DFT mechanistic study on the formation of 8-oxoguanine and spiroiminodihydantoin mediated by iron Fenton reactions

Fenton reactions unavoidably take place in the human body and have been demonstrated to cause oxidative DNA damage. However, the molecular-level understanding of DNA damage mediated by Fenton reactions is limited. Herein, density functional theory (DFT) calculations were made to investigate the counterion effects on aqueous Fenton reactions and the detailed mechanisms of chemical modifications to guanine induced by Fenton reactions. Our calculations show that the activation energy of the Fenton reaction catalyzed by a pure aquo complex [Fe-II(H2O)(6)](2+) is too high to agree with experiments, whereas complexation with counteranions reduces the activation energy to a reasonable range. This result suggests that Fe-II-counteranion complexes are the real catalyst for fast aqueous Fenton reactions. In addition, we found that the Fenton oxidation mediated by Fe-II bonded to the N7 atom of guanine can result in the formation of 8-oxoguanine and spiroiminodihydantoin through multiple reaction pathways, including the electrophilic addition of OH, H-abstraction by OH, and oxygen atom transfer of oxoiron(iv) species. The activation of hydrogen peroxide by ferrous iron is the rate-determining step. The guanine N7-bound iron ion and the coordinated counteranion were found to play an important role in the Fenton oxidation of guanine.

Automated summary

The study investigated the counterion effects on aqueous Fenton reactions and the chemical modifications to guanine induced by Fenton reactions using density functional theory (DFT) calculations. The results suggest that Fe-II-counteranion complexes are the real catalyst for fast aqueous Fenton reactions and the guanine N7-bound iron ion and the coordinated counteranion play important roles in the Fenton oxidation of guanine.