Lack of phenotypic alteration of hmUra-DNA glycosylase-deficient hamster cells exposed to DNA-damaging agents.

V79mut1 cells are resistant to the toxic effects of 5-hydroxymethyl-2'-deoxyuridine (hmdUrd) and are deficient in the DNA repair enzyme hydroxymethyluracil-DNA glycosylase (hmUDG). We have therefore proposed that the toxicity of hmdUrd results from the repair of the lesion from DNA. In order to clarify the biological role of hmUDG, we have determined whether the repair-deficient cells showed resistance or sensitivity to the toxic or mutagenic effects of other DNA-damaging agents. Cells were exposed to hmdUrd, ionizing or ultraviolet radiation, to the alkylating agent MNNG, and to oxidative stress produced by hypoxanthine/xanthine oxidase, glucose/glucose oxidase, nitric oxide donor SNAP, or to H2O2. The V79mut1 cells did not show increased mutagenesis in response to hmdUrd. Relative to the V79 parent cells, the V79mut1 cells were not markedly altered in sensitivity to oxidizing agents and ionizing radiation (which produce hmdUra in DNA). The repair-deficient cells wee equally sensitive as the parent V79 cells to DNA damage induced by ultraviolet radiation or by MNNG. No significant differences were seen between the parent and the repair-deficient cells in terms of synthesis of poly(ADP-ribose) in response to damage or in their sensitization to 3-aminobenzamide. Thus, the loss of the 5-hydroxymethyluracil (hmUra)-DNA glycosylase activity in mammalian cells in culture confers no obvious deleterious effect on cell survival or mutagenicity in response to a wide range of DNA damage. These studies indicate that the major lesion known to be repaired by hmUra-DNA glycosylase, an hmUra residue replacing thymine, is produced in cells only in small quantities as the result of exposure to common DNA-damaging agents. These results raise the possibility that hmUra-DNA glycosylase may have evolved to respond to other lesions than hmUra residues formed from the oxidation of thymine.

Toxicity of camptothecin to Chinese hamster cells containing 5-hydroxymethyl-2'-deoxyuridine in their DNA.

5-Hydroxymethyl-2'-deoxyuridine (hmdUrd) is incorporated into the DNA of V79 Chinese hamster cells as an analogue of thymidine. Incorporated residues are then recognized and excised by hmUra-DNA glycosylase (hmUDG). The removal of large numbers of hmUra residues and subsequent strand breakage is cytotoxic, as has been demonstrated by our finding that a mutant cell line, which is deficient in this enzyme, is resistant to hmdUrd (Boorstein et al., 1992a). In order to determine whether topoisomerase I plays a role in hmUDG initiated base excision repair, V79 cells and repair deficient V79mut1 cells were exposed to combinations of hmdUrd and the topoisomerase I inhibitors camptothecin (CPT), CPT-11, and beta-lapachone. Treatment of V79 cells with hmdUrd followed by non-toxic concentrations of camptothecin or CPT-11 showed significant enhancement of the baseline cytotoxicity of the hmdUrd alone. In contrast, camptothecin and CPT-11 had no effect in combination with hmdUrd in the V79mut1 cells. Non-toxic concentrations of beta-lapachone, which inhibits topoisomerase I by a different mechanism than camptothecin and CPT-11, produced no synergistic toxicity in V79 cells. Neither camptothecin nor CPT-11 inhibited removal of hmdUrd from hmdUrd treated cells, nor did they affect hmdUrd-induced poly(ADP-ribose) synthesis. Camptothecin did not alter the cell cycle distribution of either hmdUrd treated cells or untreated cells at concentrations sufficient to cause synergistic toxicity with hmdUrd. Results from our study indicate that the utility of topoisomerase I inhibitors may be enhanced by sensitizing cells with hmdUrd initiated repair activity which arrests cells in S-phase and produces DNA lesions that are further converted into lethal damage by camptothecin.