Abstract
Background: DNA has been a pharmacological target for different types of treatment, such as antibiotics and chemotherapy agents, and is still a potential target in many drug discovery processes. However, most docking and scoring approaches were parameterised for protein-ligand interactions; their suitability for modelling DNA-ligand interactions is uncertain. Objective: This study investigated the performance of four scoring functions on DNA-ligand complexes. Material & Methods: Here, we explored the ability of four docking protocols and scoring functions to discriminate the native pose of 33 DNA-ligand complexes over a compiled set of 200 decoys for each DNA-ligand complexes. The four approaches were the AutoDock, ASP@GOLD, ChemScore@GOLD and GoldScore@GOLD. Results: Our results indicate that AutoDock performed the best when predicting binding mode and that ChemScore@GOLD achieved the best discriminative power. Rescoring of AutoDock-generated decoys with ChemScore@GOLD further enhanced their individual discriminative powers. All four approaches have no discriminative power in some DNA-ligand complexes, including both minor groove binders and intercalators. Conclusion: This study suggests that the evaluation for each DNA-ligand complex should be performed in order to obtain meaningful results for any drug discovery processes. Rescoring with different scoring functions can improve discriminative power.
Highlights
DNA is an important target for various types of treatments, most notably in cancer [1]
Our results indicate that AutoDock performed the best when predicting binding mode and that ChemScore@GOLD achieved the best discriminative power
Combining the results of this study and those in the literature, we believe that certain docking protocols and scoring functions, including AutoDock, ASP, ChemScore and GoldScore, are capable of reproducing the experimental crystallographic structure of DNA-ligand complexes using specific protocols [7, 9, 43]
Summary
DNA is an important target for various types of treatments, most notably in cancer [1] Certain chemotherapy agents, such as doxorubicin and daunorubicin are classic examples of small molecules that bind to double-stranded DNA and produce therapeutic effects [2, 3]. Apart from the therapeutic effects, drug molecules with a high ability to bind DNA may Docking is a popular technique of computational drug design to study the interactions between drug molecules and their associated receptors [10]. It consists of two main components, which are docking algorithms and scoring functions. Most docking and scoring approaches were parameterised for protein-ligand interactions; their suitability for modelling DNA-ligand interactions is uncertain
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