Chris Benz

Schedule-dependent cytotoxicity of methotrexate and 5-fluorouracil in human colon and breast tumor cell lines.

The effect of sequential methotrexate and 5-fluorouracil on the clonal growth of the human colon adenocarcinoma cell, HCT-8, and the hormone-dependent human breast carcinoma cell, 47-DN, was examined. In both cell lines, when 5-fluorouracil was given during the last 6 h of a 24 h methotrexate exposure period, there was marked synergistic inhibition of clonal growth. Shorter intervals or the reverse sequence of drugs were either additive or antagonistic. These results indicate the importance of the drug sequence and time interval between drug administration for optimal cytotoxicity in these human cell lines. This information suggests that the administration of methotrexate 18 h before 5-fluorouracil may have potential application in the design of clinical trials for these malignancies.

Lactic dehydrogenase isozymes, 31P magnetic resonance spectroscopy, and in vitro antimitochondrial tumor toxicity with gossypol and rhodamine-123

Three compounds that share specific antimitochondrial properties are gossypol, rhodamine-123, and lonidamine. We compare the antiproliferative activities of these drugs against six human cell lines derived from breast (T47-D), pancreas (MiaPaCa, RWP-2), prostate (DU-145), colon (HCT-8), and cervix (HeLa) carcinomas. Tumor cells enriched in cathodal LDH isozymes (LDH4 and LDH5) are significantly more sensitive to gossypol and rhodamine-123. When compared for ability to inhibit growth of human marrow in soft agar, 10 microM gossypol shows little effect on colony formation whereas 10 microM rhodamine-123 completely prevents stem cell growth, suggesting that gossypol may have the most favorable therapeutic index. Within 24 h of drug administration, there is a relative increase in intracellular inorganic phosphate pools and a marked decline in soluble high-energy phosphates in sensitive tumor cells, as measured by 31P magnetic resonance spectroscopy. These studies suggest that specific antimitochondrial agents might be selectively administered on the basis of tumor LDH isozyme content and noninvasively monitored for antiproliferative activity by 31P spectroscopy.

Uridine and cytidine metabolism following inhibition of de novo pyrimidine synthesis by pyrazofurin

Pyrazofurin, an inhibitor of orotidylate decarboxylase, imposes an absolute nutritional requirement for exogenous uridine to maintain normal growth of L5178Y, P388, L1210, W256 and S180 cells in vitro. The amount of uridine necessary for cell division when de novo uridine nucleotide synthesis is inhibited by pyrazofurin is: L5178Y, 30.5; P388, 39.7; L1210, 53.3: W256, 70.6; and S180, 886 fmol/cell. Cytidine, which can be deaminated to uridine, will substitute for uridine to maintain normal cell growth in the presence of growth-inhibitory concentrations of pyrazofurin (5 microM). The requirements for cytidine and uridine are identical. If cytidine deamination is prevented by tetrahydrouridine (100 microM), cytidine can no longer support growth in the presence of pyrazofurin. Cytidine and uridine, as expected, are additive in their effect to permit normal growth of pyrazofurin treated cells. Tetrahydrouridine does not alter this additive effect, indicating that when both nucleotides are added to pyrazofurin treated cells each nucleotide replenishes their respective nucleotide pools and cytidine deamination is unnecessary to allow cell growth. Incorporation of [14C]uridine into the acid insoluble cell fraction of L5178Y cells was 25 fmol/cell at 48 h and remained constant during the remaining growth of the pyrazofurin treated cell suspension. The [14C]uridine acid soluble pool of 4 fmol/cell also was maximum at 48 h but declined during the subsequent growth of the suspension culture to approx. 2 fmol/cell at 96 h. This decline in the acid soluble pool is correlated with a 42% decrease in modal cell volume during this phase of cell growth which would maintain a constant specific activity of uridine in this pool. This may explain the decline in the acid soluble pool while the acid insoluble pool remains constant during growth of suspension cultures of L51878Y cells. The block in pyrimidine synthesis de novo induced by pyrazofurin provides a useful and quick method for the evaluation of uridine and cytidine metabolism of tumor cell specimens.

Thymidine enhancement of methotrexate and 5-fluorouracil toxicity in cultured human colon carcinoma

SummaryCultures of human colon carcinoma, HCT-8, were treated with millimolar concentrations of thymidine by different schedules designed to cytokinetically and biochemically modulate methotrexate (MTX) and 5-fluorouracil (FUra) toxicity. Thymidine (dThd)-synchronized HCT-8 cells monitored by flow cytofluorometry showed increased sensitivity to MTX and synergistic cytotoxicity to the combination MTX-FUra. FUra toxicity in synchronized cells showed no significant phase specificity overall, but a pattern of relative G2/M resistance was correlated with decreased intracellular FUra accumulation, incorporation into RNA, and formation of FdUMP. In asynchronous cultures dThd reduced MTX toxicity when given within the first 12 h of a 24-h MTX exposure, and also appeared to reduce the MTX-induced synergistic enhancement of FUra toxicity. When dThd was administered with FUra alone in asynchronous cultures, progressive, and synergistic enhancement of FUra toxicity was observed only after 6 h dThd pretreatment. Unlike MTX-FUra synergy, this schedule-dependent synergism between dThd and FUra did not correlate with intracellular FUra accumulation or specific incorporation into total cellular RNA. These results suggest that less well studied mechanisms of dThd modulation, other than enhanced deoxynucleotide formation or total RNA incorporation, may biochemically enhance FUra toxicity in HCT-8 cells.

Modulation of 5-Fluorouracil Toxicity via Estrogen Receptor

Modulation of 5-fluorouracil (FUra) metabolism and toxicity by methotrexate (MTX) and other antimetabolites occurs in many cultured tumor cell lines, including the estrogen receptor positive human mammary carcinoma, 47-DN. The growth rate of this cell line depends on exogenously administered insulin and estradiol, and can be reversibly inhibited by the antiestrogen, tamoxifen (TAM).