Abstract
Although seeking to develop a general and accurate binding free energy calculation method for protein–protein and protein–ligand interactions has been a continuous effort for decades, only limited successes have been obtained so far. Here, we report the development of a metadynamics-based procedure that calculates Dissociation Free Energy (DFE) and its application to 19 non-congeneric protein–protein complexes and hundreds of protein–ligand complexes covering eight targets. We achieved very high correlations in comparison to experimental binding free energies for these diverse sets of systems, demonstrating the generality and accuracy of the method. Since structures of most proteins are available owing to the recent success of prediction by artificial intelligence, a general free energy method such as DFE, combined with other methods, can make structure-based drug design a widely viable and reliable solution to develop both traditional small molecule drugs and biologic drugs as well as PROTACS.
Highlights
A general method able to accurately calculate binding affinities of protein–protein complexes (PPC) and protein–ligand complexes (PLC) would be highly empowering for rational design of biologic and small molecule drugs. (“Ligand” refers to small molecule)
The procedure to be reported in this paper generates Dissociation Free Energies (DFE) of molecular complexes such as PPCs and PLCs
Assuming that the complex structure of two molecules is known and used as the starting point, a complex is dissociated by performing a standard metadynamics run with a user-defined distance between the two molecules used as the collective variable (CV)
Summary
A general method able to accurately calculate binding affinities of protein–protein complexes (PPC) and protein–ligand complexes (PLC) would be highly empowering for rational design of biologic and small molecule drugs. (“Ligand” refers to small molecule). Funnel-Metadynamics might be one of the most elegant methods that has been developed so far[7,8,9], but it was designed only for PLC and not for PPC Another elegant approach is Free Energy Perturbation (FEP) which generates rigorous relative free e nergies[10,11,12], but its applicability was limited to calculation of relative binding free energy changes among congeneric series of ligands, and the relative free energy changes resulting from point mutations of proteins[13,14,15]. Our procedure derives DFE from the FES profiles of the one-way trip runs
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