated as catalytically inactive apoproteins. ApoArg49Ala forms a stable noncovalent complex with reduced 5-deazaFAD that exhibits properties similar to those observed for the corresponding complex with apoCys315Ala. The results show that elimination of a basic residue at position 49 blocks covalent flavinylation but does not prevent noncovalent flavin binding. The Arg49Lys mutant contains covalently bound FAD, but its flavin content is approximately 4-fold lower than wild-type MSOX. However, most of the apoprotein in the Arg49Lys preparation is reconstitutable with FAD in a reaction that exhibits kinetic parameters similar to those observed for flavinylation of wild-type apoMSOX. Although covalent flavinylation is scarcely affected, the specific activity of the Arg49Lys mutant is only 4% of that observed with wild-type MSOX. The results show that a basic residue at position 49 is essential for covalent flavinylation of MSOX and suggest that Arg49 also plays an important role in sarcosine oxidation.     

Identification of the covalently bound flavin of thiamin dehydrogenase.

Thiamin dehydrogenase, a flavoprotein isolated from an unidentified soil bacterium, contains 1 mol of covalently bound FAD/mol of enzyme. A flavin peptide, isolated from tryptic-chymotryptic digests of the enzyme and hydrolyzed to the FMN level, shows a pH-dependent fluorescence yield being maximal at pH 3.5 to 4.0 and decreasing over 90% at pH 7.5 with a pKa of 5.8. Acid hydrolysis of the peptide results in an aminoacylflavin which shows a pKa of fluorescence quenching of 5.2. Absorption and electron paramagnetic resonance spectral data show the covalent substituent to be at the 8alpha position of the flavin as is the case with all known enzymes containing covalently bound flavin. The aminoacylflavin gives a negative Pauly reaction but yields 1 mol of histidine on drastic acid hydrolysis thus showing an imidazole ring nitrogen as the 8alpha substituent of the flavin. The aminoacylflavin differs from synthetic 8alpha-[N(3)-histidyl]riboflavin or its acid-modified form in pKa of fluorescence quenching, in electrophoretic mobility, in being reduced by borohydride, and in being labile to storage, yielding 8-formylriboflavin. In all of these properties, however, the 8alpha-histidylriboflavin isolated from thiamin dehydrogenase is indistinguishable from 8alpha-[N(1)-histidyl]riboflavin. It is therefore concluded that the FAD moiety of thiamin dehydrogenase is covalently linked via the 8alpha-methylene group to the N(1) position of the imidazole ring of histidine.     

Kinetic studies of the mechanism of carbon-hydrogen bond breakage by the heterotetrameric sarcosine oxidase of Arthrobacter sp. 1-IN

The reaction of heterotetrameric sarcosine oxidase (TSOX) of Arthrobactor sp. 1-IN has been studied by stopped-flow spectroscopy, with particular emphasis on the reduction of the enzyme by sarcosine. Expression of the cloned gene encoding TSOX in Escherichia coli enables the production of TSOX on a scale suitable for stopped-flow studies. Treatment of the enzyme with sulfite provides the means for selective formation of a flavin-sulfite adduct with the covalent 8alpha-(N(3)-histidyl)-FMN. Formation of the sulfite-flavin adduct suppresses internal electron transfer between the noncovalent FAD (site of sarcosine oxidation) and the covalent FMN (site of enzyme oxidation) and thus enables detailed characterization of the kinetics of FAD reduction by sarcosine using stopped-flow methods. The rate of FAD reduction displays a simple hyperbolic dependence on sarcosine concentration. Studies in the pH range 6.5-10 indicate there are no kinetically influential ionizations in the enzyme-substrate complex. A plot of the limiting rate of flavin reduction/the enzyme-substrate dissociation constant (k(lim)/K(d)) versus pH is bell-shaped and characterized by two macroscopic pK(a) values of 7.4 +/- 0.1 and 10.4 +/- 0.2: potential candidates for the two ionizable groups are discussed with reference to the structure of monomeric sarcosine oxidase (MSOX). The kinetic data are discussed with reference to potential mechanisms for the oxidation of amine molecules by flavoenzymes. Additionally, kinetic isotope effect studies of the rate of C-H bond breakage suggest that a ground-state quantum tunneling mechanism for H-transfer, facilitated by the low-frequency thermal motions of the protein molecule, accounts for C-H bond cleavage by TSOX. TSOX thus provides another example of C-H bond breakage by ground-state quantum tunneling, driven by protein dynamics [vibrationally enhanced ground-state quantum tunneling (VEGST)], for the oxidation of amines by enzymes.     

Role of the covalent flavin linkage in monomeric sarcosine oxidase

Monomeric sarcosine oxidase (MSOX) is a prototypical member of a recently recognized family of amine-oxidizing enzymes that all contain covalently bound flavin. Mutation of the covalent flavin attachment site in MSOX produces a catalytically inactive apoprotein (apoCys315Ala) that forms an unstable complex with FAD (K(d) = 100 muM), similar to that observed with wild-type apoMSOX where the complex is formed as an intermediate during covalent flavin attachment. In situ reconstitution of sarcosine oxidase activity is achieved by assaying apoCys315Ala in the presence of FAD or 8-nor-8-chloroFAD, an analogue with an approximately 55 mV higher reduction potential. After correction for an estimated 65% reconstitutable apoprotein, the specific activity of apoCys315Ala in the presence of excess FAD or 8-nor-8-chloroFAD is 14% or 80%, respectively, of that observed with wild-type MSOX. Unlike oxidized flavin, apoCys315Ala exhibits a high affinity for reduced flavin, as judged by results obtained with reduced 5-deazaFAD (5-deazaFADH(2)) where the estimated binding stoichiometry is unaffected by dialysis. The Cys315Ala.5-deazaFADH(2) complex is also air-stable but is readily oxidized by sarcosine imine, a reaction accompanied by release of weakly bound oxidized 5-deazaFAD. The dramatic difference in the binding affinity of apoCys315Ala for oxidized and reduced flavin indicates that the protein environment must induce a sizable increase in the reduction potential of noncovalently bound flavin (DeltaE(m) approximately 120 mV). The covalent flavin linkage prevents loss of weakly bound oxidized FAD and also modulates the flavin reduction potential in conjunction with the protein environment.     

Kinetic studies on the role of Lys-171 and Lys-358 in the beta subunit of sarcosine oxidase from Corynebacterium sp. U-96

Heterotetrameric sarcosine oxidase from Corynebacterium sp.U-96(SO-U96) contains non-covalent and covalent flavins. Lys-358 and Lys-171 in the beta subunit is present at non-covalent flavin adenine dinucleotide (FAD)- and covalent flavin monodinucleotide (FMN)-binding sites, respectively. The Lys-358 mutant, K358R showed 0.07% activity and higher apparent K(m) for sarcosine than the wild-type enzyme, but K358A and K358D mutants showed no activity, suggesting the importance of amino group of Lys358 in the sarcosine-binding to the enzyme. The Lys171 mutants, K171R, K171A and K171D showed 58, 39 and 32% activity of the wild-type enzyme, respectively. An apparent K(m) for oxygen and K(d) of enzyme-sulphite complex increased by the mutation. The rate of reduction of the FAD of K171 mutants with sarcosine did not change by the mutation. The stopped-flow photodiode array analyses of the anaerobic reduction with sarcosin of the wild-type and K171 mutant enzymes showed characteristic spectra of neutral and anionic semiquinones, especially for K171A enzyme. On the basis of these results, the reductive-half reaction of the wild-type and K171 mutant enzymes is explained by a mechanism involving the semiquinones. Low activity of K171 mutants is suggested to be derived from the low rate of oxidation of the reduced FMN in the enzyme.     

Organization of the genes involved in dimethylglycine and sarcosine degradation in Arthrobacter spp.: implications for glycine betaine catabolism.

The nucleotide sequences of two cloned DNA fragments containing the structural genes of heterotetrameric sarcosine oxidase (soxBDAG) and dimethylglycine dehydrogenase (dmg) from Arthrobater spp. 1-IN and Arthrobacter globiformis, respectively, have been determined. Open reading frames were identified in the soxBDAG operon corresponding to the four subunits of heterotetrameric sarcosine oxidase by comparison with the N-terminal amino-acid sequences and the subunit relative molecular masses of the purified enzyme. Alignment of the deduced sarcosine oxidase amino-acid sequence with amino-acid sequences of functionally related proteins indicated that the arthrobacterial enzyme is highly homologous to sarcosine oxidase from Corynebacterium P-1. Deletion and expression analysis, and alignment of the deduced amino-acid sequence of the dmg gene, showed that dmg encodes a novel dimethylglycine oxidase, which is related to eukaryotic dimethylglycine dehydrogenase, and contains nucleotide-binding, flavinylation and folate-binding motifs. The recombinant dimethylglycine oxidase was purified to homogeneity and characterized. The DNA located upstream and downstream of both the soxBDAG and dmg genes is predicted to encode enzymes involved in the tetrahydrofolate-dependent assimilation of methyl groups. Based on the sequence analysis reported herein, pathways are proposed for glycine betaine catabolism in Arthrobacter species, which involve the identified folate-dependent enzymes.     

A mutant sarcosine oxidase in which activity depends on flavin adenine dinucleotide

The covalent flavin attachment site in the Arthrobacter sarcosine oxidase (cysteine at position 318) was replaced with serine, and the mutational effect of C318S was analyzed. Wild type and C318S with a C-terminal 6-histidine tag were constructed and homogeneously purified by the single step. The covalently binding to flavin was not essential to the enzyme activity because the C318S mutant exhibited extremely weak activity. Moreover, the activity of the mutant was recovered in the presence of flavin adenine dinucleotide (FAD), and significantly increased as the concentration of FAD increased. This dependence of the mutant on FAD indicates that the noncovalent binding of free FAD to the mutant enzyme is reversible.     

Acyl-CoA oxidase from Candida tropicalis

Acyl coenzyme A oxidase (acyl-CoA oxidase) has been isolated in good yield from Candida tropicalis pK 233 grown on n-alkanes. Gel filtration, sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and measurement of flavin content suggest that the oxidase is an octamer of Mr 75 000 subunits each containing one flavin. The oxidase yields the red semiquinone form on dithionite or photochemical reduction, slowly forms an N-5 adduct with 0.16 M sulfite at pH 7.4, and is rapidly reduced by borohydride, forming the 3,4-dihydroflavin isomer. The red flavosemiquinone is only kinetically stabilized with respect to disproportionation in the free enzyme but is thermodynamically stabilized on binding enoyl-CoA derivatives. The enzyme is reduced by butyryl-, octanoyl-, and palmitoyl-CoA without formation of prominent long-wavelength bands. Acyl-CoA oxidase and the acyl-CoA dehydrogenases share many similarities in their interaction with CoA derivatives. For example, both enzymes stabilize the anionic radical on binding enoyl-CoA derivatives, both dehydrogenate 2-oxoheptadecyldethio-CoA but cannot utilize S-heptadecyl-CoA, both form long-wavelength bands with CoA persulfide species, and both enzymes are attacked by the suicide substrates 3,4-pentadienoyl-CoA and (methylene-cyclopropyl)acetyl-CoA at the flavin prosthetic group.     

Glycine oxidase from Bacillus subtilis. Characterization of a new flavoprotein.

Glycine oxidase (GO) is a homotetrameric flavoenzyme that contains one molecule of non-covalently bound flavin adenine dinucleotide per 47 kDa protein monomer. GO is active on various amines (sarcosine, N-ethylglycine, glycine) and d-amino acids (d-alanine, d-proline). The products of GO reaction with various substrates have been determined, and it has been clearly shown that GO catalyzes the oxidative deamination of primary and secondary amines, a reaction similar to that of d-amino acid oxidase, although its sequence homology is higher with enzymes such as sarcosine oxidase and N-methyltryptophane oxidase. GO shows properties that are characteristic of the oxidase class of flavoproteins: it stabilizes the anionic flavin semiquinone and forms a reversible covalent flavin-sulfite complex. The approximately 300 mV separation between the two FAD redox potentials is in accordance with the high amount of the anionic semiquinone formed on photoreduction. GO can be distinguished from d-amino acid oxidase by its low catalytic efficiency and high apparent K(m) value for d-alanine. A number of active site ligands have been identified; the tightest binding is observed with glycolate, which acts as a competitive inhibitor with respect to sarcosine. The presence of a carboxylic group and an amino group on the substrate molecule is not mandatory for binding and catalysis.     

Cofactors in sarcosine oxidase from Corynebacterium sp. U-96

Sarcosine oxidase from Corynebacterium sp. U-96 is a heterotetrameric enzyme that was reported to contain 1 mol of covalently bound FAD and 1 mol of non-covalently-bound FAD. This work describes the result of reinvestigation of the cofactors in this enzyme. The enzyme was found to contain 1 mol of non-covalently-bound NAD⁺, 1 mol of non-covalently-bound FAD, and 1 mol of covalent FMN. The covalent FMN was identified by the mass and amino acid sequence analyses of the flavin peptide.     

Interaction of tetrahydrofolate and other folate derivatives with bacterial sarcosine oxidase

Sarcosine oxidase from Corynebacterium sp. P-1 binds 2 mol of tetrahydrofolate/mol of enzyme (KD = 8.8 microM). The same stoichiometry is observed with tetrahydropteroyltetraglutamate (KD = 15.4 microM). Binding is also observed with pteroyltetraglutamate and with 5-formyltetrahydrofolate. In the case of the pteroylmonoglutamates, binding appears to be sensitive to changes in the pteridine ring since no binding is observed with 5-methyltetrahydrofolate or with folate. Sarcosine oxidase can be specifically adsorbed onto an affinity matrix prepared by coupling 5-formyltetrahydrofolate to AH-Sepharose. Tetrahydrofolate does not affect the rate of sarcosine oxidation but does block the formation of formaldehyde as a final product. In the presence of tetrahydrofolate, sarcosine oxidation is accompanied by the formation of 5,10-methylenetetrahydrofolate at a rate that exceeds the rate at which formaldehyde (or a precursor) can be released into solution and which is also considerably faster than the nonenzymic reaction of free formaldehyde with tetrahydrofolate. It is suggested that tetrahydrofolate may serve primarily to trap formaldehyde as it is formed at the active site during sarcosine oxidation. The existence of a catalytically significant binding site for tetrahydrofolate appears to be a general property of sarcosine oxidizing enzymes since similar results have previously been obtained with mammalian sarcosine dehydrogenase, an enzyme that is structurally and mechanistically very different from bacterial sarcosine oxidase.     

Cloning, expression and crystallization of heterotetrameric sarcosine oxidase from Pseudomonas maltophilia

Heterotetrameric sarcosine oxidase (TSOX) is a complex bifunctional enzyme that catalyzes the oxidation of the methyl group in sarcosine (N-methylglycine) and transfer of the oxidized methyl group into the one-carbon metabolic pool. In addition to four different subunits, TSOX contains three coenzymes (FAD, FMN, and NAD) and a binding site for tetrahydrofolate, the coenzyme acceptor of the oxidized methyl group from sarcosine. Based on preliminary success in crystallization of the natural enzyme, the genes encoding the subunits for TSOX from Pseudomonas maltophilia (pTSOX) were cloned by functional screening of a genomic library. Recombinant enzyme exhibiting the same specific activity as natural pTSOX could not be isolated using a similar or identical purification procedure. This difficulty was overcome by affinity purification of recombinant pTSOX containing a C-terminal (His)(6) tag on the subunit (gamma) encoded by soxG, the gene located at the 3' end of the pTSOX operon. Affinity-purified pTSOX could not be crystallized, a problem traced to microheterogeneity in the recombinant enzyme where about half of the FMN is present in a modified form that is not found in the natural enzyme and may be a biosynthetic intermediate. The modified flavin was eliminated by expression of the recombinant enzyme in the presence of sarcosine, the same reagent used to induce expression of the natural enzyme. Homogenous recombinant pTSOX was isolated from cells grown in the presence of sarcosine by chromatography on affinity and hydrophobic interaction matrices. High quality crystals that diffract to 1.85 A resolution have been obtained.     

Purification and characterization of an aldehyde oxidase from Pseudomonas sp. KY 4690

An aldehyde oxidase, which oxidizes various aliphatic and aromatic aldehydes using O(2) as an electron acceptor, was purified from the cell-free extracts of Pseudomonas sp. KY 4690, a soil isolate, to an electrophoretically homogeneous state. The purified enzyme had a molecular mass of 132 kDa and consisted of three non-identical subunits with molecular masses of 88, 39, and 18 kDa. The absorption spectrum of the purified enzyme showed characteristics of an enzyme belonging to the xanthine oxidase family. The enzyme contained 0.89 mol of flavin adenine dinucleotide, 1.0 mol of molybdenum, 3.6 mol of acid-labile sulfur, and 0.90 mol of 5'-CMP per mol of enzyme protein, on the basis of its molecular mass of 145 kDa. Molecular oxygen served as the sole electron acceptor. These results suggest that aldehyde oxidase from Pseudomonas sp. KY 4690 is a new member of the xanthine oxidase family and might contain 1 mol of molybdenum-molybdpterin-cytosine dinucleotide, 1 mol of flavin adenine dinucleotide, and 2 mol of [2Fe-2S] clusters per mol of enzyme protein. The enzyme showed high reaction rates toward various aliphatic and aromatic aldehydes and high thermostability.