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ElectroShape: fast molecular similarity calculations incorporating shape, chirality and electrostatics

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Abstract

We present ElectroShape, a novel ligand-based virtual screening method, that combines shape and electrostatic information into a single, unified framework. Building on the ultra-fast shape recognition (USR) approach for fast non-superpositional shape-based virtual screening, it extends the method by representing partial charge information as a fourth dimension. It also incorporates the chiral shape recognition (CSR) method, which distinguishes enantiomers. It has been validated using release 2 of the Directory of useful decoys (DUD), and shows a near doubling in enrichment ratio at 1% over USR and CSR, and improvements as measured by Receiver Operating Characteristic curves. These improvements persisted even after taking into account the chemotype redundancy in the sets of active ligands in DUD. During the course of its development, ElectroShape revealed a difference in the charge allocation of the DUD ligand and decoy sets, leading to several new versions of DUD being generated as a result. ElectroShape provides a significant addition to the family of ultra-fast ligand-based virtual screening methods, and its higher-dimensional shape recognition approach has great potential for extension and generalisation.

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Authors and Affiliations

  1. InhibOx, Pembroke House, 36-37 Pembroke Street, Oxford, OX1 1BP, UK

    M. Stuart Armstrong, Garrett M. Morris, Paul W. Finn, Raman Sharma & Richard I. Cooper

  2. Department of Chemistry, InhibOx Laboratory, University of Oxford, Pembroke House, 36-37 Pembroke Street, Oxford, OX1 1BP, UK

    Loris Moretti & W. Graham Richards

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  1. M. Stuart Armstrong
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  2. Garrett M. Morris
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  4. Raman Sharma
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  5. Loris Moretti
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  7. W. Graham Richards
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Corresponding author

Correspondence to M. Stuart Armstrong.

Additional information

This research was financed in part by the 6th Framework Program of the European Union (DeZnIT, Project Number 037303) and by the National Foundation for Cancer Research (NFCR).

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Armstrong, M.S., Morris, G.M., Finn, P.W. et al. ElectroShape: fast molecular similarity calculations incorporating shape, chirality and electrostatics. J Comput Aided Mol Des 24, 789–801 (2010). https://doi.org/10.1007/s10822-010-9374-0

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