Abstract
Multiply damaged sites (MDSs) are generated in DNA by ionizing radiation. In vitro studies predict that base excision repair in cells will convert MDSs to lethal double strand breaks (DSBs) when two opposing base damages are situated >/=2 bp apart. If the lesions are situated immediately 5' or 3' to each other, repair is predicted to occur sequentially due to inhibition of the DNA glycosylase by a single strand break repair intermediate. In this study, we examined how the distance between two opposing lesions alters the mutation frequency of an 8-oxodG in an MDS, and whether repair generates DSBs and deletions in bacteria. The 8-oxodG mutation frequency declined in MutY-deficient bacteria when the opposing 8-oxodG was 6 bp away, and was similar to a single 8-oxodG when the lesions were separated by 14 bp. However, the number of deletions detected for the MDSs was equivalent to the undamaged sequence. Using a separate assay, MDSs consisting of two 8-oxodG or an 8-oxodG opposite a uracil were not converted to DSBs in the absence of DNA replication in wild-type and transcription-coupled repair-deficient bacteria. This is the first study showing that DSB-repair intermediates and deletions are not formed during repair of clustered 8-oxodGs in cells.