Focal adhesion kinase activity is required for actomyosin contractility-based invasion of cells into dense 3D matrices

Claudia T Mierke,Birga Soetje,Tom Kunschmann,Wolfgang H Ziegler,Stefanie Puder,Tony Fischer

doi:10.1038/srep42780

Claudia T Mierke, Birga Soetje + Show 4 more

Open Access

https://doi.org/10.1038/srep42780

Copy DOI

Journal: Scientific Reports	Publication Date: Feb 16, 2017
Citations: 51	License type: open-access

Affiliation: Hannover Medical School, Leipzig University

Abstract

The focal adhesion kinase (FAK) regulates the dynamics of integrin-based cell adhesions important for motility. FAK’s activity regulation is involved in stress-sensing and focal-adhesion turnover. The effect of FAK on 3D migration and cellular mechanics is unclear. We analyzed FAK knock-out mouse embryonic fibroblasts and cells expressing a kinase-dead FAK mutant, R454-FAK, in comparison to FAK wild-type cells. FAK knock-out and FAKR454/R454 cells invade dense 3D matrices less efficiently. These results are supported by FAK knock-down in wild-type fibroblasts and MDA-MB-231 human breast cancer cells showing reduced invasiveness. Pharmacological interventions indicate that in 3D matrices, cells deficient in FAK or kinase-activity behave similarly to wild-type cells treated with inhibitors of Src-activity or actomyosin-contractility. Using magnetic tweezers experiments, FAKR454/R454 cells are shown to be softer and exhibit impaired adhesion to fibronectin and collagen, which is consistent with their reduced 3D invasiveness. In line with this, FAKR454/R454 cells cannot contract the matrix in contrast to FAK wild-type cells. Finally, our findings demonstrate that active FAK facilitates 3D matrix invasion through increased cellular stiffness and transmission of actomyosin-dependent contractile force in dense 3D extracellular matrices.

Highlights

focal adhesion kinase (FAK) functions in cellular mechanics as its activity depends on the rigidity of the microenvironment and it is supposed to be a mechanosensor of tissue rigidity[29,30]
These results indicate that FAK protein expression correlates with increased fibroblast invasion in dense 3D collagen matrices
Stiffness measurements revealed significantly higher mean cell stiffness when cells expressed FAK wild-type protein compared to the kinase-dead R454 FAK mutant, (Fig. 4D). These results indicate that in focal adhesions, expression of FAK wild-type protein, whose kinase activity is induced upon engagement of integrins, increases cellular stiffness and can facilitate cell migration into 3D extracellular matrices

Summary

Introduction

FAK functions in cellular mechanics as its activity depends on the rigidity of the microenvironment and it is supposed to be (part of) a mechanosensor of tissue rigidity[29,30]. Focal adhesion, or stretch-activated signaling pathways, as well as myosin II appear to act as mechanosensors. They operate by transducing signals to downstream regulatory proteins in response to the mechanical properties of the microenvironment, and, by the induction of force-dependent stress-stiffening of the cells as detected by magnetic twisting cytometry[17,32]. FAK wild-type mouse embryonic fibroblasts display increased invasiveness into 3D extracellular matrices compared to FAK knock-out cells. Knock-down of FAK (and Pyk2) in FAK wild-type fibroblasts decreased cell invasion into 3D extracellular matrices. We found that FAK activity contributes substantially to the invasiveness of fibroblasts by providing cellular signaling, which coordinates the transmission of contractile and protrusive (compressive) forces towards extracellular matrix

Objectives

Results

Conclusion