Preferential localization of DNA damage induced by depurination and bleomycin in a plasmid containing a scaffold-associated region.

Recent evidence suggests that DNA damage of various origins is not randomly distributed in the genome but appears to be clustered in unidentified hypersensitive regions of the chromatin. A model was proposed that stipulates that unpaired DNA stretches, such as those found in scaffold- (or matrix)-associated regions (SARs) under torsional strain, are candidate regions of hypersensitivity to DNA damage in vivo. In this study, we assessed in vitro the relative susceptibility of supercoiled plasmids containing a SAR or chromatin loop DNA segment to DNA damage induced by acid-catalyzed depurination or FeIII-bleomycin. Single-strand specific S1 nuclease was used in combination with 3'-end-labeling to detect single-strand breaks or gaps, after cleavage of abasic sites or removal of 3'-phosphoglycolates by Escherichia coli endonuclease IV. The optimal conditions of DNA cleavage specificity by S1 nuclease were determined. Using these conditions, the DNA cleavage patterns obtained showed (i) a preferential localization of S1 hypersensitive sites in the SAR DNA as compared with plasmid or chromatin loop DNA and (ii) a strikingly similar localization of DNA damage with the two clastogenic treatments.