Induction and processing of promutagenic O4-ethylthymine lesion in specific gene segments of plasmid DNA

Site-specific induction and repair of benzo[a]pyrene diol epoxide DNA damage in human H-ras protooncogene as revealed by restriction cleavage inhibition

Most genotoxic DNA base modifications localized at key genomic sequences constitute the molecular alterations crucial or mutagenesis and tumorigenesis. We have utilized lesion-rendered inhibition of restriction endonuclease cleavage for the analysis of site-specific DNA damage induced by (+/-)-7,8-dihydroxy-anti-9, 10-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene (benzo[a]pyrene diol epoxide, anti-BPDE) in human genes. The H-ras protooncogene and insulin gene sequences were used as targets for modification in vitro and in vivo. Selective induction of individual facultative bands, resulting from covalent modification of the cognate recognition sites, was observed in modified plasmid DNA for a number of restriction nucleases. The ras gene-specific damage, at the PstI, BstYI, NotI and BstEII recognition sites, was visualized and quantitated in human genomic DNA adducted by anti-BPDE. Repair of lesions at hexanucleotide sequences and/or regions surrounding the restriction site, was assessed as a gradual disappearance of facultative bands in DNA from repair-proficient human fibroblasts exposed to the carcinogen in confluent culture. Efficiency of the PstI site-specific repair was compared at low and high levels of initial damage. Higher genotoxic dose caused a decrease in the extent of adduct removal from the bulk DNA, while the specific site of the ras gene was still subject to fast repair. No measurable PstI site-specific repair was detected in the insulin gene. These results show the region-selective induction of bulky anti-BPDE DNA damage in non-related genomic targets and suggest that repair of these lesions in human cells proceeds with the efficiency tightly controlled at different levels of initial genotoxic load.

Repair of base alkylation damage in targeted restriction endonuclease sequences of plasmid DNA

Sequence specific ethylation damage and repair of ethyl-adducts in selected restriction endonuclease recognition sites within p220-ras plasmid DNA was assessed by a modified Southern blotting coupled immunoprobing technique. In situ UV irradiation of DNA in gels clearly ameliorated the immunodetection of minute amounts of facultative fragments generated due to inhibition of enzyme cleavage site by covalent alkylation modification of the cognate sites. Specific and quantitative localization of induced facultative fragments was achieved in as low as 1 ng of DNA digest corresponding to a peak intensity below 0.1 absorbance unit upon laser scanning. An ENU dose dependent increase in the intensity of representative 7.1 and 7.7 kb facultative fragments was observed as a result of cleavage block at EcoRI (G/ATTC) and BamHI (G/GATCC) restriction endonuclease sites, respectively. To determine the repair in prokaryotic cells, the half-life of repairable alkyl-adducts was assessed in plasmid DNA established in various Escherichia coli strains as a function of post-treatment incubation time in the recovery medium. The repair is indicated by the gradual disappearance of the 7.1, 7.7, 11.9 and 5.5 kb facultative fragments within the wild-type and mutant E. coli strains. The ethyl-adducts within EcoRI and BamHI restriction sites were effectively lost from the target DNA in repair-proficient E. coli with an estimated t1/2 of approximately 40 min. However, decreased overall rate and at least 2.2-times lesser extent of repair was observed in the repair-deficient (ada+ogt-) and (ada-ogt+) cells. No measurable repair was noticed in alkyltransferase defective double mutant (ada-ogt-) even after 2 h of post-treatment incubation. The repair of ethyl-adducts at NotI site (GC/GGCCGC) in 5.5 kb facultative fragment occurred at a relatively faster rate (t1/2 of 27 min) in wild-type bacteria. A 1.5-fold slower repair of ethyl-adducts in BamHI and EcoRI sequences containing G/G and A/G at their cleavage sites was observed compared to C/G in NotI sequence. These results demonstrate the regioselective induction of alkyl-adducts in ethylated DNA and their differential repair in E. coli due to varied efficiency of the repair enzymes for promutagenic DNA base lesions present in different sequence context.