scholarly article | Q13442814 |
P2093 | author name string | Brenton D Hoffman | |
Kasie L Collins | |||
Trevor R Ham | |||
P2860 | cites work | Quantifying Molecular Forces with Serially Connected Force Sensors | Q92560673 |
GFP's mechanical intermediate states | Q27315229 | ||
Vinculin phosphorylation at residues Y100 and Y1065 is required for cellular force transmission | Q27339859 | ||
Extracellular rigidity sensing by talin isoform-specific mechanical linkages | Q28269303 | ||
Coordinated integrin activation by actin-dependent force during T-cell migration | Q28822113 | ||
Measuring mechanical tension across vinculin reveals regulation of focal adhesion dynamics | Q29615714 | ||
Stretching single talin rod molecules activates vinculin binding | Q29617762 | ||
Cell adhesion: integrating cytoskeletal dynamics and cellular tension | Q29618066 | ||
Exploring the energy landscape of GFP by single-molecule mechanical experiments | Q30160409 | ||
Spider Silk Peptide Is a Compact, Linear Nanospring Ideal for Intracellular Tension Sensing | Q30277657 | ||
Talin tension sensor reveals novel features of focal adhesion force transmission and mechanosensitivity. | Q30355317 | ||
Hairpins under tension: RNA versus DNA. | Q30388441 | ||
Fluid shear stress on endothelial cells modulates mechanical tension across VE-cadherin and PECAM-1. | Q30412646 | ||
E-cadherin is under constitutive actomyosin-generated tension that is increased at cell-cell contacts upon externally applied stretch | Q30425577 | ||
Mechanisms of mechanotransduction. | Q30439168 | ||
Dynamic molecular processes mediate cellular mechanotransduction | Q30453937 | ||
Quantifying cellular traction forces in three dimensions | Q30492594 | ||
Tension sensing nanoparticles for mechano-imaging at the living/nonliving interface | Q30538990 | ||
Nanoparticle tension probes patterned at the nanoscale: impact of integrin clustering on force transmission | Q30590254 | ||
The cancer glycocalyx mechanically primes integrin-mediated growth and survival | Q30656235 | ||
Cooperative Vinculin Binding to Talin Mapped by Time-Resolved Super Resolution Microscopy. | Q30843071 | ||
Theory, analysis, and interpretation of single-molecule force spectroscopy experiments | Q33375593 | ||
Coordination between Intra- and Extracellular Forces Regulates Focal Adhesion Dynamics. | Q33652832 | ||
Vinculin in cell-cell and cell-matrix adhesions | Q33885204 | ||
The unfolding kinetics of ubiquitin captured with single-molecule force-clamp techniques | Q33904638 | ||
Ideal, catch, and slip bonds in cadherin adhesion | Q34461981 | ||
A DNA-based molecular probe for optically reporting cellular traction forces | Q34588696 | ||
Molecular mechanism of vinculin activation and nanoscale spatial organization in focal adhesions | Q35812139 | ||
A General Approach for Generating Fluorescent Probes to Visualize Piconewton Forces at the Cell Surface | Q35921985 | ||
An experimental study of GFP-based FRET, with application to intrinsically unstructured proteins | Q36393225 | ||
Constructing modular and universal single molecule tension sensor using protein G to study mechano-sensitive receptors. | Q36579766 | ||
Nesprin-2G, a Component of the Nuclear LINC Complex, Is Subject to Myosin-Dependent Tension | Q36724244 | ||
Defining single molecular forces required to activate integrin and notch signaling | Q37010172 | ||
Demonstration of catch bonds between an integrin and its ligand. | Q37267611 | ||
Ultrafast folding kinetics and cooperativity of villin headpiece in single-molecule force spectroscopy. | Q37318067 | ||
The mechanical integrin cycle. | Q37360851 | ||
The fibronectin synergy site re-enforces cell adhesion and mediates a crosstalk between integrin classes | Q37613896 | ||
Integrin-generated forces lead to streptavidin-biotin unbinding in cellular adhesions | Q37686053 | ||
The radial distribution function of worm-like chains. | Q37762185 | ||
Force generation, transmission, and integration during cell and tissue morphogenesis | Q37899183 | ||
Construction, imaging, and analysis of FRET-based tension sensors in living cells. | Q38339831 | ||
Molecular-Scale Tools for Studying Mechanotransduction. | Q38595692 | ||
A fluorescence energy transfer-based mechanical stress sensor for specific proteins in situ | Q38619850 | ||
The Piconewton Force Awakens: Quantifying Mechanics in Cells. | Q38932984 | ||
The Mechanics of Single Cell and Collective Migration of Tumor Cells | Q38998765 | ||
Protein unfolding under isometric tension-what force can integrins generate, and can it unfold FNIII domains? | Q39063121 | ||
Single Molecule Force Measurements in Living Cells Reveal a Minimally Tensioned Integrin State | Q39251023 | ||
Molecular stretching modulates mechanosensing pathways. | Q39285525 | ||
Cyclic mechanical reinforcement of integrin-ligand interactions | Q39540623 | ||
Titin-Based Nanoparticle Tension Sensors Map High-Magnitude Integrin Forces within Focal Adhesions. | Q41394155 | ||
Integrin extension enables ultrasensitive regulation by cytoskeletal force | Q43083575 | ||
Cell adhesion. The minimal cadherin-catenin complex binds to actin filaments under force | Q43191625 | ||
Actin retrograde flow actively aligns and orients ligand-engaged integrins in focal adhesions | Q44839017 | ||
Visualizing the interior architecture of focal adhesions with high-resolution traction maps | Q46134902 | ||
Monodisperse measurement of the biotin-streptavidin interaction strength in a well-defined pulling geometry | Q47158104 | ||
Targeting extracellular matrix stiffness to attenuate disease: From molecular mechanisms to clinical trials. | Q47202192 | ||
Mapping the 3D orientation of piconewton integrin traction forces | Q47235805 | ||
Force loading explains spatial sensing of ligands by cells | Q47277135 | ||
Molecular Tension Probes for Imaging Forces at the Cell Surface. | Q47328232 | ||
Mechanically switching single-molecule fluorescence of GFP by unfolding and refolding | Q47407846 | ||
Multiplexing molecular tension sensors reveals piconewton force gradient across talin-1. | Q47747855 | ||
Vinculin forms a directionally asymmetric catch bond with F-actin. | Q47782587 | ||
Force-Dependent Folding and Unfolding Kinetics in DNA Hairpins Reveals Transition-State Displacements along a Single Pathway | Q48048345 | ||
ATP as a biological hydrotrope. | Q48061258 | ||
Investigating piconewton forces in cells by FRET-based molecular force microscopy. | Q50527823 | ||
Mechanical unfolding pathways of the enhanced yellow fluorescent protein revealed by single molecule force spectroscopy. | Q50709417 | ||
Force-Induced Rupture of a DNA Duplex: From Fundamentals to Force Sensors. | Q50771895 | ||
Force regulated conformational change of integrin αVβ3. | Q51246524 | ||
Vinculin Force-Sensitive Dynamics at Focal Adhesions Enable Effective Directed Cell Migration. | Q52324898 | ||
Tunable molecular tension sensors reveal extension-based control of vinculin loading | Q56533245 | ||
Local Tension on Talin in Focal Adhesions Correlates with F-Actin Alignment at the Nanometer Scale | Q57114179 | ||
A small proportion of Talin molecules transmit forces at developing muscle attachments in vivo | Q64114745 | ||
Visualizing mechanical tension across membrane receptors with a fluorescent sensor | Q82257928 | ||
Control of Mechanotransduction by Molecular Clutch Dynamics | Q87927600 | ||
Programmable Multivalent DNA-Origami Tension Probes for Reporting Cellular Traction Forces | Q89133141 | ||
The Desmosomal Cadherin Desmoglein-2 Experiences Mechanical Tension as Demonstrated by a FRET-Based Tension Biosensor Expressed in Living Cells | Q89292332 | ||
Engineering the cellular mechanical microenvironment - from bulk mechanics to the nanoscale | Q91651536 | ||
P304 | page(s) | 83-94 | |
P577 | publication date | 2019-10-19 | |
P1433 | published in | Current Opinion in Biomedical Engineering | Q63882873 |
P1476 | title | Molecular Tension Sensors: Moving Beyond Force | |
P478 | volume | 12 |
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