Molecular simulation studies on the binding activity and selectivity of 3-amino-phenyl-5-chloro-pyrimidine-2, 4-diamine derivatives in complexes with kinases c-Met and ALK

Receptor tyrosine kinases c-Met and ALK have been demonstrated to be important therapeutic targets for cancer therapy. However, selectivity and drug resistance could hinder the development of their corresponding inhibitors. In this study, three compounds with similar scaffold were examined to study activity and selectivity mechanism towards c-Met or ALK by utilising a combined approach of computational techniques, including flexible dock, molecular electrostatic potential (MESP) calculations, molecular dynamic (MD) simulation, and binding free-energy calculation. Molecular simulation provides us new chemical insights into steric and electronic complementarities of these inhibitors to target binding sites. The computed binding free energies were consistent with the changing trend of experimental affinities on c-Met and ALK. H-bond with Asp169 and hydrophobic interaction with Phe36 of c-Met, respectively, could be crucial for the binding affinity of an inhibitor binding to c-Met. Meanwhile, for inhibitor–ALK complex, both H-bond interactions with Arg28 and Met101 and hydrophobic interactions with Leu30, Val38, and Leu158 could enhance the bioactivity and selectivity. The present work may provide a structural understanding of molecular mechanism expected to be valuable for the guidelines of the development of new potent c-Met or ALK selective inhibitors.