Surflex-Dock 2.1: robust performance from ligand energetic modeling, ring flexibility, and knowledge-based search

The Surflex flexible molecular docking method has been generalized and extended in two primary areas related to the search component of docking. First, incorporation of a small-molecule force-field extends the search into Cartesian coordinates constrained by internal ligand energetics. Whereas previ...

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Veröffentlicht in:Journal of computer-aided molecular design 2007-05, Vol.21 (5), p.281-306
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description The Surflex flexible molecular docking method has been generalized and extended in two primary areas related to the search component of docking. First, incorporation of a small-molecule force-field extends the search into Cartesian coordinates constrained by internal ligand energetics. Whereas previous versions searched only the alignment and acyclic torsional space of the ligand, the new approach supports dynamic ring flexibility and all-atom optimization of docked ligand poses. Second, knowledge of well established molecular interactions between ligand fragments and a target protein can be directly exploited to guide the search process. This offers advantages in some cases over the search strategy where ligand alignment is guided solely by a "protomol" (a pre-computed molecular representation of an idealized ligand). Results are presented on both docking accuracy and screening utility using multiple publicly available benchmark data sets that place Surflex's performance in the context of other molecular docking methods. In terms of docking accuracy, Surflex-Dock 2.1 performs as well as the best available methods. In the area of screening utility, Surflex's performance is extremely robust, and it is clearly superior to other methods within the set of cases for which comparative data are available, with roughly double the screening enrichment performance.
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subjects Accuracy
Algorithms
Alignment
Cartesian coordinates
Drug Design
Flexibility
Ligands
Methods
Models, Chemical
Molecular docking
Molecular interactions
Optimization
Polycyclic Compounds - chemistry
Robustness
Screening
Search methods
Search process
Software
Studies
Thermodynamics
title Surflex-Dock 2.1: robust performance from ligand energetic modeling, ring flexibility, and knowledge-based search
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