Integrin Molecular Tension within Motile Focal Adhesions

Forces transmitted by integrins regulate many important cellular functions. Previously, we developed tension gauge tether (TGT) as a molecular force sensor and determined the threshold tension across a single integrin-ligand bond, termed integrin tension, required for initial cell adhesion. Here, we...

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Veröffentlicht in:	Biophysical journal 2015-12, Vol.109 (11), p.2259-2267
Hauptverfasser:	Wang, Xuefeng, Sun, Jie, Xu, Qian, Chowdhury, Farhan, Roein-Peikar, Mehdi, Wang, Yingxiao, Ha, Taekjip
Format:	Artikel
Sprache:	eng
Schlagworte:	Actomyosin - metabolism Animals Base Sequence Biological Transport Biomechanical Phenomena Cell Adhesion Cell adhesion & migration Cell Biophysics CHO Cells Cricetinae Cricetulus DNA, Single-Stranded - genetics DNA, Single-Stranded - metabolism Fluorescence Fluorescent Dyes - metabolism Focal Adhesions - metabolism Immobilized Proteins - metabolism Integrins - metabolism Ligands Mechanical Phenomena Molecules Tension
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creator	Wang, Xuefeng Sun, Jie Xu, Qian Chowdhury, Farhan Roein-Peikar, Mehdi Wang, Yingxiao Ha, Taekjip
description	Forces transmitted by integrins regulate many important cellular functions. Previously, we developed tension gauge tether (TGT) as a molecular force sensor and determined the threshold tension across a single integrin-ligand bond, termed integrin tension, required for initial cell adhesion. Here, we used fluorescently labeled TGTs to study the magnitude and spatial distribution of integrin tension on the cell-substratum interface. We observed two distinct levels of integrin tension. A >54 pN molecular tension is transmitted by clustered integrins in motile focal adhesions (FAs) and such force is generated by actomyosin, whereas the previously reported ∼40 pN integrin tension is transmitted by integrins before FA formation and is independent of actomyosin. We then studied FA motility using a TGT-coated surface as a fluorescent canvas, which records the history of integrin force activity. Our data suggest that the region of the strongest integrin force overlaps with the center of a motile FA within 0.2 μm resolution. We also found that FAs move in pairs and that the asymmetry in the motility of an FA pair is dependent on the initial FA locations on the cell-substratum interface.
doi_str_mv	10.1016/j.bpj.2015.10.029
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Previously, we developed tension gauge tether (TGT) as a molecular force sensor and determined the threshold tension across a single integrin-ligand bond, termed integrin tension, required for initial cell adhesion. Here, we used fluorescently labeled TGTs to study the magnitude and spatial distribution of integrin tension on the cell-substratum interface. We observed two distinct levels of integrin tension. A >54 pN molecular tension is transmitted by clustered integrins in motile focal adhesions (FAs) and such force is generated by actomyosin, whereas the previously reported ∼40 pN integrin tension is transmitted by integrins before FA formation and is independent of actomyosin. We then studied FA motility using a TGT-coated surface as a fluorescent canvas, which records the history of integrin force activity. Our data suggest that the region of the strongest integrin force overlaps with the center of a motile FA within 0.2 μm resolution. 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Previously, we developed tension gauge tether (TGT) as a molecular force sensor and determined the threshold tension across a single integrin-ligand bond, termed integrin tension, required for initial cell adhesion. Here, we used fluorescently labeled TGTs to study the magnitude and spatial distribution of integrin tension on the cell-substratum interface. We observed two distinct levels of integrin tension. A >54 pN molecular tension is transmitted by clustered integrins in motile focal adhesions (FAs) and such force is generated by actomyosin, whereas the previously reported ∼40 pN integrin tension is transmitted by integrins before FA formation and is independent of actomyosin. We then studied FA motility using a TGT-coated surface as a fluorescent canvas, which records the history of integrin force activity. Our data suggest that the region of the strongest integrin force overlaps with the center of a motile FA within 0.2 μm resolution. 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subjects	Actomyosin - metabolism Animals Base Sequence Biological Transport Biomechanical Phenomena Cell Adhesion Cell adhesion & migration Cell Biophysics CHO Cells Cricetinae Cricetulus DNA, Single-Stranded - genetics DNA, Single-Stranded - metabolism Fluorescence Fluorescent Dyes - metabolism Focal Adhesions - metabolism Immobilized Proteins - metabolism Integrins - metabolism Ligands Mechanical Phenomena Molecules Tension
title	Integrin Molecular Tension within Motile Focal Adhesions
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