Among vanadium compounds with potential medicinal applications, [VO(acac)] is one of the most promising for its antidiabetic and anticancer activity. In the organism, however, interconversion of the oxidation state to +III and +V and binding to proteins are possible. In this report, the transformation of V(acac), VO(acac), and VO(acac) (Formula presented.) after the interaction with two model proteins, lysozyme (Lyz) and ubiquitin (Ub), was studied with ESI-MS (ElectroSpray Ionization-Mass Spectroscopy), EPR (Electron Paramagnetic Resonance), and computational (docking) techniques. It was shown that, in the metal concentration range close to that found in the organism (15-250 ?M), V(acac) is oxidized to VO(acac) and VO(acac), which--in their turn--interact with proteins to give n[VO(acac)]-Protein and n[VO(acac)]-Protein adducts. Similarly, the complex in the +IV oxidation state, VO(acac), dissociates to the mono-chelated species VO(acac) which binds to Lyz and Ub. Finally, VO(acac) (Formula presented.) undergoes complete dissociation to give the 'bare' VO (Formula presented.) ion that forms adducts n[VO]-Protein with n = 1-3. Docking calculations allowed the prediction of the residues involved in the metal binding. The results suggest that only the VO complex of acetylacetonate survives in the presence of proteins and that its adducts could be the species responsible of the observed pharmacological activity, suggesting that in these systems VO ion should be used in the design of potential vanadium drugs. If V or VO potential active complexes had to be designed, the features of the organic ligand must be adequately modulated to obtain species with high redox and thermodynamic stability to prevent oxidation and dissociation.

Biospeciation of Potential Vanadium Drugs of Acetylacetonate in the Presence of Proteins

Ugone Valeria;Sanna Daniele;
2020

Abstract

Among vanadium compounds with potential medicinal applications, [VO(acac)] is one of the most promising for its antidiabetic and anticancer activity. In the organism, however, interconversion of the oxidation state to +III and +V and binding to proteins are possible. In this report, the transformation of V(acac), VO(acac), and VO(acac) (Formula presented.) after the interaction with two model proteins, lysozyme (Lyz) and ubiquitin (Ub), was studied with ESI-MS (ElectroSpray Ionization-Mass Spectroscopy), EPR (Electron Paramagnetic Resonance), and computational (docking) techniques. It was shown that, in the metal concentration range close to that found in the organism (15-250 ?M), V(acac) is oxidized to VO(acac) and VO(acac), which--in their turn--interact with proteins to give n[VO(acac)]-Protein and n[VO(acac)]-Protein adducts. Similarly, the complex in the +IV oxidation state, VO(acac), dissociates to the mono-chelated species VO(acac) which binds to Lyz and Ub. Finally, VO(acac) (Formula presented.) undergoes complete dissociation to give the 'bare' VO (Formula presented.) ion that forms adducts n[VO]-Protein with n = 1-3. Docking calculations allowed the prediction of the residues involved in the metal binding. The results suggest that only the VO complex of acetylacetonate survives in the presence of proteins and that its adducts could be the species responsible of the observed pharmacological activity, suggesting that in these systems VO ion should be used in the design of potential vanadium drugs. If V or VO potential active complexes had to be designed, the features of the organic ligand must be adequately modulated to obtain species with high redox and thermodynamic stability to prevent oxidation and dissociation.
2020
Istituto di Chimica Biomolecolare - ICB - Sede Secondaria Sassari
anticancer action
antidiabetic action
drug design
metal drugs
proteins
transport in the organism
vanadium
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/20.500.14243/411234
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