Reciprocal intra- and extra-cellular polarity enables deep mechanosensing through layered matrices

Christopher Walter, Jairaj Mathur, Amit Pathak

Research output: Contribution to journalArticlepeer-review

1 Scopus citations

Abstract

Adherent cells migrate on layered tissue interfaces to drive morphogenesis, wound healing, and tumor invasion. Although stiffer surfaces are known to enhance cell migration, it remains unclear whether cells sense basal stiff environments buried under softer, fibrous matrix. Using layered collagen-polyacrylamide gel systems, we unveil a migration phenotype driven by cell-matrix polarity. Here, cancer (but not normal) cells with stiff base matrix generate stable protrusions, faster migration, and greater collagen deformation because of “depth mechanosensing” through the top collagen layer. Cancer cell protrusions with front-rear polarity produce polarized collagen stiffening and deformations. Disruption of either extracellular or intracellular polarity via collagen crosslinking, laser ablation, or Arp2/3 inhibition independently abrogates depth-mechanosensitive migration of cancer cells. Our experimental findings, validated by lattice-based energy minimization modeling, present a cell migration mechanism whereby polarized cellular protrusions and contractility are reciprocated by mechanical extracellular polarity, culminating in a cell-type-dependent ability to mechanosense through matrix layers.

Original languageEnglish
Article number112362
JournalCell Reports
Volume42
Issue number4
DOIs
StatePublished - Apr 25 2023

Keywords

  • CP: Cell biology
  • atomic force microscopy
  • cell migration
  • cell polarity
  • collagen
  • depth sensing
  • extracellular matrix polarity
  • laser ablation
  • layered matrix
  • mechanobiology
  • mechanosensing

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