Skip to main content
Journal cover image

Probe Sensitivity to Cortical versus Intracellular Cytoskeletal Network Stiffness.

Publication ,  Journal Article
Vahabikashi, A; Park, CY; Perkumas, K; Zhang, Z; Deurloo, EK; Wu, H; Weitz, DA; Stamer, WD; Goldman, RD; Fredberg, JJ; Johnson, M
Published in: Biophys J
February 5, 2019

In development, wound healing, and pathology, cell biomechanical properties are increasingly recognized as being of central importance. To measure these properties, experimental probes of various types have been developed, but how each probe reflects the properties of heterogeneous cell regions has remained obscure. To better understand differences attributable to the probe technology, as well as to define the relative sensitivity of each probe to different cellular structures, here we took a comprehensive approach. We studied two cell types-Schlemm's canal endothelial cells and mouse embryonic fibroblasts (MEFs)-using four different probe technologies: 1) atomic force microscopy (AFM) with sharp tip, 2) AFM with round tip, 3) optical magnetic twisting cytometry (OMTC), and 4) traction microscopy (TM). Perturbation of Schlemm's canal cells with dexamethasone treatment, α-actinin overexpression, or RhoA overexpression caused increases in traction reported by TM and stiffness reported by sharp-tip AFM as compared to corresponding controls. By contrast, under these same experimental conditions, stiffness reported by round-tip AFM and by OMTC indicated little change. Knockout (KO) of vimentin in MEFs caused a diminution of traction reported by TM, as well as stiffness reported by sharp-tip and round-tip AFM. However, stiffness reported by OMTC in vimentin-KO MEFs was greater than in wild type. Finite-element analysis demonstrated that this paradoxical OMTC result in vimentin-KO MEFs could be attributed to reduced cell thickness. Our results also suggest that vimentin contributes not only to intracellular network stiffness but also cortex stiffness. Taken together, this evidence suggests that AFM sharp tip and TM emphasize properties of the actin-rich shell of the cell, whereas round-tip AFM and OMTC emphasize those of the noncortical intracellular network.

Duke Scholars

Altmetric Attention Stats
Dimensions Citation Stats

Published In

Biophys J

DOI

EISSN

1542-0086

Publication Date

February 5, 2019

Volume

116

Issue

3

Start / End Page

518 / 529

Location

United States

Related Subject Headings

  • Vimentin
  • Mice
  • Mechanical Phenomena
  • Humans
  • Gene Knockout Techniques
  • Fibroblasts
  • Endothelial Cells
  • Cytoskeleton
  • Biophysics
  • Biomechanical Phenomena
 

Citation

APA
Chicago
ICMJE
MLA
NLM
Vahabikashi, A., Park, C. Y., Perkumas, K., Zhang, Z., Deurloo, E. K., Wu, H., … Johnson, M. (2019). Probe Sensitivity to Cortical versus Intracellular Cytoskeletal Network Stiffness. Biophys J, 116(3), 518–529. https://doi.org/10.1016/j.bpj.2018.12.021
Vahabikashi, Amir, Chan Young Park, Kristin Perkumas, Zhiguo Zhang, Emily K. Deurloo, Huayin Wu, David A. Weitz, et al. “Probe Sensitivity to Cortical versus Intracellular Cytoskeletal Network Stiffness.Biophys J 116, no. 3 (February 5, 2019): 518–29. https://doi.org/10.1016/j.bpj.2018.12.021.
Vahabikashi A, Park CY, Perkumas K, Zhang Z, Deurloo EK, Wu H, et al. Probe Sensitivity to Cortical versus Intracellular Cytoskeletal Network Stiffness. Biophys J. 2019 Feb 5;116(3):518–29.
Vahabikashi, Amir, et al. “Probe Sensitivity to Cortical versus Intracellular Cytoskeletal Network Stiffness.Biophys J, vol. 116, no. 3, Feb. 2019, pp. 518–29. Pubmed, doi:10.1016/j.bpj.2018.12.021.
Vahabikashi A, Park CY, Perkumas K, Zhang Z, Deurloo EK, Wu H, Weitz DA, Stamer WD, Goldman RD, Fredberg JJ, Johnson M. Probe Sensitivity to Cortical versus Intracellular Cytoskeletal Network Stiffness. Biophys J. 2019 Feb 5;116(3):518–529.
Journal cover image

Published In

Biophys J

DOI

EISSN

1542-0086

Publication Date

February 5, 2019

Volume

116

Issue

3

Start / End Page

518 / 529

Location

United States

Related Subject Headings

  • Vimentin
  • Mice
  • Mechanical Phenomena
  • Humans
  • Gene Knockout Techniques
  • Fibroblasts
  • Endothelial Cells
  • Cytoskeleton
  • Biophysics
  • Biomechanical Phenomena