We report here on the synthesis and multi-technique characterization of [Ru2Cl((2-phenylindol-3-yl)glyoxyl-L-leucine-Lphenylalanine) 4] a novel diruthenium (II,III) complex obtained reacting [Ru2(μ-O2CCH3)4Cl] with a dual indolylglyoxylyl dipeptide anticancer agent. We soon realised that the compound is very stable in several different conditions including aqueous buffers or organic solvents. It is also completely unreactive toward proteins. The high stability is also suggested by cellular experiments in a glioblastoma cell line. Indeed, while the parent ligand exerts high cytotoxic effects in the low μM range, the complex is completely non-cytotoxic against the same line, most probably because of the lack of ligand release. To investigate the reasons for such high stability, we carried out DFT calculations that are fully consistent with the experimental findings. Results highlight that the stability of [Ru2Cl((2-phenylindol-3-yl)glyoxyl-L-leucine-L-phenylalanine)4] relies on the nature of the ligand, including its steric hindrance that prevents the reaction of any nucleophilic group with the Ru2 core. The ligand displacement is the key step to allow the reactivity with biological targets of metal-based prodrugs. Accordingly, we discuss the implications of some important aspects that should be considered when active molecules are chosen as ligand for the synthesis of paddle-wheels like complexes with medicinal applications.
A mixed valence diruthenium (II, III) complex endowed with high stability: from experimental evidence to theoretical interpretation
Valentina Notarstefano;
2020-01-01
Abstract
We report here on the synthesis and multi-technique characterization of [Ru2Cl((2-phenylindol-3-yl)glyoxyl-L-leucine-Lphenylalanine) 4] a novel diruthenium (II,III) complex obtained reacting [Ru2(μ-O2CCH3)4Cl] with a dual indolylglyoxylyl dipeptide anticancer agent. We soon realised that the compound is very stable in several different conditions including aqueous buffers or organic solvents. It is also completely unreactive toward proteins. The high stability is also suggested by cellular experiments in a glioblastoma cell line. Indeed, while the parent ligand exerts high cytotoxic effects in the low μM range, the complex is completely non-cytotoxic against the same line, most probably because of the lack of ligand release. To investigate the reasons for such high stability, we carried out DFT calculations that are fully consistent with the experimental findings. Results highlight that the stability of [Ru2Cl((2-phenylindol-3-yl)glyoxyl-L-leucine-L-phenylalanine)4] relies on the nature of the ligand, including its steric hindrance that prevents the reaction of any nucleophilic group with the Ru2 core. The ligand displacement is the key step to allow the reactivity with biological targets of metal-based prodrugs. Accordingly, we discuss the implications of some important aspects that should be considered when active molecules are chosen as ligand for the synthesis of paddle-wheels like complexes with medicinal applications.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.