deoxyguanosine-triphosphate and Lymphoma

Purine nucleoside phosphorylase (PNP; EC 2.4.2.1) deficiency is thought to cause T-lymphocyte depletion by accumulation of dG and dGTP, resulting in feedback inhibition of ribonucleotide reductase (RR; EC 1.17.4.1) and hence DNA synthesis. To test for additional toxic mechanisms of dG, we selected a double mutant of the mouse T-lymphoma S-49 cell line, dGuo-L, which is deficient in PNP and partially resistant to dGTP feedback inhibition of RR. The effects of dG on dGuo-L cells (concn. causing 50% inhibition, IC50 = 150 microM) were compared with those on the wild-type cells (IC50 = 30 microM) and the NSU-1 mutant with PNP deficiency only (IC50 = 15 microM). Fluorescence flow cytometry showed that equitoxic dG concentrations arrested wild-type and NSU-1 cells at the G1-S interface while allowing continued DNA synthesis in the S-phase, whereas the double mutant dGuo-L cells progressed through the cell cycle normally. dGuo-L cells accumulated high levels of dGTP in G1-phase, but not in S-phase cells, because of the utilization of dGTP for DNA synthesis and limited capacity to synthesize dGTP from dG. These results support the hypothesis that dG/dGTP toxicity occurs in the G1-phase or at the G1-S interface. Failure of dG to arrest the double mutant dGuo-L cells at the G1-S interface allows these cells to escape into S-phase, with an accompanying drop in dGTP levels. Thus the partial resistance of dGuo-L cells to dG toxicity may result from their shorter residence time in G1, allowing them to sustain higher dGTP levels. Hence RR inhibition by dGuo may not be the primary toxic mechanism in S-49 cells; rather, it may serve as an accessory event in dG toxicity by keeping the cells in the sensitive phase of the cell cycle. Among the possible targets of dG toxicity is RNA synthesis, which was inhibited at an early stage in dGuo-L cells.

Topics: Animals; Cell Cycle; Cell Division; Deoxyguanine Nucleotides; Deoxyguanosine; DNA, Neoplasm; Lymphoma; Mice; Mutation; Pentosyltransferases; Purine-Nucleoside Phosphorylase; Ribonucleotide Reductases; RNA, Neoplasm; T-Lymphocytes; Tumor Cells, Cultured

DNA precursor synthesis can be blocked specifically by the drug hydroxyurea (HU) which has therefore been used for anticancer therapy. High concentrations of HU, however, affect other processes than DNA synthesis; nevertheless, most studies on the biological action of HU have been made with concentrations at least one order of magnitude higher than those needed for cell-growth inhibition. In this study we characterized the effects of low concentrations of HU (i.e. concentrations leading to 50% inhibition of cell growth in 72 h) on cell cycle kinetics and nucleotide pools in mouse S49 cells with various defined alterations in DNA precursor synthesis. The effect of 50 microM HU on deoxyribonucleoside triphosphate pools was a 2-3-fold decrease in the dATP and dGTP pools, with no change in the dCTP pool and a certain increase in the dTTP pool. Addition of deoxycytidine or thymidine led to a partial reversal of the growth inhibition and cell-cycle perturbation caused by HU, and was accompanied by an increased level of the deoxyribonucleoside triphosphates. Addition of purine deoxyribonucleoside gave no protection, indicating that salvage of these nucleosides could not supply precursors for DNA synthesis in T-lymphoma cells. We observed a higher sensitivity to HU of cells lacking purine nucleoside phosphorylase or with a ribonucleotide reductase with altered allosteric regulation. Cells lacking thymidine kinase or deoxycytidine kinase were just as sensitive as wild-type cells.

Topics: Animals; Cell Cycle; Cell Line; Deoxyadenine Nucleotides; Deoxycytidine Kinase; Deoxycytosine Nucleotides; Deoxyguanine Nucleotides; Deoxyribonucleotides; Hydroxyurea; Lymphoma; Mice; Mutation; Purine-Nucleoside Phosphorylase; Ribonucleotide Reductases; T-Lymphocytes; Thymidine Kinase; Thymine Nucleotides

Topics: Animals; Cell Line; Deoxyguanine Nucleotides; Deoxyguanosine; DNA; Guanine; Lymphoma; Mice; Mutation; Mycophenolic Acid; Nucleic Acid Precursors; Purine-Nucleoside Phosphorylase; Ribonucleotide Reductases

Terminal transferase (TdT) activity and antigen have been measured in 267 specimens of human bone marrow and peripheral blood by using a biochemical assay for enzymatic activity and an immunofluorescence test for antigen. Oligo p(dA)50 and dGTP were used as reagents in the biochemical assay and either rabbit anti-calf TdT or rabbit anti-human TdT was used as the primary antibody for immunofluorescence. Because both false-positive and false-negative detection of TdT antigen occurs, the biochemical assay of TdT activity is considered the standard against which immunofluorescence assays must be measured. If specimens of cells contained TdT activity, then the immunofluorescence detected antigen in 91% of cases (rabbit anti-calf TdT) and 95% of cases (rabbit anti-human TdT). When no TdT activity was detected, the immunofluorescence test was positive in 7.8% of cases (rabbit anti-calf TdT) and 5.2% of cases (rabbit anti-human TdT). When air-dried slices were shipped by air mail to a distant location before being stained for immunofluorescence, TdT antigen was detected in only 33% of matched pair cases which contained TdT activity. From this study, the authors conclude that with current methodology, immunofluorescence tests for TdT antigen must be carried out on slides prepared in the testing laboratory and that such tests are reliable in more than 90% of cases. However, because a small percentage of results are false positives and false negatives, the authors suggest that if a patient's clinical response is not consistent with the immunofluorescence TdT result, an enzymatic assay for TdT activity be carried out.

Topics: Antigens; Bone Marrow; Deoxyguanine Nucleotides; DNA Nucleotidylexotransferase; DNA Nucleotidyltransferases; Evaluation Studies as Topic; Fluorescent Antibody Technique; Humans; Leukemia; Lymphoma; Oligodeoxyribonucleotides; Specimen Handling; Tritium

Incubation of mouse T lymphoma (S-49) cells with the inosinate dehydrogenase inhibitor mycophenolic acid produced a depletion of both GTP and dGTP, and resulted in growth inhibition, partial reduction in RNA synthesis, and drastic inhibition of DNA synthesis. Similar results suggested to others that the depletion of dGTP is primarily responsible for toxicity. However, guanosine was as effective as deoxyguanosine at preventing mycophenolic acid toxicity although deoxyguanosine was more effective at elevating dGTP levels. Moreover, in hypoxanthine-guanine phosphoribosyltransferase-deficient mutants of S-49 (6MPR-3-3) deoxyguanosine was unable to prevent mycophenolic acid toxicity or to re-establish normal DNA synthesis, although it returned cellular dGTP but not GTP levels to normal. No other nucleotide levels changed in a way which could account for the toxicity. Incubation of cells with a combination of deoxyadenosine, deoxycytidine, and erythro-9-(2-hydroxy-3-nonyl)adenine produced a selective depletion of dGTP to levels similar to that produced by mycophenolic acid, but did not affect cell growth. Studies with cells synchronized by centrifugal elutriation show that the toxicity of mycophenolic acid is specific to the S-phase of the cell cycle. Addition of actinomycin D at a concentration that inhibited RNA synthesis increased the availability of GTP and re-established normal DNA synthesis in mycophenolic acid-treated S-49 cells. These results suggest that the depletion of GTP rather than that of dGTP produces toxic effects in S-49 cells and that GTP is required for DNA synthesis.

Topics: Animals; Cell Division; Cell Line; Deoxyguanine Nucleotides; DNA, Neoplasm; Guanosine Triphosphate; Hypoxanthine Phosphoribosyltransferase; Kinetics; Lymphoma; Mice; Mutation; Mycophenolic Acid; Neoplasms, Experimental