Network analysis of dynamically important residues in protein structures mediating ligand-binding conformational changes

According to the generalized conformational selection model, ligand binding involves the co-existence of at least two conformers with different ligand-affinities in a dynamical equilibrium. Conformational transitions between them should be guaranteed by intramolecular vibrational dynamics associated...

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Veröffentlicht in:	European biophysics journal 2019-09, Vol.48 (6), p.559-568
Hauptverfasser:	Saldaño, Tadeo E., Tosatto, Silvio C. E., Parisi, Gustavo, Fernandez-Alberti, Sebastian
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Sprache:	eng
Schlagworte:	Aliphatic compounds Binding Biochemistry Biological and Medical Physics Biomedical and Life Sciences Biophysics Buried structures Cell Biology Helices Life Sciences Ligands Membrane Biology Mutation Nanotechnology Network analysis Networks Neurobiology Original Article Proteins Residues Vibrations
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container_title	European biophysics journal
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creator	Saldaño, Tadeo E. Tosatto, Silvio C. E. Parisi, Gustavo Fernandez-Alberti, Sebastian
description	According to the generalized conformational selection model, ligand binding involves the co-existence of at least two conformers with different ligand-affinities in a dynamical equilibrium. Conformational transitions between them should be guaranteed by intramolecular vibrational dynamics associated to each conformation. These motions are, therefore, related to the biological function of a protein. Positions whose mutations are found to alter these vibrations the most can be defined as key positions, that is, dynamically important residues that mediate the ligand-binding conformational change. In a previous study, we have shown that these positions are evolutionarily conserved. They correspond to buried aliphatic residues mostly localized in regular structured regions of the protein like β-sheets and α-helices. In the present paper, we perform a network analysis of these key positions for a large dataset of paired protein structures in the ligand-free and ligand-bound form. We observe that networks of interactions between these key positions present larger and more integrated networks with faster transmission of the information. Besides, networks of residues result that are robust to conformational changes. Our results reveal that the conformational diversity of proteins seems to be guaranteed by a network of strongly interconnected key positions rather than individual residues.
doi_str_mv	10.1007/s00249-019-01384-1
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subjects	Aliphatic compounds Binding Biochemistry Biological and Medical Physics Biomedical and Life Sciences Biophysics Buried structures Cell Biology Helices Life Sciences Ligands Membrane Biology Mutation Nanotechnology Network analysis Networks Neurobiology Original Article Proteins Residues Vibrations
title	Network analysis of dynamically important residues in protein structures mediating ligand-binding conformational changes
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