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Molecular-scale substrate anisotropy, crowding and division drive collective behaviours in cell monolayers

Yimin Luo, Mengyang Gu, Minwook Park, Xinyi Fang, Younghoon Kwon, Juan Manuel Urueña, Javier Read de Alaniz, Matthew E. Helgeson, Cristina Marchetti, Megan T. Valentine

2023Journal of The Royal Society Interface26 citationsDOIOpen Access PDF

Abstract

The ability of cells to reorganize in response to external stimuli is important in areas ranging from morphogenesis to tissue engineering. While nematic order is common in biological tissues, it typically only extends to small regions of cells interacting via steric repulsion. On isotropic substrates, elongated cells can co-align due to steric effects, forming ordered but randomly oriented finite-size domains. However, we have discovered that flat substrates with nematic order can induce global nematic alignment of dense, spindle-like cells, thereby influencing cell organization and collective motion and driving alignment on the scale of the entire tissue. Remarkably, single cells are not sensitive to the substrate's anisotropy. Rather, the emergence of global nematic order is a collective phenomenon that requires both steric effects and molecular-scale anisotropy of the substrate. To quantify the rich set of behaviours afforded by this system, we analyse velocity, positional and orientational correlations for several thousand cells over days. The establishment of global order is facilitated by enhanced cell division along the substrate's nematic axis, and associated extensile stresses that restructure the cells' actomyosin networks. Our work provides a new understanding of the dynamics of cellular remodelling and organization among weakly interacting cells.

Topics & Concepts

Liquid crystalSteric effectsAnisotropySubstrate (aquarium)IsotropyChemical physicsActive matterMorphogenesisBiophysicsCollective motionMaterials scienceLength scaleOrder (exchange)NanotechnologyChemistryPhysicsBiologyStereochemistryOpticsCell biologyMechanicsClassical mechanicsOptoelectronicsEcologyGeneBiochemistryFinanceEconomicsMicro and Nano RoboticsCellular Mechanics and InteractionsAdvanced Materials and Mechanics
Molecular-scale substrate anisotropy, crowding and division drive collective behaviours in cell monolayers | Litcius