How vinculin regulates force transmission

Dumbauld, David W.; Lee, Ted T.; Singh, Ankur; Scrimgeour, Jan; Gersbach, Charles A.; Zamir, Evan A.; Fu, Jianping; Chen, Christopher; Curtis, Jennifer E.; Craig, Susan W.; Garcı́a, Andrés J.

doi:10.1073/pnas.1216209110

Cited by 219 publications

(256 citation statements)

References 44 publications

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“…2, we observed a similar hierarchical organization of FA proteins along the z-dimension, with the N-C polarized orientation of talin that seems to span the FA core, linking with actin stress fibers. These results suggest that vinculin is dispensable for the stratified nanoscale architecture of FAs, consistent with previous studies documenting FA assembly and maturation in the absence of vinculin (33,34).…”

Section: Resultssupporting

confidence: 81%

Talin determines the nanoscale architecture of focal adhesions

Liu

Wang

Goh

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

180

169

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Insight into how molecular machines perform their biological functions depends on knowledge of the spatial organization of the components, their connectivity, geometry, and organizational hierarchy. However, these parameters are difficult to determine in multicomponent assemblies such as integrin-based focal adhesions (FAs). We have previously applied 3D superresolution fluorescence microscopy to probe the spatial organization of major FA components, observing a nanoscale stratification of proteins between integrins and the actin cytoskeleton. Here we combine superresolution imaging techniques with a protein engineering approach to investigate how such nanoscale architecture arises. We demonstrate that talin plays a key structural role in regulating the nanoscale architecture of FAs, akin to a molecular ruler. Talin diagonally spans the FA core, with its N terminus at the membrane and C terminus demarcating the FA/stress fiber interface. In contrast, vinculin is found to be dispensable for specification of FA nanoscale architecture. Recombinant analogs of talin with modified lengths recapitulated its polarized orientation but altered the FA/stress fiber interface in a linear manner, consistent with its modular structure, and implicating the integrin-talin-actin complex as the primary mechanical linkage in FAs. Talin was found to be ∼97 nm in length and oriented at ∼15°relative to the plasma membrane. Our results identify talin as the primary determinant of FA nanoscale organization and suggest how multiple cellular forces may be integrated at adhesion sites.superresolution microscopy | focal adhesions | talin | mechanobiology | nanoscale architecture C ell adhesion to the ECM is a highly coordinated process that involves ECM-specific recognition by integrin transmembrane receptors, and their aggregation with numerous cytoplasmic proteins into dense supramolecular complexes called focal adhesions (FAs) (1). Actin stress fibers terminate at FAs where actomyosin contractility is transmitted to the ECM, generating traction (2-5). Mechanical tension impinging on each FA is implicated in key steps including the elongation, reinforcement, and maintenance of the FA structures (6). FA mechanotransduction is a major aspect of cellular microenvironment sensing with wide-ranging consequences in physiological and pathological processes (7-10). However, molecular-scale spatial parameters that specify FA nanoscale organization have been difficult to access experimentally. Nevertheless, these are essential to understand how mechanosensitivity arises within such complex molecular machines (11-15).Previously 3D superresolution fluorescence microscopy has unveiled the nanoscale organization of major FA components, whereby a core region of ∼30 nm interposes between the integrin and the actin cytoskeleton along the vertical (z) axis (16). The FA core consists of a membrane-proximal layer that contains signaling proteins such as FAK (focal adhesion kinase) and paxillin, an intermediate zone that contains force-transduction proteins s...

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Section: Resultssupporting

confidence: 81%

Talin determines the nanoscale architecture of focal adhesions

Liu

Wang

Goh

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

180

169

View full text Add to dashboard Cite

show abstract

“…The interaction of vinculin with acidic phospholipids and ␣-actinin may also contribute to the conversion of vinculin to an open conformation (33)(34)(35). Mechanical forces exerted on cells may also promote stabilization of the activated open conformation of vinculin (36). Changes in the conformation of vinculin enable it to act as a molecular switch for connections between cytoskeletal actin filaments and membrane adhesion protein complexes during stimulation of the cell and thus regulate the transmission of mechanical forces between the cytoskeleton and the extracellular matrix during contraction, adhesion, and migration.…”

mentioning

confidence: 99%

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

Huang

Day

Gunst

2014

Journal of Biological Chemistry

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“…To better understand the relative contribution of these two interfaces to FA force transfer as well as the force transfer pathway within FAs, we examined the traction force and adhesions strength of two vinculin mutants: (1) a molecule comprising only V H (1-851) and lacking most of the proline-rich strap and actinbinding tail, and (2) a full-length vinculin (T12) with mutations in several key residues responsible for the strong head-tail interaction, promoting an active confirmation of the protein capable of readily binding talin and actin. 3 We found that V H does not increase traction force whereas T12 increased traction force by 2-fold over vinculin-null cells and 40% over wild-type vinculin, suggesting that connectivity between extracellular matrixintegrin clusters and the actin CSK is required for the generation of strong traction forces. These vinculin-mediated increases in traction force could be mediated by direct and indirect interactions with the actin CSK.…”

Section: Vinculin Regulates But Is Not Required For the Generation mentioning

confidence: 84%

“…Indeed, the study of force-FA relationships is the central focus of our lab. [2][3][4][5][6] FAs regulate their size, shape, and molecular composition in response to a variety of mechanical stimuli, including substrate stiffness, externally applied forces, and internally generated contractile forces. 7,8 The molecular mechanisms that govern FA mechanoresponses remain, however, largely unknown.…”

Section: A Helping Handmentioning

confidence: 99%

“…4,5 Having established the contribution of endogenous vinculin to adhesion strength, our most recent experiments focused on elucidating the relative contributions of the structural domains of vinculin to force transfer at FAs -a key output of FA mechanotransduction. 3 Using vinculin-null cells expressing vinculin mutants, we first analyzed the contributions of vinculin to two quantitative measures of cellular force: (1) traction force and (2) adhesion strength. Traction force measures the magnitude and direction of internally generated forces as they are applied through FAs to the extracellular matrix.…”

Section: Vinculin Regulates But Is Not Required For the Generation mentioning

confidence: 99%

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