Force-dependent conformational switch of α-catenin controls vinculin binding

Yao, Mingxi; Qiu, Wei; Liu, Ruchuan; Efremov, Artem K.; Cong, Peiwen; Seddiki, Rima; Payre, Manon; Lim, Chwee Teck; Ladoux, Benoît; Mège, René-Marc; Yan, Jie

doi:10.1038/ncomms5525

Cited by 406 publications

(504 citation statements)

References 73 publications

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“…Its activation and recruitment to force-activated talin (and likely to ␣-catenin) involve phosphorylation and allosteric interactions with cytosolic binding partners (34,61,63,64). Conversely, recent experimental data demonstrated that force directly activates ␣-catenin (30,42), and the present simulations suggest that this occurs by a process involving salt-bridge disruption within the M region. Despite sharing a core structural motif, these proteins differ in their activation mechanisms, functional binding partners, and roles in force transduction.…”

Section: Salt-bridgesmentioning

confidence: 45%

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Structural Determinants of the Mechanical Stability of α-Catenin

Newhall

Ishiyama

et al. 2015

Journal of Biological Chemistry

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Background:We investigated how ␣-catenin transduces force at cell-to-cell adhesions. Results: Molecular dynamics simulations identified structural features contributing to ␣-catenin stability and its deformation under applied force. Conclusion: A cooperative network of salt bridges in ␣-catenin regulates both ␣-catenin stability and how it unfolds under force. Significance: These findings reveal the molecular basis of experimental observations and the impact of reported cancer-linked ␣-catenin mutants.

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Section: Salt-bridgesmentioning

confidence: 45%

“…Recent single protein unfolding studies reported the forced unfolding of MI-MIII when stretched along the N-to-C-terminal axis (42). The protein appeared to unfold in three sequential steps in which an initial unfolding event at ϳ5 pN appeared to expose the VBS in MI, while retaining the structures of MII and MIII.…”

mentioning

confidence: 99%

Structural Determinants of the Mechanical Stability of α-Catenin

Newhall

Ishiyama

et al. 2015

Journal of Biological Chemistry

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“…4 Although the cadherin-catenin complex is commonly described as the 'core' VE-cadherin complex, many other proteins can associate, such as scaffolding proteins and cytoskeletal regulators. 3,5 Some of these proteins, including vinculin, [6][7][8][9][10][11] epithelial protein lost in neoplasm (EPLIN) 12,13 a-actinin 14 and afadin, 15,16 have been found to bind to both a-catenin and actin and are therefore suggested to act as a link between the cadherin-catenin complex and actin. However, biochemical studies showed that a minimal cadherin-catenin complex consisting of E-cadherin, b-catenin and aE-catenin can directly bind to filamentous actin (F-actin).…”

Section: Introductionmentioning

confidence: 99%

“…17 Interestingly, binding of vinculin to aEcatenin has also been demonstrated to be stabilized by tension. 18,19 In endothelial cells, force exerted on cell-cell junctions was shown to recruit vinculin, which protected VE-cadherin junctions against opening. 11 Together, these data suggest that tension on junctions may promote binding of cadherin/b-catenin as well as vinculin to a-catenin, resulting in their re-enforcement and growth.…”

Section: Introductionmentioning

confidence: 99%

Small Rho GTPase-mediated actin dynamics at endothelial adherens junctions

Buul

Timmerman

2016

Small GTPases

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VE-cadherin-based cell-cell junctions form the major restrictive barrier of the endothelium to plasma proteins and blood cells. The function of VE-cadherin and the actin cytoskeleton are intimately linked. Vascular permeability factors and adherent leukocytes signal through small Rho GTPases to tightly regulate actin cytoskeletal rearrangements in order to open and re-assemble endothelial cell-cell junctions in a rapid and controlled manner. The Rho GTPases are activated by guanine nucleotide exchange factors (GEFs), conferring specificity and context-dependent control of cell-cell junctions. Although the molecular mechanisms that couple cadherins to actin filaments are beginning to be elucidated, specific stimulus-dependent regulation of the actin cytoskeleton at VEcadherin-based junctions remains unexplained. Accumulating evidence has suggested that depending on the vascular permeability factor and on the subcellular localization of GEFs, cell-cell junction dynamics and organization are differentially regulated by one specific Rho GTPase. In this Commentary, we focus on new insights how the junctional actin cytoskeleton is specifically and locally regulated by Rho GTPases and GEFs in the endothelium.

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“…This can finally lead to the activation of chemical signaling cascades. As discussed in Yap (2017), AJs function as mechanosensors (Huveneers and de Rooij 2013;Yao et al 2014;Ladoux et al 2015;Muhamed et al 2016), whereas a role in force sensing has so far not been attributed to desmosomes. At the same time, desmosome-mediated intercellular adhesion is much stronger than AJmediated cohesion as shown by the epithelial sheet assay: Whereas depletion of the desmosomal plaque component plakophilin 1 (PKP1) in keratinocytes disrupts epithelial cohesion on application of mechanical stress, knockdown of the corresponding components from AJs, p120, or p0071/PKP4, has no immediate effect on intercellular cohesion (Fig.…”

mentioning

confidence: 99%

Desmosomes and Intermediate Filaments: Their Consequences for Tissue Mechanics

Hatzfeld

Keil

Magin

2017

Cold Spring Harb Perspect Biol

116

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Adherens junctions (AJs) and desmosomes connect the actin and keratin filament networks of adjacent cells into a mechanical unit. Whereas AJs function in mechanosensing and in transducing mechanical forces between the plasma membrane and the actomyosin cytoskeleton, desmosomes and intermediate filaments (IFs) provide mechanical stability required to maintain tissue architecture and integrity when the tissues are exposed to mechanical stress. Desmosomes are essential for stable intercellular cohesion, whereas keratins determine cell mechanics but are not involved in generating tension. Here, we summarize the current knowledge of the role of IFs and desmosomes in tissue mechanics and discuss whether the desmosome-keratin scaffold might be actively involved in mechanosensing and in the conversion of chemical signals into mechanical strength.

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Force-dependent conformational switch of α-catenin controls vinculin binding

Cited by 406 publications

References 73 publications

Structural Determinants of the Mechanical Stability of α-Catenin

Structural Determinants of the Mechanical Stability of α-Catenin

Small Rho GTPase-mediated actin dynamics at endothelial adherens junctions

Desmosomes and Intermediate Filaments: Their Consequences for Tissue Mechanics

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