Dynamic heterogeneity as a strategy of stem cell self-renewal
Dynamic heterogeneity as a strategy of stem cell self-renewal
To maintain cycling adult tissue in homeostasis the balance between proliferation and differentiation of stem cells needs to be precisely regulated. To investigate how stem cells achieve perfect self-renewal, emphasis has been placed on models in which stem cells progress sequentially through a one-way proliferative hierarchy. However, investigations of tissue regeneration have revealed a surprising degree of flexibility, with cells normally committed to differentiation able to recover stem cell competence following injury. Here, we investigate whether the reversible transfer of cells between states poised for proliferation or differentiation may provide a viable mechanism for a heterogeneous stem cell population to maintain homeostasis even under normal physiological conditions. By addressing the clonal dynamics, we show that such models of "dynamic heterogeneity" may be equally capable of describing the results of recent lineage tracing assays involving epithelial tissues. Moreover, together with competition for limited niche access, such models may provide a mechanism to render tissue homeostasis robust. In particular, in 2D epithelial layers, we show that the mechanism of dynamic heterogeneity avoids some pathological dependencies that undermine models.
7509-7514
Greulich, Philip
65da32ad-a73a-435a-86e0-e171437430a9
Simons, Benjamin D.
02e0ea52-9b7f-4b80-a856-a22cc1991ba3
5 July 2016
Greulich, Philip
65da32ad-a73a-435a-86e0-e171437430a9
Simons, Benjamin D.
02e0ea52-9b7f-4b80-a856-a22cc1991ba3
Greulich, Philip and Simons, Benjamin D.
(2016)
Dynamic heterogeneity as a strategy of stem cell self-renewal.
Proceedings of National Academy of Sciences of the United States of America, 113 (27), .
(doi:10.1073/pnas.1602779113).
Abstract
To maintain cycling adult tissue in homeostasis the balance between proliferation and differentiation of stem cells needs to be precisely regulated. To investigate how stem cells achieve perfect self-renewal, emphasis has been placed on models in which stem cells progress sequentially through a one-way proliferative hierarchy. However, investigations of tissue regeneration have revealed a surprising degree of flexibility, with cells normally committed to differentiation able to recover stem cell competence following injury. Here, we investigate whether the reversible transfer of cells between states poised for proliferation or differentiation may provide a viable mechanism for a heterogeneous stem cell population to maintain homeostasis even under normal physiological conditions. By addressing the clonal dynamics, we show that such models of "dynamic heterogeneity" may be equally capable of describing the results of recent lineage tracing assays involving epithelial tissues. Moreover, together with competition for limited niche access, such models may provide a mechanism to render tissue homeostasis robust. In particular, in 2D epithelial layers, we show that the mechanism of dynamic heterogeneity avoids some pathological dependencies that undermine models.
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Accepted/In Press date: 9 May 2016
e-pub ahead of print date: 16 June 2016
Published date: 5 July 2016
Organisations:
Applied Mathematics
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Local EPrints ID: 410447
URI: http://eprints.soton.ac.uk/id/eprint/410447
PURE UUID: b335ccf1-f86e-47ec-a165-a5cf520eb28e
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Date deposited: 08 Jun 2017 16:31
Last modified: 16 Mar 2024 04:17
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Author:
Benjamin D. Simons
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