Microscale mechanisms of agarose-induced disruption of collagen remodeling

Theresa A. Ulrich; Tae Geol Lee; Hyun Kyong Shon; Dae Won Moon; Sanjay Kumar

doi:10.1016/j.biomaterials.2011.04.045

Microscale mechanisms of agarose-induced disruption of collagen remodeling

Theresa A. Ulrich, Tae Geol Lee, Hyun Kyong Shon, Dae Won Moon, Sanjay Kumar

Department of New Biology

Research output: Contribution to journal › Article › peer-review

50 Scopus citations

Abstract

Cells are strongly influenced by the local structure and mechanics of the extracellular matrix (ECM). We recently showed that adding agarose to soft collagen ECMs can mechanically stiffen these hydrogels by two orders of magnitude while limiting 3D cell motility, which we speculated might derive from agarose-mediated inhibition of collagen fiber deformation and remodeling. Here, we directly address this hypothesis by investigating the effects of agarose on cell-collagen interactions at the microscale. Addition of agarose progressively restricts cell spreading, reduces stress fiber and focal adhesion assembly, and inhibits macroscopic gel compaction. While time-of-flight secondary ion mass spectrometry and scanning electron microscopy fail to reveal agarose-induced alterations in collagen ligand presentation, the latter modality shows that agarose strongly impairs cell-directed assembly of large collagen bundles. Agarose-mediated inhibition of cell spreading and cytoarchitecture can be rescued by β-agarase digestion or by covalently crosslinking the matrix with glutaraldehyde. Based on these results, we argue that cell spreading and motility on collagen requires local matrix stiffening, which can be achieved via cell-mediated fiber remodeling or by chemically crosslinking the fibers. These findings provide new mechanistic insights into the regulatory function of agarose and bear general implications for cell adhesion and motility in fibrous ECMs.

Original language	English
Pages (from-to)	5633-5642
Number of pages	10
Journal	Biomaterials
Volume	32
Issue number	24
DOIs	https://doi.org/10.1016/j.biomaterials.2011.04.045
State	Published - Aug 2011

Bibliographical note

Funding Information:
We thank D. Leong (Technical Instruments) for assistance with equipment and software, and Dr. G. Min at the Electron Microscopy Laboratory at UC Berkeley for assistance with scanning electron microscopy. TAU gratefully acknowledges the support of the UC Berkeley Graduate Division, National Science Foundation, and National Defense Science and Engineering Graduate Fellowships. SK gratefully acknowledges grant support from UC Berkeley, the UC Cancer Research Coordinating Committee, the Arnold and Mabel Beckman Young Investigator Award, NSF ( CMMI 0727420 ), and NIH (Physical Sciences Oncology Center Grant 1U54CA143836 ; Director’s New Innovator Award 1DP2OD004213, a part of the NIH Roadmap for Medical Research). TGL gratefully acknowledges grant support from the Bio-Signal Analysis Technology Innovation Program of the MEST, South Korea.

Keywords

Brain
Cell adhesion
ECM (extracellular matrix)
Elasticity
Hydrogel
Mechanical properties

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10.1016/j.biomaterials.2011.04.045

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title = "Microscale mechanisms of agarose-induced disruption of collagen remodeling",

abstract = "Cells are strongly influenced by the local structure and mechanics of the extracellular matrix (ECM). We recently showed that adding agarose to soft collagen ECMs can mechanically stiffen these hydrogels by two orders of magnitude while limiting 3D cell motility, which we speculated might derive from agarose-mediated inhibition of collagen fiber deformation and remodeling. Here, we directly address this hypothesis by investigating the effects of agarose on cell-collagen interactions at the microscale. Addition of agarose progressively restricts cell spreading, reduces stress fiber and focal adhesion assembly, and inhibits macroscopic gel compaction. While time-of-flight secondary ion mass spectrometry and scanning electron microscopy fail to reveal agarose-induced alterations in collagen ligand presentation, the latter modality shows that agarose strongly impairs cell-directed assembly of large collagen bundles. Agarose-mediated inhibition of cell spreading and cytoarchitecture can be rescued by β-agarase digestion or by covalently crosslinking the matrix with glutaraldehyde. Based on these results, we argue that cell spreading and motility on collagen requires local matrix stiffening, which can be achieved via cell-mediated fiber remodeling or by chemically crosslinking the fibers. These findings provide new mechanistic insights into the regulatory function of agarose and bear general implications for cell adhesion and motility in fibrous ECMs.",

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author = "Ulrich, {Theresa A.} and Lee, {Tae Geol} and Shon, {Hyun Kyong} and Moon, {Dae Won} and Sanjay Kumar",

note = "Funding Information: We thank D. Leong (Technical Instruments) for assistance with equipment and software, and Dr. G. Min at the Electron Microscopy Laboratory at UC Berkeley for assistance with scanning electron microscopy. TAU gratefully acknowledges the support of the UC Berkeley Graduate Division, National Science Foundation, and National Defense Science and Engineering Graduate Fellowships. SK gratefully acknowledges grant support from UC Berkeley, the UC Cancer Research Coordinating Committee, the Arnold and Mabel Beckman Young Investigator Award, NSF ( CMMI 0727420 ), and NIH (Physical Sciences Oncology Center Grant 1U54CA143836 ; Director{\textquoteright}s New Innovator Award 1DP2OD004213, a part of the NIH Roadmap for Medical Research). TGL gratefully acknowledges grant support from the Bio-Signal Analysis Technology Innovation Program of the MEST, South Korea. ",

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AU - Kumar, Sanjay

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AB - Cells are strongly influenced by the local structure and mechanics of the extracellular matrix (ECM). We recently showed that adding agarose to soft collagen ECMs can mechanically stiffen these hydrogels by two orders of magnitude while limiting 3D cell motility, which we speculated might derive from agarose-mediated inhibition of collagen fiber deformation and remodeling. Here, we directly address this hypothesis by investigating the effects of agarose on cell-collagen interactions at the microscale. Addition of agarose progressively restricts cell spreading, reduces stress fiber and focal adhesion assembly, and inhibits macroscopic gel compaction. While time-of-flight secondary ion mass spectrometry and scanning electron microscopy fail to reveal agarose-induced alterations in collagen ligand presentation, the latter modality shows that agarose strongly impairs cell-directed assembly of large collagen bundles. Agarose-mediated inhibition of cell spreading and cytoarchitecture can be rescued by β-agarase digestion or by covalently crosslinking the matrix with glutaraldehyde. Based on these results, we argue that cell spreading and motility on collagen requires local matrix stiffening, which can be achieved via cell-mediated fiber remodeling or by chemically crosslinking the fibers. These findings provide new mechanistic insights into the regulatory function of agarose and bear general implications for cell adhesion and motility in fibrous ECMs.

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JO - Biomaterials

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ER -

Microscale mechanisms of agarose-induced disruption of collagen remodeling

Abstract

Bibliographical note

Keywords

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