Oxidation and Glycolytic Cleavage of Etheno and Propano DNA Base Adducts†

[Image: see text] Non-invasive strategies for the analysis of endogenous DNA damage are of interest for the purpose of monitoring genomic exposure to biologically produced chemicals. We have focused our research on the biological processing of DNA adducts and how this may impact the observed products in biological matrixes. Preliminary research has revealed that pyrimidopurinone DNA adducts are subject to enzymatic oxidation in vitro and in vivo and that base adducts are better substrates for oxidation than the corresponding 2′-deoxynucleosides. We tested the possibility that structurally similar exocyclic base adducts may be good candidates for enzymatic oxidation in vitro. We investigated the in vitro oxidation of several endogenously occurring etheno adducts [1,N(2)-ε-guanine (1,N(2)-ε-Gua), N(2),3-ε-Gua, heptanone-1,N(2)-ε-Gua, 1,N(6)-ε-adenine (1,N(6)-ε-Ade), and 3,N(4)-ε-cytosine (3,N(4)-ε-Cyt)] and their corresponding 2′-deoxynucleosides. Both 1,N(2)-ε-Gua and heptanone-1,N(2)-ε-Gua were substrates for enzymatic oxidation in rat liver cytosol; heteronuclear NMR experiments revealed that oxidation occurred on the imidazole ring of each substrate. In contrast, the partially or fully saturated pyrimidopurinone analogues [i.e., 5,6-dihydro-M(1)G and 1,N(2)-propanoguanine (PGua)] and their 2′-deoxynucleoside derivatives were not oxidized. The 2′-deoxynucleoside adducts, 1,N(2)-ε-dG and 1,N(6)-ε-dA, underwent glycolytic cleavage in rat liver cytosol. Together, these data suggest that multiple exocyclic adducts undergo oxidation and glycolytic cleavage in vitro in rat liver cytosol, in some instances in succession. These multiple pathways of biotransformation produce an array of products. Thus, the biotransformation of exocyclic adducts may lead to an additional class of biomarkers suitable for use in animal and human studies.