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Author Notes:

Corresponding Author: k.salaita@emory.edu

The manuscript was written through contributions of all authors. All authors have given approval to the final version of the manuscript.

We thank Dr. Oskar Laur from Custom Cloning Core Facility Yerkes-Microbiology at Emory University for sequencing all the plasmids.

We thank Leann Quertinmont (Emory University) for DH5-alpha and BL21(DE3) competent E. coli cells.

We thank Dr. Benjamin Geiger (Department of Molecular Cell Biology at Weizmann Institute) for REF cells stably expressing GFP-tagged β3-integrins.

We also thank Dr. Ada Cavalcanti-Adam (Max Planck Institute for Intelligent Systems, Stuttgart, Germany) for plasmid encoding mCherry-lifeact.

Subjects:

Research Funding:

K.S. acknowledges support from the NIH (R01-GM097399), the Alfred P. Sloan Research Fellowship, and the NSF CAREER award.

Keywords:

  • Science & Technology
  • Physical Sciences
  • Technology
  • Chemistry, Multidisciplinary
  • Chemistry, Physical
  • Nanoscience & Nanotechnology
  • Materials Science, Multidisciplinary
  • Physics, Applied
  • Physics, Condensed Matter
  • Chemistry
  • Science & Technology - Other Topics
  • Materials Science
  • Physics
  • Integrins
  • mechanotransduction
  • biophysics
  • focal adhesion
  • CELL-ADHESION
  • IMMUNOGLOBULIN DOMAINS
  • MECHANICAL TENSION
  • DYNAMICS
  • MECHANOTRANSDUCTION
  • PROTEIN
  • PROBES
  • ARCHITECTURE
  • MICROSCOPY
  • MIGRATION

Titin-Based Nanoparticle Tension Sensors Map High-Magnitude Integrin Forces within Focal Adhesions

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Journal Title:

Nano Letters

Volume:

Volume 16, Number 1

Publisher:

, Pages 341-348

Type of Work:

Article | Post-print: After Peer Review

Abstract:

Mechanical forces transmitted through integrin transmembrane receptors play important roles in a variety of cellular processes ranging from cell development to tumorigenesis. Despite the importance of mechanics in integrin function, the magnitude of integrin forces within adhesions remains unclear. Literature suggests a range from 1 to 50 pN, but the upper limit of integrin forces remains unknown. Herein we challenge integrins with the most mechanically stable molecular tension probe, which is comprised of the immunoglobulin 27th (I27) domain of cardiac titin flanked with a fluorophore and gold nanoparticle. Cell experiments show that integrin forces unfold the I27 domain, suggesting that integrin forces exceed 30-40 pN. The addition of a disulfide bridge within I27 clamps the probe and resists mechanical unfolding. Importantly, incubation with a reducing agent initiates SH exchange, thus unclamping I27 at a rate that is dependent on the applied force. By recording the rate of S-S reduction in clamped I27, we infer that integrins apply 110 ± 9 pN within focal adhesions of rat embryonic fibroblasts. The rates of S-S exchange are heterogeneous and integrin subtype-dependent. Nanoparticle titin tension sensors along with kinetic analysis of unfolding demonstrate that a subset of integrins apply tension many fold greater than previously reported.

Copyright information:

© 2015 American Chemical Society

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