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)

2',2'-Difluorodeoxycytidine (dFdC) is a new deoxycytidine analogue with good activity against human leukemic cell lines and murine solid tumors, while the activity of 1-beta-D-arabinofuranosylcytosine (ara-C) is established in experimental systems and for the treatment of human adult leukemia. This study compared the cellular metabolism and cytotoxic properties of dFdC and ara-C in Chinese hamster ovary cells. In wild-type cells, dFdC was significantly more cytotoxic than ara-C after both 4- and 18-h incubations. The 5'-triphosphate of dFdC (dFdCTP) was the major cellular metabolite (85-90%), reaching cellular concentrations up to 20-fold greater than those observed for ara-C 5'-triphosphate at equimolar concentrations of the parent drug. A deoxycytidine kinase-deficient mutant neither accumulated dFdCTP nor showed any cytotoxic response up to drug concentrations of 100 microM. The cytotoxicity of dFdC could be competitively reversed by deoxycytidine further suggesting that dFdC, like ara-C, required phosphorylation by deoxycytidine kinase for biological activity. Several explanations for the different cellular accumulation of the drug triphosphates were established: (a) nucleoside transport studies demonstrated that the membrane permeation of dFdC was 65% more rapid than that of ara-C; (b) deoxycytidine kinase had a higher affinity for dFdC (Km = 3.6 microM) than for ara-C (Km = 8.8 microM), while the Km for deoxycytidine was 1.4 microM; (c) the elimination of intracellular dFdCTP was biphasic with t1/2 alpha = 3.9 and t1/2 beta greater than 16 h while the degradation of ara-CTP was monophasic and significantly faster (t1/2 = 0.7 h). The comparatively long half-life of dFdCTP was related to the prolonged inhibition of DNA synthesis after removal of exogenous nucleoside. Together these factors contribute to the more potent cytotoxicity of dFdC compared with ara-C.
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PMID:Comparison of the cellular pharmacokinetics and toxicity of 2',2'-difluorodeoxycytidine and 1-beta-D-arabinofuranosylcytosine. 338 95

The mixed disulfide of methyl mercaptan and L-homocysteine, S-(methylthio)-L-homocysteine (L-SMETH), inhibits the growth of L-1210 leukemia cells in culture at micromolar concentrations. The inhibition is markedly promoted by added cupric ion, but not by ions of other metals, is stereospecific, and is competitive with glutamine. For example, at 10 microM each of L-SMETH and Cu2+, almost complete growth inhibition was observed if cells were grown in 1 mM glutamine, 50% inhibition at 2 mM glutamine, and none at 4 mM glutamine. The inhibition is also completely relieved by cytidine in noncompetitive manner, but not by guanosine or uridine, indicating that the principal damage to the cellular economy resides in the amination of UTP to CTP. This was confirmed by high performance liquid chromatography analysis of cell extracts, which showed a marked decrease in CTP with increases in the levels of UTP, GTP, and ATP. A major swelling of cells leading to lysis accompanies the inhibition and increases in DNA and protein per cell confirms this unbalanced growth. The chemical basis for this biological interaction is presented.
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PMID:Evidence for a copper:S-(methylthio)-L-homocysteine complex as a glutamine antagonist of cytidine triphosphate synthesis in L1210 murine leukemia cells. 341 27

Twenty-seven patients with refractory leukemia were treated with 1-beta-D-arabinofuranosylcytosine (ara-C), 0.3 to 3.0 g/m2 as i.v. infusions over 1, 2, 4, or 24 h. The pharmacokinetics of ara-C in plasma and its 5'-triphosphate (ara-CTP) in leukemic cells from peripheral blood were studied after a single infusion of 3 g/m2 over 2 h in 13 patients. Accumulation of ara-CTP in leukemic cells remained linear until 1 to 2 h after the infusion. At the time when the rate of ara-CTP accumulation deviated from linearity, the plasma concentration of ara-C was 5- to 20-fold lower [8.1 +/- 4.4 (SD) microM] than the steady-state level during the infusion. Plasma ara-C and cellular ara-CTP pharmacokinetics were studied after two serial infusions in 14 additional patients. Varying the duration of infusion of an ara-C dose between 1, 2, and 4 h (corresponding to infusion rates of 3000, 1500, and 750 mg/m2/h) did not substantially change the rate of ara-CTP accumulation by leukemic cells. The peak ara-CTP concentration and the area under the concentration times time curve (AUC) of ara-CTP in leukemic cells increased with prolongation of the infusion. Although steady-state concentration of ara-C and AUC of ara-C in plasma were proportionally reduced by 1.0 or 0.5 g/m2 infusion over 2 h, ara-CTP accumulation rate and AUC in leukemic cells did not change compared with administration of 3 g/m2 over 2 h. However, when the infusion rate was further reduced to 0.4 or 0.3 g/m2 over 2 h, resulting in steady-state plasma ara-C concentrations of less than 7 microM, the accumulation rate of ara-CTP was substantially reduced as was the ara-CTP intracellular AUC. The cellular elimination rate of ara-CTP remained constant under all infusion conditions. These findings support the conclusion that high-dose ara-C therapy, as currently administered, results in plasma ara-C concentrations that saturate the accumulation of ara-CTP by circulating leukemic cells. We recommend that intermediate dose rates, 200 to 250 mg/m2/h, be evaluated in future studies as an alternative to the substantially higher ara-C dose rates currently in use.
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PMID:Saturation of 1-beta-D-arabinofuranosylcytosine 5'-triphosphate accumulation in leukemia cells during high-dose 1-beta-D-arabinofuranosylcytosine therapy. 347 22

The pharmacokinetics of 1-beta-D-arabinofuranosylcytosine (ara-C) and 9-beta-D-arabinofuranosyl-2-fluoroadenine (F-ara-A) and their respective 5'-triphosphates, ara-CTP and F-ara-ATP, were compared in human plasma and circulating leukemic blasts (CLB) since initial phosphorylation of ara-C and F-ara-A is catalyzed by the same enzyme, deoxycytidine kinase. These investigations were conducted in 4 patients after the first infusion of high-dose ara-C therapy (3 g/m2 i.v. infused over 2 hr) and, following the failure of each to respond, after the initial bolus of F-ara-A monophosphate (50-100 mg/m2 i.v. over 30 min) in a subsequent treatment regimen. The median terminal rate of elimination (t1/2) of F-ara-A was 8.4 hr compared to 2.2 hr for ara-C. The median t1/2 for F-ara-ATP in CLB was 12.2 hr relative to 1.9 hr for ara-CTP. To evaluate the possibility that diminished deoxycytidine kinase was a mechanism of drug resistance, the relative area under the concentration X time curve (AUC) of the active triphosphate of each prodrug in the CLB of individuals was compared. The intracellular nucleotide AUC was normalized by dividing it by the AUC of the respective nucleoside in plasma. A value of 1.0 for the resulting ratio would be expected if the accumulation and retention of F-ara-ATP and ara-CTP were identical. In these patients, however, this ratio ranged between 0.2 and 68.2. When a similar analysis was performed in vitro using four established human leukemia cell lines, a 150-fold variation was found in the normalized nucleotide AUC ratio. Thus, the metabolic characteristics of ara-CTP in CLB of patients who fail to respond to high-dose ara-C may not predict the cellular metabolism of F-ara-ATP in the same patient at a later disease stage.
Leukemia 1987 Sep
PMID:Comparison between the plasma and intracellular pharmacology of 1-beta-D-arabinofuranosylcytosine and 9-beta-D-arabinofuranosyl-2-fluoroadenine 5'-monophosphate in patients with relapsed leukemia. 347 43

The pharmacodynamic parameters of 1-beta-D-arabinofuranosylcytosine (ara-C) in patient plasma and its active anabolite 1-beta-D-arabinofuranosylcytosine-5-triphosphate (ara-CTP) in circulating and bone marrow blast cells were studied in 20 pediatric patients with acute leukemia. ara-C (3 g/m2) was administered as a short-term infusion over 3 h every 12 h for a total of eight doses. The peak plasma concentration of ara-C ranged from 0.02 to 5.6 microM after the first dose of ara-C. The area under the concentration-time curve (AUC) of ara-C in plasma ranged from 302 to 20,298 microMh after the first dose of ara-C. The half-life of elimination (t1/2,el) of ara-C from plasma was 2.4 +/- 1.5 h in three patients with acute nonlymphoblastic leukemia (ANLL) and 4.78 +/- 4.1 h in 9 patients with acute lymphoblastic leukemia (ALL). The intracellular peak concentration of ara-CTP in circulating blast cells averaged 432.2 +/- 14.5 microM and 544.3 +/- 330 microM in patients with ANLL and ALL, respectively. The elimination kinetics of ara-CTP was monoexponential with t1/2,el of 3.30 +/- 0.8 h and 6.9 +/- 2.8 h in patients with ANLL and ALL. DNA synthetic capacity (DSC) of the blast cells was inhibited to between 24 and 64% of control after the first dose of ara-C and it declined further to between 1 and 32% after four doses of ara-C. The AUC of ara-CTP in leukemic cells ranged from 1,073 to 14,751 microMh and it was not related to the AUC of ara-C in plasma. The pharmacodynamic parameters of ara-CTP in circulating blast cells were more homogeneous in patients with ANLL than in patients with ALL. Four of six patients (67%) with ANLL and six of 14 patients (43%) with ALL achieved either complete remission or partial remission with high dose ara-C. We conclude that treatment of pediatric patients with leukemia in relapse with high dose ara-C is tolerable and moderately successful. Inhibition of DSC is positively correlated with the probability of having zero nadir peripheral blast cells. In turn there is a trend for a zero nadir peripheral blast cell count to be related to achievement of a response to therapy. This latter result is consistent with the results of larger studies in adults with leukemia.
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PMID:Biochemical pharmacology of high dose 1-beta-D-arabinofuranosylcytosine in childhood acute leukemia. 347 50

Six patients with acute nonlymphoblastic leukemia (ANLL) were treated sequentially with one subcutaneous (SC) injection (50 mg/m2) and one 156 hour continuous intravenous (IV) infusion (100 mg/m2/d) of 1-beta-D-arabinofuranosylcytosine (ara-C) with an interval of 12 hours. Leukemic cells were isolated from venous blood samples. The intracellular concentration of ara-C 5'-triphosphate (ara-CTP) was determined by high-performance liquid chromatography, and in two of the patients the plasma concentration of ara-C was determined by radioimmunoassay. A rapid biphasic elimination of the drug from plasma with an initial half-life of 18 minutes was seen after SC injection. After about 1.5 hours, the concentration was lower than that obtained at steady-state during continuous IV infusion. In the leukemic cells, the concentration of ara-CTP was higher after SC injection than during continuous IV infusion for about five hours. The mean half-life was 2.1 hours. Judging from the intracellular concentration of ara-CTP, considered to be the active metabolite, the results suggest that SC administration of ara-C can mimic continuous IV infusion if the dose interval is reduced from the traditional 12 hours to four to six hours. The results of this study emphasize the differences between the plasma pharmacokinetics of the parent drug and the concentration of the active metabolite in leukemic cells.
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PMID:ara-C in plasma and ara-CTP in leukemic cells after subcutaneous injection and continuous intravenous infusion of ara-C in patients with acute nonlymphoblastic leukemia. 358 91

In consideration of the full spectrum of hematologic and nonhematologic toxicity juxtaposed to the response rates (Tables 2-5), it appears that for relapsed patients with AML, six to eight consecutive doses of HDara-C or four doses started on days 1 and 8 have the optimal therapeutic index. These regimens are associated with a 25% CR rate and have comparable tolerable and reversible toxicity spectra. An increase in the total number of doses to 12 does not appear to increase the remission frequency in relapsed patients but does decidedly increase the spectrum, frequency, and severity of toxic manifestations. Studies of important pharmacologic determinants such as membrane transport and cellular accumulation of ara-CTP suggest that a lower unit dose may be just as effective, an approach that could potentially lower the frequency and severity of toxicity. However, these concepts must be tested in suitably designed clinical trials. In contrast to the response rate noted in patients with relapsed AML, patients with refractory AML have a substantially lower CR rate (approximately 10%) when treated with HDara-C alone. These lower CR rates are comparable to those reported for other recently introduced new drugs such as m-AMSA and mitoxantrone. In this setting of primary refractory leukemia, multi-institutional and cooperative group trials of HD-ara-C----ASNase show a consistently higher response rate in the range of 30% to 50%. Why ASNase should especially contribute to this particular group is unknown at present. Studies show that the gene for asparagine synthetase is repressed in AML cells. It is speculated that in the initial leukemia cell population (as encountered in refractory AML), the gene for asparagine synthetase is repressed and hence, the leukemia is sensitive to ASNase. In contrast, in the relapsed patient with recurrent leukemia, the gene for asparagine synthetase may be derepressed and the leukemia would be ASNase-insensitive. The therapeutic index of HDara-C----ASNase is schedule dependent. In leukemic mice, pretreatment or concurrent administration of ASNase and HDara-C leads to antagonism of both the therapeutic and toxic effects of HDara-C. These effects are consistent with similar effects of other protein synthesis inhibitors on ara-C toxicity.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Sequential high-dose ara-C and asparaginase versus high-dose ara-C alone in the treatment of patients with relapsed and refractory acute leukemias. 358 97

The cytotoxic effect of cytosine arabinoside (ara-C) is presumably mediated by cytosine arabinoside 5'-triphosphate (ara-CTP). We tested for a correlation between intracellular ara-CTP pharmacokinetics and clinical response among 51 patients who received high dose ara-C (3 g/m2 at 12-hr intervals) as therapy for refractory acute leukemia. After accounting for pretreatment clinical variables that correlated with response, measurement of ara-CTP pharmacokinetics added significant prognostic information. This provides a rationale for manipulation of schedules of high dose ara-C administration in those patients whose pharmacokinetic characteristics are inconsistent with response to an every 12-hr schedule.
Leukemia 1987 Aug
PMID:Variables predicting response to high dose cytosine arabinoside therapy in patients with refractory acute leukemia. 366 71

Acivicin (NSC 163501) and dichloroallyl lawsone (NSC 126771) are potent inhibitors of nucleotide biosynthesis with consequent anti-cancer activity against certain experimental tumors. To determine in detail the metabolic events induced by each inhibitor, we have devised a new two-dimensional chromatographic procedure for measurement of the concentrations of all pyrimidine intermediates and some purine nucleotides from 100 microliter of an extract of cells grown in the presence of [14C]bicarbonate. Addition of acivicin (25 microM) to mouse L1210 leukemia cells causes severe depletion in the cellular levels of CTP and GTP, accumulation of uridine nucleotides, and abrupt but transient increases in the concentrations of the early intermediates of both the pyrimidine and purine pathways. Addition of dichloroallyl lawsone (25 microM) results in a rapid depletion of uridine and cytidine nucleotides; carbamyl aspartate and dihydroorotate accumulate to high levels in an equilibrium ratio of 20.5:1, and orotate, orotidine, and UMP increase transiently before decreasing to levels approaching their original steady states. The predominant inhibitory effects of acivicin are upon the reactions UTP----CTP and XMP----GMP, but there is also an initial transient activation of both the pyrimidine and purine pathways by acivicin. The data obtained with dichloroallyl lawsone are consistent with inhibition of the conversion of UMP----UDP initially followed by potent inhibition of dihydroorotate----orotate.
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PMID:Effects of acivicin and dichloroallyl lawsone upon pyrimidine biosynthesis in mouse L1210 leukemia cells. 377 55

The effect of 3-deazauridine (DAUR) on the intracellular purine and pyrimidine nucleotide pools and on the metabolism of azacitidine (aza-CR) in L1210 cells, sensitive (L1210/0) and resistant (L1210/ara-C) to cytarabine (ara-C), was examined. The consequences of such a modulation were correlated with the therapeutic efficacy of this combination in mice bearing L1210 leukemia. In vitro and in vivo treatment of both L1210 sublines with DAUR produced a dose- and time-dependent reduction in the CTP and dCTP pools and an increase in the UTP pool. In addition to these changes in the pyrimidine nucleotide pools, DAUR produced a modest increase in the GTP pool and a marked expansion of the ATP pool in L1210/ara-C 12 hrs following in vivo drug treatment. These perturbations in nucleoside triphosphate pools were more pronounced in L1210/ara-C cells. Treatment of mice bearing L1210/ara-C with 100 mg/kg of DAUR reduced the CTP and dCTP pools in the leukemic cells by greater than 90% within 1-3 hrs after administration of the drug, with complete recovery of these pools occurring within 12 hrs. Fluctuation of the pyrimidine nucleoside pools after DAUR treatment was correlated with the subsequent increase in aza-CR metabolism and its incorporation into RNA and with the potentiation of the in vivo toxicity of aza-CR. In mice bearing L1210/0 or L1210/ara-C tumors, DAUR or aza-CR produced a less than or equal to 23% increase in life-span (ILS). Administration of aza-CR 3 hrs after DAUR, however, produced about an 80% ILS among mice bearing L1210/ara-C tumors, but no more than an approximately 20% ILS among mice bearing L1210/0 tumors. These data suggest that the therapeutic activity of the sequential combination of DAUR and aza-CR against mice bearing L1210/ara-C cannot be explained, per se, on the basis of the initial intracellular modulation of nucleotide pools, since DAUR affected these pools of the two tumors to approximately the same degree. What appears to be important, however, is that such a modulation by DAUR preferentially affected the metabolism of aza-CR in leukemic cells resistant to ara-C which are devoid of deoxycytidine kinase activity.
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PMID:Effect of 3-deazauridine on the metabolism, toxicity, and antitumor activity of azacitidine in mice bearing L1210 leukemia sensitive and resistant to cytarabine. 619 May 58


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