Influence of d Orbital Occupation on the Binding of Metal Ions to Adenine

Abstract

Threshold collision-induced dissociation of M⁺(adenine) with xenon is studied using guided ion beam mass spectrometry. M⁺ includes all 10 first-row transition metal ions: Sc⁺, Ti⁺, V⁺, Cr⁺, Mn⁺, Fe⁺, Co⁺, Ni⁺, Cu⁺, and Zn⁺. For the systems involving the late metal ions, Cr⁺ through Cu⁺, the primary product corresponds to endothermic loss of the intact adenine molecule, whereas for Zn⁺, this process occurs but to form Zn + adenine⁺. For the complexes to the early metal ions, Sc⁺, Ti⁺, and V⁺, intact ligand loss competes with endothermic elimination of purine and of HCN to form MNH⁺ and M⁺(C₄H₄N₄), respectively, as the primary ionic products. For Sc⁺, loss of ammonia is also a prominent process at low energies. Several minor channels corresponding to formation of M⁺(C_xH_xN_x), x = 1−3, are also observed for these three systems at elevated energies. The energy-dependent collision-induced dissociation cross sections for M⁺(adenine), where M⁺ = V⁺ through Zn⁺, are modeled to yield thresholds that are directly related to 0 and 298 K bond dissociation energies for M⁺−adenine after accounting for the effects of multiple ion−molecule collisions, kinetic and internal energy distributions of the reactants, and dissociation lifetimes. The measured bond energies are compared to those previously studied for simple nitrogen donor ligands, NH₃ and pyrimidine, and to results for alkali metal cations bound to adenine. Trends in these results and theoretical calculations on Cu⁺(adenine) suggest distinct differences in the binding site propensities of adenine to the alkali vs transition metal ions, a consequence of s−dσ hybridization on the latter.