The structure of 6-(2-hydroxybenzylamino)purine acetic acid solvate

Supramolecular architectures assembled by the interaction of purine nucleobases with metal-oxalato frameworks. Non-covalent stabilization of the 7H-adenine tautomer in the solid-state

The synthesis, crystal structure and variable-temperature magnetic measurements of the compounds [Mn(mu-ox)(H2O)(7H-pur-kappaN9)]n (1), {[Mn(mu-ox)(H2O)2].(7H-ade).(H2O)}n (2) and {[Cu(mu-ox)(H2O)(7H-ade-kappaN9)][Cu(mu-ox)(mu-H2O)(7H-ade-kappaN9)]. approximately 10/3H2O}n (3), (where ox: oxalato dianion, pur: purine, and ade: adenine) are reported. Compounds 1and 2 contain one-dimensional chains in which manganese(II) atoms are bridged by bis-bidentate oxalato ligands. The distorted octahedral geometry around each metal centre is completed in compound 1 by one water molecule and the imidazole N9 donor site of the purine ligand, which is a rare example of direct binding between the Mn(II) ion and the N donor site of an isolated nucleobase. Unlike 1, the adenine moiety in compound 2 is not bonded to manganese atoms and the metal coordination polyhedron is filled by two water molecules in a cis-arrangement. Its crystal building is constructed from pi-stacked layers of Watson-Crick hydrogen-bonded adenine...(H2O2)...adenine aggregates and zig-zag Mn(II)-oxalato chains held together by means of a strong network of hydrogen bonding interactions. The nucleobase exists in the lattice as the 7H-adenine tautomer which represents an unprecedented solid-state characterization of this minor tautomer as free molecule (without metal coordination) stabilized through non-covalent interactions. Compound consists of two slightly different [Cu(ox)(H2O)(7H-ade-kappaN9)] units in which the nucleobase coordinates through the imidazole N9 atom. The planar complex entities are parallel stacked and joined by means of long Cu-O bonds involving oxygen atoms from the oxalato and the aqua ligands, giving one-dimensional chains with a [4 + 1] square-planar pyramidal and a [4 + 2] octahedral coordination around the metal centre, respectively. Self-assembled process of compound 3 is further driven by an in-plane network of hydrogen bonding interactions to generate a porous 3D structure containing parallel channels filled by guest water molecules. Variable-temperature magnetic susceptibility measurements of all the complexes show the occurrence of antiferromagnetic interactions between the paramagnetic centres. DFT calculations have been performed to check the influence of packing in the stability of the 7H-amino tautomer of 2 and in the complex geometry of 3.

Synthetic, spectral, magnetic and in vitro cytotoxic activity studies of cobalt(II) complexes with cytokinin derivatives: X-ray structure of 6-(3-methoxybenzylamino)purinium chloride monohydrate

Cobalt(II) complexes with 6-(2-hydroxybenzylamino)purine (HL1), 6-(2-methoxybenzylamino)purine (HL2), 6-(3-methoxybenzylamino)purine (HL3) and 6-(4-methoxybenzylamino)purine (HL4) of the composition [Co(L1)Cl(H2O)2].H2O (1), [Co(L2)Cl(H2O)2] (2), [Co(L3)2(H2O)2].2H2O (3), [Co(L4)2(H2O)2].2H2O (4) have been synthesized. The compounds have been characterized by elemental analysis, FT-IR, ES+ MS (electrospray mass spectra in the positive ion mode) and electronic spectroscopies, magnetic and conductivity data as tetrahedral high-spin cobalt(II) complexes. The thermal stability of the complexes has also been studied. The cytotoxicity of the complexes (1-4) was determined by a Calcein acetoxymethyl (AM) assay. Human malignant melanoma (G361), human chronic myelogenous erythroleukemia (K562), human osteogenic sarcoma (HOS) and human breast adenocarcinoma (MCF7) cell lines were used for the testing. The molecular structure of 6-(3-methoxybenzylamino)purinium chloride monohydrate, H2L3+.Cl.H2O, i.e. a protonated form of the free HL(3) ligand, has been determined by a single crystal X-ray analysis. The geometry optimisation and infrared frequencies calculations of HL1, HL2, and H2L3+ and H2L4+ were performed using density-functional theory (DFT) calculations at the B3LYP/6-31G* level of the theory. The geometry of complex (1) was optimised at the same level of the theory.