KEGG:D02011 - FACTA Search

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Query: KEGG:D02011 (FAD)
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1. The effects of various inhibitors and activators on the azo- and nitro-reductases of Moniezia expansa have been studied. Both reductions were partially inhibited by FAD, FMN, riboflavin, allopurinol, dicoumarol, 5-nitro-2-furaldehyde, azide and cyanide at 1 mM. Both reactions were stimulated by hypoxanthine. Menadione, nitrofurantoin, SKF 525-A (2-diethylaminoethyl 2,2-diphenylvalerate) and fluoride were without effect. 2. Xanthine- and aldehyde-oxidase activities were not detected in the enzyme preparation. 3. The substrate specificity of the azo- and nitro-reductases were determined. Azobenzene, 4-dimethylamino-azobenzene and 1,2-dimethyl-4-(4-carboxyphenylazo)-5-hydroxybenzene, nitrobenzene, 4-nitrohippuric acid and the isomers of nitrophenol, nitroanisole, nitrobenzoic acid, nitrobenzaldehyde and nitrobenzyl alcohol were reduced. Nitrobenzaldehyde isomers were not reduced to the alcohols and the coumaric acids were not reduced to the phenylpropionic acids. 4. The products of azo- and nitro-reduction were the corresponding amines; hydroxylamino- and hydrazo-compounds were not detected. 5. The pH optima and cofactor requirements were the same for both azo- and nitro-reduction. Neither reaction was inhibited by oxygen.
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PMID:Azo- and nitro-reductases of the cestode Moniezia expansa. Substrate specificity, reaction products and the effects of flavins and other compounds. 1 14

Procedures for the purification of an aldehyde dehydrogenase from extracts of the obligate methylotroph, Methylomonas methylovora are described. The purified enzyme is homogeneous as judged from polyacrylamide gel electrophoresis. In the presence of an artificial electron acceptor (phenazine methosulfate), the purified enzyme catalyzes the oxidation of straight chain aldehydes (C1--C10 tested), aromatic aldehydes (benzaldehyde, salicylaldehyde), glyoxylate, and glyceraldehyde. Biological electron acceptors such as NAD+, NADP+, FAD, FMN, pyridoxal phosphate, and cytochrome c cannot act as electron carriers. The activity of the enzyme is inhibited by sulfhydryl agents [p-chloromercuribenzoate, N-ethylmaleimide and 5,5-dithiobis (2-nitrobenzoic acid)], cuprous chloride, and ferrour nitrate. The molecular weight of the enzyme as estimated by gel filtration is approximately 45000 and the subunit size determined by sodium dodecyl sulfate-gel electrophoresis is approximately 23000. The purified enzyme is light brown and has an absorption peak at 410 nm. Reduction of enzyme with sodium dithionite or aldehyde substrate resulted in the appearance of peaks at 523 nm and 552nm. These results suggest that the enzyme is a hemoprotein. There was no evidence that flavins were present as prosthetic group. The amino acid composition of the enzyme is also presented.
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PMID:Microbial oxidation of methane and methanol: purification and properties of a heme-containing aldehyde dehydrogenase from Methylomonas methylovora. 4 58

Cell-free extracts of methanol-grown Amycolatopsis methanolica contain dye-linked dehydrogenase activities for formate and methyl formate. Fractionation of the extracts revealed that the (unstable) activity for formate resides in membrane particles, while that for methyl formate belongs to a soluble enzyme that was purified and characterized. The enzyme, indicated as formate-ester dehydrogenase, appeared to be a molybdoprotein (4 Fe, 3 or 4 S, 1 Mo and 1 FAD were found for each enzyme molecule), with a molecular mass of 186 kDa and consisting of two subunits of equal size. Product identification suggests that the formate moiety in the ester becomes hydroxylated to a carbonate group after which the unstable alkyl carbonate decomposes into CO2 and the alcohol moiety. Based on structural and catalytic characteristics, the enzyme appears to be very similar to an enzyme isolated from Comamonas testosteroni [Poels, P. A., Groen, B. W. & Duine, J. A. (1987) Eur. J. Biochem. 166, 575-579] which was at that time considered to be an aldehyde dehydrogenase. Formate-ester dehydrogenase activity appeared to be present in several other bacteria. Possible roles for the A. methanolica enzyme in C1 dissimilation (oxidation of methyl formate to methanol and CO2 or a factor-formate adduct to factor plus CO2) or in general aldehyde oxidation, are discussed.
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PMID:Dye-linked dehydrogenase activities for formate and formate esters in Amycolatopsis methanolica. Characterization of a molybdoprotein enzyme active with formate esters and aldehydes. 159 91

Currently, two major pathways are distinguished along which the polyamines are metabolized: the interconversion pathway and the so-called terminal polyamine catabolism. In vertebrates, the interconversion pathway is a cyclic process which controls polyamine turnover. In conjunction with polyamine transport, it regulates intracellular polyamine homeostasis. In vertebrates, putrescine, the precursor of spermidine and spermine, is exclusively formed by decarboxylation of ornithine--as far as de novo synthesis is concerned. Spermidine and spermine synthase form spermidine from putrescine, and spermine from spermidine, by transfer of aminopropyl residues from decarboxylated S-adenosylmethionine. In the catabolic branch of the interconversion cycle, spermine is degraded to spermidine, and spermidine to putrescine. The first step in this sequence is acetylation in the N1 position. This is followed by oxidative splitting of the acetylated polyamines, whereby the aminopropyl residues which originated from decarboxylated S-adenosylmethionine are removed. The enzyme catalyzing this step is an FAD-dependent oxidase (polyamine oxidase). Ornithine decarboxylase, S-adenosylmethionine decarboxylase, and acetyl CoA:polyamine N1-acetyltransferase are highly regulated, inducible enzymes with a high turnover rate. Depending on the physiological situation, each of these enzymes may become rate limiting. Terminal polyamine catabolism is catalyzed by Cu2(+)-dependent amine oxidases, of which only diamine oxidase has been well defined. By oxidative deamination of a primary amino group, each intermediate of the interconversion cycle can be transformed into an aldehyde, which is further oxidized to an amino acid or a gamma-lactam. The products of the terminal catabolism as well as the acetylated polyamines are urinary excretory products. In addition to intracellularly synthesized polyamines, polyamines from various tissues and from exogenous sources (such as the gastrointestinal tract) may be utilized by those tissues which have a high demand. Polyamines play a paramount role in growth processes. In order to control growth (for example of tumors), it is necessary to block all major polyamine sources. If only one source is blocked, the remaining sources are usually capable of furnishing sufficient polyamines to support growth processes.
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PMID:Polyamine metabolism. 226 65

The kinetic course of the reaction of methanol and deutero-methanol with FAD-dependent alcohol oxidase was investigated under single-turnover conditions [kred approximately equal to 15000 min-1 (1H3COH) and approximately equal to 4300 min-1 (2H3COH)] and multiple-turnover conditions [TNmax approximately equal to 6000 min-1 (1H3COH) and approximately equal to 3100 min-1 (2H3COH)]. A kinetic scheme for the overall catalytic mechanism is proposed, which is characterized by (1) formation of a Michaelis complex between enzyme and substrate, (2) the reductive step involving partly rate-limiting scission of the substrate C-H bond, (3) reaction of the complex of reduced enzyme and aldehyde with dioxygen, and (4) a significant contribution of the dissociation rate of product from its complex with reoxidized enzyme to the overall rate. Prolonged turnover of various alcohols, including methanol, results in progressive inactivation of the enzyme by two processes. In the absence of catalase the inactivation rate increases with time due to accumulation of hydrogen peroxide, which is a potent inactivator (Kd approximately equal to 1.6 mM; kinact approximately equal to 0.55 min-1). In the presence of catalase inactivation during turnover is much slower, the process showing pseudo-first-order kinetics (Kinact approximately equal to 0.6 mM; kinact approximately equal to 0.005 min-1 with methanol). The ratio kcat/kinact varies with different alcohols but is always greater than 10(5). Propargyl alcohol and methylenecyclopropyl alcohol cannot be considered as suicide substrates, as compared to analogous substrates of other flavin oxidases.
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PMID:Flavin-dependent alcohol oxidase from yeast. Studies on the catalytic mechanism and inactivation during turnover. 353 34

Aldehyde dehydrogenase from Pseudomonas testosteroni was purified to homogeneity. The enzyme has a pH optimum of 8.2, uses a wide range of aldehydes as substrates and cationic dyes (Wurster's blue, phenazine methosulphate and thionine), but not anionic dyes (ferricyanide and 2.6-dichloroindophenol), NAD(P)+ or O2, as electron acceptors. Haem c and pyrroloquinoline quinone appeared to be absent but the common cofactors of molybdenum hydroxylases were present. Xanthine was not a substrate and allopurinol was not an inhibitor. Alcohols were inhibitors only when turnover of the enzyme occurred in aldehyde conversion. The enzyme has a relative molecular mass of 186,000, consists of two subunits of equal size (Mr 92,000), and 1 enzyme molecule contains 1 FAD, 1 molybdopterin cofactor, 4 Fe and 4 S. It is a novel type of NAD(P)+-independent aldehyde dehydrogenase since its catalytic and physicochemical properties are quite different from those reported for already known aldehyde-converting enzymes like haemoprotein aldehyde dehydrogenase (EC 1.2.99.3), quino-protein alcohol dehydrogenases (EC 1.1.99.8) and molybdenum hydroxylases.
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PMID:NAD(P)+-independent aldehyde dehydrogenase from Pseudomonas testosteroni. A novel type of molybdenum-containing hydroxylase. 360 27

Methanol oxidase isolated from Hansenula polymorpha contains two distinct flavin cofactors in approximately equal amounts. One has been identified as authentic FAD and the other as a modified form of FAD differing only in the ribityl portion of the ribityldiphosphoadenosine side chain. The significance of this finding is as yet unknown. Previous studies have shown that cyclopropanol irreversibly inactivates methanol oxidase [Mincey, T., Tayrien, G., Mildvan, A. S., & Abeles, R. H. (1980) Proc. Natl. Acad. Sci. U.S.A. 77, 7099-7101]. We have now established that inactivation is accompanied by covalent modification of the flavin cofactor. The stoichiometry of this reaction is 1 mol of cyclopropanol/mol of active flavin. The structure of the covalent adduct was determined by NMR, IR, and UV spectral studies to be an N5,C4a-cyclic 4a,5-dihydroflavin. Reduction of the covalent adduct with NaBH4 at pH 9.0 before removal from the enzyme converted it to the 1-(ribityldiphosphoadenosine)-substituted 4-(3-hydroxypropyl)-2,3-dioxoquinoxaline. Cyclopropyl ring cleavage accompanies inactivation, and covalent bond formation occurs between a methylene carbon of cyclopropanol and N5 of flavin. Methanol oxidase was also reconstituted with 5-deazaflavin adenine dinucleotide (dFAD). Reconstituted enzyme did not catalyze the oxidation of alcohols to the corresponding aldehydes, nor did reduced reconstituted enzyme catalyze the reverse reaction. Incubation of reconstituted enzyme with cyclopropanol resulted in an absorbance decrease at 399 nm, but no irreversible covalent modification of the deazaflavin cofactor. A reversible addition complex between cyclopropanol and dFAD is formed. The structure of that complex was not definitively established, but it is likely that it is formed through the addition of cyclopropoxide to C5 of dFAD. The failure of dFAD-reconstituted methanol oxidase to catalyze the oxidation of substrate, as well as the lack of reaction with cyclopropanol, supports a radical mechanism for alcohol oxidation and cyclopropanol inactivation. Methanol oxidase catalyzes the oxidation of cyclopropylcarbinol to the corresponding aldehyde. No ring-opened products were detected. The failure to form ring-opened products has been used as an argument against radical processes [MacInnes, I., Nonhebel, D. C., Orsculik, S. T., & Suckling, C. J. (1982) J. Chem. Soc., Chem. Commun., 121-122]. We present arguments against this interpretation.
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PMID:Mechanism of action of methanol oxidase, reconstitution of methanol oxidase with 5-deazaflavin, and inactivation of methanol oxidase by cyclopropanol. 389 2

A method for enzymatic determination of riboflavin was developed by enzymatic reduction of 2,6-dichlorophenolindophenol using a vitamin B2-aldehyde-forming enzyme prepared from Schizophyllum commune. The enzymatic method enabled us to determine riboflavin in a mixture containing riboflavin, FMN and FAD without separation of riboflavin. Moreover, the total amount of flavins in the mixture was shown to be determined by the enzyme in the presence of phosphatase.
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PMID:A method for quantitation of vitamin B2 by using an enzyme (producing vitamin B2-aldehyde) from Schizophyllum commune. 626 Sep 17

A highly specific inducible membrane-bound 4-pyridoxic acid dehydrogenase has been solubilized and purified to apparent homogeneity from Pseudomonas MA-1 grown with pyridoxine as a sole source of carbon and nitrogen. The undenatured enzyme migrates as a single band on gel electrophoresis; denatured preparations show two barely resolved bands (Mr = 63,000 and 61,000). Undenatured preparations aggregate readily, as evidenced by Mr values of 148,000, 470,000, and greater than 670,000 obtained by density gradient centrifugation or by gel filtration under various conditions. The enzyme contains FAD but no Fe or acid-labile S; an average minimum molecular weight of 131,000 was calculated from the FAD content. In the presence of 2,6-dichloroindophenol, the enzyme dehydrogenates 4-pyridoxic acid to the corresponding aldehyde; this reaction is not inhibited by CN-. At the pH optimum of 8.0, a Vm of approximately 7.0 mumol min-1 mg-1 and a Km of 9 microM were obtained. 2,6-Dichloroindophenol, phenazine methosulfate, and menadione are effective electron acceptors; ubiquinones are less active, while NAD, FAD, and O2 are inactive. However, in membrane fractions, oxygen supports 4-pyridoxic acid oxidation via a CN--sensitive electron transport chain, indicating that the dehydrogenase probably is coupled to ATP generation in such preparations.
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PMID:The bacterial oxidation of vitamin B6. 4-Pyridoxic acid dehydrogenase: a membrane-bound enzyme from Pseudomonas MA-1. 634 42

By techniques involving differential centrifugation and specific precipitation with CaCl2, it was shown that dimethylamine and trimethylamine mono-oxygenase activities co-sediment with NADPH-cytochrome c reductase activity in sphaeroplast lysates of Candida utilis grown on trimethylamine as sole nitrogen source. Since the active fraction also contained low levels of cytochromes P-450 and P-420, it was concluded that the two amine mono-oxygenases are located in the smooth endoplasmic reticulum and thus end up in the microsomal fraction on cell fractionation. Ten to twenty-fold enrichment of mono-oxygenase specific activity could be achieved by separation of activity from soluble protein by centrifugation or gel filtration. Cell-free extracts prepared in the absence of FAD showed only very low mono-oxygenase activity for either substrate. Some activity could be restored by addition of flavin nucleotides: there was a fivefold stimulation by FAD and a fourfold stimulation by FMN. All trimethylamine mono-oxygenase activity was lost when a partially purified preparation containing both activities was incubated for more than 24 h at 0 degrees C, suggesting that separate enzymes are responsible for the oxidation of secondary and tertiary amines. The enzyme preparation oxidized a wide range of secondary alkylamines up to dibutylamine and tertiary alkylamines up to tributylamine. Primary amines, choline, di- and triethanolamine, spermine, spermidine and substituted anilines were not oxidized. NADH had a lower apparent Km value and higher Vmax value than NADPH. Secondary and tertiary alkylamines containing more than one kind of alkyl group gave more than one kind of aldehyde on oxidation. Stoicheiometry determinations showed a consumption of 1 mol NAD(P)H and 1 mol O2 per mol aldehyde formed. Carbon monoxide, cyanide, proadifen hydrochloride (SKF 525-A), mercurials and mercaptoethanol all inhibited both activities.
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PMID:Subcellular localization and properties of partially purified dimethylamine and trimethylamine mono-oxygenase activities in Candida utilis. 654 83

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