<p>Cancer-associated fibroblasts are major architects of the tumour stroma, where their aligned, elongated morphology forms a capsule that mechanically restrains tumour expansion. However, it is unclear how this supracellular organization emerges and persists. Here we show that fibroblasts generate a fibronectin matrix that progressively acquires the same nematic order as the cell layer, and that this matrix in turn feeds back to immobilize both cells and topological defects. Using long-term live imaging, traction force microscopy, matrix microfabrication and hydrodynamic modelling, we find that this reciprocal coupling induces an ageing process in which cellular flows and defect motion slow dramatically and ultimately freeze. Despite this arrest, the monolayer remains active, with defects concentrating contractile forces that may represent mechanical weak points. Disrupting fibronectin production fluidizes the capsule, reactivates defect dynamics and compromises its barrier-like function. These findings reveal a self-organizing mechanism by which fibroblasts and their matrix co-evolve to create a mechanically stable, yet active, stromal architecture with direct implications for tumour dissemination.</p>

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Fibronectin matrix remodelling modulates the active nematic dynamics of cancer-associated fibroblasts

  • Cécile Jacques,
  • Louisiane Perrin,
  • Joseph Ackermann,
  • Samuel Bell,
  • Olivier Zajac,
  • Ambre Lapierre,
  • Lucas Anger,
  • Clément Hallopeau,
  • Carlos Pérez-González,
  • Lakshmi Balasubramaniam,
  • Xavier Trepat,
  • Benoît Ladoux,
  • Ananyo Maitra,
  • Raphael Voituriez,
  • Danijela Matic Vignjevic

摘要

Cancer-associated fibroblasts are major architects of the tumour stroma, where their aligned, elongated morphology forms a capsule that mechanically restrains tumour expansion. However, it is unclear how this supracellular organization emerges and persists. Here we show that fibroblasts generate a fibronectin matrix that progressively acquires the same nematic order as the cell layer, and that this matrix in turn feeds back to immobilize both cells and topological defects. Using long-term live imaging, traction force microscopy, matrix microfabrication and hydrodynamic modelling, we find that this reciprocal coupling induces an ageing process in which cellular flows and defect motion slow dramatically and ultimately freeze. Despite this arrest, the monolayer remains active, with defects concentrating contractile forces that may represent mechanical weak points. Disrupting fibronectin production fluidizes the capsule, reactivates defect dynamics and compromises its barrier-like function. These findings reveal a self-organizing mechanism by which fibroblasts and their matrix co-evolve to create a mechanically stable, yet active, stromal architecture with direct implications for tumour dissemination.