Hydrogen Evolution Facilitates Reduction of DNA Guanine Residues at the Hanging Mercury Drop Electrode:Evidence for a Chemical Mechanism

• Autoři: DAŇHEL Aleš; HAVRAN Luděk; TRNKOVÁ Libuše; FOJTA Miroslav
• Rok publikování: 2016
• Druh: Článek v odborném periodiku
• Časopis / Zdroj: Electroanalysis
• Fakulta / Pracoviště MU: Středoevropský technologický institut
• www: http://onlinelibrary.wiley.com/doi/10.1002/elan.201600242/full
• Doi: http://dx.doi.org/10.1002/elan.201600242
• Obor: Analytická chemie, separace
• Klíčová slova: guanine; DANN; cisplatin; mercury electrode; catalytic hydrogen evolution; electrochemical reduction; chemical reduction; cyclic voltammetry
• Popis: Guanine (G), as well as G residues in nucleosides, nucleotides and nucleic acids, undergo chemically reversible (but electrochemically irreversible) reduction/oxidation processes at the mercury-based electrodes. It has been established that G is reduced to 7,8-dihydroguanine at highly negative potentials. The reduction product is oxidized back to G around -0.25V, giving rise to anodic peak G. Previous studies suggested involvement of a chemical mechanism involving electrochemically generated hydrogen radicals in the G reduction process. In this work we studied effects of cisplatin and pH on the G reduction process. We have found that catalytic hydrogen evolution accompanying electrochemical reduction of cisplatin markedly facilitates reduction of G. Minimum negative potential required for G reduction were shifted to less negative values and correlated with the onset of catalytic currents of cisplatin. Analogous shifts of the potential of G reduction were observed upon lowering pH of the background electrolyte (i.e., increasing the availability of protons to generate hydrogen radicals). Ammonium ions markedly increased efficiency of G reduction, which may be explained by generation of active hydrogen via formation and subsequent decomposition of ammonium amalgam. Our results strongly suggest that chemical mechanism(s) involving hydrogen radicals, electrochemically and/or electrocatalytically generated at the HMDE, contribute to the guanine 7,8-dihydroguanine conversion.