Litcius/Paper detail

Topology-guided polar ordering of collective cell migration

Emma Lång, Anna Lång, Pernille Blicher, Torbjørn Rognes, Paul Dommersnes, Stig Ove Bøe

2024Science Advances19 citationsDOIOpen Access PDF

Abstract

The ability of epithelial monolayers to self-organize into a dynamic polarized state, where cells migrate in a uniform direction, is essential for tissue regeneration, development, and tumor progression. However, the mechanisms governing long-range polar ordering of motility direction in biological tissues remain unclear. Here, we investigate the self-organizing behavior of quiescent epithelial monolayers that transit to a dynamic state with long-range polar order upon growth factor exposure. We demonstrate that the heightened self-propelled activity of monolayer cells leads to formation of vortex-antivortex pairs that undergo sequential annihilation, ultimately driving the spread of long-range polar order throughout the system. A computational model, which treats the monolayer as an active elastic solid, accurately replicates this behavior, and weakening of cell-to-cell interactions impedes vortex-antivortex annihilation and polar ordering. Our findings uncover a mechanism in epithelia, where elastic solid material characteristics, activated self-propulsion, and topology-mediated guidance converge to fuel a highly efficient polar self-ordering activity.

Topics & Concepts

PolarTopology (electrical circuits)MonolayerAnnihilationMotilityVortexOrder (exchange)Cell polarityActive matterPhysicsBiophysicsChemical physicsCellMaterials scienceNanotechnologyChemistryCell biologyBiologyMechanicsMathematicsBiochemistryAstronomyQuantum mechanicsFinanceEconomicsCombinatoricsMicro and Nano RoboticsCellular Mechanics and InteractionsAdvanced Materials and Mechanics