Fast docking using the CHARMM force field with EADock DSS
Citations Over TimeTop 1% of 2011 papers
Abstract
The prediction of binding modes (BMs) occurring between a small molecule and a target protein of biological interest has become of great importance for drug development. The overwhelming diversity of needs leaves room for docking approaches addressing specific problems. Nowadays, the universe of docking software ranges from fast and user friendly programs to algorithmically flexible and accurate approaches. EADock2 is an example of the latter. Its multiobjective scoring function was designed around the CHARMM22 force field and the FACTS solvation model. However, the major drawback of such a software design lies in its computational cost. EADock dihedral space sampling (DSS) is built on the most efficient features of EADock2, namely its hybrid sampling engine and multiobjective scoring function. Its performance is equivalent to that of EADock2 for drug-like ligands, while the CPU time required has been reduced by several orders of magnitude. This huge improvement was achieved through a combination of several innovative features including an automatic bias of the sampling toward putative binding sites, and a very efficient tree-based DSS algorithm. When the top-scoring prediction is considered, 57% of BMs of a test set of 251 complexes were reproduced within 2 Å RMSD to the crystal structure. Up to 70% were reproduced when considering the five top scoring predictions. The success rate is lower in cross-docking assays but remains comparable with that of the latest version of AutoDock that accounts for the protein flexibility.
Related Papers
- → Critical assessment of the automated AutoDock as a new docking tool for virtual screening(2006)185 cited
- → Research Article: pso@autodock: A Fast Flexible Molecular Docking Program Based on Swarm Intelligence(2007)114 cited
- → DINC: A new AutoDock-based protocol for docking large ligands(2013)60 cited
- → Auto dock-based incremental docking protocol to improve docking of large ligands(2012)10 cited
- → Evaluation of protein-ligand docking methods on peptide-ligand complexes for docking small ligands to peptides(2017)15 cited