Gas phase ion chemistry of charged silver(I) adenine ions via multistage mass spectrometry experiments and DFT calculations.

Electrospray ionization (ESI) of solutions containing adenine and AgNO(3) yields polymeric Ad(x)+ Ag(y)-zH species. Density functional theory (DFT) calculations have been used to examine potential structures for several of the smaller ions while multistage mass spectrometry experiments have been used to probe their unimolecular reactivity (via collision-induced dissociation (CID)) and bimolecular reactivity (via ion-molecule reactions with the neutral reagents acetonitrile, methanol, butylamine and pyridine). DFT calculations of neutral adenine tautomers and their silver ion adducts provide insights into the binding modes of adenine. We find that the most stable Ad + Ag ion does not correspond to the most stable neutral adenine tautomer, consistent with previous studies that have shown that transition metal ions can stabilize rare tautomeric forms of nucleobases. Both the charge and the stoichiometry of the Ad(x)+ Ag(y)-zH complexes play pivotal roles in directing the types of fragmentation and ion-molecule reactions observed. Thus, Ad(2)+ Ag(2) is observed to dissociate to Ad + Ag and to react with butylamine via proton transfer, while Ad(2)+ Ag(2)- H fragments via loss of neutral adenine to form the Ad + Ag(2)- H ion and does not undergo proton transfer to butylamine. DFT calculations on several isomeric Ad(2)+ Ag(2) ions suggest that planar centrosymmetric cations, in which two adjacent silver atoms are bridged by two N7H adenine tautomers via N(3),N(9)-bidentate interactions, are the most stable. The Ad + Ag(2)-H ion adds two neutral reagents in ion-molecule reactions, consistent with the presence of two vacant coordination sites. It undergoes a silver atom loss to form the Ad + Ag - H radical cation, which in turn fragments quite differently to the even electron Ad + Ag ion. Several other pairs of radical cation/even electron adenine-silver complexes were also found to undergo different fragmentation reactions.