Pre-existing soft modes of motion uniquely defined by native contact topology facilitate ligand binding to proteins

Lidio Meireles, Mert Gur, Ahmet Bakan, Ivet Bahar*

*Corresponding author for this work

Research output: Contribution to journalReview articlepeer-review

84 Citations (Scopus)

Abstract

Modeling protein flexibility constitutes a major challenge in accurate prediction of protein-ligand and protein-protein interactions in docking simulations. The lack of a reliable method for predicting the conformational changes relevant to substrate binding prevents the productive application of computational docking to proteins that undergo large structural rearrangements. Here, we examine how coarse-grained normal mode analysis has been advantageously applied to modeling protein flexibility associated with ligand binding. First, we highlight recent studies that have shown that there is a close agreement between the large-scale collective motions of proteins predicted by elastic network models and the structural changes experimentally observed upon ligand binding. Then, we discuss studies that have exploited the predicted soft modes in docking simulations. Two general strategies are noted: pregeneration of conformational ensembles that are then utilized as input for standard fixed-backbone docking and protein structure deformation along normal modes concurrent to docking. These studies show that the structural changes apparently "induced" upon ligand binding occur selectively along the soft modes accessible to the protein prior to ligand binding. They further suggest that proteins offer suitable means of accommodating/facilitating the recognition and binding of their ligand, presumably acquired by evolutionary selection of the suitable three-dimensional structure. Published by Wiley-Blackwell.

Original languageEnglish
Pages (from-to)1645-1658
Number of pages14
JournalProtein Science
Volume20
Issue number10
DOIs
Publication statusPublished - Oct 2011
Externally publishedYes

Keywords

  • Coarse-grained normal mode analysis
  • Collective motions
  • Elastic network models
  • Flexible docking
  • Intrinsic dynamics
  • Mechanism of ligand binding

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