Abstract
Vinculin is an important constituent of both cell-cell and cell-matrix junctions, where it plays crucial roles in the regulation of cell adhesion and migration. When activated, it mediates the linkage between cadherins (cell-cell) or integrins (cell-matrix) and the actin cytoskeleton through interactions with various proteins. The activation of vinculin requires structural conversions from an autoinhibited conformation to the "open" conformations in which the occluded binding sites of its different ligands become exposed, while the structural dynamics underlying the vinculin activation remains largely unknown. Here we report the first computational study of large scale conformational dynamics of full-length vinculin. We find that the "holding" and "releasing" motions between vinculin tail and pincer-like structure formed by first three domains of vinculin are the dominant motions near the native state of vinculin, indicating that an inherent flexibility of vinculin has a large influence on its allostery. We also find a cooperative dissociation between the head and tail domains of vinculin with increasing temperature in both thermodynamic and kinetic simulations, implying that vinculin may function as an allosteric switch in response to external signals. We show that the kinetics of vinculin unfolding exhibits specific sequential patterns, suggesting that a sophisticated interplay between domains may synergistically contribute to vinculin activation. We further find that the interaction between vinculin-binding site peptide from talin and vinculin significantly destabilizes the intramolecular head-tail interactions, suggesting a direct role of talin binding in vinculin activation.
Highlights
Vinculin, a highly conserved 117-kDa intracellular protein (1066 residues), plays critical roles in the maintenance and regulation of cell shape, adhesion, and migration [1,2,3,4,5] that are essential to many physiological and pathological processes such as embryogenesis, wound healing, and metastasis
We find a cooperative dissociation between the head and tail domains of vinculin with increasing temperature in both thermodynamic and kinetic simulations, implying that vinculin may function as an allosteric switch in response to external signals
We find that the intrinsic flexibility of vinculin, which is defined in the absence of ligand, has a large influence on the allosteric properties of vinculin
Summary
A highly conserved 117-kDa intracellular protein (1066 residues), plays critical roles in the maintenance and regulation of cell shape, adhesion, and migration [1,2,3,4,5] that are essential to many physiological and pathological processes such as embryogenesis, wound healing, and metastasis. Vinculin is held in a “closed,” autoinhibited conformation by intramolecular interactions between the head and tail domains (Vt) [6, 7]. Domains D1 and D3 form a pincer-like structure holding the vinculin tail in an autoinhibited state (Fig. 1) in which many ligand-binding sites are occluded. It was found that the binding of specific short talin peptides (ϳ30 amino acids) to the D1 domain alone is sufficient for releasing intramolecular head-tail interactions in the D1-Vt complex by provoking significant structural changes of the D1 domain, suggesting an alternative pathway of vinculin activation, in which PtdIns[4,5]P2 may not be required [15, 16]. The time scale of the conformational dynamics and the size of vinculin are beyond the resolution capabilities of the current all-atom molecular
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