In the presence of Cu(II) ions, supercoiled DNA is cleaved in neutral solution by low concentrations of thiols. Supercoiled plasmid DNA is cleaved first to open circular DNA, which in turn produces linear DNA and eventually fragments. Cleavage is strongly temperature-dependent and is maximal at 0.10-0.25 M-NaCl concentration. In the presence of excess of either component of the Cu(II)-thiol pair, the extent of cleavage depended on the concentration of the limiting partner, and was easily detectable down to micromolar concentrations of limiting GSH. Scavengers of oxygen-derived species (such as hydrogen peroxide, superoxide radical ion and hydroxyl radical) indicated that the hydroxyl radical may be involved in the cleavage mechanism. DNA cleavage leads to some production of 2-thiobarbituric acid-reactive species and some of the cleavage sites, at least, had 5'-hydroxy and/or 3'-hydroxy groups. There was extensive base damage before cleavage. Studies with S1 nuclease indicated no gross sequence preference for Cu(II)-GSH cleavage of pSP64 plasmid DNA. The Cu(II)-thiol system did not appear to target special structural features in the DNA such as Z-DNA inserts, cruciform structures or left-handed (but non-Z) DNA. Cleavage might arise from a reagent generated either by the Cu(II)-thiol combination in free solution or by attack involving Cu(II) ions pre-bound to DNA. The attack of GSH plus Cu(II) ions on DNA may be a potential toxic lesion under physiological conditions unless special protective measures operate efficiently in the cell.