Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: 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)

Our previous studies indicated that K562 cells loaded with arabinosyl-2-fluoroadenine 5'-triphosphate (F-ara-ATP) accumulated arabinosylcytosine 5'-triphosphate (ara-CTP) at a threefold higher rate compared to the control cells. In the present study lymphocytes were obtained from patients with chronic lymphocytic leukemia before and after F-ara-A monophosphate therapy. The rate of ara-CTP accumulation after in vitro ara-C incubation was compared in lymphocytes obtained prior to therapy without any other manipulation, after ex vivo F-ara-ATP (100 mumol/L) treatment, and after in vivo F-ara-A monophosphate therapy. Lymphocytes showed a 2.2-fold (n = 23) and 1.7-fold (n = 23) median increase in the cellular concentration of ara-CTP after an ex vivo incubation with 100 mumol/L F-ara-A and 20 to 24 hours after the first dose (25 or 30 mg/m2) of F-ara-A monophosphate in vivo treatment, respectively. Although the rates of F-ara-ATP and ara-CTP accumulation varied among patients, a relationship was observed in individuals between the cellular concentration of F-ara-ATP at the beginning of the ara-C incubation and ara-CTP accumulation. These studies strongly suggest that a protocol designed to administer F-ara-A monophosphate prior to ara-C infusion will augment ara-CTP accumulation by leukemia cells.
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PMID:Modulation of arabinosylcytosine metabolism by arabinosyl-2-fluoroadenine in lymphocytes from patients with chronic lymphocytic leukemia: implications for combination therapy. 247 21

We hypothesized that the steady-state concentration of intracellular cytarabine 5'-triphosphate (ara-CTPss) in leukemia cells is proportional to the dose rate of cytarabine (ara-C) during continuous infusion. To evaluate this possibility, patients with acute myelogenous leukemia in relapse were treated with two sequential schedules of serially increasing ara-C dose rates over a total of 36 hours. Schedule I consisted of serial infusions of 250, 500, and 750 mg/m2 each over 12 hours. Subsequently, patients entered on schedule II received 500, 1,000, and 1,500 mg/m2 serially, each over 12 hours. Steady-state levels of ara-CTP were achieved within four hours after beginning ara-C infusion and, in separate studies of a single ara-C dose rate, were shown to be maintained beyond 36 hours. Four patients treated with schedule I and two patients treated with schedule II showed a linear dose rate-dependent increase-of ara-CTPss at all three dose rates. The cells of one patient on schedule I and two patients on schedule II had a dose rate-dependent ara-CTPss increase only over the first two dose levels, while no increase or lower ara-CTPss was observed at the third dose rate. The ara-CTPss of one patient on schedule II did not change. These results suggest that there is a proportionality between the continuous infusion dose rate of ara-C and the ara-CTPss in circulating leukemia cells within the dose range of 250 to 1,000 mg/m2 over 12 hours. This opens the possibility that pharmacologic determinations may be used to redirect the ara-C dose rate to achieve a desired ara-CTPss level in leukemia blasts during therapy.
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PMID:Patient-specific dose rate for continuous infusion high-dose cytarabine in relapsed acute myelogenous leukemia. 270 90

DUP 785 (NSC 368390; Brequinar sodium) is a new inhibitor of pyrimidine de novo biosynthesis with antitumor activity against several experimental tumors. DUP 785 inhibits the mitochondrial enzyme dihydroorotate dehydrogenase, blocking the conversion of dihydroorotate to orotate. We examined the influence of exposure time to DUP 785 on its growth-inhibitory effects in L1210 murine leukemia and WiDR human adenocarcinoma cells and the effects of pyrimidine (deoxy) nucleosides on reversal of growth-inhibition. The results were correlated with changes in intracellular pyrimidine nucleotide pools and cell cycle distribution. In L1210 cells, a continuous exposure to 25 microM DUP 785 up to 96 hr caused complete growth inhibition. A 2 hr exposure of cells to the drug did not affect growth. In WiDR cells, exposure to the drug for 1-24 hr, followed by cultivation in drug-free medium resulted in recovery of growth. However, cells exposed to the drug for 48 hr or longer were not able to resume growth when recultured in drug-free medium. Reversal studies were performed to know whether selective depletion of one of the pyrimidine (deoxy) nucleotides might be related to the growth-inhibitory effects of DUP 785. Neither thymidine, deoxycytidine alone, deoxycytidine plus tetrahydrouridine; nor cytidine plus tetrahydrouridine added after 24 hr were able to reverse cell growth inhibition induced by 25 microM DUP 785. However, uridine and cytidine alone reversed growth inhibition. UTP and CTP pools in L1210 cells decreased to about 30-40% of control levels after 4 hr of drug exposure, while dTTP and dCTP pools decreased to about 30% of control levels. There were no significant changes in purine nucleotide pools. In WiDR cells, UTP and CTP pools decreased rapidly after drug exposure and were substantially depleted after 24 hr. Reculture of cells in drug-free medium resulted in a significant recovery of UTP and CTP levels only for cells exposed to DUP 785 for 1-24 hr. For cells exposed to the drug for 48 and 72 hr recovery of nucleotide pools was minimal. In L1210 cells, a 12-hr exposure to the drug caused an accumulation of cells in the early S-phase. In WiDR cells, there was a clear accumulation of cells in the S-phase of the cell cycle after 24 hr drug exposure.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:DUP 785 (NSC 368390): schedule-dependency of growth-inhibitory and antipyrimidine effects. 284 Sep 10

In this study, 1-beta-D-arabinofuranosylcytosine 5'-triphosphate (ara-CTP) formation, retention, and incorporation into DNA were simultaneously evaluated in vivo in mice bearing leukemia cells sensitive to 1-beta-D-arabinofuranosylcytosine (ara-C) (L1210/0), leukemia cells resistant to ara-C (L1210/R), P288, and lymphosarcoma P1798, namely cells characterized by differential sensitivity to ara-C. In L1210/R cells, resistance to ara-C was correlated with low deoxycytidine-cytidine kinase activity (0.04 nmol/mg protein/min), with a low level of intracellular accumulation of ara-CTP, with a low level of incorporation of ara-C into DNA, and with no significant inhibition of thymidine incorporation into DNA. Thus a simple measurement of the intracellular pool of total ara-C nucleotides is sufficient to identify cells with this type of resistance. In contrast, in cells with sufficient deoxycytidine-cytidine kinase activity (greater than 0.1 nmol/mg protein/min), the factors determining the quality of response to ara-C could be distinguished as follows: (a) those which are responsible for in vitro cytotoxicity (producing in vivo cytoreduction); and (b) those which are responsible for in vivo selectivity (producing long term survivors). In P288 cells which are sensitive in vitro to ara-C, the determining factor for this sensitivity is the amount of ara-CTP formed which produced greater than 80% inhibition of thymidine incorporation into DNA. The lack of antitumor activity in vivo, however, was due to similarities in ara-CTP retention in target tumor cells (P288) and normal bone marrow cells. In both cases, ara-CTP retention at 4 h was less than 10% of the value obtained at 30 min. In contrast, in cells such as L1210 and P1798 long term survivors (cures) were directly correlated with higher ara-CTP retention. For example, 4 h after drug administration, ara-CTP retentions were 20, 82, and 6% for L1210, P1798, and bone marrow cells, respectively. At 24 h, 20% ara-CTP was retained intracellularly by P1798 tumor cells. In summary, results presented herein demonstrate the importance of differential ara-CTP retention as the most critical determinant of response for the induction of long term survivors, and ara-C incorporation into DNA by tumor cells after in vivo treatment appears to be less significant. These data also demonstrate close correlation between ara-CTP pools, retention, and the extent of inhibition of recovery of thymidine incorporation into DNA.
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PMID:1-beta-D-arabinofuranosylcytosine metabolism and incorporation into DNA as determinants of in vivo murine tumor cell response. 299 96

In vivo effects of DL-alpha-difluoromethylornithine (DFMO) on the metabolism of polyamines and nucleotide phosphates were monitored in P388/S leukemia cells grown intraperitoneally in BDF1 inbred male mice. Inhibiting the ornithine decarboxylase (ODC) activity DFMO depleted putrescine and spermidine to 30-50 and 50-60%, respectively, and increased spermine to 25-60% compared with the controls, when given as 2% solution in drinking water of the tumor-bearing animals. DFMO treatment caused a parallel 56% elevation of total nucleotide content in tumor cells with distinct and significant increase of some nucleotide phosphates. The most pronounced alterations were shown in the intracellular UTP (202%), CTP (103%), ADP (92%) and ATP (71%) concentrations. Changes in polyamine and nucleotide phosphate metabolisms were dependent on tumor progression. A possible explanation of the metabolic events induced by DFMO is discussed.
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PMID:In vivo effects of DL-alpha-difluoromethylornithine on the polyamine and nucleotide phosphate metabolism in P388/S leukemia cells. 308 89

The ability of the nucleoside transport inhibitors, 4-nitrobenzyl-6-thioinosine (NBTI) and dipyridamole (DP) to prevent 1-beta-D arabinofuranosylcytosine (Ara-C) toxicity was evaluated in two human leukemia cell lines, Molt 4 and HL-60. At non-toxic concentrations, DP (in Molt4 and HL-60) and NBTI (only in Molt 4) provided significant protection, whereas HL-60 was quite insensitive to NBTI. The different response of these two cell lines to NBTI and DP was also noted in the toxicity of other nucleoside analogs, including 9-beta-D arabinofuranosyladenine (Ara-A), 2'-chlorodeoxyadenosine (CdA), tubercidin and 5'-bromodeoxyuridne (BUdR). A transport study of [3H]-Ara-C revealed that NBTI partially inhibited the drug entry into HL-60 cells, which correlated well with Ara-CTP generation.
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PMID:Prevention of 1-beta-D arabinofuranosylcytosine toxicity by 4-nitrobenzyl-6-thioinosine or dipyridamole in human leukemia cell lines. 316 9

In a phase II study, patients with chronic myelogenous leukemia in blast crisis (CML-BC) were treated with intravenous (IV) mitoxantrone (5 mg/m2 per day given over 30 min x 5 days and high-dose arabinosylcytosine (ara-C) (3 g/m2 IV q 12 h x 6). The effect of this treatment on DNA damage was studied in the leukemia cells of four patients using the alkaline elution technique modified to measure DNA in unlabeled human cells. A fluorescence assay using Hoechst 33258 dye was applied for the determination of eluted DNA. After a single infusion of mitoxantrone, neither frank nor protein-associated single-strand breaks (SSB) were observed. Even repeated treatment with mitoxantrone on 3 consecutive days did not induce significant SSB. However, after the combined sequential infusion of ara-C and mitoxantrone the DNA elution pattern changed, showing significant DNA damage. SSB remained apparent after 24 h and increased with subsequent doses of ara-C and mitoxantrone. Studies of other patients treated with ara-C alone did not reveal significant SSB (n = 5). Following mitoxantrone infusion the median peak concentrations of intracellular ara-CTP (the triphosphate of ara-C) exceeded 900 microM, a value greater than that observed in CML-BC patients receiving ara-C alone (230 microM, n = 15, P less than 0.02). The present study shows the applicability of the alkaline elution method for the assay of DNA damage in vivo. The enhanced DNA damage after combined treatment with mitoxantrone and high-dose ara-C suggests a synergistic drug effect.
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PMID:Mitoxantrone-induced DNA damage in leukemia cells is enhanced by treatment with high-dose arabinosylcytosine. 316 25

After four days of treatment with 10(-8) M TPA, differentiation of the human T-lymphoblastoid cell line MOLT-4 was induced along the T cell lineage, confirmed by a fall in adenosine deaminase and 5'-ectonucleotidase and a rise in purine nucleoside phosphorylase activity. TPA-treated cells became resistant to the cytotoxic effects of 1-beta-D-arabinofuranosylcytosine (Ara-C), 9-beta-D-arabinofuranosyladenine (Ara-A), and 2-chlorodeoxyadenosine. This was, in part, due to the altered cell cycle distribution (accumulation of cells in the G1 phase), since the toxicity of Ara-C and Ara-A is S phase specific. The diminished rate of Ara-C transport concomitant with Ara-CTP formation after TPA treatment is considered to be the biochemical basis for this acquired resistance.
Leukemia 1988 Jul
PMID:Changes in sensitivity to anticancer drugs during TPA-induced cellular differentiation in a human T-lymphoblastoid cell line (MOLT-4). 326 Jun 48

Human recombinant GM-CSF (rGM-CSF) is under investigation as a growth-protective agent for normal hematopoietic elements in phase I trials of myelosuppressive chemotherapy and in bone marrow transplantation. We determined the effect of rGM-CSF on the metabolism of high dose Ara-C in bone marrow mononuclear cells (BMMCs) from healthy volunteers and patients with ANLL. Cells were incubated with rGM-CSF alone, Ara-C alone, or a combination of the two drugs. Treatment with rGM-CSF alone yielded approximately a twofold increment in intracellular dCTP pools in normal BMMCs but not in leukemic blasts. Exposure to rGM-CSF in conjunction with Ara-C corrected Ara-C-mediated declines in dCTP levels and decreased cytosine arabinoside triphosphate (Ara-CTP) accumulation in normal BMMCs but not in their leukemic counterparts. Furthermore, when exposure to Ara-C was preceded by treatment with rGM-CSF for 18 hr, an even greater reduction in the Ara-CTP/dCTP pool ratio was observed in normal versus leukemic elements; however, this did not significantly change Ara-C DNA incorporation in the two cell types. The differential effect of rGM-CSF on the phosphorylation of Ara-C in normal BMMCs versus leukemic blasts has potential implications for the use of a regimen consisting of rGM-CSF and high dose Ara-C in the treatment of ANLL with chemotherapy or autologous bone marrow transplantation.
Leukemia 1988 Dec
PMID:Effect of recombinant GM-CSF on the metabolism of cytosine arabinoside in normal and leukemic human bone marrow cells. 326 63

We tested whether bromodeoxyuridine (BrdUrd), an analogue of thymidine (dThd), enhances 1-beta-D-arabinofuranosylcytosine (ara-C) metabolic activation, as does dThd. HL-60 cells were exposed to 10, 100, or 1000 nM ara-C for 3 h. Simultaneous exposure of log phase HL-60 cells to BrdUrd (1-1000 microM) and ara-C for 3 h resulted in enhancement of ara-C incorporation into DNA, with a doubling of incorporation in response to 10 nM ara-C occurring at concentrations of BrdUrd greater than 100 microM. Preexposure of cells to BrdUrd for 16 h followed by addition of ara-C for 3 h resulted in even greater ara-C incorporation into DNA. This increase was most marked at the lower concentrations of ara-C (10 and 100 nM), where approximately 3-fold enhancement of ara-C incorporation was observed in response to BrdUrd concentrations greater than 100 microM. Intracellular pools of 1-beta-D-arabinofuranosyl-CTP increased significantly (up to 3-fold) following 16-h exposure to BrdUrd (30, 100, or 300 microM) at all concentrations of ara-C tested. The ara-C phosphorylating activity of cell-free extracts obtained following 16-h exposure of cells to BrdUrd increased 1.5- to 2.3-fold over control. Intracellular dCTP pools fell to approximately 50% of control after exposure to 750 microM BrdUrd or dThd. Exposure to BrdUrd for 16 h caused a concentration-dependent increase in cells with S-phase DNA content, as assessed by flow cytometry, with a doubling of cells in S phase (to 60%) observed in response to 500 microM BrdUrd. HL-60 cells exposed to identical conditions of BrdUrd for 3 h showed no significant alteration in cell cycle phase distribution. Thus, although BrdUrd does increase cells in S phase, the increased ara-C incorporation caused by BrdUrd cannot be explained solely on a cytokinetic basis since enhancement of incorporation was observed after a 3-h exposure of cells to BrdUrd and ara-C. The combination of ara-C (100 nM) and BrdUrd (100-1000 microM) exhibited cytotoxic synergism, as measured by the fluorescein diacetate/propidium iodide method. These data demonstrate a clear potential for BrdUrd modulation of ara-C metabolism in human leukemia. Additionally, the interaction of BrdUrd and ara-C should be considered in the interpretation of studies of the effects of ara-C on DNA synthesis as measured by flow cytometric quantification of incorporated BrdUrd.
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PMID:Bromodeoxyuridine enhancement of 1-beta-D-arabinofuranosylcytosine metabolic activation and toxicity in HL-60 leukemic cells. 333 18


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