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Query: EC:3.1.3.5 (
5'-nucleotidase
)
3,167
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
1. Extracts of several plant species contained nucleoside-AMP phosphotransferase activity. The ratio of activity with thymidine to that with uridine as nucleoside substrate was essentially constant, both between species and throughout plant development. Evidence is presented that the total thymidine-AMP phosphotransferase activity of the leaves of Asplenium nidus (bird's-nest fern) and of Helianthus tuberosus (Jerusalem artichoke) increases during maturation. 2.
Thymidine
-AMP phosphotransferase was purified 22-fold from a very rich source of this activity, extracts of A. nidus. 3. A broad specificity towards both nucleoside and nucleoside 5'-monophosphate substrates is displayed by this preparation, and the evidence suggests that all could be due to a single enzyme. 4. Nucleosides that act as substrates will also inhibit phosphotransfer to other nucleosides, with Ki values close to the corresponding Km values found when utilized as substrates. 5. Ca2+-activated ATP phosphohydrolase was separated from the phosphotransferase by differential complexing to Blue Dextran in the presence of urea, whereas an
AMP phosphohydrolase
activity was closely associated with thymidine-AMP phosphotransferase through all separation techniques used. 6. Metal ions did not activate either of the latter two activities, and 1,10-phenanthroline was found to inhibit the phosphotransferase. 7. Km values for AMP for the respective activities were 0.11 mM (thymidine phosphotransferase) and 0.20 mM (
AMP phosphohydrolase
) and for thymidine (phosphotransferase only) 0.88 mM. 8. 3':5'-Cyclic AMP was found to inhibit both phosphotransferase and
AMP phosphohydrolase
activities, with Ki values of 0.056 mM and 0.15 mM respectively. It is suggested that this inhibitor would be of value in revealing the existence of thymidine kinase in plant extracts with high thymidine phosphotransferase activity.
...
PMID:Thymidine phosphotransferase and nucleotide phosphohydrolase of the fern Asplenium nidus. General properties and inhibition by adenosine 3':5'-cyclic monophosphate. 18 31
Chronic exposure of H9 cells to 25 microM zidovudine (H9-AZT cells) causes a 2- to 3-fold increase in thymidine kinase (TK) activity (Agarwal RP, Int J Purines Pyrimidine Res, in press). The present study compared thymidine (TdR) and AZT anabolism in H9 and H9-AZT cells. After a 3.5-hr incubation with 10 microM TdR or AZT, the total intracellular accumulations of AZT (48.7 microM in H9 cells and 32.8 microM in H9-AZT cells) were 46.4% of TdR accumulation. Other major differences between TdR and AZT anabolism were: (i) the majority of TdR (84-87%) was incorporated into DNA compared to less than 1% of AZT; and (ii) whereas distribution of TdR in the nucleotides was TTP greater than TMP greater than TDP, zidovudine distributed was AZT-MP much greater than AZT-TP much greater than AZT-DP. Because of the poor substrate activity of AZT-MP for thymidylate kinase (TMP-kinase), most of the AZT (95-98%) remained as AZT-MP. TMP-kinase activities with TMP as substrate were 47.6 +/- 20.3 and 91.4 +/- 28.8 pmol/mg protein/min in H9 and H9-AZT cells, respectively. 5'-Nucleotidase activities with TMP as substrate were 428.9 +/- 37.8 and 255.9 +/- 28.7 pmol/mg protein/min in H9 and H9-AZT cells, respectively. Activities of these enzymes with AZT-MP as a substrate were very low. Despite an increase in TK and TMP-kinase, and a decrease in
5'-nucleotidase
activities, the total intracellular accumulations of TdR and AZT were reduced significantly (P less than 0.05) to 67.5% in H9-AZT cells.
Thymidine
transport (0.66 to 0.68 pmol/sec/10(6) cells) was similar in both the cell lines. The severe reductions of TdR salvage caused by chronic exposure of cells to AZT, if it occurs in AIDS patients on AZT chemotherapy, may explain some of the long-term clinical toxicities of the drug.
...
PMID:Thymidine and zidovudine metabolism in chronically zidovudine-exposed cells in vitro. 186 45
We have previously reported that 5'-aminothymidine (5'-AdThd), an antagonist of the feedback inhibition exerted by dTTP that regulates thymidine kinase, enhances the uptake and cytotoxicity of 5-iododeoxyuridine in various human bladder cancer cell lines but not in normal human urothelial cells (HU) propagated in vitro. In this work we have analyzed the factors that could potentially account for the differential effect of 5'-AdThd among various cell types: 647V (a human bladder cancer cell line); HU; SV-HU (a SV40-transformed human urothelial cell line), and C3H/10T1/2 mouse embryo fibroblasts (10T1/2) cells. 5'-AdThd enhanced the uptake of IdUrd in SV-HU cells (greater than 400%), similar to what we have observed before for 647V cells. However, in 10T1/2 and HU cells, 5'-AdThd only minimally increased the uptake of 5-iododeoxyuridine (about 160%).
Thymidine
kinases purified from the different sources were similarly sensitive to inhibition by dTTP or 5'-AdThd and to deinhibition of the dTTP-induced regulation of enzyme activity by 5'-AdThd. Furthermore, [3H]-5'-AdThd permeated and accumulated intracellularly in all cell types. In none of these cultures was nucleoside phosphorylase activity detected, as indicated by the inability of the cells to produce thymine or iodouracil after exposure to the appropriate nucleosides. Also, 5'-AdThd did not affect the breakdown of dTMP by crude preparations of cytosolic
5'-nucleotidase
from the different cells. We found that intracellular dTTP pools in the various cell types were substantially high (15-26 microM) compared to the sensitivity of thymidine kinase to inhibition by dTTP (IC50 2-4 microM). This suggests that thymidine kinase is in a strongly inhibited state in situ. To test the sensitivity of thymidine kinase (in situ) to regulation by dTTP we investigated: (a) the effect of depleting intracellular dTTP pools with methotrexate on the uptake of thymidine (dThd); and (b) the effect of pH on the uptake of dThd and its perturbation by 5'-AdThd, since the inhibition of thymidine kinase activity by dTTP is known to be pH dependent. We found that a 47% reduction of dTTP pools by methotrexate in 10T1/2 and HU cells did not result in an increase in thymidine kinase activity, as indicated by the lack of an effect on the uptake of dThd. However, we have previously shown that, under similar conditions, 647V cells show a substantial increase in dThd uptake.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:Basis for the differential modulation of the uptake of 5-iododeoxyuridine by 5'-aminothymidine among various cell types. 270 29
The nucleoside content of 32 elapid and viperid venoms was examined. Free purines, principally adenosine (ADO), inosine (INO), and guanosine (GUA), comprised as much as 8.7% of the solid components of some venoms. Thus, purines are far more abundant in some venoms than many proteinaceous toxins. Hypoxanthine (HYP) was found in about half of elapid and viperine venoms, in which it is a relatively minor constituent (<60 microg/g). Adenosine monophosphate (AMP) was tentatively identified in only three elapid and two viperid venoms. The pyrimidines, uridine (URI) and cytidine (CYT), were also found in most elapid and viperine venoms. In most of these, the amount of uridine was substantially greater than that of cytidine.
Thymidine
(THY) was not found in any venom, indicating that DNA from disintegration of glandular cells is not the source of venom nucleosides. In contrast to elapid and viperine venoms, most crotaline venoms are devoid of free nucleosides. Elapid and viperine venoms also contained other minor, low molecular weight constituents that could not be positively identified. Some had spectra identical to those of adenosine, nicotinamide adenine dinucleotide (NAD), inosine, xanthosine (XAN), and guanosine, while others had unique spectra. There is no apparent correlation between quantities of venom nucleosides and literature values for the three dominant venom enzymes that release endogenous nucleosides,
5'-nucleotidase
(5NUC), phosphodiesterase (PDE), and alkaline phosphomonoesterase (PME).
...
PMID:Taxonomic distribution and quantitative analysis of free purine and pyrimidine nucleosides in snake venoms. 1562 16
