3868-32-4Relevant articles and documents
Chemistry of the 8-Nitroguanine DNA Lesion: Reactivity, Labelling and Repair
Alexander, Katie J.,McConville, Matthew,Williams, Kathryn R.,Luzyanin, Konstantin V.,O'Neil, Ian A.,Cosstick, Richard
, p. 3013 - 3020 (2018/02/09)
The 8-nitroguanine lesion in DNA is increasingly associated with inflammation-related carcinogenesis, whereas the same modification on guanosine 3′,5′-cyclic monophosphate generates a second messenger in NO-mediated signal transduction. Very little is known about the chemistry of 8-nitroguanine nucleotides, despite the fact that their biological effects are closely linked to their chemical properties. To this end, a selection of chemical reactions have been performed on 8-nitroguanine nucleosides and oligodeoxynucleotides. Reactions with alkylating reagents reveal how the 8-nitro substituent affects the reactivity of the purine ring, by significantly decreasing the reactivity of the N2 position, whilst the relative reactivity at N1 appears to be enhanced. Interestingly, the displacement of the nitro group with thiols results in an efficient and specific method of labelling this lesion and is demonstrated in oligodeoxynucleotides. Additionally, the repair of this lesion is also shown to be a chemically feasible reaction through a reductive denitration with a hydride source.
Formation and reactions of N7-aminoguanosine and derivatives
Guengerich, F. Peter,Mundkowski, Ralf G.,Voehler, Markus,Kadlubar, Fred F.
, p. 906 - 916 (2007/10/03)
Arylamines are mutagens and carcinogens and are thought to initiate tumors by forming adducts with DNA. The major adducts are C8-guanyl, and we have previously suggested a role for guanyl-N7 intermediates in the formation process. N7-Aminoguanosine (Guo) was synthesized and characterized, with the position of the NH2 at N7 established by two- dimensional rotating frame Overhauser enhancement NMR spectroscopy. In DMF, N7-NH2Guo formed C8-NH2Guo and the cyclic product C8:5'-O-cycloGuo. In aqueous media, these products were formed along with 8-oxo-7,8-dihydroGuo, N7-NH2guanine, and a product characterized as a purine 8,9-ring-opened derivative (N-aminoformamidopyrimidine). The rate of aqueous decomposition of N7-NH2Guo increased with pH, with a t( 1/2 ) of 10 h at pH 7 and a t( 1/2 ) of 2 h at pH 9. The rate of migration of NH2 from N7 to C8 is fast enough to explain the formation of C8-NH2Guo from the reaction of 2,4- dinitrophenoxyamine with Guo but not the formation of C8-(arylamino)Guo in the reaction of Guo with aryl hydroxylamine esters; however, the fluorenyl moiety may facilitate the proposed rearrangement by stabilizing an incipient negative charge in the transfer. In the reaction of Guo with N-hydroxy-2- aminofluorene and acetylsalicylic acid, a peak with the mass spectrum expected for N7-(2-aminofluorenyl)Guo was detected early in the reaction and was distinguished from C8-(2-aminofluorenyl)Guo. NMR experiments with [8- 13C]Guo also provided some additional support for transient formation of N7-(2-aminofluorenyl)Guo. We conclude that a guanyl-N7 intermediate is reasonable in the reaction of activated arylamines with nucleic acids, although an exact rate of transfer of an N7-arylamine group to the C8 position has not yet been quantified. The results provide an explanation for the numerous products associated with modification of DNA by activated arylamines. However, the contribution of 'direct' reaction at the guanine C8 atom cannot be excluded.