Molecular dynamics simulations of the rat m3-muscarinic seven-helix-bundle receptor models were performed on the free, agonist-bound and antagonist-bound forms. A comparative structural/dynamics analysis was performed in order to explain the perturbations induced by the functionally different ligands when binding to their target receptor. Theoretical quantitative structure-activity relationship models were developed; a good correlation was obtained between the interaction energies of the minimized average ligand-receptor complexes and the pharmacological affinities of the considered ligands. The consistency obtained between the structural rearrangement of the transmembrane seven-helix-bundle models considered and the experimental pharmacological efficacies and affinities of the ligands constitutes an important validation of the 3-D models proposed and allows the inference of the mechanism of ligand-induced or mutation-induced receptor activation at the molecular level.