Effects of N-hydroxy-N'-aminoguanidine isoquinoline in combination with other inhibitors of ribonucleotide reductase on L1210 cells

The 1-isoquinolylmethylene derivative of N-hydroxy-N'-aminoguanidine (HAG) is the most potent agent of the recently synthesized series of HAG-derived ribonucleotide reductase inhibitors. To potentiate the effects of the HAG-isoquinoline drug [HAG-1-isoquinolylmethylene tosylate (HAG-IQ)], we combined it with other inhibitors of ribonucleotide reductase. Using mouse leukemia L1210 cell cultures, we tested drug combinations for their cytostatic and cytotoxic properties and for their effects on intracellular ribonucleotide reductase activity and nucleic acid synthesis. Deoxyguanosine or deoxyadenosine combined with HAG-IQ inhibited cell growth in an additive manner; three-drug combinations, HAG-IQ plus either deoxyguanosine/8-aminoguanosine or deoxyadenosine/deoxycoformycin, were strongly synergistic. When Desferal, an iron chelator, was added to these combinations, the four-drug combinations increased inhibition of cell growth and increased cytotoxicity. The intracellular target of these drug combinations in L1210 cells was the ribonucleotide reductase site. The formation of deoxycytidine from [14C]cytidine and incorporation into DNA were markedly inhibited by these drug combinations, while RNA synthesis was unaffected. These data show that the antiproliferative and cytotoxic effects of HAG-IQ, a potent inhibitor by itself, can be further potentiated in combinations with other ribonucleotide reductase inhibitors.     

Characterization of L1210 cell growth inhibition by the bacterial iron chelators parabactin and compound II

Microbial siderophores represent a class of iron chelators characterized by their high affinity (i.e., formation constants, greater than 10(40) M) for ferric iron. Previously, we demonstrated that the bacterial siderophores, N-[3-(2,3-dihydroxybenzamido)propyl]-N-[4-(2, 3-dihydroxybenzamino)butryl]-2-(2-hydroxyphenyl) trans-5-methyloxazoline-4-carboxamide (Parabactin) and N1,N8-bis(2,3-dihydroxybenzoyl)spermidine (Compound II), inhibit the growth of L1210 cells and the replication of DNA (but not RNA) viruses at low micromolar concentrations (Biochem. Biophys. Res. Commun., 121: 848-854, 1984). The basis for this antiproliferative effect on L1210 cells has now been investigated further. Onset of growth inhibition induced by 5 microM Parabactin occurs much earlier than with an equimolar concentration of Compound II but, once established by either chelator, inhibition appears to be irreversible. Growth inhibition was fully preventable with exogenous FeCl3 when given at the same time as the chelators. Flow cytometric analysis revealed a G1-S cycle block following treatment for 4 h with either 5 microM Parabactin or 30 microM Compound II. The block was readily reversed with exogenous FeCl3, allowing cells to progress to mid-S phase by 3 h and to G1 again by 9 h. Thereafter, cells accumulated at a second block located at S phase. The treatment conditions required for the initial cell cycle block (at 4 h) were adapted for subsequent studies. Clonogenicity of L1210 cells in soft agar following a 4-h exposure was reduced to 22% of control by 5 microM Parabactin and to 16% by 30 microM Compound II. Neither growth inhibition in suspension culture nor decreased clonogenicity in soft agar could be reversed with exogenous iron, following treatment with the chelators. Both chelators caused an early and significant decrease in [14C]thymidine incorporation over the 4-h period (50% inhibitory concentration at 4 h, 0.4 microM for Parabactin and 6.0 microM for Compound II). [3H]Uridine incorporation was inhibited later than [14C]thymidine and to a much lesser extent, while [3H]leucine incorporation was not significantly affected. Treatment of cells with 5 microM Parabactin or Compound II for 4 h decreased deoxy-adenosine triphosphate pools by 38 and 70%, respectively, and increased deoxythymidine triphosphate pools by 67 and 36%, respectively, suggesting interference with ribonucleotide reductase. Indeed, extracts of cells treated for 4 h with either 5 microM Parabactin or 30 microM Compound II exhibit a 97 to 98% decrease in cytidine-5'-diphosphate reductase activity compared to control, whereas DNA polymerase was elevated slightly.(ABSTRACT TRUNCATED AT 400 WORDS)     

Cross-resistance patterns in hydroxyurea-resistant leukemia L1210 cells

Hydroxyurea is an inhibitor of ribonucleotide reductase and is specifically directed at the non-heme iron subunit (which contains the free radical) of this enzyme. Leukemia L1210 cells, grown in the presence of increasing concentrations of hydroxyurea, developed resistance to hydroxyurea. For hydroxyurea, the wild-type L1210 cells required a drug concentration of 85 microM to inhibit cell growth by 50%, and the hydroxyurea-resistant (HU-7-S7) cells required a concentration of approximately 2000 microM. The resistant L1210 cells were cross-resistant to 2,3-dihydro-1H-pyrazolo[2,3-a]imidazole/Desferal. However, these HU-7-S7 cells remained sensitive to 4-methyl-5-amino-1-formylisoquinoline thiosemicarbazone and 1-isoquinolylmethylene-N-hydroxy-N'-amino-guanidine tosylate (inhibitors directed at the same subunit as hydroxyurea). The HU-7-S7 cells retained their sensitivity to deoxyadenosine/erythro-9-(2-hydroxy-3-nonyl)adenine and deoxyguanosine/8-amino-guanosine (inhibitors directed at the effector-binding subunit of ribonucleotide reductase). The L1210 cells developed for resistance to hydroxyurea were sensitive to the non-ribonucleotide reductase inhibitors, methotrexate and 1-beta-D-arabinofuranosylcytosine. Ribonucleotide reductase activity was elevated in the HU-7-S7 cells (CDP reductase, 5.5-fold increase; ADP reductase, 13.2-fold increase). The addition of exogenous effector-binding subunit caused much greater stimulation of reductase activities in the extracts from the resistant cells than from the wild-type cells. The reductase activity in cell-free extracts from the resistant cells was inhibited by hydroxyurea, 2,3-dihydro-1H-pyrazolo[2,3-a]imidazole and dATP to the same extent as the activity from the wild-type L1210 cells. These data indicate that resistance to hydroxyurea in these L1210 cells is to some extent related to increased reductase activity. However, the specificity of resistance of these L1210 cells to inhibitors of ribonucleotide reductase depends on the nature of the inhibitor and the subunit at which the inhibitor is directed.     

Cell cycle synchronization and growth inhibition by 3-hydroxypyridin-4-one iron chelators in leukemia cell lines.

The effect of bidentate 3-hydroxypyridin-4-one (HPO) iron chelators on cell cycle arrest with subsequent cycle synchronization has been compared with that of the hexadentate desferrioxamine (DFO) in K562 and Daudi cells. The relationships between chelator concentration and inhibition of growth, DNA synthesis and ribonucleotide reductase, and phase of cell cycle arrest have also been explored. HPOs and DFO arrest the cell cycle in a dose-dependent manner causing a blockade at the G1-S border after 24 h at concentrations above 30 microM iron-binding equivalents. This is associated with reduced ribonucleotide reductase activity and concomitant cessation of DNA synthesis and growth. When the chelator is subsequently removed, HPO-treated cells synchronously cascade into S phase, unlike DFO-treated cells which resume cycling in a nonsynchronous manner. Chelator concentrations of approximately 25 microM and 3 microM iron-binding equivalents inhibited growth, DNA synthesis, and ribonucleotide reductase activity by 50% in K562 and Daudi cells, respectively. Concentrations less than 10 microM iron-binding equivalents inhibited K562 cell growth without an effect on DNA synthesis but with accumulation of cells in G2 and M phases. These results suggest that HPOs have advantages over DFO as cell cycle synchronization agents and may be useful adjuncts in cell cycle-specific treatment regimens.     

Effects of 5-aza-2'-deoxycytidine on survival and cell cycle progression of L1210 leukemia cells

The in-vitro effects of the antileukemic agent 5-aza-2'-deoxycytidine (5-aza-dCyd), on DNA synthesis, growth, cloning in agar, and cell cycle traverse of L1210 leukemia cells were studied. 5-Aza-dCyd at 0.1 microgram/ml for 10 hr (cytotoxic concentration) did not inhibit DNA synthesis but produced a very potent growth inhibition, and changed markedly the DNA flow cytometric histograms. A 5-h continuous exposure to the drug at concentrations ranging from 0.1 to 10 micrograms/ml caused an accumulation of cells in the S portion of the DNA histograms indicating a slowing of the progression of cells in the S phase. A longer exposure time (10 h) at the same concentrations led to a bimodal DNA distribution (peaks at G1 and G2-M) and a depletion of the S phase. When the exposure time to 5-aza-dCyd (0.1 microgram/ml) was extended to 15 and 20 h, there was a decrease in the G2-M peak and an augmentation of the G1 peak. To determine if 5-aza-dCyd produced a block in cell cycle progression, L1210 cells were treated for 10 h with colcemid and 5-aza-dCyd simultaneously for 10 h. Colcemid alone, or colcemid in combination with 5-aza-dCyd produced an accumulation of cells under a single G2-M peak. This indicates that 5-aza-dCyd did not block the progression of L1210 cells through S phase, but only produced a slowing down of this event. These results, indicating that 5-aza-dCyd does not block cell cycle progression and that its cytotoxic action is not self-limiting, are of importance for designing future clinical trials.     

Differences in intracellular sites of action of Adriamycin in neoplastic and normal differentiated cells

PURPOSE: This study was performed to clarify the intracellular specificity of the differential cytotoxic effects of Adriamycin (ADM) on neoplastic and normal cells. METHODS: The mouse lymphocytic leukemia cell line L1210 and pig kidney proximal tubular epithelial cell line LLC-PK1 were used as neoplastic and normal cells, respectively. These cells were treated with various concentrations of ADM for 24 h and toxicological parameters were determined. RESULTS: ADM (0.1-10 microM) significantly down-regulated cell growth rate and [3H]thymidine incorporation into DNA in the log phase, and at concentrations of more than 1 microM reduced the viability of both cell lines. Lipid peroxidation was increased at 1 microM ADM in L1210 cells and at 10 microM ADM in LLC-PK1 cells. The microsomal and nuclear fractions of both cell lines showed approximately the same level of ADM-induced superoxide anion (O2-) production, while the mitochondrial fraction of differentiated LLC-PK1 cells produced the highest levels of O2-. Differentiated LLC-PK1 cells showed the highest mitochondrial NADH-cytochrome c reductase activity. L1210 cells showed lower mitochondrial activities of enzymes involved in scavenging of reactive oxygen species, such as superoxide dismutase, glutathione peroxidase and catalase, than the other cells. CONCLUSIONS: These results suggest that ADM exerts cytostatic effects on neoplastic and normal undifferentiated cells through the inhibition of DNA synthesis by DNA intercalation, and cytotoxic effects on neoplastic cells through the accumulation of reactive oxygen species resulting from low scavenger enzyme activities. The cytotoxic effects on normal differentiated cells may be related to the high levels of production of reactive oxygen species due to high mitochondrial NADH-cytochrome c reductase activity.     

Effects of cytotoxicity of 2-chloro-2'-deoxyadenosine and 2-bromo-2'-deoxyadenosine on cell growth, clonogenicity, DNA synthesis, and cell cycle kinetics

The cytotoxic effects of the adenosine deaminase resistant analogues 2-bromo-2'-deoxyadenosine (2-BrdAdo) and 2-chloro-2'-deoxyadenosine (2-CldAdo) have been compared with those of deoxyadenosine (dAdo). Like 2-CldAdo, 2-BrdAdo is highly effective in inhibiting the growth of many T-lymphoblastoid, B-lymphoblastoid, and myeloid cell lines in culture. Concentrations required to inhibit growth of CCRF-CEM human T-lymphoblastoid cells by 50% (IC50) are: 2-CldAdo, 0.045 microM; 2-BrdAdo, 0.068 microM; dAdo, 0.9 microM in the presence of 5 microM erythro-9-(2-hydroxy-3-nonyl)adenine. Like dAdo, 2-BrdAdo causes a much greater decrease in DNA synthesis than in RNA and protein synthesis. For each of the nucleosides the concentration required to cause 50% inhibition of DNA synthesis (as measured by thymidine incorporation) in an 18-h exposure is very similar to the IC50 for growth and to the concentration required to decrease viability (clonogenicity) over 18 h by 50% (EC50). A fraction of CCRF-CEM cells (approximately equal to 30%) is resistant to killing by exposure to 2-BrdAdo or 2-CldAdo for 4 h at concentrations 100 times the EC50, but 3% of cells are resistant to exposure for 4 h to a concentration of dAdo 3 times the EC50. Each of the three nucleosides causes accumulation of cells in S phase, the accumulation becoming more marked with longer periods of exposure and with higher concentrations of nucleoside. During exposures for 18-24 h at a concentration of nucleoside near the EC50 most cells accumulate in S, with most in early S, whereas exposure to concentrations greater than EC95 accumulates cells at the G1/S border. This suggests that loss of viability is associated with a blockade of some process specifically occurring at the initiation of S phase. At an optimum dosage schedule, 2-BrdAdo and 2-CldAdo have similar therapeutic effects against L1210 in vivo, both producing over 99% cell kill, but the optimum dosage of 2-CldAdo is lower.     

2,6-Diaminopurinedeoxyriboside as a prodrug of deoxyguanosine in L1210 cells

The mode of action of the antiproliferative nucleoside analogue 2,6-diaminopurinedeoxyriboside (DAPdR) has been characterized in cultured L1210 cells. A marked concentration-dependent decrease in DNA synthesis and ribonucleotide reductase activity occurred in L1210 cells exposed to 0.05 to 1.0 mM DAPdR. Concomitantly, dGTP levels increased as much as 1100-fold as compared to untreated controls. Adenosine deaminase efficiently catalyzed DAPdR conversion to deoxyguanosine in vitro. In a comparative study, DAPdR and deoxyguanosine gave similar results. A 50% inhibition of cell growth during a 72-h incubation was achieved with 0.14 mM DAPdR or 0.26 mM deoxyguanosine. Deoxycytidine rescued the L1210 cells from DAPdR and deoxyguanosine toxicity to the same extent. DAPdR and deoxyguanosine counteracted the toxic effects of mycophenolic acid with the same efficiency. While DAPdR was not metabolized to its 5'-triphosphate, 2,6-diaminopurine was converted to 2,6-diaminopurineriboside 5'-triphosphate in L1210 cells; accordingly 50% inhibition of cell growth occurred at 0.015 mM 2,6-diaminopurine. Combinations of DAPdR with erythro-9-(2-hydroxy-3-nonyl)adenine or deoxycoformycin resulted in antagonism instead of an expected synergism. These data suggest that DAPdR exerts its toxicity on L1210 cells as a prodrug of deoxyguanosine.     

Comparison of in vivo and in vitro effects of continuous exposure of L1210 cells to 6-thioguanine

In this study the cytokinetic and antitumor effects of 12-h continuous treatment with 6-thioguanine (TG) were studied in L1210 cells in vivo and in vitro. Loss of clonogenicity in vitro was maximized at a drug concentration of 0.2 microM. Higher drug concentrations produced less cell kill, and the surviving fraction observed after exposure to 25 microM TG was 1 log higher than at 0.2 microM (2% versus 0.2% of control cloning efficiency, respectively). Delayed G2 arrest in vitro was also found to be most pronounced at 0.2 microM, with G1 arrest more predominant at higher concentrations. Studies in vivo were conducted using C57BL X DBA/2 F1 mice, with or without advanced L1210 ascites tumor. In initial experiments performed on animals without tumor, the 50% lethal dose for 12-h s.c. infusions of TG was approximately 0.8 mumol/kg/min. Correlation of steady-state TG plasma levels with infusion rate revealed a linear relationship up to 0.62 mumol/kg/min, above which the TG plasma concentration increased disproportionately to input rate. Total body clearance of TG, calculated from the linear portion of this curve, was 123 ml/kg/min. The antitumor effects of TG infusions were correlated with steady state plasma concentrations achieved in each individual animal, and it was found that dose rates yielding levels from 1 to 10 microM increased survival time by about 40%, with no apparent optimum plasma level in this range. Examination of the cytokinetic effects caused by TG infusions at the low and high ends of this maximally therapeutic range showed that, as was the case in vitro, lower concentrations of TG caused delayed G2 arrest, while higher concentrations induced more rapid G1 arrest. On the basis of these, as well as previous findings, we propose that the operative mechanism of cell kill by TG in vivo may be dose dependent and may be reflected by the relative degree of G2 versus G1 arrest. We also suggest that the appropriate strategy for the clinical use of TG is to determine the drug concentration which produces maximum G2 arrest of tumor cells, and to infuse continuously at a rate to achieve that level for the maximum time tolerated by the patient, rather than to select an arbitrary length of infusion followed by escalation to maximum tolerated drug concentration.     

Inhibition of tumor cell growth by Schiff bases of hydroxysemicarbazide

The inhibitory activities of Schiff bases of hydroxysemicarbazide (HSC) against eight human and murine tumor cell lines and one non-cancer cell line were studied using MTS/PES microculture tetrazolium and methylene blue assays. Compounds 1 (1-[9-(10-methylanthryl)methylene]-4-HSC), 2 (1-[2-hydroxy-3,5-dibromobenzylidene]-4-HSC) and 3 (1-[2,3,4-trihydroxybenzylidene]-4-HSC), which have been shown to be active against murine leukemia L1210 cells in our laboratories, inhibited human leukemia CCRF-CEM cells with similar IC50s ranging from 2.7 to 7.0 microM. Of the compounds tested against attached tumor cell lines (B16, CHO, HT29, ZR75) at 50 microM concentration, compound 1 showed the strongest inhibition, followed by 4 (1-[2-(5-nitrothienyl)methylene]-4-HSC), 2 and 5 (1-[2-hydroxy-3,5-diiodobenzylidene]-4-HSC) with more than 50% inhibition. The IC50s of compound 1 were found to range from 2.7 to 12 microM against the attached tumor cell lines examined. As compared with hydroxyurea, compound 1 had more favorable selectivity against tumor cells. Further more, compound 1 was found to have IC50s of 2.8 and 6.5 microM against hydroxyurea-resistant and gemcitabine-resistant KB cells, respectively, but had no cross-resistance with hydroxyurea and gemcitabine (two known ribonucleotide reductase inhibitors acting at different sites of the same enzyme). In conclusion, several Schiff bases of HSC showed inhibition of tumor cell growth at micromolar concentration and had no cross-resistance with hydroxyurea-resistant KB cells.     

ICI D1694, a quinazoline antifolate thymidylate synthase inhibitor that is a potent inhibitor of L1210 tumor cell growth in vitro and in vivo: a new agent for clinical study

N-(5-[N-(3,4-dihydro-2-methyl-4-oxoquinazolin-6-ylmethyl)-N- methylamino]-2-thenoyl)-L-glutamic acid (ICI D1694) is a water-soluble, folate-based thymidylate synthase (TS) inhibitor designed to be a less toxic and more potent analogue of the clinically tested N10-propargyl-5,8-dideazafolic acid. Inhibition of isolated L1210 TS by ICI D1694 is mixed noncompetitive (although tending toward competitive), with a Ki of 62 nM (Kies = 960 nM). The synthetic gamma-polyglutamates are up to 2 orders of magnitude more potent as inhibitors of TS; e.g., the tetraglutamate (glu4) has a Ki of 1.0 nM (Kies = 15 nM). Although inhibitory activity of ICI D1694 toward rat liver dihydrofolate reductase was similar to that of TS (Ki = 92 nM; competitive inhibition) the polyglutamate derivatives did not show enhanced activity. ICI D1694 was also a very potent inhibitor of L1210 cell growth (50% inhibitory activity = 8 nM). L1210 growth inhibition was not observed in the presence of thymidine, consistent with TS being the locus of action. Folinic acid antagonized L1210 growth inhibition in a competitive fashion such that the highest folinic acid concentration used (25 microM) increased the 50% inhibitory activity 6000-fold. When given as a 4-h delayed "rescue", folinic acid was much less effective in antagonizing growth inhibition. These observations are consistent with folinic acid competing with ICI D1694 for uptake into the cell and/or intracellular polyglutamation. The L1210:1565 cell line, which has greatly impaired reduced-folate/methotrexate transport and thus is resistant to methotrexate, was significantly cross-resistant to ICI D1694 (121-fold), suggesting that ICI D1694 is dependent on this uptake mechanism for good cytotoxic potency in L1210 cells. L1210 cells that were incubated for 4 h with 0.1 microM 3H-ICI D1694 accumulated approximately 1.5 microM intracellular 3H, and the high performance liquid chromatography analysis of the cell extracts demonstrated that 96% of the 3H was associated with the ICI D1694 polyglutamate fractions (principally glu4). Upon resuspension in drug-free medium for 24 h, approximately 75% of the cellular 3H was retained, this being the higher polyglutamate pool (glu4-6). In mice, after a single bolus injection of 10 mg/kg of ICI D1694, TS was inhibited greater than 80% for 24 h in ascitic L1210:NCI cells (as measured by the rate of 3H release from [5-3H]deoxyuridine). ICI D1694 cured the L1210:ICR ascitic tumor in mice at 0.4 mg/kg daily for 5 days (maximum tolerated dose, approximately 50 mg/kg).(ABSTRACT TRUNCATED AT 400 WORDS)     

The effects of alpha-methylene-gamma-lactone purines and pyrimidines on L1210 lymphoid leukemia nucleic acid metabolism

Purine and pyrimidine adducts of alpha-methylene-gamma-lactone demonstrated potent cytotoxicity against murine L1210 lymphoid leukemia growth as well as a variety of human tissue cultured tumors. The most potent compound, 9-[(2-methyl-4-methylene-5-oxotetrahydrofuran-2-yl)-methyl 1] adenine 1 demonstrated significant inhibition of DNA synthesis in L1210 leukemic cells with moderate inhibition of protein synthesis. The major enzyme activities inhibited by 1 were DNA polymerase alpha, ribonucleoside reductase and t-RNA polymerase with marginal inhibition of thymidine kinase, TMP kinase, PRPP amidotransferase and IMP dehydrogenase. The inhibition of DNA polymerase alpha activity by 1 was evident at the lowest concentration 25 microM and was evident within 15 min incubation at 100 microM. The magnitude of enzyme inhibition was consistent with the observed DNA synthesis inhibition by 1. The only deoxyribonucleotide level reduced by 1 was the dATP pool level. U.V. absorption of DNA after interacting with 1 demonstrated a hyperchromic effect and L1210 DNA strand scission was observed after 24 hr incubation with 1 suggesting some type of interference with the DNA template by the drug.     

The role of apoptosis in cell killing by cisplatin: a flow cytometric study.

Cell killing of L1210 cells by cisplatin has been studied using flow cytometry and DNA gel electrophoresis. Ten hours after a supralethal dose of drug (100 microM), extensive apoptosis was induced. Cells were also susceptible to the induction of apoptosis by nutritional deprivation, for example by incubation in arginine-deficient medium. After treatment in full medium with doses of drug in the range 1-10 microM, cells experienced a slow-down in S-phase transit followed by a G2 block. Cells either overcame the G2 block and continued to cycle or enlarged and eventually died. There was no evidence to suggest that cells dying from the G2 block underwent apoptosis. The data were consistent with a dual mechanism of cell death-higher doses of drug led to rapid death through apoptosis; lower doses led to death at later times resulting from failure to overcome a block in G2.     

In vitro antitumor mechanism of a new platinum complex, (-)-(R)-2-aminomethylpyrrolidine(1,1-cyclobutanedicarboxylato+ ++) platinum(II)

The antitumor mechanism of (-)-(R)-2- aminomethylpyrrolidine (1.1-cyclobutanedicarboxylato)platinum(II) (DWA2114R) was examined using cultured murine L1210 leukemia cells by estimating its effects on parameters such as proliferation, macromolecular synthesis, morphology and cell cycle progression. Each parameter was estimated in cells concomitantly exposed to the drug for 24-48 hr. More than 0.1 microM of DWA2114R markedly inhibited cell proliferation as well as DNA synthesis, and it decreased in mitotic index in a concentration-dependent manner. One microM of DWA2114R decreased DNA synthesis by 80% in the cells treated for 24 hr, while the inhibition of RNA synthesis was less than 40%. A significant inhibition of protein synthesis was caused only by treatment with a high concentration (100 microM) of the drug. Under complete cytostatic conditions (10 microM of DWA2114R), cell volume markedly increased and about 40% of the total cells were polynucleate. In addition, flow cytometrical analysis revealed that most of these cells were accumulated in the G2/M phase of the cell cycle, and a new peak located in the G2/M phase of tetraploid cells emerged. On the other hand, the cells treated with 100 microM of the drug did not increase in volume and their progress in the cell cycle was almost completely blocked.     

Synergistic inhibition of leukemia L1210 cell growth in vitro by combinations of 2-fluoroadenine nucleosides and hydroxyurea or 2,3-dihydro-1H-pyrazole[2,3-a]imidazole

9-beta-D-Arabinofuranosyl-2-fluoroadenine (2-F-ara-A) and 2-fluoro-2'-deoxyadenosine (2-FdAdo) were potent inhibitors of L1210 cell growth in culture. Even though these 2-fluoroadenine nucleosides are very poor substrates for adenosine deaminase, erythro-9-(2-hydroxyl-3-nonyl)adenine potentiated the growth-inhibitory properties of 2-FdAdo but not 2-F-ara-A in a synergistic manner. 2-FdAdo and 2-F-ara-A inhibited the conversion of [3H]cytidine to deoxycytidine nucleotides and incorporation into DNA, suggesting that ribonucleotide reductase was an intracellular site of action. 2-F-ara-A (6 microM) in combination with 2,3-dihydro-1H-pyrazole[2,3-a]imidazole gave synergistic inhibition of L1210 cell growth. At lower concentrations of 2-F-ara-A, the inhibition by this combination was only additive. The addition of Desferal to the combination of 2-F-ara-A plus 2,3-dihydro-1H-pyrazole[2,3-a]imidazole provided a strong synergistic combination. Similar results were obtained with combinations which included F-ara-A, hydroxyurea, and Desferal. The combinations of 2-FdAdo plus 2,3-dihydro-1H-pyrazole[2,3-a]imidazole or hydroxyurea gave strong synergistic inhibition of L1210 cell growth, even at the lowest concentration of 2-FdAdo (0.6 microM) studied. The presence of Desferal in the combination served to further potentiate the synergism.     

Leukemia L1210 cell lines resistant to ribonucleotide reductase inhibitors

Leukemia L1210 cell lines, ED1 and ED2, were generated which were resistant to the cytotoxic effects of deoxyadenosine/erythro-9-(2-hydroxyl-3-nonyl)adenine and deoxyadenosine/erythro-9-(2-hydroxyl-3-nonyl)adenine plus 2,3-dihydro-1H-pyrazole[2,3a]imidazole/Desferal, respectively. The ED1 and ED2 were characterized to show that these cell lines had increased levels of ribonucleotide reductase as measured by CDP reduction. The reductase activity in crude cell-free extracts from the ED1 and ED2 cells was not inhibited by dATP. For CDP reductase, the activation by adenylylimido diphosphate and inhibition by dGTP and dTTP in these extracts from the ED1 and ED2 cells were the same as for the wild-type L1210 cells. The ED1 and ED2 cells were highly cross-resistant, as measured by growth inhibition, to deoxyguanosine/8-aminoguanosine, 2-fluorodeoxyadenosine, and 2-fluoroadenine arabinoside. While the ED2 cells showed resistance to 2,3-dihydro-1H-pyrazole-[2,3a]-imidazole/Desferal (6-fold), the ED1 and ED2 cell lines showed less resistance to hydroxyurea, 4-methyl-5-amino-1-formylisoquinoline thiosemicarbazone, and the dialdehyde of inosine. These data indicate that the mechanisms of resistance to the ribonucleotide reductase inhibitors are related to the increased level of ribonucleotide reductase activity and to the decreased sensitivity of the effector-binding subunit to dATP.     

Metabolic effects and kill of human T-cell leukemia by 5-deazaacyclotetrahydrofolate, a specific inhibitor of glycineamide ribonucleotide transformylase.

Metabolic effects and mode of cytotoxicity of 5-deazaacyclotetrahydrofolate (5-DACTHF, BW543U76), a glycineamide ribonucleotide transformylase inhibitor, were studied in MOLT-4 cells, a human T-cell leukemia line. 5-DACTHF inhibits purine synthesis with 50% inhibitory concentration values of 0.5 microM and 0.08 microM following 6- or 24-h exposure to drug, respectively. At 6 h, adenine nucleotide synthesis is preferentially inhibited over guanine nucleotide synthesis. A similar effect was observed with another glycineamide ribonucleotide transformylase inhibitor, 5,10-dideazatetrahydrofolate. GTP was depleted to 40% of control and ATP to 10% of control by 5 microM 5-DACTHF. After a transitory increase, UTP and CTP were depleted to 30% of control. Deoxynucleotides were also depleted by the drug; dCTP was depleted to the greatest extent, followed by dATP, dTTP, and dGTP, respectively. MOLT-4 cell growth was inhibited by 5-DACTHF with a 50% inhibitory concentration of 0.066 microM. Complete reversal was effected by hypoxanthine, and there was no reversal by thymidine. The drug was cytotoxic to MOLT-4 cells in the range 0.25 to 5.0 microM, but a minimum of 48 h was required for trypan blue-staining dead cells to appear. The rate and extent of kill with the thymidylate synthase inhibitor 2-methyl-10-propargyl-5,8-dideazafolate was greater than with 5-DACTHF, which indicates that kill by inhibition of thymidylate synthase is more effective than that by inhibition of purine synthesis. Electron microscopy of MOLT-4 cells exposed to 5-DACTHF showed electron-dense mitochondria and nuclear changes reminiscent of apoptosis. These morphological changes were accompanied by the appearance of DNA strand breaks at approximately 180-base pair intervals (internucleosomal breaks). Concomitant proteolysis of nuclear proteins poly(ADP-ribose) polymerase and lamin B was observed.     

Tissue pharmacokinetics, inhibition of DNA synthesis and tumor cell kill after high-dose methotrexate in murine tumor models.

In Sarcoma 180 and L1210 ascites tumor models, the initial rate of methotrexate accumulation in tumor cells in the peritoneal cavity and in small intestine (intracellularly) after s.c. doses up to 800 mg/kg, showed saturation kinetics. These results and the fact that initial uptake in these tissues within this dosage range was inhibited to the expected relative extent by the simultaneous administration of leucovorin suggest that carrier mediation and not passive diffusion is the major route of drug entry at these extremely high doses. Maximum accumulation of intracellular drug occurred within 2 hr and reached much higher levels in small intestine than in tumor cells at the higher dosages. At a 3-mg/kg dose of methotrexate s.c., intracellular exchangeable drug levels persisted more than four times longer in L1210 cells than in small intestine, but differences in persistence (L1210 cell versus gut) diminished markedly with increasing dosage. At 96 mg/kg, the difference in persistence was less than 2-fold. In small intestine and L1210 cells, theduration of inhibition of DNA synthesis at different dosages correlated with the extent to which exchangeable drug was retained. Toxic deaths occurred when inhibition in small intestine lasted longer than 25 to 30 hr. Recovery of synthesis in small intestine and L1210 cells occurred synchronously and only below dosages of 400 mg/kg. Within 24 hr after dosages of greater than 24 mg/kg, the rate of tumor cell loss increased to a point characterized by a single exponential (t1/2=8.5 hr). The total cell loss, but not the rate of cell loss, was dose dependent.     

Cytostatic and cytotoxic properties of pyronin Y: relation to mitochondrial localization of the dye and its interaction with RNA

Pyronin Y (PY) is an intercalating cationic dye that shows specificity towards RNA. In viable cells this dye also accumulates in mitochondria. The cytostatic and cytotoxic effects of PY on L1210 and Chinese hamster ovary cells were studied in relation to its intracellular localization and compared with the affinity of PY to bind to double-stranded DNA and RNA and its propensity to condense single-stranded DNA and RNA. Antitumor properties of PY were tested on L1210 leukemia and Sarcoma 180 ascites in mice. At a concentration of 1.7 to 3.3 microM, PY was localized almost exclusively in mitochondria of cultured cells, similar to another mitochondrial probe, rhodamine 123. At that concentration PY was not toxic but suppressed cell growth, arresting cells in G1. At a concentration of 6.7 to 33.0 microM, PY was also localized in nucleoli and uniformly in cytoplasm, bound to the RNase-sensitive material therein. At that high concentration PY induced cell arrest in G2 and S and was cytotoxic. The dye exhibited a propensity to bind and condense (precipitate) single-stranded nucleic acids, and condensation could be measured by the appearance of light-scattering products. Among a variety of natural and synthetic nucleic acids the most sensitive were the RNA polymer, polyriboadenylate, and the copolymer, polyriboadenylate and polyriboguanylate, which underwent condensation at a PY concentration of 6.6 to 10.0 microM. Natural and synthetic DNA polymers were resistant to condensation. The data suggest that the cytostatic (G2 and S arrest) and cytotoxic (inability to exclude trypan blue, loss of clonogenicity) effects of PY seen at 6.7 to 33.0 microM concentration may be a consequence of the dye binding to RNA. PY may intercalate to double-stranded RNA and/or cause the specific condensation of single-stranded RNA; the polyadenylated sections of mRNA appear to be the most sensitive cellular targets to undergo condensation. PY showed antitumor properties extending survival of L1210 leukemic mice by 50% and slowing growth of Sarcoma 180 ascites tumor. The possibility that certain antitumor drugs, generally believed to act via intercalation to DNA, may exert chemotherapeutic effects via their interactions with RNA is discussed.     

Increased sensitivity of hydroxyurea-resistant leukemic cells to gemcitabine.

Tumor cell resistance to certain chemotherapeutic agents may result in cross-resistance to related antineoplastic agents. To study cross-resistance among inhibitors of ribonucleotide reductase, we developed hydroxyurea-resistant (HU-R) CCRF-CEM cells. These cells were 6-fold more resistant to hydroxyurea than the parent hydroxyurea-sensitive (HU-S) cell line and displayed an increase in the mRNA and protein of the R2 subunit of ribonucleotide reductase. We examined whether HU-R cells were cross-resistant to gemcitabine, a drug that blocks cell proliferation by inhibiting ribonucleotide reductase and incorporating itself into DNA. Contrary to our expectation, HU-R cells had an increased sensitivity to gemcitabine. The IC50 of gemcitabine was 0.061 +/- 0.03 microM for HU-R cells versus 0.16 +/- 0.02 microM for HU-S cells (P = 0.005). The cellular uptake of [3H]gemcitabine and its incorporation into DNA were increased in HU-R cells. Over an 18-h incubation with radiolabeled gemcitabine (0.25 microM), gemcitabine uptake was 286 +/- 37.3 fmol/10(6) cells for HU-R cells and 128 +/- 8.8 fmol/10(6) cells for HU-S cells (P = 0.03). The incorporation of gemcitabine into DNA was 75 +/- 6.7 fmol/10(6) cells for HU-R cells versus 22 +/- 0.6 fmol/10(6) cells for HU-S cells (P < 0.02). Our studies suggest that the increased sensitivity of HU-R cells to gemcitabine results from increased drug uptake by these cells. This, in turn, favors the incorporation of gemcitabine into DNA, resulting in enhanced cytotoxicity. The increased sensitivity of malignant cells to gemcitabine after the development of hydroxyurea resistance may be relevant to the design of chemotherapeutic trials with these drugs.