Random population-wide genetic damage induced in replicating cells treated with methotrexate.

Low lethality treatment of the NIH 3T3 mouse cell line with methotrexate (MTX) during exponential multiplication results in heterogeneous, heritable reduction in growth rate of most if not all the replicatively surviving cells. The effective concentrations of MTX are 10 to 100 times higher in molecular, cellular and developmental biology medium 402 (MCDB 402) than in Dulbecco's modification of Eagle's medium (DMEM) medium because of the folate-sparing presence of adenine, thymidine and, particularly, of folinic acid in MCDB 402 medium. The reduced growth rates are detectable during early passages of surviving populations before the faster growing cells dominate them. The heritable effect is most clearly demonstrated by sequestered cloning of many individual cells immediately after drug treatment, and repeatedly measuring the growth rates of the clones in serial passages. After 7-10 passages of the clones, there is an increase in growth rate of some of the slow growing clones presumably due to the generation and selection of faster growing cells. Evidence from mutagenic studies at a single genetic locus in other cell lines suggests that heritable reductions in growth rate arise from chromosome aberrations although point mutations may also contribute to the effect. Clastogenic changes can be induced by a wide variety of mutagens and carcinogens, many of which are used in chemotherapy of cancer and other chronic diseases. The population-wide, heritable damage to cells may be the source of, or may contribute to, late-occurring side effects of treatment in cancer and other chronic diseases.