In S. cerevisiae, the REV3 gene, encoding the catalytic subunit of polymerase zeta, is involved in translesion synthesis and required for the production of mutations induced by ultraviolet radiation (UV) photoproducts and other DNA fork-blocking lesions, and for the majority of spontaneous mutations. To determine whether hREV3, the human homolog of yeast REV3, is similarly involved in error-prone translesion synthesis past UV photoproducts and other lesions that block DNA replication, an hREV3 antisense construct under the control of the TetP promoter was transfected into an infinite life span human fibroblast cell strain that expresses a high level of tTAk, the activator of that promoter. Three transfectant strains expressing high levels of hREV3 antisense RNA were identified and compared with their parental cell strain for sensitivity to the cytotoxic and mutagenic effects of UV. The three hREV3 antisense-expressing cell strains were not more sensitive than the parental strain to the cytotoxic effect of UV, but the frequency of mutants induced by UV in their HPRT gene was significantly reduced, i.e. to 14% that of the parent. Two of these hREV3 antisense-expressing cell strains were compared with the parental strain for sensitivity to (+/-)-7beta,8alpha-dihydroxy-9alpha,10alpha-epoxy-7,8,9,10-tetrahydrobenzo [a]pyrene (BPDE). They were not more sensitive than the parent strain to the cytotoxic effect of BPDE, but the frequency of mutants induced was significantly reduced, i.e. in one strain, to 17% that of the parent, and in the other, to 24%. DNA sequencing showed that the kinds of mutations induced by BPDE in the parental and the derivative strains did not differ and were similar to those found previously with finite life span human fibroblasts. The data strongly support the hypothesis that hRev3 plays a critical role in the induction of mutations by UV or BPDE. Because the level of hRev3 protein in human fibroblasts is below the level of antibody detection, it was not possible to demonstrate that the decrease in mutagenesis reflected decreased hRev3 protein. However, the conclusion is supported by the fact that in a similar study with a strain expressing a high level of antisense hREV1, a very similar result was obtained, i.e. UV or BPDE mutagenesis was virtually eliminated.

O:(6)-methylguanine is responsible for homologous recombination induced by N:-methyl-N:'-nitro-N:-nitrosoguanidine (MNNG) [H. Zhang et al. (1996) CARCINOGENESIS:, 17, 2229]. To test the hypothesis that mismatch repair is causally involved in this process, we generated mismatch repair-deficient strains from a human fibroblast line containing a substrate for detecting intrachromosomal homologous recombination. The four strains selected for study exhibited greatly increased resistance to the cytotoxic effects of MNNG, which was not affected by depletion of O:(6)-alkylguanine-DNA alkyltransferase, and greatly increased sensitivity to the mutagenic effect of MNNG, suggesting that the mutagenic base modifications induced in these four cell strains by MNNG persist in their genomic DNA. Tests showed that their extracts are deficient in the repair of G:T mismatches. The frequency of homologous recombination induced by MNNG in three of these strains was significantly (5-7-fold) lower than that induced in the parental cell strain. This was not the result of a generalized defect in recombination, because when (+/-)-7beta,8alpha-dihydroxy-9alpha,10alpha-epox y-7,8,9, 10-tetrahydrobenzo[a]pyrene was used to induce recombination, all three lines responded with a normal or even a somewhat higher frequency than that observed in the parental strain. The lack of recombination displayed by the fourth strain was shown to result from the loss of part of the recombination substrate. The results strongly suggest that functional mismatch repair is required for MNNG-induced homologous recombination.

N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), which alkylates many positions in DNA including the 06 position of guanine, efficiently induces intrachromosomal homologous recombination in mouse L-cells. To investigate the role of 06-methylguanine in the induction of homologous recombination in human cells, three cell strains containing duplicated copies of the Herpes simplex virus I thymidine kinase (Htk) gene and three cell strains containing duplicated copies of the gene coding for hygromycin phosphotransferase (hyg) were treated with MNNG. Neither the Htk genes nor the hyg genes code for a functional enzyme because each contains an insertion mutation at a unique site, i.e. 8-bp XhoI linker insertions in the Htk genes and 10-bp HindIII linker insertions in the hyg genes. These cell strains differ in their level of 06-alkylguanine-DNA alkyltransferase (AGT), which specifically removes the methyl group from the 06 position of guanine. Generation of a functional Htk or hyg gene has been shown to require intrachromosomal homologous recombination between the two mutant Htk genes or the two mutant hyg genes. In all six cell strains, MNNG induced a dose-dependent increase in the frequency of homologous recombination. In each set, there was an inverse correlation between the frequency of MNNG-induced recombination and the level of AGT activity. To further study the role of 06-methylguanine in the induction of homologous recombination, we used 06-benzylguanine to inactivate AGT in two additional human cell strains containing the hyg recombination substrate. After depletion of AGT activity by 06-benzylguanine, both cell strains showed a significantly elevated level of MNNG-induced homologous recombination. These results indicate that 06-methylguanine is the principal lesion responsible for the induction of homologous recombination in these human cells by this methylating agent.