Correlated cell movements drive epithelial finger formation

Sander C. Kammeraat; Yann-Edwin Keta; Paul Appleton; Ian P. Newton; Tanniemola B. Liverpool; Rastko Sknepnek; Inke Näthke; Silke Henkes

doi:10.48550/arXiv.2508.01046

Correlated cell movements drive epithelial finger formation

Sander C. Kammeraat, Yann-Edwin Keta, Paul Appleton, Ian P. Newton, Tanniemola B. Liverpool, Rastko Sknepnek, Inke Näthke, Silke Henkes

Research output: Contribution to journal › Article (Academic Journal) › peer-review

Abstract

Epithelia form protective barriers in multicellular organisms. To maintain homeostasis, they must be able to regenerate and heal damaged areas. This occurs through collective cell migration, during which finger-like protrusions commonly appear. Whether these protrusions are driven by specialised leader cells, biochemical cues, or generic physical interactions remains unclear. Integrating in vitro imaging, agent-based simulations, and continuum modelling, we show that correlated active cell motion alone suffices to produce fingers. Leader cells, signalling, and proliferation modulate, but do not trigger, this pattern. Our results show that the key mechanism underlying a complex biological process can be understood using a general framework of the physics of dense active matter.

Original language	English
Journal	Physical Review X
DOIs	https://doi.org/10.48550/arXiv.2508.01046
Publication status	Submitted - 1 Aug 2025

Bibliographical note

13 pages, 5 figures, Supplementary Information as Appendix

Keywords

cond-mat.soft
physics.bio-ph

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10.48550/arXiv.2508.01046Licence: CC BY

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title = "Correlated cell movements drive epithelial finger formation",

abstract = "Epithelia form protective barriers in multicellular organisms. To maintain homeostasis, they must be able to regenerate and heal damaged areas. This occurs through collective cell migration, during which finger-like protrusions commonly appear. Whether these protrusions are driven by specialised leader cells, biochemical cues, or generic physical interactions remains unclear. Integrating in vitro imaging, agent-based simulations, and continuum modelling, we show that correlated active cell motion alone suffices to produce fingers. Leader cells, signalling, and proliferation modulate, but do not trigger, this pattern. Our results show that the key mechanism underlying a complex biological process can be understood using a general framework of the physics of dense active matter.",

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note = "13 pages, 5 figures, Supplementary Information as Appendix",

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doi = "10.48550/arXiv.2508.01046",

language = "English",

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T1 - Correlated cell movements drive epithelial finger formation

AU - Kammeraat, Sander C.

AU - Keta, Yann-Edwin

AU - Appleton, Paul

AU - Newton, Ian P.

AU - Liverpool, Tanniemola B.

AU - Sknepnek, Rastko

AU - Näthke, Inke

AU - Henkes, Silke

N1 - 13 pages, 5 figures, Supplementary Information as Appendix

PY - 2025/8/1

Y1 - 2025/8/1

N2 - Epithelia form protective barriers in multicellular organisms. To maintain homeostasis, they must be able to regenerate and heal damaged areas. This occurs through collective cell migration, during which finger-like protrusions commonly appear. Whether these protrusions are driven by specialised leader cells, biochemical cues, or generic physical interactions remains unclear. Integrating in vitro imaging, agent-based simulations, and continuum modelling, we show that correlated active cell motion alone suffices to produce fingers. Leader cells, signalling, and proliferation modulate, but do not trigger, this pattern. Our results show that the key mechanism underlying a complex biological process can be understood using a general framework of the physics of dense active matter.

AB - Epithelia form protective barriers in multicellular organisms. To maintain homeostasis, they must be able to regenerate and heal damaged areas. This occurs through collective cell migration, during which finger-like protrusions commonly appear. Whether these protrusions are driven by specialised leader cells, biochemical cues, or generic physical interactions remains unclear. Integrating in vitro imaging, agent-based simulations, and continuum modelling, we show that correlated active cell motion alone suffices to produce fingers. Leader cells, signalling, and proliferation modulate, but do not trigger, this pattern. Our results show that the key mechanism underlying a complex biological process can be understood using a general framework of the physics of dense active matter.

KW - cond-mat.soft

KW - physics.bio-ph

U2 - 10.48550/arXiv.2508.01046

DO - 10.48550/arXiv.2508.01046

M3 - Article (Academic Journal)

SN - 2160-3308

JO - Physical Review X

JF - Physical Review X

ER -

Correlated cell movements drive epithelial finger formation

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