David R. McNaughton scite author profile

David R. McNaughton

5Publications

22Citation Statements Received

0Citation Statements Given

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Affiliations

University of Manitoba

Publications

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Inhibition of mammalian ribonucleotide reductase by a dinucleotide produced in eucaryotic cells

Lewis

McNaughton

Goh

et al. 1977

Journal Cellular Physiology

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HS3, a highly phosphorylated dinucleoside originally purified from the fungus Achlya, has been isolated from Chinese hamster ovary cells undergoing glutamine starvation. The HS3 compounds obtained from the fungal and mammalian sources exhibited similar physical and chemical properties. This unusual dinucleotide may be an important regulator of eucaryotic ribonucleoside diphosphate reductase activity; for 50 micrometer HS3, isolated from either mammalian or fungal cells, significantly inhibited CDP reduction in Achlya or hamster cell preparations, but only marginally affected the activity of the enzyme from E. coli. Studies with HS3 isolated from Achlya and partially purified mammalian ribonucleotide reductase indicated that the compound noncompetitively inhibited the reduction of varying concentrations of the substrates CDP, ADP and GDP with Ki values of 23 micrometer, 14 micron and 16 micron respectively. These inhibitor concentrations are well below the estimated intracellular levels of HS3 in glutamine starved cells and suggest that HS3 inhibition of ribonucleotide reduction may be responsible for the rapid inhibition of DNA synthesis seen under these culture conditions.

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Regulation of fungal ribonucleotide reductase by unusual dinucleotides

Lewis

McNaughton

LéJohn

et al. 1976

Biochemical and Biophysical Research Communications

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Phosphorylated guanosine derivatives of eukaryotes: Regulation of DNA-dependent RNA polymerases I, II, and III in fungal development

McNaughton¹,

Klassen²,

LéJohn³

1975

Biochemical and Biophysical Research Communications

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Diguanosine nucleotides of fungi that regulate RNA polymerases isolated and partially characterised

LéJohn¹,

Cameron²,

McNaughton³

et al. 1975

Biochemical and Biophysical Research Communications

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Recharacterization of fungal dinucleoside polyphosphate (HS3)

McNaughton¹,

Klassen²,

Loewen³

et al. 1978

Can. J. Biochem.

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Three polyphosphorylated dinucleosides given the pseudonyms of HS3, HS2, and HS1 that were erroneously described as diguanosine polyphosphates (LéJohn, H. B., Cameron, L. E., McNaughton, D. R. & Klassen, G. R. (1975) Biochem, Biophys, Res, Commun. 66, 460-467) have been repurified and partially recharacterized. They have proved to be extremely complex molecules; chemical (HCl and KOH hydrolysis), physical (ultraviolet-light spectral analysis and ion-exchange chromatography), and enzymic (nucleotide pyrophosphatase and bacterial alkaline phosphatase hydrolysis) studies showed that (i) all three HS compounds are uracil rich and (ii) only HS3 contains a purine nucleoside and glutamate. The partial structure of HS3 was deciphered as a moiety of ADP--sugar X--glutamate (the mode of attachment of glutamate is obscure) that is covalently linked to another moiety composed of UDP, mannitol, and four phosphates. Sugar X had chromatographic characteristics of ribitol, but the chromatographic isolate also contained a ninhydrin-sensitive entity presumed to be an amino group. Sugar X, THEREFore, may be an amino sugar polyol. Only the general chemical compositions of HS2 and HS1 were determined. Each contained two uridines and HS2 had 10 phosphates whereas HS1 had 12.

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