Your search keyword '"Large, Peter J."' showing total 16 results

1. Assimilatory reduction of trimethylamine N-oxide in the yeast Sporopachydermia cereana

Author

Whitfield, David and Large, Peter J.

Abstract

Washed microsomal preparations (100 000 xg sediment) from the yeast Sporopachydermia cereana that had been grown on trimethylamine N-oxide as sole nitrogen source catalysed the NAD(P)H-dependent reduction of trimethylamine N-oxide to trimethylamine. Under anaerobic conditions, this was the sole reaction product, but under aerobic conditions only small amounts of trimethylamine accumulated, most being further metabolized to methylamine and formaldehyde (no detectable dimenthylamine accumulated due to its rapid turnover). In the absence of NAD(P)H, no formation of amines or formaldehyde from trimethylamine N-oxide was detected. The trimethylamine N-oxide reductase activity was inhibited by quinacrine, Cu2+ ions, triethylamine N-oxide (apparent Ki 0.43 mM) and dimethyl sulphoxide (Ki 0.94 mM). Chlorate and nitrate failed to inhibit the enzyme. The Km for trimethylamine N-oxide was 29 µM. Triethylamine N-oxide was also reduced by the microsomal preparation with the formation of acetaldehyde, and this reduction was sensitive to the same inhibitors as trimethylamine N-oxide, suggesting that both amine oxides are metabolized by the same enzyme(s). It is concluded that trimethylamine N-oxide is metabolized in this yeast via an NAD(P)H-dependent reductase.

Published

1987

2. Microbial oxidation of amines. Partial purification of a trimethylamine mono-oxygenase from Pseudomonas aminovorans and its role in growth on trimethylamine

Author

Boulton, Christopher A., Crabbe, M. James C., and Large, Peter J.

Abstract

1. A mono-oxygenase, which oxidizes trimethylamine and other tertiary amines bearing methyl or ethyl groups, was partially purified sixfold from Pseudomonas aminovorans grown on trimethylamine as sole carbon source. 2. The preferred electron donor was NADPH. The enzyme had a pH optimum of 8.0–9.4 for trimethylamine oxidation, and 8.8–9.2 for dimethylamine oxidation. 3. The oxidation product of trimethylamine was shown to be trimethylamine N-oxide. Other tertiary amines were probably also converted into N-oxides. 4. The enzyme also oxidized secondary amines. 5. The oxidation of trimethylamine was only slightly inhibited by CO and not at all by KCN or proadifen hydrochloride (SKF 525-A), but was inhibited by trimethylsulphonium chloride, tetramethylammonium chloride, 2,4-dichloro-6-phenylphenoxyethylamine (Lilly 53325) and its NN-diethyl derivative (Lilly 18947). 6. The oxidation of dimethylamine showed a similar response to inhibitors and a parallel loss in activity on heating at 35°C. 7. The activities of the trimethylamine mono-oxygenase, trimethylamine N-oxide demethylase and the secondary-amine mono-oxygenase increased severalfold during adaptation of succinate-grown bacteria to growth on trimethylamine, and the trimethylamine mono-oxygenase was the first enzyme to show an increase in activity. It is concluded that all three enzymes are involved in growth on trimethylamine by this organism.

Published

1974

3. Oxidation of N-alkyl- and NN-dialkylhydroxylamines by partially purified preparations of trimethylamine mono-oxygenase from Pseudomonas aminovorans

Author

Boulton, Christopher A. and Large, Peter J.

Published

1975

4. Solubilization and Partial Purification of N-Methylglutamate Dehydrogenase from Pseudomonas aminovorans

Author

BAMFORTH, CHARLES W. and LARGE, PETER J.

Published

1975

5. Oxidation of N‐alkyl‐ and NN‐dialkylhydroxylamines by partially purified preparations of trimethylamine mono‐oxygenase from Pseudomonas aminovorans

Author

Boulton, Christopher A. and Large, Peter J.

Published

1975

6. Microbial oxidation of amines. Distribution, purification and properties of two primary-amine oxidases from the yeast Candida boidinii grown on amines as sole nitrogen source

Author

Haywood, Geoffrey W. and Large, Peter J.

Abstract

1. The yeast Candida boidinii was grown on glucose as carbon source with a range of amines and amino acids as nitrogen sources. Cells grown on amines contained elevated activities of catalase. If the amines contained N-methyl groups, formaldehyde dehydrogenase, formate dehydrogenase and S-formylglutathione hydrolase were also elevated in activity compared with cells grown on (NH4)2SO4. 2. Cells grown on all the amines tested, but not those grown on urea or amino acids, contained an oxidase attacking primary amines, which is referred to as methylamine oxidase. In addition, cells grown on some amines contained a second amine oxidase, which is referred to as benzylamine oxidase. 3. Both amine oxidases were purified to near homogeneity. 4. Benzylamine oxidase was considerably more stable at 45 and 50°C than was methylamine oxidase. 5. Both enzymes had a pH optimum in the region of 7.0, and had a considerable number of substrates in common. There were, however, significant differences in the substrate specificity of the two enzymes. The ratio V/Kapp.m increased with increasing n-alkyl carbon chain length for benzylamine oxidase, but decreased for methylamine oxidase. 6. Both enzymes showed similar sensitivity to carbonyl-group reagents, copper-chelating agents and other typical ‘diamine oxidase inhibitors’. 7. The stoicheiometry for the reaction catalysed by each enzyme was established. 8. The kinetics of methylamine oxidase were examined by varying the methylamine and oxygen concentrations in turn. A non-Ping Pong kinetic pattern with intersecting double-reciprocal plots was obtained, giving Km values of 10mum for O2 and 198mum for methylamine. The significance of this unusual kinetic behaviour is discussed. Similar experiments were not possible with the benzylamine oxidase, because it seemed to have an even lower Km for O2. 9. Both enzymes had similar subunit Mr values of about 80000, but the benzylamine oxidase behaved as if it were usually a dimer, Mr 136000, which under certain conditions aggregated to a tetramer, Mr 288000. Methylamine oxidase was mainly in the form of an octamer, Mr 510000, which gave rise quite readily to dimers of Mr 150000, and on gel filtration behaved as if the Mr was 286000.

Published

1981

7. The Kinetic Mechanism of N-Methylglutamate Dehydrogenase from Pseudomonas aminovorans

Author

BAMFORTH, CHARLES W. and LARGE, PETER J.

Published

1978

8. Specific Activities of Enzymes of the Serine Pathway of Carbon Assimilation in Pseudomonas aminovorans and Pseudomonas MS grown on Methylamine

Author

LARGE, PETER J. and CARTER, ROBERT H.

Published

1973

9. The route of lysine breakdown in Candida tropicalis

Author

Large, Peter J. and Robertson, Anne

Abstract

Candila tropicalis was found to contain high levels of the following enzymes after growth in defined medium on l-lysine as sole nitrogen source: l-lysine N6-acetyltransferase, N6-acetyllysineaminotransferase, and aminotransferase activity for 5-aminovalerate and 4-aminobutyrate. Extracts were also capable of converting 5-acetamidovalerate (and 4-acetamidobutyrate) to acetate. N6-Acetyllysine however, only gave rise to acetate in the presence of 2-oxoglutarate, NAD+ and thiamine pyrophosphate. These activities were undetectable or present in much lower concentrations in cells that had been grown on ammonium sulphate as sole nitrogen source. It is concluded that l-lysine is degraded in this organism via N6-acetyllysine, 5-acetamidovalerate and 5-aminovalerate, both nitrogen atoms being removed by transamination.

Published

1991

10. Control of benzylamine oxidase activity in Kluyveromyces fragilis grown on primary amines as nitrogen source

Author

Sherlock, Lesley A. and Large, Peter J.

Abstract

After growth on a mixture of ammonium and either methylamine or n-butylamine as nitrogen sources, benzylamine oxidase activity in yeasts from a number of different genera was found to be repressed to a lesser extent by ammonium than was methylamine oxidase. Catalase activity was better repressed by ammonium with methylamine as the nitrogen source than with n-butylamine. During growth of Kluyveromyces fragilis on equimolar mixtures of ammonium and an amine as nitrogen sources, benzylamine oxidase synthesis began during the period of exclusive growth on ammonium, and a period of simultaneous use of both nitrogen sources was observed just before the ammonium was exhausted. Addition of ammonium to cultures growing on n-butylamine as nitrogen source had no immediate repressive effect on benzylamine oxidase or catalase synthesis. However, growth on limiting ammonium in the absence of amines did give rise to low levels of amine oxidase and derepression of catalase activity. It is concluded that benzylamine oxidase in yeasts is induced strongly by amines as well as being less strongly repressed by ammonium than methylamine oxidase.

Published

1985

11. A single amine oxidase mediates utilization of primary aliphatic amines as nitrogen source by Kluyveromyces lactis

Author

Heath, Lesley A. and Large, Peter J.

Abstract

Yeasts of the genus Kluyveromyces grew very slowly on methylamine as sole nitrogen source. Methylamine oxidase activity in cell-free extracts was very low. Under conditions known to separate methylamine oxidase from benzylamine oxidase in other yeast genera, only a single enzyme was detected in Kluyveromyces lactis. This enzyme could oxidize benzylamine, n-butylamine and (very poorly) methylamine. The enzyme lost no activity on heating at 45°C and had a high affinity and Vmax for benzylamine and 1-aminoalkanes of long-chain length, with a very low affinity and Vmax for methylamine. It is concluded that growth of K. lactis on methylamine involves only benzylamine oxidase, and that a methylamine oxidase of the type found in other yeasts does not occur.

Published

1984

12. Enzymes metabolizing dimethylamine, trimethylamine and trimethylamine N-oxide in the yeast Sporopachydermia cereana grown on amines as sole nitrogen source

Author

Whitfield, David and Large, Peter J.

Abstract

Sporopachydermia cereana, an ascosporogenous yeast, grew on dimethylamine, trimethylamine or trimethylamine N-oxide as sole nitrogen sources and produced mono-oxygenases for dimethylamine and trimethylamine that were significantly more stable than the corresponding enzymes found in Candida utilis. No trimethylamine mono-oxygenase activity was found in S. cereana grown on dimethylamine. In cells grown on trimethylamine N-oxide (but not on the other nitrogen sources), evidence for an enzyme metabolizing the N-oxide, possibly an aldolase, but more probably a reductase was obtained. All these activities showed a similar requirement for the presence of FAD or FMN in the extract buffer during isolation to retain activity. Amine mono-oxygenase activities showed a similar sensitivity to inhibitors, including proadifen hydrochloride and carbon monoxide as the corresponding enzymes in C. utilis. The trimethylamine N-oxide-dependent oxidation of NADH was more sensitive to inhibition by EDTA, N-ethylmaleimide and β-phenylethylamine than the mono-oxygenases, and less sensitive to KCN, and activity was significantly higher with NADPH than was observed with the 2 mono-oxygenases.

Published

1986

13. Cell-free oxidation of dimethylamine by a mono-oxygenase in the methazotrophic yeast Candida utilis

Author

GREEN, JEFFREY and LARGE, PETER J.

Published

1983

14. The methionine sulphoxide reductase activity of the yeast dimethyl sulphoxide reductase system

Author

Gibson, Richard M. and Large, Peter J.

Abstract

Glycyl-l-methionine sulphoxide and N-acetyl-l-methionine sulphoxide were less effective inhibitors of the dimethyl sulphoxide (DMSO) reductase activity of Saccharomyces cerevisiae NCYC240 than was l-methionine (±)-sulphoxide. Methionine sulphoxide reductase and DMSO reductase activities from crude extracts co-purified over five purification steps and the two activities eluted from columns in exactly the same fractions. Both activities were sensitive to the same inhibitors. It was concluded that: (1) the DMSO reductase activity of S. cerevisiae is a property of a methionine sulphoxide reductase different from that of Black et al. [J. Biol. Chem. 235 (1960) 2910–2916], and (2) free methionine sulphoxide rather than peptidyl methionine sulphoxide is probably the enzyme's true substrate.

Published

1985

15. The involvement of thioredoxin and thioredoxin reductase in the dimethyl sulphoxide reductase system of Saccharomyces cerevisiae

Author

Gibson, Richard M. and Large, Peter J.

Abstract

Dimethyl sulphoxide (DMSO) reductase activity in crude extracts of Saccharomyces cerevisiae NCYC240 was stimulated by addition of thioredoxin, but not by addition of thioredoxin reductase. The activity was partially purified. DEAE-cellulose could be used to separate thioredoxin and its reductase (which bound to the column) from the terminal DMSO-reductase protein (which failed to bind). The highly unstable purified terminal reductase so obtained required both thioredoxin and thioredoxin reductase to reconstitute activity with either dithiothreitol (DTT) or NADPH as electron donor. Partially purified terminal reductase had an Mr of about 15000.

Published

1985

16. Methodological Developments in Biochemistry (Volume 2): Preparative Techniques

Author

LARGE, PETER J.

Published

1973