Universality of clone dynamics during tissue development
Universality of clone dynamics during tissue development
The emergence of complex organs is driven by the coordinated proliferation, migration and differentiation of precursor cells. The fate behaviour of these cells is reflected in the time evolution of their progeny, termed clones, which serve as a key experimental observable. In adult tissues, where cell dynamics is constrained by the condition of homeostasis, clonal tracing studies based on transgenic animal models have advanced our understanding of cell fate behaviour and its dysregulation in disease1,2. But what can be learnt from clonal dynamics in development, where the spatial cohesiveness of clones is impaired by tissue deformations during tissue growth? Drawing on the results of clonal tracing studies, we show that, despite the complexity of organ development, clonal dynamics may converge to a critical state characterized by universal scaling behaviour of clone sizes. By mapping clonal dynamics onto a generalization of the classical theory of aerosols, we elucidate the origin and range of scaling behaviours and show how the identification of universal scaling dependences may allow lineage-specific information to be distilled from experiments. Our study shows the emergence of core concepts of statistical physics in an unexpected context, identifying cellular systems as a laboratory to study non-equilibrium statistical physics.
Atomic,Classical and Continuum Physics,Complex Systems,Condensed Matter Physics,Mathematical and Computational Physics,Molecular,Optical and Plasma Physics,Physics,Theoretical,general
469-474
Rulands, Steffen
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Lescroart, Fabienne
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Chabab, Samira
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Hindley, Christopher J.
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Prior, Nicole
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Sznurkowska, Magdalena K.
be5655db-fc33-471e-ba16-46a92a971fae
Huch, Meritxell
defdc21f-6ca2-4a97-ab38-436adce9d37c
Philpott, Anna
b0150842-7865-4a18-b807-64a5c8b316b1
Blanpain, Cedric
15064108-025f-44e2-a5e1-8020d829160a
Simons, Benjamin D.
02e0ea52-9b7f-4b80-a856-a22cc1991ba3
1 May 2018
Rulands, Steffen
a7e89444-6d35-4f18-804c-0c8b32c61fa7
Lescroart, Fabienne
62f5f025-b98f-4e0a-8680-3370033ae34e
Chabab, Samira
744628db-8fc4-4182-bcda-6e9cc2f7147c
Hindley, Christopher J.
3f009c77-55b7-4810-b741-6a67618e1406
Prior, Nicole
27851f03-6041-4409-a15c-a2a164b883e0
Sznurkowska, Magdalena K.
be5655db-fc33-471e-ba16-46a92a971fae
Huch, Meritxell
defdc21f-6ca2-4a97-ab38-436adce9d37c
Philpott, Anna
b0150842-7865-4a18-b807-64a5c8b316b1
Blanpain, Cedric
15064108-025f-44e2-a5e1-8020d829160a
Simons, Benjamin D.
02e0ea52-9b7f-4b80-a856-a22cc1991ba3
Rulands, Steffen, Lescroart, Fabienne, Chabab, Samira, Hindley, Christopher J., Prior, Nicole, Sznurkowska, Magdalena K., Huch, Meritxell, Philpott, Anna, Blanpain, Cedric and Simons, Benjamin D.
(2018)
Universality of clone dynamics during tissue development.
Nature Physics, 14, .
(doi:10.1038/s41567-018-0055-6).
Abstract
The emergence of complex organs is driven by the coordinated proliferation, migration and differentiation of precursor cells. The fate behaviour of these cells is reflected in the time evolution of their progeny, termed clones, which serve as a key experimental observable. In adult tissues, where cell dynamics is constrained by the condition of homeostasis, clonal tracing studies based on transgenic animal models have advanced our understanding of cell fate behaviour and its dysregulation in disease1,2. But what can be learnt from clonal dynamics in development, where the spatial cohesiveness of clones is impaired by tissue deformations during tissue growth? Drawing on the results of clonal tracing studies, we show that, despite the complexity of organ development, clonal dynamics may converge to a critical state characterized by universal scaling behaviour of clone sizes. By mapping clonal dynamics onto a generalization of the classical theory of aerosols, we elucidate the origin and range of scaling behaviours and show how the identification of universal scaling dependences may allow lineage-specific information to be distilled from experiments. Our study shows the emergence of core concepts of statistical physics in an unexpected context, identifying cellular systems as a laboratory to study non-equilibrium statistical physics.
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More information
Accepted/In Press date: 23 January 2018
e-pub ahead of print date: 26 February 2018
Published date: 1 May 2018
Keywords:
Atomic,Classical and Continuum Physics,Complex Systems,Condensed Matter Physics,Mathematical and Computational Physics,Molecular,Optical and Plasma Physics,Physics,Theoretical,general
Identifiers
Local EPrints ID: 441782
URI: http://eprints.soton.ac.uk/id/eprint/441782
ISSN: 1745-2473
PURE UUID: 02e928c1-813d-4c61-9cec-593ca5f10b9e
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Date deposited: 26 Jun 2020 16:45
Last modified: 17 Mar 2024 04:02
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Contributors
Author:
Steffen Rulands
Author:
Fabienne Lescroart
Author:
Samira Chabab
Author:
Christopher J. Hindley
Author:
Magdalena K. Sznurkowska
Author:
Meritxell Huch
Author:
Anna Philpott
Author:
Cedric Blanpain
Author:
Benjamin D. Simons
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