Dynamic Visualization of α-Catenin Reveals Rapid, Reversible Conformation Switching between Tension States

Kim, Tae Jin; Zheng, Shuai; Sun, Jie; Muhamed, Ismaeel; Wu, Jun; Lei, Lei; Kong, Xinyu; Leckband, Deborah; Wang, Yingxiao

doi:10.1016/j.cub.2014.11.017

Cited by 143 publications

(158 citation statements)

References 37 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%

“…As a force transducer in the mechanical chain between cadherins and the cytoskeleton, ␣-catenin is postulated to adopt an autoinhibited conformation in the absence of junctional tension, but mechanical stress alters the conformation to expose a cryptic binding site for the actin-binding protein, vinculin (18,30). At cadherin complexes, vinculin is an ␣-catenin effector that binds the exposed vinculin-binding site (VBS) 3 in the force-activated ␣-catenin conformation (15, 19, 20, 30 -32).…”

mentioning

confidence: 99%

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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%

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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“…Vinculin is then recruited to adherens junctions and becomes associated with more actin filaments thus reinforcing cell-cell adhesion (Kim et al, 2015;le Duc et al, 2010;Yao et al, 2014;Yonemura et al, 2010). Thus, we decided to investigate whether Vinculin and α-Catenin also interacted during Drosophila embryogenesis.…”

Section: Interaction Between Vinculin and α-Cateninmentioning

confidence: 99%

“…Although biochemical studies had challenged the notion that the Cadherin-Catenin complex binds directly to F-actin Yamada et al, 2005), recent experimental findings using an optical trap assay have shown that strong and stable bonds between the Cadherin-Catenin complex and an actin filament form under force, probably requiring a conformational change of α-Catenin (Buckley et al, 2014). Force-dependent conformational changes in vertebrate αE-Catenin (also known as CTNNA1) regulate its binding to Vinculin, an actin-binding protein, and reinforce intercellular adhesion (Kim et al, 2015;le Duc et al, 2010;Yao et al, 2014;Yonemura et al, 2010). Moreover, using a fluorescence resonance energy transfer (FRET) tension sensor, it has been shown that the actomyosin cytoskeleton exerts tensile forces on E-Cadherin in an α-Catenin-dependent manner (Borghi et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

α-Catenin stabilises Cadherin–Catenin complexes and modulates actomyosin dynamics to allow pulsatile apical contraction

Jurado

Navascués

Gorfinkiel

2016

Journal of Cell Science

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We have investigated how cell contractility and adhesion are functionally integrated during epithelial morphogenesis. To this end, we have analysed the role of α-Catenin, a key molecule linking E-Cadherin-based adhesion and the actomyosin cytoskeleton, during Drosophila embryonic dorsal closure, by studying a newly developed allelic series. We find that α-Catenin regulates pulsatile apical contraction in the amnioserosa, the main force-generating tissue driving closure of the embryonic epidermis. α-Catenin controls actomyosin dynamics by stabilising and promoting the formation of actomyosin foci, and also stabilises DE-Cadherin (Drosophila E-Cadherin, also known as Shotgun) at the cell membrane, suggesting that medioapical actomyosin contractility regulates junction stability. Furthermore, we uncover a genetic interaction between α-Catenin and Vinculin, and a tension-dependent recruitment of Vinculin to amniosersoa apical cell membranes, suggesting the existence of a mechano-sensitive module operating in this tissue.

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“…The rudiments of intercellular mechanotransduction mechanisms have been identified in only a few cases (Barry et al, 2014;Collins et al, 2012;Kim et al, 2015;le Duc et al, 2010;Tzima et al, 2005;Yonemura et al, 2010). E-cadherin complexes at epithelial intercellular junctions are force sensitive (Barry et al, 2014;le Duc et al, 2010;Thomas et al, 2013;Yonemura et al, 2010), and α-catenin is an identified force-transducing protein in these complexes (Yonemura et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

E-cadherin-mediated force transduction signals regulate global cell mechanics

Muhamed

Sehgal

et al. 2016

Journal of Cell Science

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104

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This report elucidates an E-cadherin-based force-transduction pathway that triggers changes in cell mechanics through a mechanism requiring epidermal growth factor receptor (EGFR), phosphoinositide 3-kinase (PI3K), and the downstream formation of new integrin adhesions. This mechanism operates in addition to local cytoskeletal remodeling triggered by conformational changes in the E-cadherin-associated protein α-catenin, at sites of mechanical perturbation. Studies using magnetic twisting cytometry (MTC), together with traction force microscopy (TFM) and confocal imaging identified force-activated E-cadherin-specific signals that integrate cadherin force transduction, integrin activation and cell contractility. EGFR is required for the downstream activation of PI3K and myosin-II-dependent cell stiffening. Our findings also demonstrated that α-catenin-dependent cytoskeletal remodeling at perturbed E-cadherin adhesions does not require cell stiffening. These results broaden the repertoire of E-cadherin-based force transduction mechanisms, and define the force-sensitive signaling network underlying the mechano-chemical integration of spatially segregated adhesion receptors.

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Dynamic Visualization of α-Catenin Reveals Rapid, Reversible Conformation Switching between Tension States

Cited by 143 publications

References 37 publications

Structural Determinants of the Mechanical Stability of α-Catenin

Structural Determinants of the Mechanical Stability of α-Catenin

α-Catenin stabilises Cadherin–Catenin complexes and modulates actomyosin dynamics to allow pulsatile apical contraction

E-cadherin-mediated force transduction signals regulate global cell mechanics

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