flavin-adenine-dinucleotide and molybdenum-cofactor

A large number of disorders and their symptoms emerge from deficiency or overproduction of specific metabolites has drawn the attention for the discovery of new therapeutic agents for the treatment of disorders. Various approaches such as computational drug design have provided the new methodology for the selection and evaluation of target protein and the lead compound mechanistically. For instance, the overproduction of xanthine oxidase causes the accumulation of uric acid which can prompt gout.. In the present study we critically discussed the various techniques such as 3-D QSAR and molecular docking for the study of the natural based xanthine oxidase inhibitors with their mechanistic insight into the interaction of xanthine oxidase and various natural leads.. The computational studies of deferent natural compounds were discussed as a result the flavonoids, anthraquinones, xanthones shown the remarkable inhibitory potential for xanthine oxidase inhibition moreover the flavonoids such as hesperidin and rutin were found as promising candidates for further exploration.

Topics: Anthraquinones; Biological Products; Coenzymes; Computer Simulation; Computer-Aided Design; Drug Design; Enzyme Inhibitors; Flavin-Adenine Dinucleotide; Flavonoids; Iron-Sulfur Proteins; Metalloproteins; Molecular Docking Simulation; Molybdenum Cofactors; Protein Conformation; Pteridines; Quantitative Structure-Activity Relationship; Xanthine Oxidase; Xanthones

FAD synthase (FMN:ATP adenylyl transferase, FMNAT or FADS, EC 2.7.7.2) is involved in the biochemical pathway for converting riboflavin into FAD. Human FADS exists in different isoforms. Two of these have been characterized and are localized in different subcellular compartments. hFADS2 containing 490 amino acids shows a two domain organization: the 3'-phosphoadenosine-5'-phosphosulfate (PAPS) reductase domain, that is the FAD-forming catalytic domain, and a resembling molybdopterin-binding (MPTb) domain. By a multialignment of hFADS2 with other MPTb containing proteins of various organisms from bacteria to plants, the critical residues for hydrolytic function were identified. A homology model of the MPTb domain of hFADS2 was built, using as template the solved structure of a T. acidophilum enzyme. The capacity of hFADS2 to catalyse FAD hydrolysis was revealed. The recombinant hFADS2 was able to hydrolyse added FAD in a Co(2+) and mersalyl dependent reaction. The recombinant PAPS reductase domain is not able to perform the same function. The mutant C440A catalyses the same hydrolytic function of WT with no essential requirement for mersalyl, thus indicating the involvement of C440 in the control of hydrolysis switch. The enzyme C440A is also able to catalyse hydrolysis of FAD bound to the PAPS reductase domain, which is quantitatively converted into FMN.

Topics: Amino Acid Sequence; Binding Sites; Coenzymes; Computer Simulation; Enzyme Activation; Flavin-Adenine Dinucleotide; Humans; Hydrolases; Metalloproteins; Models, Chemical; Models, Molecular; Molecular Sequence Data; Molybdenum Cofactors; Multienzyme Complexes; Nucleotidyltransferases; Protein Binding; Protein Conformation; Protein Structure, Tertiary; Pteridines; Structure-Activity Relationship; Substrate Specificity

A bifunctional hydratase/alcohol dehydrogenase was isolated from the cyclohexanol degrading bacterium Alicycliphilus denitrificans DSMZ 14773. The enzyme catalyzes the addition of water to α,β-unsaturated carbonyl compounds and the subsequent alcohol oxidation. The purified enzyme showed three subunits in SDS gel, and the gene sequence revealed that this enzyme belongs to the molybdopterin binding oxidoreductase family containing molybdopterins, FAD, and iron-sulfur clusters.

Topics: Alcohol Dehydrogenase; Cloning, Molecular; Coenzymes; Comamonadaceae; DNA, Bacterial; Electrophoresis, Polyacrylamide Gel; Flavin-Adenine Dinucleotide; Hydro-Lyases; Iron Carbonyl Compounds; Iron-Sulfur Proteins; Metalloproteins; Molecular Sequence Data; Molybdenum Cofactors; Protein Subunits; Pteridines; Sequence Analysis, DNA

NAD(P)H:nitrate reductase (NaR, EC 1.7.1.1-3) is a useful enzyme in biotechnological applications, but it is very complex in structure and contains three cofactors-flavin adenine dinucleotide, heme-Fe, and molybdenum-molybdopterin (Mo-MPT). A simplified nitrate reductase (S-NaR1) consisting of Mo-MPT-binding site and nitrate-reducing active site was engineered from yeast Pichia angusta NaR cDNA (YNaR1). S-NaR1 was cytosolically expressed in high-density fermenter culture of methylotrophic yeast Pichia pastoris. Total amount of S-NaR1 protein produced was approximately 0.5 g per 10 L fermenter run, and methanol phase productivity was 5 microg protein/g wet cell weight/h. Gene copy number in genomic DNA of different clones showed direct correlation with the expression level. S-NaR1 was purified to homogeneity in one step by immobilized metal affinity chromatography (IMAC) and total amount of purified protein per run of fermentation was approximately 180 mg. Polypeptide size was approximately 55 kDa from electrophoretic analysis, and S-NaR1 was mainly homo-tetrameric in its active form, as shown by gel filtration. S-NaR1 accepted electrons efficiently from reduced bromphenol blue (kcat = 2081 s(-1)) and less so from reduced methyl viologen (kcat = 159 s(-1)). The nitrate KM for S-NaR1 was 30 +/- 3 microM, which is very similar to YNaR1. S-NaR1 is capable of specific nitrate reduction, and direct electric current, as shown by catalytic nitrate reduction using protein film cyclic voltammetry, can drive this reaction. Thus, S-NaR1 is an ideal form of this enzyme for commercial applications, such as an enzymatic nitrate biosensor formulated with S-NaR1 interfaced to an electrode system.

Topics: Binding Sites; Bioreactors; Coenzymes; Electrochemistry; Eukaryotic Cells; Fermentation; Flavin-Adenine Dinucleotide; Fungal Proteins; Heme; Metalloproteins; Methanol; Molecular Structure; Molecular Weight; Molybdenum Cofactors; Nitrate Reductase; Nitrate Reductases; Pichia; Pteridines

Gene duplication is a primary source of molecular substrate for the emergence of evolutionary novelties. The chances for redundant gene sequences to evolve new functions are small compared with the probability that the copies become disabled by deleterious mutations. Functional divergence after gene duplication can result in two alternative evolutionary fates: one copy acquires a novel function (neofunctionalization), or each copy adopts part of the tasks of their parental gene (subfunctionalization). The relative prevalence of each outcome is unknown. Similarly unknown is the relative importance of positive selection versus random fixation of neutral mutations. Aldehyde oxidase (Ao) and xanthine dehydrogenase (Xdh) genes encode two complex members of the xanthine oxidase family of molybdo-flavoenzymes that carry different functions. Ao is known to have originated from a duplicate of an Xdh gene in eukaryotes, before the origin of multicellularity. We show that (i) Ao evolved independently twice from two different Xdh paralogs, the second time in the chordates, before the diversification of vertebrates; (ii) after each duplication, the Ao duplicate underwent a period of rapid evolution during which identical sites across the two molecules, involving the flavin adenine dinucleotide and substrate-binding pockets, were subjected to intense positive Darwinian selection; and (iii) the second Ao gene likely endured two periods of redundancy, initially as a duplicate of Xdh and later as a functional equivalent of the old Ao, which is currently absent from the vertebrate genome. Caution is appropriate in structural genomics when using sequence similarity for assigning protein function.

Topics: Aldehyde Oxidase; Animals; Binding Sites; Biological Evolution; Cattle; Coenzymes; Evolution, Molecular; Flavin-Adenine Dinucleotide; Flavonoids; Gene Duplication; Ligands; Metalloproteins; Molybdenum Cofactors; Protein Binding; Pteridines; Xanthine Dehydrogenase

Assimilatory NADH:nitrate reductase (EC 1.6.6.1), a complex Mo-pterin-, cytochrome b(557)-, and FAD-containing protein, catalyzes the regulated and rate-limiting step in the utilization of inorganic nitrogen by higher plants. A codon-optimized gene has been synthesized for expression of the central cytochrome b(557)-containing fragment, corresponding to residues A542-E658, of spinach assimilatory nitrate reductase. While expression of the full-length synthetic gene in Escherichia coli did not result in significant heme domain production, expression of a Y647* truncated form resulted in substantial heme domain production as evidenced by the generation of "pink" cells. The histidine-tagged heme domain was purified to homogeneity using a combination of NTA-agarose and size-exclusion FPLC, resulting in a single protein band following SDS-PAGE analysis with a molecular mass of approximately 13 kDa. MALDI-TOF mass spectrometry yielded an m/z ratio of 12,435 and confirmed the presence of the heme prosthetic group (m/z=622) while cofactor analysis indicated a 1:1 heme to protein stoichiometry. The oxidized heme domain exhibited spectroscopic properties typical of a b-type cytochrome with a visible Soret maximum at 413 nm together with epr g-values of 2.98, 2.26, and 1.49, consistent with low-spin bis-histidyl coordination. Oxidation-reduction titrations of the heme domain indicated a standard midpoint potential (E(o)') of -118 mV. The isolated heme domain formed a 1:1 complex with cytochrome c with a K(A) of 7 microM (micro=0.007) and reconstituted NADH:cytochrome c reductase activity in the presence of a recombinant form of the spinach nitrate reductase flavin domain, yielding a k(cat) of 1.4 s(-1) and a K(m app) for cytochrome c of 9 microM. These results indicate the efficient expression of a recombinant form of the heme domain of spinach nitrate reductase that retained the spectroscopic and thermodynamic properties characteristic of the corresponding domain in the native spinach enzyme.

Topics: Amino Acid Sequence; Base Sequence; Coenzymes; Cytochrome c Group; Electrophoresis, Polyacrylamide Gel; Escherichia coli; Flavin-Adenine Dinucleotide; Gene Expression Regulation, Bacterial; Heme; Kinetics; Metalloproteins; Models, Chemical; Molecular Sequence Data; Molybdenum Cofactors; Nitrate Reductase (NADH); Nitrate Reductases; Oxidation-Reduction; Protein Conformation; Pteridines; Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization; Spinacia oleracea; Yeasts

Rhodobacter capsulatus xanthine dehydrogenase (XDH) is composed of two subunits, XDHA and XDHB. Immediately downstream of xdhB, a third gene was identified, designated xdhC, which is cotranscribed with xdhAB. Interposon mutagenesis revealed that the xdhC gene product is required for XDH activity. However, XDHC is not a subunit of active XDH, which forms an alpha2beta2 heterotetramer in R. capsulatus. It was shown that XDHC neither is a transcriptional regulator for xdh gene expression nor influences XDH stability. To analyze the function of XDHC for XDH in R. capsulatus, inactive XDH was purified from an xdhC mutant strain. Analysis of the molybdenum cofactor content of this enzyme demonstrated that in the absence of XDHC, no molybdopterin cofactor MPT is present in the XDHAB tetramer. In contrast, absorption spectra of inactive XDH isolated from the xdhC mutant revealed the presence of iron-sulfur clusters and flavin adenine dinucleotide, demonstrating that XDHC is not required for the insertion of these cofactors. The absence of MPT from XDH isolated from an xdhC mutant indicates that XDHC either acts as a specific MPT insertase or might be a specific chaperone facilitating the insertion of MPT and/or folding of XDH during or after cofactor insertion.

Topics: Coenzymes; Enzyme Stability; Flavin-Adenine Dinucleotide; Genes, Bacterial; Iron; Metalloproteins; Models, Biological; Molecular Sequence Data; Molybdenum; Molybdenum Cofactors; Mutagenesis, Insertional; Open Reading Frames; Pteridines; Rhodobacter capsulatus; Spectrometry, Fluorescence; Spectrophotometry; Sulfur; Transcription, Genetic; Xanthine Dehydrogenase

Carbon monoxide dehydrogenases (CO-DH) are the enzymes responsible for the oxidation of CO to carbon dioxide in carboxydobacteria and consist of three nonidentical subunits containing molybdopterin flavin adenine dinucleotide (FAD), and two different iron-sulfur clusters (O. Meyer, K. Frunzke, D. Gadkari, S. Jacobitz, I. Hugendieck, and M. Kraut, FEMS Microbiol. Rev. 87:253-260, 1990). The three structural genes of CO-DH in Hydrogenophaga pseudoflava were cloned and characterized. The genes were clustered on the chromosome in the transcriptional order cutM-cutS-cutL. The cloned cutM, cutS, and cutL genes had open reading frames of 864, 492, and 2,412 nucleotides, coding for proteins with calculated molecular weights of 30,694, 17,752, and 87,224, respectively. The overall identities in the nucleotide sequence of the genes and the amino acid sequence of the subunits with those of other carboxydobacteria were 64.5 to 74.3% and 62.8 to 72.3%, respectively. Primer extension analysis revealed that the transcriptional start site of the genes was the nucleotide G located 47 bp upstream of the cutM start codon. The deduced amino acid sequences of the three subunits of CO-DH implied the presence of molybdenum cofactor, FAD, and iron-sulfur centers in CutL, CutM, and CutS, respectively. Fluorometric analysis coupled with denaturing polyacrylamide gel electrophoresis of fractions from hydroxyapatite column chromatography in the presence of 8 M urea of active CO-DH and from gel filtration of spontaneously inactivated enzyme revealed that the large and medium subunits of CO-DH in H. pseudoflava bind molybdopterin and FAD cofactors, respectively. Iron-sulfur centers of the enzyme were identified to be present in the small subunit on the basis of the iron content in each subunit eluted from the denaturing polyacrylamide gels.

Topics: Aldehyde Oxidoreductases; Amino Acid Sequence; Base Sequence; Binding Sites; Cloning, Molecular; Coenzymes; Flavin-Adenine Dinucleotide; Genes, Bacterial; Iron-Sulfur Proteins; Macromolecular Substances; Metalloproteins; Molecular Sequence Data; Molybdenum Cofactors; Multienzyme Complexes; Multigene Family; Open Reading Frames; Pseudomonas; Pteridines; Recombinant Proteins; Restriction Mapping; Sequence Alignment; Sequence Homology, Amino Acid; Transcription, Genetic

Xanthine dehydrogenase (XDH) is induced in Comamonas acidovorans cells incubated in a limited medium with hypoxanthine as the only carbon and nitrogen source. The enzyme has been purified to homogeneity using standard techniques and characterized. It contains two subunits with M(r) values of 90 and 60 kDa. Gel filtration studies show the enzyme to have an alpha 2 beta 2 native structure. No precursor form of the enzyme is observed on Western blot analysis of cell extracts obtained at various stages of enzyme induction. Metal analysis of the purified enzyme shows 1.1 Mo, 4.0 Fe, and 3.6 phosphorus atoms per alpha beta protomer. Cofactor analysis shows the enzyme to contain a single molybdopterin mononucleotide and one FAD per alpha beta protomer. Electron spin resonance and circular dichroism spectral studies of the oxidized and reduced forms of the enzyme suggest the Fe centers to be two nonidentical [2Fe-2S] clusters. Electron spin resonance signals due to Mo(V) and neutral FAD radical are also observed in the reduced form of the enzyme. Purified enzyme preparations ranged from 70% to 100% functionality. The enzyme is irreversibly inactivated by CN- and is inhibited on incubation with allopurinol. With xanthine and NAD+ as substrates the enzyme has a specific activity of 50 units/mg, a kcat value of 120 s-1, an activity/flavin ratio of 1930, and respective Km values of 66 and 160 mM. Using 8-D-xanthine as substrate, a DV value of 1.8 is found with no change in Km. Thus, the Km and KD values of the enzyme for xanthine are equal. These data show Comamonas XDH to exhibit structural properties similar to bovine milk xanthine oxidase/dehydrogenase and to chicken liver xanthine dehydrogenase. Although the bacterial enzyme exhibits a 6-7-fold greater turnover rate than bovine or avian enzymes, the catalytic efficiencies (as measured by V/K) are similar for all three enzymes.

Topics: Animals; Cattle; Chickens; Circular Dichroism; Coenzymes; Electron Spin Resonance Spectroscopy; Flavin-Adenine Dinucleotide; Gram-Negative Aerobic Bacteria; Iron-Sulfur Proteins; Kinetics; Macromolecular Substances; Metalloproteins; Molecular Weight; Molybdenum; Molybdenum Cofactors; Phosphates; Protein Structure, Secondary; Pteridines; Substrate Specificity; Xanthine Dehydrogenase

The usefulness in structure/function studies of molybdenum-containing hydroxylases in work with rosy mutant strains of Drosophila melanogaster has been investigated. At least 23 such strains are available, each corresponding to a single known amino acid change in the xanthine dehydrogenase sequence. Sequence comparisons permit identification, with some certainty, of regions associated with the iron-sulphur centres and the pterin molybdenum cofactor of the enzyme. Procedures have been developed and rigorously tested for the assay in gel-filtered extracts of the flies, of different catalytic activities of xanthine dehydrogenase by the use of various oxidizing and reducing substrates. These methods have been applied to 11 different rosy mutant strains that map to different regions of the sequence. All the mutations studied cause characteristic activity changes in the enzyme. In general these are consistent with the accepted assignment of the cofactors to the different domains and with the known reactivities of the molybdenum, flavin and iron-sulphur centres. Most results are interpretable in terms of the mutation affecting electron transfer to or from one redox centre only. The activity data provide evidence that FAD and the NAD+/NADH binding sites are retained in mutants mapping to the flavin domain. Therefore, despite some indications from sequence comparisons, it is concluded that the structure of this domain of xanthine dehydrogenase cannot be directly related to that of other flavoproteins for which structural data are available. The data also indicate that the artificial electron acceptor phenazine methosulphate acts at the iron-sulphur centres and suggest that these centres may not be essential for electron transfer between molybdenum and flavin. The work emphasizes the importance of combined genetic and biochemical study of rosy mutant xanthine dehydrogenase variants in probing the structure and function of enzymes of this class.

Topics: Amino Acid Sequence; Animals; Binding Sites; Chromatography, Gel; Coenzymes; Drosophila melanogaster; Flavin-Adenine Dinucleotide; Iron-Sulfur Proteins; Metalloproteins; Molecular Sequence Data; Molybdenum; Molybdenum Cofactors; Mutation; NAD; Pteridines; Sequence Alignment; Structure-Activity Relationship; Xanthine Dehydrogenase

Xanthine dehydrogenase has been purified from Pseudomonas aeruginosa cultured on a rich medium and induced with hypoxanthine. The enzyme was shown to contain FAD, iron sulfur centers and a molybdenum cofactor as prosthetic groups. Analysis of the molybdenum cofactor in this enzyme has revealed that the cofactor contains molybdopterin (MPT) rather than molybdopterin guanine dinucleotide or molybdopterin cytosine dinucleotide which have previously been identified in a number of molybdoenzymes of bacterial origin. The pterin cofactor in P.aeruginosa xanthine dehydrogenase was alkylated and the resulting product was identified as dicarboxamidomethyl molybdopterin. In addition, the pterin released from the enzyme by denaturation with guanidine-HCl was found to chromatograph on Sephadex G-15 with an apparent molecular weight of 350. These results document the first example of a bacterial enzyme with a molybdenum cofactor comprising molybdopterin and the metal only.

Topics: Animals; Chickens; Chromatography, Gel; Chromatography, High Pressure Liquid; Coenzymes; Electron Spin Resonance Spectroscopy; Flavin-Adenine Dinucleotide; Metalloproteins; Molecular Structure; Molybdenum; Molybdenum Cofactors; Pseudomonas aeruginosa; Pteridines; Spectrum Analysis; Xanthine Dehydrogenase

Assimilatory nitrate reductase (NR) from Chlorella is homotetrameric, each subunit containing FAD, heme, and Mo-pterin in a 1:1:1 stoichiometry. Measurements of NR activity and steady-state reduction of the heme component under conditions of NADH limitation or competitive inhibition by nitrite suggested intramolecular electron transfer between heme and Mo-pterin was a rate-limiting step and provided evidence that heme is an obligate intermediate in the transfer of electrons between FAD and Mo-pterin. In addition to the physiological substrates NADH and nitrate, various redox mediators undergo reactions with one or more of the prosthetic groups. These reactions are coupled by NR to NADH oxidation or nitrate reduction. To test whether intramolecular redox reactions of NR were rate-determining, rate constants for redox reactions between NR and several chemically diverse mediators were measured by cyclic voltammetry in the presence of NADH or nitrate. Reduction of ferrocenecarboxylic acid, dichlorophenolindophenol, and cytochrome c by NADH-reduced NR was coupled to reoxidation at a glassy carbon electrode (ferrocene and dichlorophenolindophenol) or at a bis(4-pyridyl) disulfide modified gold electrode (cytochrome c), yielding rate constants of 10.5 x 10(6), 1.7 x 10(6), and 2.7 x 10(6) M-1 s-1, respectively, at pH 7. Kinetics were consistent with a second-order reaction, implying that intramolecular heme reduction by NADH and endogenous FAD was not limiting. In contrast, reduction of methyl viologen and diquat at a glassy carbon electrode, coupled to oxidation by NR and nitrate, yielded similar kinetics for the two dyes. In both cases, second-order kinetics were not obeyed, and reoxidation of dye-reduced Mo-pterin of NR by nitrate became limiting at low scan rates.(ABSTRACT TRUNCATED AT 250 WORDS)

Topics: Chlorella; Coenzymes; Electrochemistry; Flavin-Adenine Dinucleotide; Glucosephosphate Dehydrogenase; Heme; Kinetics; Metalloproteins; Molybdenum Cofactors; NAD; Nitrate Reductase; Nitrate Reductases; Oxidation-Reduction; Pteridines; Spectrophotometry

The quinoline oxidoreductase from Pseudomonas putida was purified 50-fold to homogeneity with 21% recovery, using ammonium sulfate precipitation, hydrophobic interaction-, anion exchange-, and gel chromatography. The Mr of the native enzyme was calculated to be 300,000 by gel filtration. SDS-polyacrylamide gel electrophoresis of the enzyme revealed three protein bands corresponding to Mr 85,000, 30,000 and 20,000. The enzyme contained 8 atoms of iron, 8 atoms of acid-labile sulfide, 2 molecules of FAD, and the molybdenum cofactor, molybdopterin. Besides quinoline, the quinoline oxidoreductase also catalysed the conversion of 5-, 6-, 7- and 8-hydroxyquinoline and 8-chloroquinoline to the corresponding 2-oxo compounds. The incorporated oxygen atom was derived from water. Cyanide and methanol were effective inhibitors.

Topics: Coenzymes; Flavin-Adenine Dinucleotide; Flavoproteins; Iron; Metalloproteins; Molecular Weight; Molybdenum; Molybdenum Cofactors; Oxidoreductases; Oxidoreductases Acting on CH-CH Group Donors; Pseudomonas; Pteridines; Soil Microbiology; Spectrophotometry; Sulfur

Potentiometric titrations of assimilatory nitrate reductase from Chlorella vulgaris were performed within the pH range 6.0-9.0. Mo(V) was measured by room temperature EPR spectroscopy while the reduction state of FAD was monitored by CD spectroscopy. Between pH 6 and 8.5, the line shape of the Mo(V) EPR signal was constant, exhibiting superhyperfine coupling to a single, exchangeable proton. Potentiometric titrations indicated the Em values for the Mo(VI)/Mo(V) (+61 mV, pH 6) and Mo(V)/Mo(IV) (+35 mV, pH 6) couples decreased with increasing pH by approximately -59 mV/pH unit, consistent with the uptake of a single proton upon reduction of Mo(VI) to Mo(V) and Mo(V) to Mo(IV). The pKa values for the dissociation of these redox-coupled protons appeared to lie outside the pH range studied: pKo(MoVI), pKo(MoV) less than 5.5; pKr(MoV), pKr(MoIV) greater than 9. The Em (n = 2) for FAD (-250 mV, pH 7) varied by approximately -30 mV/pH unit within the pH range 6.0-9.0. Low-temperature EPR potentiometry at the extreme pH values indicated less than 0.5% conversion of FAD to the semiquinone form at the midpoint of the titrations. In contrast, NADH-reduced enzyme exhibited approximately 3-5% of the FAD in the semiquinone form, present as the anionic (FAD.-) species, the spectrum characterized by a line width of 1.3 mT at both pH 6.0 and 9.0.(ABSTRACT TRUNCATED AT 250 WORDS)

Topics: Chlorella; Circular Dichroism; Coenzymes; Electron Spin Resonance Spectroscopy; Flavin-Adenine Dinucleotide; Hydrogen-Ion Concentration; Metalloproteins; Molybdenum; Molybdenum Cofactors; Nitrate Reductase; Nitrate Reductases; Oxidation-Reduction; Potentiometry; Pteridines

It was deduced many years ago from indirect evidence that demolybdo xanthine oxidase is present in normal bovine milk. This has now been confirmed by isolation of this enzyme form by a method based on the folate-gel affinity-chromatography procedure described Nishino & Tsushima [(1986) J. Biol. Chem. 261, 11242-11246]. Enzymic and spectroscopic properties of demolybdo xanthine oxidase, which retains flavin and iron-sulphur centres, are generally in accordance with expectations. Like the normal enzyme, it yields on denaturation material fluorescing at 460 nm. Molybdenum cofactor activity measured by the Neurospora crassa nit-1 assay in the presence of added molybdate was 33% of that of the normal enzyme. The absorption spectrum in the near-u.v. region differs slightly, but significantly, from that of the active and desulpho forms of the enzyme. It is concluded that the molybdenum cofactor site contains a pterin-like material not identical with that in the normal enzyme. The significance of the occurrence of demolybdo xanthine oxidase in milk is discussed, and evidence in the literature for demolybdo forms of other molybdoenzymes is briefly reviewed. Additional studies on the use of the affinity procedure for large-scale preparation of high-activity xanthine oxidase are described. In agreement with our ability to isolate the demolybdo enzyme, the procedure appears less effective in eliminating the demolybdo than the desulpho enzyme.

Topics: Animals; Chromatography, Affinity; Coenzymes; Electron Spin Resonance Spectroscopy; Flavin-Adenine Dinucleotide; Metalloproteins; Milk; Molybdenum; Molybdenum Cofactors; NAD; Pteridines; Spectrophotometry; Xanthine Oxidase

Radioactively labeled carbon monoxide (CO) dehydrogenase has been obtained in good yield and purity from Pseudomonas carboxydoflava grown in the presence of [32P]phosphate. One enzyme molecule contained an average of 8.32 molecules of phosphate. The entire phosphate content was confined to 2 molecules of FAD and 2 molecules of a pterin. These were noncovalently bound. Molybdoenzyme cofactors could be extracted into N-methyl formamide; pterins were isolated by thin-layer chromatography. CO dehydrogenase contained a novel pterin, different from molybdopterin, which was also resolved in other bacterial molybdoenzymes. Therefore, it was tentatively named bactopterin. The characteristic features of bactopterin were as follows. A relative molecular mass, Mr, of 730 which was much greater than that of molybdopterin (330) (Mr values refer to molybdenum-free forms of the cofactors; presumably, the latter were also devoid of the sulfhydryl groups contained in the native compounds). A content of 2 molecules of phosphate/molecule compared to only 1 phosphate in molybdopterin. Bactopterin was three times less susceptible to air oxidation than molybdopterin. Native bactopterin was cleaved by perchloric acid into two phosphorous-containing fragments with Mr of 330 and 420. The smaller one is believed to be very similar to molybdopterin, the larger one was not a pterin but probably contained an aromatic structure.

Topics: Aldehyde Oxidoreductases; Chromatography, Gel; Chromatography, Thin Layer; Coenzymes; Cytosine Nucleotides; Flavin-Adenine Dinucleotide; Formamides; Metalloproteins; Molecular Weight; Molybdenum; Molybdenum Cofactors; Multienzyme Complexes; Perchlorates; Phosphates; Pseudomonas; Pteridines; Pterins

The carbon monoxide oxidases (COXs) purified from the carboxydotrophic bacteria Pseudomonas carboxydohydrogena and Pseudomonas carboxydoflava were found to be molybdenum hydroxylases, identical in cofactor composition and spectral properties to the recently characterized enzyme from Pseudomonas carboxydovorans (O. Meyer, J. Biol. Chem. 257:1333-1341, 1982). All three enzymes exhibited a cofactor composition of two flavin adenine dinucleotides, two molybdenums, eight irons and eight labile sulfides per dimeric molecule, typical for molybdenum-containing iron-sulfur flavoproteins. The millimolar extinction coefficient of the COXs at 450 nm was 72 (per two flavin adenine dinucleotides), a value similar to that of milk xanthine oxidase and chicken liver xanthine dehydrogenase at 450 nm. That molybdopterin, the novel prosthetic group of the molybdenum cofactor of a variety of molybdoenzymes (J. Johnson and K. V. Rajagopalan, Proc. Natl. Acad. Sci. U.S.A. 79:6856-6860, 1982) is also a constituent of COXs from carboxydotrophic bacteria is indicated by the formation of identical fluorescent cofactor derivatives, by complementation of the nitrate reductase activity in extracts of Neurospora crassa nit-l, and by the presence of organic phosphate additional to flavin adenine dinucleotides. Molybdopterin is tightly but noncovalently bound to the protein. COX, sulfite oxidase, xanthine oxidase, and xanthine dehydrogenase each contains 2 mol of molybdopterin per mol of enzyme. The presence of a trichloroacetic acid-releasable, so-far-unidentified, phosphorous-containing moiety in COX is suggested by the results of phosphate analysis.

Topics: Aldehyde Oxidoreductases; Animals; Cattle; Chickens; Coenzymes; Female; Flavin-Adenine Dinucleotide; Liver; Metalloproteins; Milk; Molecular Weight; Molybdenum; Molybdenum Cofactors; Oxidation-Reduction; Oxidoreductases Acting on Sulfur Group Donors; Pseudomonas; Pteridines; Species Specificity; Spectrophotometry; Xanthine Dehydrogenase