Multipose Binding in Molecular Docking

Atkovska, Kalina, Samsonov, Sergey A., Paszkowski-Rogacz, Maciej, Pisabarro, M. Teresa

09 July 2014

Molecular docking has been extensively applied in virtual screening of small molecule libraries for lead identification and optimization. A necessary prerequisite for successful differentiation between active and non-active ligands is the accurate prediction of their binding affinities in the complex by use of docking scoring functions. However, many studies have shown rather poor correlations between docking scores and experimental binding affinities. Our work aimed to improve this correlation by implementing a multipose binding concept in the docking scoring scheme. Multipose binding, i.e., the property of certain protein-ligand complexes to exhibit different ligand binding modes, has been shown to occur in nature for a variety of molecules. We conducted a high-throughput docking study and implemented multipose binding in the scoring procedure by considering multiple docking solutions in binding affinity prediction. In general, improvement of the agreement between docking scores and experimental data was observed, and this was most pronounced in complexes with large and flexible ligands and high binding affinities. Further developments of the selection criteria for docking solutions for each individual complex are still necessary for a general utilization of the multipose binding concept for accurate binding affinity prediction by molecular docking.

Docking

Molekulares Docking

Scoring-Optimierung

Bindungsaffinität

Vorhersage

TU Dresden

Publikationsfonds

immultipose binding

high-throughput docking

scoring optization

binding affinity prediction

Technical University Dresden

Publication funds

ddc:570

ddc:540

rvk:WA 15000

rvk:VA 1120

Multipose Binding in Molecular Docking

Atkovska, Kalina, Samsonov, Sergey A., Paszkowski-Rogacz, Maciej, Pisabarro, M. Teresa

09 July 2014

Molecular docking has been extensively applied in virtual screening of small molecule libraries for lead identification and optimization. A necessary prerequisite for successful differentiation between active and non-active ligands is the accurate prediction of their binding affinities in the complex by use of docking scoring functions. However, many studies have shown rather poor correlations between docking scores and experimental binding affinities. Our work aimed to improve this correlation by implementing a multipose binding concept in the docking scoring scheme. Multipose binding, i.e., the property of certain protein-ligand complexes to exhibit different ligand binding modes, has been shown to occur in nature for a variety of molecules. We conducted a high-throughput docking study and implemented multipose binding in the scoring procedure by considering multiple docking solutions in binding affinity prediction. In general, improvement of the agreement between docking scores and experimental data was observed, and this was most pronounced in complexes with large and flexible ligands and high binding affinities. Further developments of the selection criteria for docking solutions for each individual complex are still necessary for a general utilization of the multipose binding concept for accurate binding affinity prediction by molecular docking.

info:eu-repo/classification/ddc/570

ddc:570

info:eu-repo/classification/ddc/540

ddc:540