Laulimalide, a cancer chemotherapeutic in preclinical development, has a unique binding site located on two adjacent β-tubulin units between tubulin protofilaments of a microtubule. Our extended protein model more accurately mimics the microtubule environment, and together with a 135 ns molecular dynamics simulation, identifies a new binding mode for laulimalide, which differs from the modes presented in work using smaller protein models. The new laulimalide-residue interactions that are computationally revealed explain the contacts observed via independent mass shift perturbation experiments. The inclusion of explicit solvent shows that many laulimalide-tubulin interactions are water mediated. The new contacts between the drug and the microtubule structure not only improve our understanding of laulimalide binding but also will be essential for efficient derivatization and optimization of this prospective cancer chemotherapy agent. Observed changes in secondary protein structure implicate the S7-H9 loop (M-loop) and H1'-S2 loop in the mechanism by which laulimalide stabilizes microtubules to exert its cytotoxic effects.
Keywords: drug discovery; molecular modeling; natural product; receptor and ligands.
© 2014 John Wiley & Sons A/S.