Structure-affinity properties of a high-affinity ligand of FKBP12 studied by molecular simulations of a binding intermediate.

With a view to explaining the structure-affinity properties of the ligands of the protein FKBP12, we characterized a binding intermediate state between this protein and a high-affinity ligand. Indeed, the nature and extent of the intermolecular contacts developed in such a species may play a role on its stability and, hence, on the overall association rate. To find the binding intermediate, a molecular simulation protocol was used to unbind the ligand by gradually decreasing the biasing forces introduced.

Classical force field parameters for two high-affinity ligands of FKBP12.

FKBP12 is an important target in the treatment of transplant rejection and is also a promising target for cancer and neurodegenerative diseases. We determined for two ligands of nanomolar affinity the set of parameters in the CHARMM force field. The fitting procedure was based on reproducing the quantum chemistry data (distances, angles, and energies).

Molecular Dynamics Simulations of a Binding Intermediate between FKBP12 and a High-Affinity Ligand.

We characterized a binding intermediate between the protein FKBP12 and one of its high-affinity ligands by means of molecular dynamics simulations. In such an intermediate, which is expected to form at the end-point of the bimolecular diffusional search, short-range interactions between the molecular partners may play a role in the specificity of recognition as well as in the association rate. Langevin dynamics simulations were carried out to generate the intermediate by applying an external biasing force to unbind the ligand from the protein.