Electron ionization of the nucleobases adenine and hypoxanthine near the threshold: a combined experimental and theoretical studyElectronic supplementary information (ESI) available: The other minor cations of adenine and hypoxanthine including their experimentally determined AEs as well as the calculated (B3LYP/6-311+G(2d,p)) absolute energies and zero-point corrected energies (ZPE) of the most stable cations and neutral conformers of adenine and hypoxanthine. See DOI: 10.1039/c4cp03452j

Electron ionization of the DNA nucleobase, adenine, and the tRNA nucleobase, hypoxanthine, was investigated near the threshold region (∼5-20 eV) using a high-resolution hemispherical electron monochromator and a quadrupole mass spectrometer. Ion efficiency curves of the threshold regions and the corresponding appearance energies (AEs) are presented for the parent cations and the five most abundant fragment cations of each molecule. The experimental ionization energies (IEs) of adenine and hypoxanthine were determined to be 8.70 ± 0.3 eV and 8.88 ± 0.5 eV, respectively. Quantum chemical calculations (B3LYP/6-311+G(2d,p)) yielded a vertical IE of 8.08 eV and an adiabatic IE of 8.07 eV for adenine and a vertical IE of 8.51 eV and an adiabatic IE of 8.36 eV for hypoxanthine, and the lowest energy optimized structures of the fragment cations and their respective neutral species were calculated. The enthalpies of the possible reactions from the adenine and hypoxanthine cations were also obtained computationally, which assisted in determining the most likely electron ionization pathways leading to the major fragment cations. Our results suggest that the imidazole ring is more stable than the pyrimidine ring in several of the fragmentation reactions from both adenine and hypoxanthine. This electron ionization study contributes to the understanding of the biological effects of electrons on nucleobases and to the database of the electronic properties of biomolecules, which is necessary for modeling the damage of DNA in living cells that is induced by ionizing radiation. These experiments near the threshold combined with computations significantly contribute to the understanding of the electron ionization pathways of adenine and hypoxanthine.