Decoding Surface Interaction of (VO)-O-IV Metallodrug Candidates with Lysozyme

The interaction of metallodrugs with proteins influences their transport, uptake, and mechanism of action. In this study, we present an integrative approach based on spectroscopic (EPR) and computational (docking) tools to elucidate the noncovalent binding modes of various (VO)-O-IV compounds with lysozyme, a prototypical model of protein receptor. Five (VO)-O-IV-flavonoid drug candidates formed by quercetin (que), morin (mor), 7,8-dihydroxyflavone (7,8-dhf), chrysin (chr), and 5-hydroxyflavone (5-hf)-effective against several osteosarcoma cell lines-and two benchmark (VO)-O-IV species of acetylacetone (acac) and catechol (cat) are evaluated. The results show a gradual variation of the EPR spectra at room temperature, which is associated with the strength of the interaction between the square pyramidal complexes [VOL2] and the surface residues of lysozyme. The qualitative strength of the interaction from EPR is [VO(que)(2)](2-) approximate to [VO(mor)(2)] > [VO(7,8-dhf)(2)](2-) > [VO(chr)(2)] approximate to [VO(5-hf)(2)] > [VO(acac)(2)] approximate to [VO(cat)(2)](2-). This observation is compared with protein-ligand docking calculations with GOLD software examining the GoldScore scoring function (F), for which hydrogen bond and van der Waals contact terms have been optimized to account for the surface interaction. The best predicted binding modes display an energy trend in good agreement with the EPR spectroscopy. Computation indicates that the strength of the interaction can be predicted by the F-max value and depends on the number of OH or CO groups of the ligands that can interact with different sites on the protein surface and, more particularly, with those in the vicinity of the active site of the enzyme. The interaction strength determines the type of signal revealed (rigid limit, slow tumbling, or isotropic) in the EPR spectra. Spectroscopic and computational results also suggest that there are several sites with comparable binding energy, with the V complexes distributing among them in a bound state and in aqueous solution in an unbound state. This kind of study and analysis could be generalized to determine the noncovalent binding modes of a generic metal species with a generic protein.