An improved adaptive genetic algorithm for protein-ligand docking

Ling Kang; Honglin Li; Hualiang Jiang; Xicheng Wang

doi:10.1007/s10822-008-9232-5

An improved adaptive genetic algorithm for protein-ligand docking

Ling Kang
, Honglin Li
, Hualiang Jiang
, Xicheng Wang^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

42 Scopus citations

Abstract

A new optimization model of molecular docking is proposed, and a fast flexible docking method based on an improved adaptive genetic algorithm is developed in this paper. The algorithm takes some advanced techniques, such as multi-population genetic strategy, entropy-based searching technique with self-adaptation and the quasi-exact penalty. A new iteration scheme in conjunction with above techniques is employed to speed up the optimization process and to ensure very rapid and steady convergence. The docking accuracy and efficiency of the method are evaluated by docking results from GOLD test data set, which contains 134 protein-ligand complexes. In over 66.2% of the complexes, the docked pose was within 2.0 Å root-mean-square deviation (RMSD) of the X-ray structure. Docking time is approximately in proportion to the number of the rotatable bonds of ligands.

Original language	English
Pages (from-to)	1-12
Number of pages	12
Journal	Journal of Computer-Aided Molecular Design
Volume	23
Issue number	1
DOIs	https://doi.org/10.1007/s10822-008-9232-5
State	Published - Jan 2009
Externally published	Yes

Keywords

Genetic algorithms
Information entropy
Molecular docking
Optimization design
Penalty function
Self-adaptation

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10.1007/s10822-008-9232-5

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abstract = "A new optimization model of molecular docking is proposed, and a fast flexible docking method based on an improved adaptive genetic algorithm is developed in this paper. The algorithm takes some advanced techniques, such as multi-population genetic strategy, entropy-based searching technique with self-adaptation and the quasi-exact penalty. A new iteration scheme in conjunction with above techniques is employed to speed up the optimization process and to ensure very rapid and steady convergence. The docking accuracy and efficiency of the method are evaluated by docking results from GOLD test data set, which contains 134 protein-ligand complexes. In over 66.2\% of the complexes, the docked pose was within 2.0 {\AA} root-mean-square deviation (RMSD) of the X-ray structure. Docking time is approximately in proportion to the number of the rotatable bonds of ligands.",

keywords = "Genetic algorithms, Information entropy, Molecular docking, Optimization design, Penalty function, Self-adaptation",

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AU - Kang, Ling

AU - Li, Honglin

AU - Jiang, Hualiang

AU - Wang, Xicheng

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N2 - A new optimization model of molecular docking is proposed, and a fast flexible docking method based on an improved adaptive genetic algorithm is developed in this paper. The algorithm takes some advanced techniques, such as multi-population genetic strategy, entropy-based searching technique with self-adaptation and the quasi-exact penalty. A new iteration scheme in conjunction with above techniques is employed to speed up the optimization process and to ensure very rapid and steady convergence. The docking accuracy and efficiency of the method are evaluated by docking results from GOLD test data set, which contains 134 protein-ligand complexes. In over 66.2% of the complexes, the docked pose was within 2.0 Å root-mean-square deviation (RMSD) of the X-ray structure. Docking time is approximately in proportion to the number of the rotatable bonds of ligands.

AB - A new optimization model of molecular docking is proposed, and a fast flexible docking method based on an improved adaptive genetic algorithm is developed in this paper. The algorithm takes some advanced techniques, such as multi-population genetic strategy, entropy-based searching technique with self-adaptation and the quasi-exact penalty. A new iteration scheme in conjunction with above techniques is employed to speed up the optimization process and to ensure very rapid and steady convergence. The docking accuracy and efficiency of the method are evaluated by docking results from GOLD test data set, which contains 134 protein-ligand complexes. In over 66.2% of the complexes, the docked pose was within 2.0 Å root-mean-square deviation (RMSD) of the X-ray structure. Docking time is approximately in proportion to the number of the rotatable bonds of ligands.

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KW - Optimization design

KW - Penalty function

KW - Self-adaptation

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An improved adaptive genetic algorithm for protein-ligand docking

Abstract

Keywords

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