Expression of the Drosophila melanogaster S3 ribosomal/repair protein in T24 human bladder cells.

Repair of 8-oxo-7,8-dihydroguanine (8-oxoG) is inefficient in human cells due to the poor catalytic properties of hOGG1, the major DNA glycosylase involved in the removal of this oxidized base. The S3 ribosomal/repair protein from Drosophila melanogaster (dS3) is endowed with a potent 8-oxoG glycolytic activity coupled with a beta, delta-AP lyase. In vitro repair experiments have shown that pure GST-tagged dS3 can stimulate a > 40-fold increase in the rate of 8-oxoG repair by human cell extracts. In this study, we expressed dS3 fused to the Enhanced Green Fluorescent Protein (EGFP) in T24 human bladder cells in order to accelerate the repair of 8-oxoG in vivo. Limiting dilution and Fluorescence-Activated Cell Sorting (FACS) were used in an effort to isolate cells with elevated EGFP-dS3 expression; however, the cells that were isolated invariably had severe growth impairment. Curiously, EGFP-dS3 expression was slightly increased after recovering cells from liquid nitrogen, but it was not possible under those conditions to achieve a significant acceleration of 8-oxoG repair. The data confirm and extend our previous results obtained with Chinese hamster CHO cells and indicate that elevated expression of dS3 may be toxic to at least some types of mammalian cells, thus limiting its use in vivo as a protective factor against oxidative DNA damage.

Effect of S. cerevisiae APN1 protein on mammalian DNA base excision repair.

Mammalian cells transfected with the S. cerevisiae APN1 protein acquire resistance to oxidizing agents, the damage of which is mainly repaired via DNA base excision repair (BER). We have recently hypothesized that this effect might be linked to the possible capacity of APN1 to accelerate mammalian BER by its 3' diesterase activity. We have investigated here the effect of pure APN1 protein on BER performed by mouse embryonic fibroblast extracts. No significant acceleration was observed in the repair of either a single AP site cleaved by the bifunctional glycosylase NTH of E. coli or the repair of a single 8-oxoguanine, initiated by the bifunctional glycosylase OGG1. Similarly, no significant effect was observed on the repair of a single U (initiated by the monofunctional glycosylase U DNA glycosylase) or the repair of a single natural abasic site. The inability of APN1 to increase the efficiency of BER initiated by bifunctional glycosylases indicates that removal of 3' blocking fragments is not the rate-limiting step of this repair pathway.

Time-course of spontaneous transformation of CD-1 mouse embryonic fibroblasts.

The spontaneous transformation of cultured mouse embryonic fibroblasts (MEF) from the outbred CD-1 mouse strain was investigated. Four MEF clones, obtained from four different mouse embryos, were cultured continuously for periods ranging from 300 to 400 days. MEF cells entered a "crisis" with acute loss of proliferation capacity after 16 +/- 2 days of culture. Surviving cells gradually acquired properties of transformed cells with the following times: the capacity to grow at a cell density of 10(5) cells/cm2 was acquired after 269 +/- 45 days. Twenty-five % anchorage-dependent colony forming ability was observed after 255 +/- 39 days. 0.5% anchorage-independent colony forming ability was observed after 290 +/- 54 days. Protective factors capable of significantly delaying the above events might be investigated with the MEF system.

Incision of AP sites in lung cancer patients: a pilot study.

DNA base excision repair (BER) removes frequent DNA lesions of either endogenous or exogenous origin. Some indications point to BER defects in lung cancer patients. We have investigated the ability of ten lung cancer patients to repair natural AP sites, the most frequent genetic lesion, using an in vitro assay in which peripheral blood lymphocytes (PBL) extracts incise randomly depurinated plasmid DNA. The median value of repair activity in patients was lower than that of matched controls but the difference did not reach significance. Unlike other BER enzymatic steps, marked defects in incision of AP sites may not be associated with lung carcinogenesis.

Effect of S. cerevisiae APN1 protein on mammalian DNA base excision repair.

Mammalian cells transfected with the S. cerevisiae APN1 protein acquire resistance to oxidizing agents, the damage of which are mainly repaired via DNA base excision repair (BER). We have recently hypothesized that this effect might be linked to the possible capacity of APN1 to accelerate mammalian BER by its 3' diesterase activity. We have investigated here the effect of pure APN1 protein on BER performed by mouse embryonic fibroblast extracts. No significant acceleration was observed in the repair of either a single AP site cleaved by the bifunctional glycosylase NTH of E. coli or the repair of a single 8-oxoguanine, initiated by the bifunctional glycosylase OGG1. Similarly, no significant effect was observed on the repair of a single U (initiated by the monofunctional glycosylase U DNA glycosylase) or the repair of a single natural abasic site. The inability of APN1 to increase the efficiency of BER initiated by bifunctional glycosylases indicates that removal of 3' blocking fragments is not the rate limiting step of this repair pathway.