Reactivity and implications in biological processes of imine-copper(II) complexes

In this work, novel imine and diimine copper(II) complexes with ligands derived from isatin, an endogenous indol, were synthesized, and extensively characterized by elemental analysis, conductivity measurements, spectroscopic techniques (IR, UV/Vis, and EPR), and electrospray mass spectrometry (ESI-MS/MS). These compounds showed a keto-enolic equilibrium in solution, with variations in the geometry around the copper ion with increasing pH, varying from a more tetrahedral configuration in acidic medium to a tetragonal one in basic solution. In order to elucidate the role of copper in the carbohydrate oxidation by molecular oxygen, kinetic studies were performed using these complexes as catalysts. A more comprehensive global rate law was determined for this process, including a copper-dependent pathway (at very low concentrations), in addition to an independent one, both influenced by alkaline medium. The proposed mechanism, under pseudo-first order conditions, combine intramolecular electronic transfer with reduction of the copper ion by the substrate, leading to the formation of intermediary reactive species (OH•-, O2•-, H2O2, CO2•-), responsible for initiation and propagation steps, and of short chain carbonylic products (glycolate, glycerate and formiate ions). To better understanding metal-carbohydrate interactions, copper(II) complexes with simple monosacharides were isolated, and characterized by elemental and thermogravimetric analyses, and spectroscopic techniques (IR, UV/Vis, and EPR), besides Raman spectroscopy, used to investigate the binding mode of the carbohydrate moiety to the copper ion, in each one of these complexes. Additionally, two novel chiral imine copper(II) complexes, derived from aminocarbohydrate ligands, were prepared and characterized by elemental analysis, conductivity measurements, and spectroscopic techniques (IR, UV/Vis, EPR, ESI-MS and CD), and one of them was also used in biological studies. Biological activity studies were carried out with the imine and diimine copper(II) complexes derived from isatin, verifying antiproliferative effect toward some tumor cell lines (promonocite U937 and neuroblastoma SH-SY5Y). Cells treated with the most active complexes were committed by the apoptotic program, as verified by citofluorimetric assays, with the complexes interfering the cell cycle in different ways (G1, G2/M or S phase. Formation of free radicals was detected, and citoplasmatic carbonylated and glycosilated proteins inside the treated cells were determined by imunologic assays. In conclusion, these studies indicated modulation of the biological activity by the imine ligand in the copper(II) complexes, with very different antiproliferative behavior, going from undetectable activity to high efficacy. Among the most active compounds, a different specificity and action mode in both cell type could be observed, evidencing their potential application as antitumoral agents. (AU)