Some chemical aspects of dose-response relationships in alkylation mutagenesis

Alkylation of DNA can lead to induction of potentially miscoding groups (promutagenic) or potentially template-inactivating groups (lethal). The proportions of these are found to vary with the chemical nature of the alkylating agent. Agents of low Swain and Scott s factor (or those tending to Ingold's S_Ni type) react relatively more extensively at O-atom sites in DNA, and yield relatively more of the miscoding O₆-alkylguanine residues. Phosphotriester formation is also relatively more extensive with S_Ni agents.Inactivation of DNA can result from depurinations, strand breakage, and cross-linkage.Both promutagenic and lethal lesions are subject to repair; 3 principal enzymatic systems appear to exist; one for excision and repair of cross-links or aralkyl groups resembles the uvr system; others for repair of single-strand breaks parallel repair of X-ray-induced breaks (exr, rec systems); another, less well defined at present, recognizes certain methylated bases, and depurinated sites (probably Goldthwait's endonuclease II).These factors can be shown to influence dose-response in alkylation mutagenesis. This, broadly, can be classified as linear with the promutagenic group-inducing or directly miscoding agents, and is independent of cytotoxicity; whereas with other agents non-linear response parallels the occurrence of “shouldered” survival curves, and reflects mutation induction by “repairs errors”.Additionally, alkylation of cellular constituents other than DNA, e.g. repair enzymes, may influence dose response, and will again depend on chemical reactivity of the agent.