Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0023418 (leukemia)
 93,477 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A limited number of biologically active materials were examined for their relative ability to selectively inhibit the replication of Gross or Rauscher murine leukemia virus (MLV) in Swiss mouse embryo cells by means of the UV-XC plaque-reduction assay. Among the compounds demonstrating significant antiviral activity against Gross MLV in vitro were 1-(4-fluorobenzyloxy) adenosine (FBAR), polyadenylic acid [poly(A)], the carbocyclic analogue of 6-methylthiopurine ribonucleoside (C-MeMPR), 3-(2,4-dinitrophenylhydrazonemethyl)rifamycin SV (AF/DNFI), and phosphonoacetic acid (PAA). Five compounds that exhibited significant antiviral activity against MLV in vitro were tested for similar activity against Rauscher MLV in vivo. Three of these selected compounds, pyrazofurin (pyrazomycin), ribavirin (Virazole), and 9-beta-D-arabinofuranosyladenine (ara-A), produced a significant (50%-100%) inhibition of virus-induced splenomegaly development in mice, whereas the other two candidate inhibitors, 3-deazauridine (deazaUR) and rifamycin SV, the other two candidate inhibitors, 3-deazauridine (deazaUR) and rifamycin SV, failed to demonstrate any in vivo activity in this 21-day leukemogenesis assay. The administration of an inhibitor of adenosine deaminase (Co-vidarabine) in combination with ara-A resulted in an enhanced antiviral response in both infected cell cultures and animals. Co-vidarabine also increased the potency of ara-AMP against Gross MLV in vitro, indicating the probable dephosphorylation of the compound to ara-A and its subsequent deamination to ara-H in this system.
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PMID:Selective inhibition of RNA tumor virus replication in vitro and evaluation of candidate antiviral agents in vivo. 28 Jan 46

Fludarabine phosphate (F-ara-AMP, Fludara) is rapidly converted in the circulation to fludarabine (F-ara-A) and is among the most effective single agents in the treatment of chronic lymphocytic leukemia. Although current treatment protocols are well tolerated, severe neurotoxicity was a consequence of high-dose F-ara-AMP regimens used in early phase I trials against adult acute leukemia. The present study showed that in mice implanted with leukemia L1210, fatal neurotoxicity, which initially manifested as hind-limb paralysis, was a consequence of high-dose F-ara-AMP treatment. However, the incidence of neurotoxicity was reduced by the coadministration of NBMPR-P, the 5'-phosphate of nitrobenzylthioinosine, a potent inhibitor of the es equilibrative nucleoside transport (NT) system. NBTGR-P, the 5'-phosphate of nitrobenzylthioguanosine (also a potent NT inhibitor) similarly prevented F-ara-AMP neurotoxicity in this experimental system. Treatment with F-ara-AMP/NBMPR-P combinations was more effective with respect to the fractional yield of "cured" mice than were the same treatment regimens without NBMPR-P.
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PMID:Protection against fludarabine neurotoxicity in leukemic mice by the nucleoside transport inhibitor nitrobenzylthioinosine. 145 62

Since 1978, over 50 clinically useful antitumor drugs or new candidate antitumor agents have been evaluated in vivo against cisplatin-resistant P388 leukemia (P388/DDPt) in our laboratories. Analysis of this data base has yielded insights into the cross-resistance, collateral sensitivity, and mechanisms of resistance of P388/DDPt. P388/DDPt was cross-resistant or marginally cross-resistant to eight agents [carmethizole.HCl, rhizoxin, dibromodulcitol, spirohydantoin mustard, hepsulfam, arabinosyl-5-azacytosine (ara-AC), tiazofurin, and deoxyspergualin]. Of these eight agents, the latter six have entered various phases of clinical trials. For these trials, it may be important to exclude or to monitor with extra care patients who have previously been treated with cisplatin. P388/DDPt was collaterally sensitive to six agents [fludarabine phosphate (2-F-ara-AMP), amsacrine (AMSA), mitoxantrone, etoposide (VP-16), batracylin, and flavone acetic acid] and, possibly, to two others (merbarone and echinomycin). These observations of collateral sensitivity suggest that a combination of cisplatin plus any one of these drugs might exhibit therapeutic synergism. Therapeutic synergism has been observed in animal models for combinations of cisplatin plus VP-16, AMSA, or mitoxantrone. The observation of collateral sensitivity for P388/DDPt to four agents (AMSA, mitoxantrone, merbarone, and VP-16) that have been reported to interact with DNA topoisomerase II suggests the possible involvement of the latter in cisplatin resistance. Both the increased sensitivity of P388/DDPt to these agents and a portion of its resistance to cisplatin could be the result of an increase in DNA topoisomerase II activity.
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PMID:Antitumor drug cross-resistance in vivo in a cisplatin-resistant murine P388 leukemia. 184 65

Ara-C at very low dosage has been reported to decrease the host toxicity of ara-AMP or ara-A in combination with 2'-deoxycoformycin, a potent adenosine deaminase inhibitor, while increasing the toxicity to intracerebral L1210 leukemia. The possibility of increasing the selectivity of ara-A by prior administration of ara-C is explored. The importance of deoxynucleoside kinases, some of which may be cancer-induced, in obtaining selective anticancer effects is discussed. The possibility of a conformational basis for the differing degrees of selectivity and activity of various novel arabinosyl nucleosides is evaluated. The levels of cyclic nucleotides, which have opposing effects on leukemia, may possibly be manipulated to interfere with the growth of cancer cells. Approaches to minimizing major metabolic distortions, such as the progressive accumulation of dATP associated with the use of potent adenosine deaminase inhibitors and which limit the therapeutic effects of ara-A, are proposed.
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PMID:Biochemical and biophysical approaches to improving the anticancer effectiveness of Ara-adenine. 629 45

2-Chloro-9-(2-deoxy-2-fluoro-beta-D-arabinofuranosyl)adenine (Cl-F-ara-A) is a new deoxyadenosine analogue that is resistant to phosphorolytic cleavage and deamination. Studies with a variety of cell lines demonstrated that Cl-F-ara-A is a potent cytotoxic agent; in cell-free systems, its triphosphate (Cl-F-ara-ATP) inhibited DNA polymerase alpha and ribonucleotide reductase. To further characterize its mechanism of cytotoxicity, the present study investigated the cellular metabolism of Cl-F-ara-A and the actions of its nucleotide metabolites in human T-lymphoblast leukemia CCRF-CEM cells. The mono-, di-, and triphosphates of Cl-F-ara-A accumulated in cells, with the monophosphate as its major metabolite. After washing cells into drug-free medium, the elimination of each Cl-F-ara-A nucleotide was nonlinear with a prolonged terminal phase. Incubation of CCRF-CEM cells with Cl-F-ara-A resulted in the incorporation of Cl-F-ara-AMP into DNA; a much lesser amount was associated with RNA, suggesting that Cl-F-ara-A is a more DNA-directed compound. The site of Cl-F-ara-AMP in DNA was related to the ratio of the cellular concentrations of the analogue triphosphate and the natural substrate dATP. At low Cl-F-ara-ATP:dATP values, incorporation was mainly in phosphodiester linkages at internal sites, whereas at higher Cl-F-ara-ATP:dATP values, Cl-F-ara-AMP was principally detected at terminal sites. Clonogenicity assays showed a strong inverse correlation between cell survival and Cl-F-ara-AMP incorporation into DNA. These results suggest that the incorporation of Cl-F-ara-A monophosphate into DNA is critical for the cytotoxicity of Cl-F-ara-A.
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PMID:Metabolism and actions of 2-chloro-9-(2-deoxy-2-fluoro-beta-D- arabinofuranosyl)-adenine in human lymphoblastoid cells. 754 Sep 50

The purpose of this paper was to ascertain whether results obtained in cell cultures of AML clonogenic blast cells would provide a useful model for a clinical regimen that combines fludarabine (F-ara-AMP) and cytosine arabinoside (ara-C). In the cultures the nucleoside F-ara-A was used. Blast cells from the continuous lines OCI/AML-2 and OCI/AML-3 were grown, either in methylcellulose to quantify clonogenic cells, or in suspension to measure self-renewal as reflected in changes in numbers of clonogenic cells. F-ara-A, like ara-C, was found to be more toxic to blast stem cells in suspension than in the clonogenic assay, indicating that F-ara-A might, in addition to general cytotoxicity, have some specific inhibitory effects on self-renewing stem cells. F-ara-A was less cytotoxic than ara-C; but, when F-ara-A was given before ara-C, synergism was seen at some F-ara-A doses, as manifested by increased ara-C cytotoxicity. In contrast, when ara-C was given before F-ara-A, protection was observed. Control experiments make it unlikely that this effect is related to changes in the cell cycle following ara-C exposure. We conclude that the cellular studies reported here confirm previous pharmacological data indicating that F-ara-A before ara-C increases the effectiveness of ara-C by increasing the accumulation of ara-CTP. However the present experiments show that the synergism between F-ara-A and ara-C is dependent on both dose and schedule.
Leukemia 1993 Jul
PMID:A cell culture model for the treatment of acute myeloblastic leukemia with fludarabine and cytosine arabinoside. 832 Oct 50

Incorporation of the anticancer drug fludarabine (9-beta-D-arabinofuranosyl-2-fluoroadenine 5'-monophosphate; F-ara-AMP) into the 3'-end of DNA during replication causes termination of DNA strand elongation and is strongly correlated with loss of clonogenicity. Because the proofreading mechanisms that remove 3'-F-ara-AMP from DNA represent a possible means of resistance to the drug, the present study investigated the excision of incorporated F-ara-AMP from DNA by the 3' --> 5'-exonuclease activity of DNA polymerase epsilon from human leukemia CEM cells. Using the drug-containing and normal deoxynucleotide oligomers (21-base) annealed to M13mp18(+) DNA as the excision substrates, we demonstrated that DNA polymerase epsilon was unable to effectively remove F-ara-AMP from the 3'-end of the oligomer. However, 3'-terminal dAMP and subsequently other deoxynucleotides were readily excised from DNA in a distributive fashion. Kinetic evaluation demonstrated that although DNA polymerase epsilon has a higher affinity for F-ara-AMP-terminated DNA (Km = 7.1 pM) than for dAMP-terminated DNA of otherwise identical sequence (Km = 265 pM), excision of F-ara-AMP proceeded at a substantially slower rate (Vmax = 0.053 pmol/min/mg) than for 3'-terminal dAMP (Vmax = 1.96 pmol/min/mg). When the 3'-5' phosphodiester bond between F-ara-AMP at the 3'-terminus and the adjacent normal deoxynucleotide was cleaved by DNA polymerase epsilon, the reaction products appeared to remain associated with the enzyme but without the formation of a covalent bond. No further excision of the remaining oligomers was observed after the addition of fresh DNA polymerase epsilon to the reaction. Furthermore, the addition of DNA polymerase alpha and deoxynucleoside triphosphates to the excision reaction failed to extend the oligomers. After DNA polymerase epsilon had been incubated with 3'-F-ara-AMP-21-mer for 10 min, the enzyme was no longer able to excise 3'-terminal dAMP from a freshly added normal 21-mer annealed to M13mp18(+) template. We conclude that the 3' --> 5' exonuclease of human DNA polymerase epsilon can remove 3'-terminal F-ara-AMP from DNA with difficulty and that this excision results in a mechanism-mediated formation of "dead end complex."
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PMID:Inhibition of the 3' --> 5' exonuclease of human DNA polymerase epsilon by fludarabine-terminated DNA. 870 31

Fludarabine and 1-beta-D-arabinofuranosylcytosine (ara-C) are effective nucleoside analogues for the treatment of leukemias when used as single agents or together. Recent trials of the fludarabine and ara-C therapy with or without growth factors suggested an improved clinical response by combining fludarabine and ara-C. The activity of these antimetabolites depends on their phosphorylation to the respective triphosphates, F-ara-ATP and ara-CTP. The principal mechanism through which these triphosphates cause cytotoxicity is incorporation into DNA and inhibition of further DNA synthesis. A model system of DNA primer extension on a defined template sequence was used to quantitate the consequences of incorporation of one or two analogues by human DNA polymerase alpha (pol alpha). The template (31-mer) was designed so that DNA pol alpha incorporated six deoxynucleotides (alternately G and T) on the 17-mer primer, followed by insertion of an A and then a C. The primer was then elongated with G and T to the full-length product. The apparent Kms of DNA pol alpha to incorporate these analogues (0. 053 and 0.077 microM, respectively) were similar to the Km for dCTP (0.037 microM) and dATP (0.044 microM), suggesting that the enzyme recognized these analogues and incorporated them efficiently on the growing DNA primer. The velocity of extension (Vmax) of these primers ranged between 0.53 and 0.77%/min when normal nucleotides were present. Once inserted at the 3'-terminus, F-ara-AMP or ara-CMP were poor substrates for extension. However, in reactions lacking dCTP and dATP and with high concentrations of ara-CTP, ara-CMP was inserted by pol alpha after incorporation of the F-ara-AMP residue. This tandem incorporation of the two analogues resulted in almost complete inhibition (99.3%) of further extension of the primer. In the presence of competing deoxynucleotides, each analogue resulted in a dose-dependent inhibition of DNA synthesis. When present together, inhibition of the primer elongation was more than additive at low concentrations of analogue triphosphates. Based on these results and the intracellular pharmacokinetics of ara-CTP and F-ara-ATP in leukemia blasts, we propose a pharmacodynamic model to explain interactions between these analogues during combination chemotherapy.
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PMID:Incorporation of fludarabine and 1-beta-D-arabinofuranosylcytosine 5'-triphosphates by DNA polymerase alpha: affinity, interaction, and consequences. 981 18

Fludarabine phosphate (2-F-ara-AMP) is an adenine nucleoside analogue that shows significant activity against chronic lymphocytic leukemia and indolent lymphoma. We assessed the cytotoxic interaction produced by the combination of the active metabolite of fludarabine phosphate, fludarabine (9-beta-D-arabinofuranosyl-2-fluoroadenine, 2-F-ara-A), and some commonly used antileukemic agents against human hairy cell leukemia cell line JOK-1, human chronic lymphocytic leukemia cell line SKW-3, and adult T cell leukemia cell lines ED-40810 (-) and SALT-3. The leukemia cells were exposed simultaneously to 2-F-ara-A and to the other agents for 4 days. Cell growth inhibition was determined using MTT reduction assay. The isobologram method of Steel and Peckham was used to evaluate the cytotoxic interaction. 2-F-ara-A and cytarabine showed synergistic effects in SKW-3 cells, additive and synergistic effects in JOK-1 and SALT-3 cells, and additive effects in ED-40810(-) cells. 2-F-ara-A and doxorubicin showed additive effects in SKW-3, ED-40810(-) and SALT-3 cell lines, and additive and synergistic effects in JOK-1 cells. 2-F-ara-A showed additive effects with etoposide, 4-hydroperoxy-cyclophosphamide, and hydroxyurea in all four cell lines. 2-F-ara-A showed antagonistic effects with methotrexate and vincristine in all four cell lines. Our findings suggest that the simultaneous administration of fludarabine phosphate with cytarabine, doxorubicin, etoposide, cyclophosphamide, or hydroxyurea would be advantageous for cytotoxic effects. Among these agents, cytarabine may be the best agent for the combination with fludarabine phosphate. The simultaneous administration of fludarabine phosphate with methotrexate or vincristine would have little cytotoxic effect, and this combination may be inappropriate. These findings may be useful in clinical trials of combination chemotherapy with fludarabine phosphate and these agents.
Leukemia 2000 Mar
PMID:In vitro cytotoxic effects of fludarabine (2-F-ara-A) in combination with commonly used antileukemic agents by isobologram analysis. 1072 Jan 30