Molecular Modeling of the Three-Dimensional Structure of Dopamine 3 (D3) Subtype Receptor: Discovery of Novel and Potent D3Ligands through a Hybrid Pharmacophore- and Structure-Based Database Searching Approach

Abstract

The dopamine 3 (D₃) subtype receptor has been implicated in several neurological conditions, and potent and selective D₃ ligands may have therapeutic potential for the treatment of drug addiction, Parkinson's disease, and schizophrenia. In this paper, we report computational homology modeling of the D₃ receptor based upon the high-resolution X-ray structure of rhodopsin, extensive structural refinement in the presence of explicit lipid bilayer and water environment, and validation of the refined D₃ structural models using experimental data. We further describe the development, validation, and application of a hybrid computational screening approach for the discovery of several classes of novel and potent D₃ ligands. This computational approach employs stepwise pharmacophore and structure-based searching of a large three-dimensional chemical database for the identification of potential D₃ ligands. The obtained hits are then subjected to structural novelty screening, and the most promising compounds are tested in a D₃ binding assay. Using this approach we identified four compounds with K_i values better than 100 nM and eight compounds with K_i values better than 1 μM out of 20 compounds selected for testing in the D₃ receptor binding assay. Our results suggest that the D₃ structural models obtained from this study may be useful for the discovery and design of novel and potent D₃ ligands. Furthermore, the employed hybrid approach may be more effective for lead discovery from a large chemical database than either pharmacophore-based or structure-based database screening alone.