The possibility was examined that mutational events at the glucose 6-phosphate dehydrogenase locus can be delayed for significantly more than one or two cell divisions following treatment of Chinese hamster cells with UV light. To detect these later mutant events, the proportion of G6PD-mutant cells in a colony was obtained by replating cells from a single colony 5-7 days after UV irradiation and staining the resulting colonies for G6PD activity. Eight colonies out of a total of 1657 colonies from the treated population yielded G6PD-negative colonies upon replating, while no mutant clones were obtained from 947 colonies grown from untreated cells. One clone contained only mutant cells suggesting that the mutation occurred before the first cell division after irradiation. A second clone contained a 1:1 ratio of mutant to wild-type cells suggesting that the mutation occurred at the first cell division. The remaining six clones contained low numbers of mutant cells and the ratio of mutant to wild-type cells in these clones was in agreement with the theoretical ratios expected for mutations occurring at the fourth (1:13), sixth (1:63), seventh (1:127), eighth (1:255), ninth (1:511), and eleventh (1:2047) cell division after UV light exposure. G6PD-mutant cells deficient in staining activity were isolated from five clones and all have significant reductions in G6PD activity confirming the genetically stable character of these mutants. These results support the conclusion that UV light induces mutants for up to 11 cell generations after treatment of mammalian cells and suggest that mutagens can induce in mammalian DNA long-term alterations which act to increase the apparently spontaneous mutation frequency.