Purpose: To employ the gamma-radiation-generated selenium(V) one-electron-oxidizing agent SeO3*- for the preparation of guanyl radicals in plasmid DNA, and to compare the behaviour of this reagent with that of other similarly reactive oxidant species.
Materials and methods: Plasmid DNA in aerobic aqueous solution was irradiated with 137Cs gamma-rays (662 keV). The solutions also contained up to 4x10(-2) mol x dm(-3) sodium selenate (Na2SeO4) and/or up to 10(-1) mol x dm(-3) sodium biselenite (NaHSeO3), as well as auxiliary scavengers such as DMSO or glycerol. In some cases, reducing agents such as ferrocyanide were also present. After irradiation, the plasmid was incubated with the Escherichia coli base excision-repair endonuclease formamidopyrimidine-DNA N-glycosylase (FPG). These treatments produced strand breaks in the plasmid. The yields of these strand breaks were quantified by agarose gel electrophoresis.
Results: In general, gamma-irradiation produced single-strand breaks (SSB) in plasmid DNA. Subsequent incubation with the endonuclease FPG increased the SSB yield by a factor of 2-100-fold. The smallest effects of FPG were observed when only DMSO or glycerol were present during irradiation. FPG incubation produced significantly larger increases in the SSB yield after gamma-irradiation in the additional presence of selenate and/or biselenite. The largest effect of FPG was observed after gamma-irradiation in the presence of 10(-2) mol x dm(-3) sodium selenate and 10(-1) mol x dm(-3) glycerol. This was indicative of extensive oxidative damage to the plasmid under these conditions and provided evidence for guanine oxidation mediated by SeO3*-. The large effect of FPG was strongly attenuated by the addition of reducing agents such as ferrocyanide. The observations suggest that these reducing agents exert their effects through the reduction of an intermediate guanyl radical.
Conclusion: By comparing the yields of breaks produced after gamma-irradiation under a range of conditions, it is possible to formulate a reaction scheme that describes the chemical reactions responsible for the formation of strand breaks and FPG-sensitive sites. By applying this scheme to the data, we can quantify rate constants for the reduction of DNA guanyl radicals by reducing agents. This reaction is of particular interest to radiation biology because it is the equivalent of the repair of DNA damage by the direct effect of ionizing radiation.