A Conformational Switch in Vinculin Drives Formation and Dynamics of a Talin-Vinculin Complex at Focal Adhesions

Abstract: Dynamic interactions between the cytoskeleton and integrins control cell adhesion, but regulatory mechanisms remain largely undefined. Here, we tested the extent to which the autoinhibitory head-tail interaction (HTI) in vinculin regulates formation and lifetime of the talin-vinculin complex, a proposed mediator of integrincytoskeleton bonds. In an ectopic recruitment assay, mutational reduction of HTI drove assembly of talin-vinculin complexes, whereas ectopic complexes did not form between talin and wild-typ… Show more

“…Importantly, kinetic analyses have recently demonstrated the involvement of myosin II in the timely maturation of FX and FA. 7,10,11 The biological mechanisms deciphering how myosin II functions in FA maturation remain to be fully unraveled, but could be through either the generation of tension, which directly affects the conformation of proteins in the adhesion complex 12 or its cross-linking activity. 11,13 Consequently, factors that can regulate both myosin II's cross-linking activities and contraction are good candidates to govern FA formation.…”

“…17 Inhibiting the molecular motor properties of myosin IIA would led to a loss of tension on actin stress fibers, resulting in significant changes in the conformation of proteins in the adhesion complex. 12 Alternatively S100A4 has been shown to impair myosin polymerization and its organization into highly defined filaments. 17 The aggregation of myosin IIA into fibers is thought to induce cross-linking activities on adjacent actin filaments, a process that is also required for FX maturation.…”

S100A4 downregulates filopodia formation through increased dynamic instability

“…Importantly, kinetic analyses have recently demonstrated the involvement of myosin II in the timely maturation of FX and FA. 7,10,11 The biological mechanisms deciphering how myosin II functions in FA maturation remain to be fully unraveled, but could be through either the generation of tension, which directly affects the conformation of proteins in the adhesion complex 12 or its cross-linking activity. 11,13 Consequently, factors that can regulate both myosin II's cross-linking activities and contraction are good candidates to govern FA formation.…”

“…17 Inhibiting the molecular motor properties of myosin IIA would led to a loss of tension on actin stress fibers, resulting in significant changes in the conformation of proteins in the adhesion complex. 12 Alternatively S100A4 has been shown to impair myosin polymerization and its organization into highly defined filaments. 17 The aggregation of myosin IIA into fibers is thought to induce cross-linking activities on adjacent actin filaments, a process that is also required for FX maturation.…”

S100A4 downregulates filopodia formation through increased dynamic instability

“…Vinculin binds to both filamentous actin and talin, which is another integrin binding protein that also cross-links actin. The conformation of vinculin can be reversibly regulated between an open state in which it can bind to actin filaments as well as to talin and ␣-actinin, and a closed conformation in which it does not bind to either of these proteins, thus enabling it to reversibly form connections between actin filaments and membrane adhesion sites (24,29). Vinculin binds to paxillin and is recruited with paxillin to the adhesion complexes of tracheal smooth muscle cells during contractile stimulation (95).…”

Actin cytoskeletal dynamics in smooth muscle: a new paradigm for the regulation of smooth muscle contraction

“…The conformational state of the vinculin molecule can be reversibly regulated between an activated "open" state and an inactive "autoinhibited" state (14,15,18,19,25,27). In the open state, binding sites for talin and ␣-actinin on the head domain of vinculin and binding sites for F-actin on the tail domain are exposed, enabling vinculin to form connections between the actin cytoskeleton and integrin adhesion complexes (14,19,26,28).…”

Vinculin Phosphorylation at Tyr1065 Regulates Vinculin Conformation and Tension Development in Airway Smooth Muscle Tissues