Stereoselective excision of thymine glycol from oxidatively damaged DNA.

DNA damage created by reactive oxygen species includes the prototypic oxidized pyrimidine, thymine glycol (Tg), which exists in oxidatively damaged DNA as two diastereoisomeric pairs. In Escherichia coli, Saccharomyces cerevesiae and mice, Tg is preferentially excised by endonuclease III (Endo III) and endonuclease VIII (Endo VIII), yNTG1 and yNTG2, and mNTH and mNEIL1, respectively. We have explored the ability of these DNA glycosylases to discriminate between Tg stereoisomers. Oligonucleotides containing a single, chromatographically pure (5S,6R) or (5R,6S) stereoisomer of Tg were prepared by oxidation with osmium tetroxide. Steady-state kinetic analyses of the excision process revealed that Endo III, Endo VIII, yNTG1, mNTH and mNEIL1, but not yNTG2, excise Tg isomers from DNA in a stereoselective manner, as reflected in the parameter of catalytic efficiency (kcat/Km). When DNA glycosylases occur as complementary pairs, failure of one or both enzymes to excise their cognate Tg stereoisomer from oxidatively damaged DNA could have deleterious consequences for the cell.

Stereoselective excision of thymine glycol lesions by mammalian cell extracts.

Thymine glycols (Tg) are major pyrimidine oxidation products produced by chemical agents and ionizing radiation. Recent improvements in purification procedures gave us the opportunity to examine the incision of DNA duplexes containing a single (5S,6R)- or (5R,6S)-Tg lesion by mouse NTH1 DNA glycosylase and mammalian cell nuclear extracts. Time course experiments and steady state enzyme kinetics indicated that mNTH1 discriminates between the cis-Tg isomers. In addition, a variety of mammalian cell nuclear extracts showed a similar discrimination between the cis-Tg isomers. Trapping of Schiff base intermediates with sodium borohydride demonstrated that a single protein-DNA complex was formed in the presence of the nuclear extracts. The electrophoretic mobility of trapped complexes formed with both Tg isomers was identical to one another and similar to that of the complex formed with recombinant mNTH1. These results suggest that among all Tg-active DNA glycosylases, NTH1 is the major enzyme in mammalian cell nuclear extracts responsible for incision of duplexes containing cis-Tg isomers.