DNA strand breakage caused by dichlorvos, methyl methanesulphonate and iodoacetamide in Escherichia coli and cultured Chinese hamster cells

The DNA damaging properties of dichlorvos (2,2 dichlorovinyl dimethyl phosphate), methyl methanesulphonate (MMS) and iodoacetamide (IAA) have been studied, using alkaline sucrose sedimentation. In a strain of E. coli deficient in DNA polymerase I (polA) both dichlorvos and MMS caused random strand breakage, MMS being about twice as efficient as dichlorvos on a molar basis. In pol⁺ bacteria, DNA strand breaks or alkali labile bonds were detected following treatment with roughly five-fold higher concentrations of MMS but at similar high concentrations of dichlorvos there was an all or none breakdown of DNA molecules to fragments of very low molecular weight which correlated well with lethality.DNA synthesized after treatment of pol⁺ and polA bacteria with MMS was of low molecular weight, indicating the presence of discontinuities. With dichlorvos, the effect was much smaller.Apparent all-or-none DNA breakdown was also found when the polA strain of E. coli was treated with low concentrations of iodoacetamide, an agent that does not detectably alkylate DNA. At higher concentrations the breakdown was suppressed and random strand breakage occurred instea. These effects did not occurr with pol⁺ bacteria and correlated well with the greater sensitivity to iodoacetamide of the polA strain in survival experiments. We suggest that the major DNA damage resulting from treatment with iodoacetamide and dichlorvos arises indirectly through alkylation of other cellular constituents and consequent uncontrolled nuclease attack on the DNA. Discontinuities in newly synthesized DNA and mutagenesis following dichlorvos treatment, however, presumably result from direct alkylation of DNA.Strand breakage caused by dichlorvos and MMS in Chinese hamster cells tended to correlate with the extent to which these agents alkylate DNA, but survivval tended to correlate with the alkylation of protein.