Ethanol radicals and nucleic acid alkylation studies in vitro and in vivo studies

Alcohol consumption has been associated with increased cancer risk and an oxidative stress condition. Ethanol metabolites responsible for these processes remain debatable. Here, we characterized novel radical metabolites of ethanol and examined their interactions with nucleic acids. First, we demonstrated that the 1-hydroxyethyl and 2-hydroxyethyl radical produced from ethanol oxidation by Fenton systems alkylated DNA and RNA in vitro to produce 8-(1HE)Gua and 8-(2-HE)Gua, respectively. Both adducts were synthesized and structurally characterized. Next, we demonstrated that acetaldehyde, the main ethanol metabolite, is oxidized by Fenton systems, peroxynitrite, xanthine oxidase, submitochondrial particles and whole rats to acetyl and methyl radicals. These radicals were characterized and their production mechanisms in vitro elucidated. The possibility of the 1-hydroxyethyl radical alkylating nucleic acids in vivo was also examined. Unexpectedly, the adduct 8-(1-HE)Gua was detected in RNA and DNA from liver of control rats and their levels were not increased by acute ethanol treatment. Overall, the results suggest that the radicals 1-hydroxyethyl, acetyl and methyl are important ethanol metabolites in vivo but they preferentially attack biomolecules other than nucleic acids. (AU)