Substrate stiffness affects early differentiation events in embryonic stem cells
Substrate stiffness affects early differentiation events in embryonic stem cells
Embryonic stem cells (ESC) are both a potential source of cells for tissue replacement therapies and an accessible tool to model early embryonic development. Chemical factors such as soluble growth factors and insoluble components of the extracellular matrix are known to affect the differentiation of murine ESCs. However, there is also evidence to suggest that undifferentiated cells can both sense the mechanical properties of their environment and differentiate accordingly. By growing ESCs on flexible polydimethylsiloxane substrates with varying stiffness, we tested the hypothesis that substrate stiffness can influence ESC differentiation. While cell attachment was unaffected by the stiffness of the growth substrate, cell spreading and cell growth were all increased as a function of substrate stiffness. Similarly, several genes expressed in the primitive streak during gastrulation and implicated in early mesendoderm differentiation, such as Brachyury, Mixl1 and Eomes, were upregulated in cell cultures on stiffer compared to softer substrates. Finally, we demonstrated that osteogenic differentiation of ESCs was enhanced on stiff substrates compared to soft substrates, illustrating that the mechanical environment can play a role in both early and terminal ESC differentiation. Our results suggest a fundamental role for mechanosensing in mammalian development and illustrate that the mechanical environment should be taken into consideration when engineering implantable scaffolds or when producing therapeutically relevant cell populations in vitro.
Embryonic stem cells, cellular mechanotransduction, gastrulation, extracellular matrix, differentiation, mammalian development. Embryonic stem cells, mammalian development.Embryonic stem cells, differentiation mammalian development
1-14
Evans, Nicholas D.
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Minelli, Caterina
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Gentleman, Eileen
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LaPointe, Vanessa
80aa25ac-909e-4094-b135-856799e92ac7
Patankar, Sameer N.
fd36c889-3a2e-429d-b7a0-65ed36a42e6e
Kallivretaki, Maria
5c92a63f-17f2-44e0-b154-cec49addf773
Chen, Xinyong
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Roberts, Clive J.
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Stevens, Molly M.
f0c6dded-e31c-4e40-bfc4-2a70fad118a6
2009
Evans, Nicholas D.
06a05c97-bfed-4abb-9244-34ec9f4b4b95
Minelli, Caterina
78d10387-de6b-489c-b55e-a4ebbdbccf90
Gentleman, Eileen
a0b4959e-7b65-46b7-9ea8-1d0f5857c22f
LaPointe, Vanessa
80aa25ac-909e-4094-b135-856799e92ac7
Patankar, Sameer N.
fd36c889-3a2e-429d-b7a0-65ed36a42e6e
Kallivretaki, Maria
5c92a63f-17f2-44e0-b154-cec49addf773
Chen, Xinyong
6d1e3fee-a5ca-4e55-8809-b24f05beb8ca
Roberts, Clive J.
ebc3d2c0-0749-40bd-b371-cdbf022c961b
Stevens, Molly M.
f0c6dded-e31c-4e40-bfc4-2a70fad118a6
Evans, Nicholas D., Minelli, Caterina, Gentleman, Eileen, LaPointe, Vanessa, Patankar, Sameer N., Kallivretaki, Maria, Chen, Xinyong, Roberts, Clive J. and Stevens, Molly M.
(2009)
Substrate stiffness affects early differentiation events in embryonic stem cells.
European Cells & Materials, 18, .
(PMID:19768669)
Abstract
Embryonic stem cells (ESC) are both a potential source of cells for tissue replacement therapies and an accessible tool to model early embryonic development. Chemical factors such as soluble growth factors and insoluble components of the extracellular matrix are known to affect the differentiation of murine ESCs. However, there is also evidence to suggest that undifferentiated cells can both sense the mechanical properties of their environment and differentiate accordingly. By growing ESCs on flexible polydimethylsiloxane substrates with varying stiffness, we tested the hypothesis that substrate stiffness can influence ESC differentiation. While cell attachment was unaffected by the stiffness of the growth substrate, cell spreading and cell growth were all increased as a function of substrate stiffness. Similarly, several genes expressed in the primitive streak during gastrulation and implicated in early mesendoderm differentiation, such as Brachyury, Mixl1 and Eomes, were upregulated in cell cultures on stiffer compared to softer substrates. Finally, we demonstrated that osteogenic differentiation of ESCs was enhanced on stiff substrates compared to soft substrates, illustrating that the mechanical environment can play a role in both early and terminal ESC differentiation. Our results suggest a fundamental role for mechanosensing in mammalian development and illustrate that the mechanical environment should be taken into consideration when engineering implantable scaffolds or when producing therapeutically relevant cell populations in vitro.
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Published date: 2009
Keywords:
Embryonic stem cells, cellular mechanotransduction, gastrulation, extracellular matrix, differentiation, mammalian development. Embryonic stem cells, mammalian development.Embryonic stem cells, differentiation mammalian development
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Local EPrints ID: 176177
URI: http://eprints.soton.ac.uk/id/eprint/176177
PURE UUID: a4c57b6d-c2b8-4ebc-9ce4-99104be89dd0
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Date deposited: 04 Mar 2011 10:11
Last modified: 03 Nov 2022 02:43
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Contributors
Author:
Caterina Minelli
Author:
Eileen Gentleman
Author:
Vanessa LaPointe
Author:
Sameer N. Patankar
Author:
Maria Kallivretaki
Author:
Xinyong Chen
Author:
Clive J. Roberts
Author:
Molly M. Stevens
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