Characterization of a lipophilic antifolate resistance provoked by treatment of mammalian cells with the antiparasitic agent pyrimethamine.

We describe the characterization of an antitumor drug resistance following multiple step selection of hamster cells to the 2,4-diaminopyrimidines (DAP) metoprine, pyrimethamine (Pyr), and trimethoprim (Tmp). Pyr and Tmp are DAP lipophilic antifolates currently used as antiparasitic and antibacterial antibiotics, respectively. Dihydrofolate reductase (DHFR) from hamster cells bore a low or poor affinity to these DAP as compared to the hydrophilic folate antagonist methotrexate (MTX). Metoprine-resistant cells over-expressed DHFR enzyme and consequently displayed a high level of resistance to both hydrophilic and lipophilic antifolates including DAP but maintained wild type sensitivity to pleiotropic drugs involved in multi-drug resistance (MDR). In contrast, although Pyr- and Tmp-resistant cells expressed parental levels of wild type DHFR, they displayed a high degree of resistance to DAP and, surprisingly, to the lipophilic MTX analogs piritrexim (PTX) and trimetrexate (TMTX), while maintaining sensitivity to MTX. These drug-resistant cells maintained wild type mRNA levels of the MDR gene product P-glycoprotein and showed collateral hypersensitivity to pleiotropic drugs. To study the underlying mechanism of this apparently new resistance phenotype, we have employed fluorescein-methotrexate (F-MTX) labeling of cells and its displacement by different antifolates. Parental AA8 and Pyr-resistant cells showed a similar level of F-MTX labeling, however, while DAP, TMTX, and PTX showed an efficient competitive displacement of F-MTX from AA8 cells, Pyr-resistant cells displayed a persistent retention of F-MTX labeling in the presence of high concentrations of these lipophilic antifolates. Pyr-resistant cells showed a wild type displacement of F-MTX with MTX. This DAP resistance phenotype was unstable as it was rapidly lost upon growth under nonselective conditions. Furthermore, when the antifolate resistance levels of Pyr-resistant cells were plotted versus the ratios of the 50% F-MTX displacement values obtained with resistant and parental AA8 cells, a good correlation (r2 > 0.98) was obtained. We conclude that Pyr-resistant cells possess a novel phenotype that derives its resistance to lipophilic antifolates solely from a predominant decrease in the accumulation of DAP and lipid-soluble analogs of MTX.