“…The interactions of nucleic acids or their constituents with metal ions have currently received intense interest owing not only to the biological importance of the metal−nucleobase bonds, the functions of nucleic acids, and genetic information transfer but also to their structural diversity, molecular recognition behaviors, and potential applications as advanced functional materials. − Native adenine (Hade) nucleobase with considerable water solubility and five possible donor sites (the endocyclic N1, N3, N7, and N9 and exocyclic N6 atoms) has already exhibited the widest range of binding possibilities including monodentate N9, − N7, ,, and N3 ,, bidentate bridging and/or chelating μ 2 -N7,N9, − μ 2 -N3,N9, μ 2 -N3,N7, μ 2 -N1,N9, and μ 2 -N6,N7 as well as tridentate μ 3 -N3,N7,N9 ,, modes, which depend essentially on the properties of the metal ion (main group or transition metal, charge, d-electron configuration, and hard- or softness), the nature of the Hade nucleobase (the basicity of the N-donor site, the degree of protonation, as well as the different tautomeric forms), and, sometimes, the auxiliary ligands that complete the metal coordination sphere. , However, the polymeric structures bridged by Hade are relatively uncommon. − ,,, Especially, the discrete/polymeric Hade-based metal complex, in which the unsubstituted Hade ligand binds the metal ion either by its individual N1 site or by combinations of N1 with more other two N donors, has never been observed by far, although it is reasonable in principle . On the other hand, in addition to the classical coordination bonds, the presence of a primary 6-amino group in Hade also offers interesting possibilities for acting as an H donor in interligand hydrogen-bonding interactions, which cooperates with the coordination bonds to stabilize and/or extend the resulting complexes into higher dimensional architectures .…”