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Detection of Functional Modes in Protein Dynamics

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  • Jochen S Hub
  • Bert L de Groot

Abstract

Proteins frequently accomplish their biological function by collective atomic motions. Yet the identification of collective motions related to a specific protein function from, e.g., a molecular dynamics trajectory is often non-trivial. Here, we propose a novel technique termed “functional mode analysis” that aims to detect the collective motion that is directly related to a particular protein function. Based on an ensemble of structures, together with an arbitrary “functional quantity” that quantifies the functional state of the protein, the technique detects the collective motion that is maximally correlated to the functional quantity. The functional quantity could, e.g., correspond to a geometric, electrostatic, or chemical observable, or any other variable that is relevant to the function of the protein. In addition, the motion that displays the largest likelihood to induce a substantial change in the functional quantity is estimated from the given protein ensemble. Two different correlation measures are applied: first, the Pearson correlation coefficient that measures linear correlation only; and second, the mutual information that can assess any kind of interdependence. Detecting the maximally correlated motion allows one to derive a model for the functional state in terms of a single collective coordinate. The new approach is illustrated using a number of biomolecules, including a polyalanine-helix, T4 lysozyme, Trp-cage, and leucine-binding protein.Author Summary: Proteins are flexible nanomachines that frequently accomplish their biological function by collective atomic motions. Such motions may be characterized by hinge, shear, or rotational motions of entire protein domains, loop movements, or subtle rearrangements of amino acid side chains. In many cases it is far from obvious how collective motions are related to a particular biological task. Therefore, we propose a novel technique termed “functional mode analysis” that, based on an ensemble of structures, aims to detect a collective motion that is directly related to a particular protein function. From the given set of protein structures, together with a “functional quantity”, the technique seeks the collective motion that is maximally correlated to the functional quantity. The chosen functional quantity can be quite general; typical examples could include the openness of a channel, active site geometry, or cleft solvent accessibility. Because the proposed framework is highly general, we expect the approach to be useful to a wide range of applications. To illustrate the new technique, we apply functional mode analysis to molecular dynamics trajectories of a polyalanine-helix, bacteriophage T4 lysozyme, Trp-cage, and Leucine-binding protein.

Suggested Citation

  • Jochen S Hub & Bert L de Groot, 2009. "Detection of Functional Modes in Protein Dynamics," PLOS Computational Biology, Public Library of Science, vol. 5(8), pages 1-13, August.
    • Handle: RePEc:plo:pcbi00:1000480
    DOI: 10.1371/journal.pcbi.1000480
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    References listed on IDEAS

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    1. Katherine Henzler-Wildman & Dorothee Kern, 2007. "Dynamic personalities of proteins," Nature, Nature, vol. 450(7172), pages 964-972, December.
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    2. Reliza J. McGinnis & Chad A. Brambley & Brandon Stamey & William C. Green & Kimberly N. Gragg & Erin R. Cafferty & Thomas C. Terwilliger & Michal Hammel & Thomas J. Hollis & Justin M. Miller & Maria D, 2022. "A monomeric mycobacteriophage immunity repressor utilizes two domains to recognize an asymmetric DNA sequence," Nature Communications, Nature, vol. 13(1), pages 1-15, December.

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