UMLS:C0023418 - FACTA Search

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Query: UMLS:C0023418 (leukemia)
93,477 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We examined the effects of high intracellular levels of Bcl-2 on the metabolism and DNA incorporation of high-dose Ara-C (HIDAC) as well as on Ara-C-induced DNA strand breaks and apoptosis of human AML HL-60 cells. HL-60/Bcl-2 and HL-60/neo cells were created by retrovirally transfecting the human AML HL-60 cells with the pZip-bcl-2 and pZip-neo plasmids, respectively. As compared to HL-60/neo, HL-60/Bcl-2 cells contained significantly higher (approximately 10-fold) p26Bcl-2, but equivalent levels of Bax and undetectable levels of Bcl-xL. HIDAC (10 or 100 microM for 4 h) produced the kilobase size and internucleosomal DNA fragmentation associated with apoptosis in HL-60/neo but not in HL-60/Bcl-2 cells. Significantly greater loss of survival (by MTT assay) and flowcytometric and morphologically recognizable apoptosis were observed in HL-60/neo cells. HIDAC did not affect Bcl-2 levels in either cell type. The intracellular accumulation of Ara-CTP relative to dCTP, Ara-C DNA incorporation and Ara-C-induced early DNA damage in the form of strand breaks (detected by alkaline elution assay) were not significantly different between HL-60/Bcl-2 and HL-60/neo cells. In addition, HIDAC treatment caused similar DNA synthesis inhibition in the two cell types. These results indicate that high intracellular levels of Bcl-2 operate distally to inhibit the final apototic cell death pathway by preventing the conversion of HIDAC-induced early DNA damage into lethal DNA fragmentation associated with apoptosis.
Leukemia 1996 Nov
PMID:Intracellular metabolism of Ara-C and resulting DNA fragmentation and apoptosis of human AML HL-60 cells possessing disparate levels of Bcl-2 protein. 889 76

Cytosine arabinoside (Ara-C) is used to treat leukemias, with complete remission induced by combination chemotherapy in approximately 70% of cases of acute myelogenous leukemia (AML). Ara-CTP acts as a competitive inhibitor of DNA polymerase and may also be incorporated into DNA. Accumulation of deoxyribonucleoside triphosphates (dNTPs) induced by Ara-C may indicate disruption of DNA synthesis in susceptible leukemia cells. A procedure has been developed for the quantification of Ara-CTP and dNTPs from small samples of leukaemia cells from patients (4 x 10(7) cells) activated with concanavalin A (10 micrograms/ml, 48 hr) and grown in the presence of [32P]orthophosphate (1.1 microM, 9 x 10(6) Ci/mol, 16 hr). The susceptibilities to Ara-C of the human leukemia cell lines CCRF-CEM (IC50 = 6.30 nM), CCRF-HSB-2 (IC50 = 10.4 nM) and MOLT-4 (IC50 = 10.0 nM) may be correlated with their abilities to accumulate high concentrations of Ara-CTP (> 1000 amol/cell) with increases of between 1.3- and 3.4-fold in dATP, dGTP and dTTP for the four cell lines, while dCTP decreased between 0.23- and 0.78-fold. By contrast, an Ara-C-resistant derivative of HL-60 cells (IC50 = 400 nM) accumulated only low concentrations of Ara-CTP (71 amol/cell) without significant changes in dNTPs. High concentrations of Ara-CTP in leukemia cells induce accumulations of dATP, dGTP and dTTP due to inhibition of DNA synthesis, and depletion of dCTP. This imbalance in the pools of the four dNTPs could lead to genetic miscoding and cell death.
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PMID:Effects of cytosine arabinoside on human leukemia cells. 893 Jan 29

The effect of recombinant human granulocyte-macrophage colony-stimulating factor (GM-CSF) on the intracellular metabolism of cytosine arabinoside (Ara-C) was comparatively analyzed in normal bone marrow mononuclear cells (NBMMC) from eight healthy volunteers and in leukemic blasts from 50 patients with acute myeloid leukemia (AML). Pretreatment with GM-CSF (100 U/ml) for 48 h resulted in a significant enhancement of DNA synthesis in both cell types: 21 of 35 AML specimens were found to be responsive to GM-CSF as defined by an increase of 3H-TdR incorporation into the DNA > 1.5-fold while NBMMC from normal donors were responsive in all cases. In GM-CSF responsive AML blasts, overall DNA polymerase and DNA polymerase alpha activity increased from a median of 84.4 to 96.1 and from 3.45 to 5.2 pmol/min x mg as compared to a median of 96.7 to 189.9 and 1.2 to 2.2 pmol/min x mg in NBMMC (P < 0.05). Median Ara-C-mediated inhibition of DNA synthesis was significantly more effective in AML blasts as compared to NBMMC (76.5 vs 55.0% at 0.05 microM and 99.0 vs 96.0% at 5.0 microM Ara-C, P < 0.01) but was not influenced by GM-CSF pretreatment. Similarly, intracellular Ara-CTP levels were higher in AML blasts as compared to NBMMC (median of 46.9 vs 18.7 at 1 microM, 167.8 vs 48.0 at 10 microM and 337.5 vs 59.5 ng/10(7) cells at 100 microM extracellular Ara-C, P < 0.01) but showed no enhancement in the presence of GM-CSF. Median deoxycytidine (DCK) and thymidine kinase (TK) activity were only slightly increased in AML blasts after GM-CSF priming. In contrast, NBMMC revealed a significant increase in TK activity after GM-CSF pretreatment (from a median of 1.9 to 3.6 pmol/min x mg, P = 0.039). At low; intermediate and high extracellular Ara-C concentrations GM-CSF pretreatment resulted in a significant enhancement of the 3H-Ara-C incorporation into the DNA in both GM-CSF responsive AML blasts and NBMMC (median of 1.3 to 2.1- and 1.4 to 1.6-fold, P < 0.05). GM-CSF non-responsive AML blasts showed no change in 3H-Ara-C incorporation into the DNA in response to GM-CSF at low Ara-C concentrations but significant increases at intermediate and high extracellular Ara-C concentrations (median increases of 1.63-fold at 1.06 microM with P = 0.01 and 1.37-fold at 10 microM extracellular Ara-C with P = 0.0+005). NBMMC revealed significantly lower GM-CSF-induced increases of the 3H-Ara-C incorporation into the DNA as compared to the effect of GM-CSF priming on DNA synthesis (median increases of 1.4 to 1.7-fold vs 2.6-fold, P < 0.05). These data reveal a different effect of GM-CSF priming on the metabolism of Ara-C in normal vs leukemic cells which may cause a preferential increase in the antileukemic cytotoxicity of Ara-C in the presence of GM-CSF.
Leukemia 1997 Apr
PMID:Differential effect of GM-CSF pretreatment on intracellular Ara-C metabolism in normal bone marrow mononuclear cells vs acute myeloid leukemia (AML) blasts. 909 97

Modulation of ara-C-induced apoptosis in human leukemia cells by the macrocyclic lactone PKC activator bryostatin 1 occurs at multiple levels, and involves a variety of oncogenes and signalling pathways. Under some circumstances, bryostatin 1 may lead to enhanced conversion of ara-C to its lethal metabolite, ara-CTP. However, bryostatin 1 is able to potentiate ara-C-mediated cytotoxicity in the absence of metabolic perturbations, presumably by modulating the cell death pathway itself. For example, chronic exposure of cells to bryostatin 1 leads to PKC down-regulation, which may alter the balance between survival (e.g., ERK) versus stress (e.g., SAPK/JNK)-related pathways. The ability of bryostatin 1 to enhance ara-C-mediated apoptosis is inversely related to its capacity to induce leukemic cell maturation and may involve the failure to down-regulate expression of the cell cycle progression-related proto-oncogene, c-myc. Finally, recent evidence suggests that bryostatin 1 may act, through modification of Bcl-2 phosphorylation status, at a distal site in the cell death pathway. These studies could provide a paradigm important for understanding the mechanism(s) by which agents acting through signal transduction pathways modulate cytotoxic drug-induced cell death
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PMID:Modulation of ara-C induced apoptosis in leukemia by the PKC activator bryostatin 1. 919 93

To establish the most effective and reasonable mode of combining and administrering ara-C with other antileukemic agents in chemotherapy for acute leukemia, the action mechanisms of ara-C was investigated in terms of intracellular pharmacodynamics and the biochemical action mechanism of ara-C was investigated in leukemic cell. Rensonable methods of administering the agent was considered as follows. 1. A low level of ara-C in the incubation medium induced a higher concentration of ara-CTP in leukemic cells. Therefore, maintenance of even a low plasma ara-C level after ara-C therapy could enhance the antileukemic effect of the agent. 2. Ara-C activation was increased in the presence of 6MP by suppressing elevation of deaminase activity in the cell suspection medium. Therefore, administration of 6MP prior to ara-C therapy could enhance the antileukemic effect of the agent. 3. Ten micrograms/ml of ara-C, corresponding to intermediate dose ara-C therapy, induced rapid endonuclease activation, DNA ladder fragmentation and subsequent apoptosis in large numbers of leukemic cells, suggesting that intermediate dose ara-C therapy is effective in reducing residual leukemic cells after therapy. 4. Blood transfusion for patients with high grade anemia prior to bebenoyl ara-C therapy prolonged higher and longer plasma drug maintenance. 5. Flowcytometry of cell cycle progression of L1210 cells treated by ara-C and daunorubicin revealed that a combination of ara-C first and daunorubicin second was superior to the reverse sequential combination. These improvements in the mode of administering ara-C could provide better results following chemotherapy for leukemia.
Leukemia 1997 Apr
PMID:Intracellular pharmacodynamics of ara-C and flowcytometric analysis of cell cycle progression in leukemia chemotherapy. 920 53

Arabinosylcytosine (ara-C) is the most effective nucleoside analogue for treatment of acute myelogenous leukemia. The cytotoxicity of ara-C depends on its conversion to the triphosphate ara-CTP. In plasma, a major metabolite of ara-C is its deamination product, arabinosyluracil (ara-U). Both ara-U and ara-U monophosphate have been detected in primary leukemia cells during in vitro investigations. Because other ara-U metabolites, especially the triphosphate (ara-UTP), may serve as additional effectors of cytotoxicity, the present study investigated whether ara-UTP accumulates in circulating leukemia blasts during ara-C therapy. Patients with relapsed acute myelogenous leukemia received 2- or 4-h infusions of 0.5 g/m2/h ara-C. Intracellular accumulation of ara-CTP and ara-UTP in circulating leukemia blasts from six patients was quantitated by high-pressure liquid chromatography, revealing that ara-UTP accumulated during ara-C therapy. The intracellular concentration of ara-UTP ranged from 6-50 microM and was between 2 and 10% of the accumulated ara-CTP. In circulating blasts, ara-UTP was maintained for several hours after the end of ara-C infusion. Leukemia blasts from patients (n=27) were incubated for 1-2 h with 1, 10, or 25 microM [3H]ara-C, and radiolabeled metabolites of ara-C were separated and quantitated by high-pressure liquid chromatography. Consistent with data obtained during ara-C therapy, [3H]ara-UTP also accumulated in blasts from all these patients during in vitro incubations with [3H]ara-C. The concentration of ara-UTP after 1 h of incubation ranged from 0.2-40 microM. Incubation of cells with the cytidine deaminase inhibitor tetrahydrouridine did not perturb ara-UTP accumulation, whereas incubation with the deoxycytidylate deaminase inhibitor tetrahydrodeoxyuridine suppressed ara-UTP formation from ara-C. These observations suggested that ara-UTP is generated through deamination of ara-C monophosphate to ara-U monophosphate by deoxycytidylate deaminase, followed by its phosphorylation to ara-UTP. Consistent with these results, incubation of blasts with up to 100 microM [3H]ara-U did not result in ara-UTP accumulation, indicating that ara-U is not phosphorylated directly in these cells. The present study demonstrated that circulating leukemia blasts accumulate ara-UTP during in vitro incubations with ara-C and during ara-C therapy.
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PMID:Accumulation of arabinosyluracil 5'-triphosphate during arabinosylcytosine therapy in circulating blasts of patients with acute myelogenous leukemia. 967 47

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

1-beta-d-Arabinofuranosylcytosine (ara-C), an effective drug for acute leukemias, must be phosphorylated to its 5'-triphosphate, ara-CTP, for activity. Our previous studies during therapy of acute myelogenous leukemia (AML) patients demonstrated that the accumulation of ara-CTP in circulating leukemia blasts was increased by a median of 2-fold when fludarabine (30 mg/m2/day over 30 min) was infused 4 h prior to intermediate dose ara-C. The augmentation was dependent on the cellular concentration of fludarabine triphosphate (F-ara-ATP). To determine the lowest dose of fludarabine needed for modulation of ara-C metabolism, the present study administered fludarabine at a test dose (15 mg/m2 over 30 min) followed by 2 g/m2 ara-C infused over 4 h. The next day, the fludarabine/ara-C couplet was repeated but with a standard dose (30 mg/m2) of fludarabine. There was a dose-dependent accumulation of F-ara-ATP in circulating leukemia blasts; the median peak concentrations were 33 and 41 microM with 15 and 30 mg/m2 of fludarabine, respectively. These intracellular levels of F-ara-ATP effectively increased ara-CTP accumulation to similar levels. To further titrate the dose of fludarabine, the next cohort of patients (n = 4) initially received fludarabine test doses of 7.5 or 5 mg/m2, followed by the 30 mg/m2 dose of fludarabine on the next day; each dose was infused 4 h prior to 2 g/m2 of ara-C. The peak levels of F-ara-ATP at 7.5 and 5 mg/m2 fludarabine were between 3 and 39 microM. The AML blasts that achieved >/=10 microM intracellular F-ara-ATP accumulated ara-CTP similar to the levels achieved after 30 mg/m2 of fludarabine. However, <10 microM intracellular F-ara-ATP resulted in less ara-CTP accumulation compared to that observed after the conventional dose of fludarabine. These data suggest that the modulation of the ara-CTP accumulation by fludarabine is dependent on the cellular concentration of F-ara-ATP, and that 15 mg/m2 fludarabine infused over 30 min consistently produces cellular F-ara-ATP levels that maximize ara-CTP accumulation in AML blasts. These findings point to the feasibility of intensifying the fludarabine-ara-C regimen by using fludarabine as a 15 mg/m2/dose twice daily with intermediate-dose ara-C.
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PMID:Minimum dose of fludarabine for the maximal modulation of 1-beta-D-arabinofuranosylcytosine triphosphate in human leukemia blasts during therapy. 981 41

Previous in vitro investigations demonstrated that human leukemia cells, when incubated with hematopoietic growth factors such as granulocyte-colony-stimulating factor (G-CSF), augment the accumulation of the triphosphate 1-beta-D-arabinofuranosylcytosine (ara-C cytarabine). To test whether G-CSF infusion prior to ara-C infusion would biologically modulate the accumulation of ara-9-beta-D-arabinofuranosylcytosine 5'-triphosphate (ara-CTP) and other ara nucleotides in the leukemia blasts during therapy, protocols were designed to infuse G-CSF prior to fludarabine (9-beta-D-arabinofuranosyl-2-fluoroadenine monophosphate) and ara-C to increase the accumulation of the active triphosphates [9-beta-D-arabinofuranosyl-2-fluoroadenine 5'-triphosphate (F-ara-ATP) and ara-CTP] in acute myelogenous leukemia (AML) blasts during therapy. To complement these in vivo studies, ex vivo accumulation of ara-CTP was also investigated before and after G-CSF infusion. Patients (n = 5) treated on the fludarabine/ara-C/G-CSF regimen received a 30 mg/m2 dose of fludarabine followed by a 2 g/m2 dose of ara-C infused i.v. for 4 h. Beginning at 24 h, and every day, patients received a 6-h infusion of 400 microgram/m2 G-CSF. At 48 h, the fludarabine and ara-C couplet was repeated. Comparison of F-ara-ATP pharmacokinetics in circulating AML cells of patients on the fludarabine/ara- C/G-CSF regimen demonstrated that the area under concentration time curve (AUC) of F-ara-ATP increased significantly (median, 1.4-fold; range, 0.9-1.5; P = 0.045) after G-CSF infusion. This was due to an increased rate of F-ara-ATP accumulation by AML cells. The AUC of ara-CTP, on the other hand, was not affected (median, 1.0-fold; range, 1.0-1.2; P = 0.571) after G-CSF infusion. Because fludarabine potentiates the accumulation of ara-CTP, the effect of G-CSF on ara-CTP metabolism may not be evident in the AML blasts of patients on the fludarabine/ara-C/G-CSF regimen. To determine the effect of G-CSF when ara-C was infused alone, four additional patients were treated on a pilot protocol in which ara-C (2 g/m2) was infused on days 1 and 3 and G-CSF on day 2. The AUC of ara-CTP accumulation in these patients decreased by a median of 48% after G-CSF infusion. Consistent with these in vivo investigations, ex vivo ara-CTP accumulation was decreased in the AML blasts after G-CSF infusion. Based on these data it could be concluded that (a) infusion of G-CSF before fludarabine augmented the rate of F-ara-ATP synthesis in circulating AML blasts during therapy, suggesting that G-CSF may benefit fludarabine therapy by biological modulation; (b) G-CSF did not increase ara-CTP accumulation, rather it may have caused it to decrease; and (c) these data imply that when G-CSF and ara-C are used in combination, administration of fludarabine prior to ara-C may maintain the ara-CTP AUC.
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PMID:Modulation of the cellular metabolism of cytarabine and fludarabine by granulocyte-colony-stimulating factor during therapy of acute myelogenous leukemia. 981 70

Arabinosylcytosine (ara-C) is a cytotoxic agent with major activity against acute leukemias. To exert this effect, it must first be phosphorylated to its active 5'-triphosphate, ara-CTP, which is incorporated into DNA. Our previous studies demonstrated that preincubation with arabinosyl-2-fluoroadenine (F-ara-A) increased the rate of ara-CTP accumulation in leukemia cells when incubated with 10 microM ara-C. Such concentrations of ara-C are readily obtained during intermittent bolus infusions of ara-C, and clinical trials were conducted using fludarabine in combination with 2-h infusions of intermediate-dose ara-C. During continuous infusion of ara-C, however, serum ara-C levels are <10 microM. Because the effectiveness of ara-C depends on the levels of intracellular ara-CTP and its incorporation into DNA, we sought to investigate the influence of fludarabine on pharmacodynamics of ara-C at concentrations of ara-C achieved during continuous infusion. Using the K562 human leukemic cell line, we established that incubation with 30 microM F-ara-A was able to modulate intracellular dNTP pools and achieve maximum enhancement of ara-CTP levels at all concentrations of ara-C tested (0.3-10.0 microM). The relative enhancement of ara-CTP concentrations ranged from 2.2- to 2.8-fold. Combination of F-ara-A with 1.0 and 3.0 microM ara-C also increased the incorporation of ara-CTP into DNA. To model the influence of F-ara-A on continuous infusion ara-C, cells were incubated with 1 microM ara-C alone or in combination with F-ara-A. The F-ara-A-incubated cells accumulated effective intracellular concentrations of F-ara-ATP, which resulted in greatly increased intracellular ara-CTP levels. These studies demonstrate the capacity of clinically attainable concentrations of F-ara-ATP to enhance the formation of ara-CTP at concentrations of ara-C that are achieved during a continuous infusion schedule. Given the important role intracellular ara-CTP concentrations and ara-CMP incorporation into DNA have on the ultimate cytotoxic capacity of ara-C against acute myelogenous leukemia blasts, these studies suggest a promising pharmacological model for improving the efficacy of the continuous infusion ara-C regimen.
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PMID:Influence of fludarabine on pharmacokinetics and pharmacodynamics of cytarabine: implications for a continuous infusion schedule. 981 15

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