Abstract
Vinculin regulates cell adhesion by strengthening contacts between extracellular matrix and the cytoskeleton. Binding of the integrin ligand, talin, to the head domain of vinculin and F-actin to its tail domain is a potential mechanism for this function, but vinculin is autoinhibited by intramolecular interactions between its head and tail domain and must be activated to bind talin and actin. Because autoinhibition of vinculin occurs by synergism between two head and tail interfaces, one hypothesis is that activation could occur by two ligands that coordinately disrupt both interfaces. To test this idea we use a fluorescence resonance energy transfer probe that reports directly on activation of vinculin. Neither talin rod, VBS3 (a talin peptide that mimics a postulated activated state of talin), nor F-actin alone can activate vinculin. But in the presence of F-actin either talin rod or VBS3 induces dose-dependent activation of vinculin. The activation data are supported by solution phase binding studies, which show that talin rod or VBS3 fails to bind vinculin, whereas the same two ligands bind tightly to vinculin head domain (K(d) approximately 100 nM). These data strongly support a combinatorial mechanism of vinculin activation; moreover, they are inconsistent with a model in which talin or activated talin is sufficient to activate vinculin. Combinatorial activation implies that at cell adhesion sites vinculin is a coincidence detector awaiting simultaneous signals from talin and actin polymerization to unleash its scaffolding activity.
Highlights
(2– 4), cardiocyte intercalated discs, smooth muscle dense plaques, the zonula adherens between epithelial cells [5], myotendinous junctions [4], as well as focal adhesions and focal complexes in lamellipodia of migrating cells in culture [1]
Cell adhesion structures consist of three domains; a transmembrane receptor such as an integrin, cadherin, or IgCam, extracellular matrix proteins or cell surface proteins that bind to the extracellular portion of these receptors, and a cytoplasmic plaque containing signaling and cytoskeletal proteins, such as focal adhesion kinase, Src, vinculin, talin, and actin, that assemble on the cytoplasmic domain of the receptors and regulate adhesion site turnover and strength
We present measurements of the affinities of vinculin, Vd1, and Vh for talin rod (Tn rod) domain in solution and of VBS3 for vinculin, Vh, and Vd1, which support the conclusion that reduction of intramolecular head-tail interaction in vinculin is the rate-limiting structural change required for vinculin and talin interaction
Summary
(2– 4), cardiocyte intercalated discs, smooth muscle dense plaques, the zonula adherens between epithelial cells [5], myotendinous junctions [4], as well as focal adhesions and focal complexes in lamellipodia of migrating cells in culture [1]. FRET reports on structural changes that accompany exposure peptide, VBS3, to mimic the postulated activated form of talin of the actin binding activity of vinculin, i.e. vinculin activation.
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