Intrinsic local destabilization of the C-terminus predisposes integrin [alpha]1 I domain to a conformational switch induced by collagen binding

Integrin-collagen interactions play a critical role in a myriad of cellular functions that include immune response, and cell development and differentiation, yet their mechanism of binding is poorly understood. There is increasing evidence that conformational flexibility assumes a central role in th...

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Bibliographic Details
Published in:Protein science 2016-09, Vol.25 (9), p.1672
Main Authors: Nunes, Ana Monica, Zhu, Jie, Jezioro, Jacqueline, Minetti, Conceição ASA, Remeta, David P, Farndale, Richard W, Hamaia, Samir W, Baum, Jean
Format: Article
Language:English
Subjects:
Allosteric properties
Binding
C-Terminus
Calorimetry
Collagen
Comparative studies
Destabilization
Deuterium
Differentiation
Experiments
Heat measurement
Helices
Hydrogen-deuterium exchange
Immune response
Immune system
Molecular modelling
NMR
Nuclear magnetic resonance
Protein interaction
Protein structure
Structural members
Switches
Titration
Titration calorimetry
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Summary:Integrin-collagen interactions play a critical role in a myriad of cellular functions that include immune response, and cell development and differentiation, yet their mechanism of binding is poorly understood. There is increasing evidence that conformational flexibility assumes a central role in the molecular mechanisms of protein-protein interactions and here we employ NMR hydrogen-deuterium exchange (HDX) experiments to explore the impact of slower timescale dynamic events. To gain insight into the mechanisms underlying collagen-induced conformational switches, we have undertaken a comparative study between the wild type integrin [alpha]1 I and a gain-of-function E317A mutant. NMR HDX results suggest a relationship between regions exhibiting a reduced local stability in the unbound I domain and those that undergo significant conformational changes upon binding. Specifically, the [alpha]C and [alpha]7 helices within the C-terminus are at the center of such major perturbations and present reduced local stabilities in the unbound state relative to other structural elements. Complementary isothermal titration calorimetry experiments have been performed to derive complete thermodynamic binding profiles for association of the collagen-like triple-helical peptide with wild type [alpha]1 I and E317A mutant. The differential energetics observed for E317A are consistent with the HDX experiments and support a model in which intrinsically destabilized regions predispose conformational rearrangement in the integrin I domain. This study highlights the importance of exploring different timescales to delineate allosteric and binding events.
ISSN:0961-8368
1469-896X
DOI:10.1002/pro.2972