Remodeling of Fibrous Extracellular Matrices by Contractile Cells: Predictions from Discrete Fiber Network Simulations

Abhilash, A.S.; Baker, Brendon M.; Trappmann, Britta; Chen, Christopher; Shenoy, Vivek B.

doi:10.1016/j.bpj.2014.08.029

Cited by 182 publications

(237 citation statements)

References 29 publications

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“…Following our earlier work on active biopolymer networks (14,15), 2D fiber networks representing electrospun matrices were created with randomly organized linear elastic fibers and breakable cross-links. The fiber properties used in our DFN simulations were based on recent experiments on electrospun methacrylated dextran (16) scaffolds.…”

Section: Methodsmentioning

confidence: 99%

“…However, in vivo, many cells reside within 3D fibrous scaffolds where the density and diameter of fibers can vary depending on the nature of the tissue (11)(12)(13). The local architecture of these fibrous networks may change significantly when cells exert forces on them, leading to phenomena such as nonlinear stiffening, reorientation, and physical remodeling of the ECM (14,15). Our recent study on cells in synthetic fibrous matrices with tunable mechanics and userdefined architecture showed that increasing fiber stiffness suppresses spreading, in contrast to hydrogels, where increased stiffness always promotes cell spreading (16).…”

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confidence: 99%

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Multiscale model predicts increasing focal adhesion size with decreasing stiffness in fibrous matrices

Cao

Ban

Baker

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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We describe a multiscale model that incorporates force-dependent mechanical plasticity induced by interfiber cross-link breakage and stiffness-dependent cellular contractility to predict focal adhesion (FA) growth and mechanosensing in fibrous extracellular matrices (ECMs). The model predicts that FA size depends on both the stiffness of ECM and the density of ligands available to form adhesions. Although these two quantities are independent in commonly used hydrogels, contractile cells break cross-links in soft fibrous matrices leading to recruitment of fibers, which increases the ligand density in the vicinity of cells. Consequently, although the size of focal adhesions increases with ECM stiffness in nonfibrous and elastic hydrogels, plasticity of fibrous networks leads to a departure from the well-described positive correlation between stiffness and FA size. We predict a phase diagram that describes nonmonotonic behavior of FA in the space spanned by ECM stiffness and recruitment index, which describes the ability of cells to break cross-links and recruit fibers. The predicted decrease in FA size with increasing ECM stiffness is in excellent agreement with recent observations of cell spreading on electrospun fiber networks with tunable cross-link strengths and mechanics. Our model provides a framework to analyze cell mechanosensing in nonlinear and inelastic ECMs.focal adhesion | mechanosensing | cell contractility | matrix physical remodeling | Rho pathway F ocal adhesions (FAs) are large macromolecular assemblies through which mechanical force and regulatory signals are transmitted between the extracellular matrix (ECM) and cells. FAs play important roles in many cellular behaviors, including proliferation, differentiation, and locomotion, and pathological processes like tumorigenesis and wound healing (1-4). For this reason, intense efforts have been devoted to understanding how key signaling molecules and ECM characteristics influence the formation and growth of FAs. In particular, in vitro studies using elastic hydrogels have shown that forces generated by actomyosin contraction are essential for the stabilization of FAs (5, 6). Numerous observations have convincingly demonstrated that cells form larger FAs as well as develop higher intracellular traction forces on stiffer ECMs (7,8), evidencing the mechanosensitive nature of FAs which has been quantitatively modeled using different (continuum, coarse-grain, and molecular) approaches (9, 10).It must be pointed out that in all of the aforementioned investigations, the substrates considered were flat (2D) and linear elastic. However, in vivo, many cells reside within 3D fibrous scaffolds where the density and diameter of fibers can vary depending on the nature of the tissue (11-13). The local architecture of these fibrous networks may change significantly when cells exert forces on them, leading to phenomena such as nonlinear stiffening, reorientation, and physical remodeling of the ECM (14, 15). Our recent study on cells in synthetic fibrous matrices wit...

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Section: Methodsmentioning

confidence: 99%

mentioning

confidence: 99%

Multiscale model predicts increasing focal adhesion size with decreasing stiffness in fibrous matrices

Cao

Ban

Baker

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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“…Additionally, contractility can facilitate and accelerate cellular alignment to traction forces and static strain. Interestingly, cell alignment does not necessarily follow preexisting matrix fiber orientation,47 but cells can use contractility to align ECM fibers 16. Using SHG imaging on nonmineralized sections, we were able to visualize a sandglass‐like fiber alignment in the defect gap along the bone axis upon flexible stabilization.…”

Section: Discussionmentioning

confidence: 99%

“…Adaption of cells to their biomechanical surrounding plays a critical role in wound healing and tissue regeneration 12, 13, 14, 15, 16. The initial healing phase is sensitive to mechanical conditions represented by the movement of the bone fragments.…”

Section: Introductionmentioning

confidence: 99%

The Interaction of BMP2‐Induced Defect Healing in Rat and Fixator Stiffness Modulates Matrix Alignment and Contraction

et al. 2018

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Successful fracture healing requires a tight interplay between mechanical and biological cues. In vitro studies illustrated that mechanical loading modulates bone morphogenetic protein (BMP) signaling. However, in the early phases of large bone defect regeneration in vivo, the underlying mechanisms leading to this mechanosensation remained unknown. We investigated the interaction of BMP2 stimulation and mechanical boundary conditions in a rat critical‐sized femoral defect model (5 mm) stabilized with three distinctly different external fixator stiffness. Defects were treated with 5 μg rhBMP2 loaded on an absorbable collagen sponge. Early matrix alignment was monitored by second‐harmonic generation imaging. Bony bridging of defects and successive healing was monitored by histology at day 7 and day 14 as well as in vivo microCT at days 10, 21, and 42 post‐operation. Femora harvested at day 42 were characterized mechanically assessing torsional load to failure ex vivo. At tissue level, differences between groups were visible at day 14 with manifest bone formation in the microCT. Histologically, we observed prolonged chondrogenesis upon flexible fixation, whereas osteogenesis started earlier after rigid and semirigid fixation. At later time points, there was a boost of bone tissue formation upon flexible fixation, whereas other groups already displayed signs of tissue maturation. Based on gene expression profiling, we analyzed the mechanobiological interplay. Already at day 3, these analyses revealed differences in expression pattern, specifically of genes involved in extracellular matrix formation. Gene regulation correlating with fixator stiffness was pronounced at day 7 comprising genes related to immunological processes and cellular contraction. The influence of loading on matrix contraction was further investigated and confirmed in a 3D bioreactor. Taken together, we demonstrate an early onset of mechanical conditions influencing BMP2‐induced defect healing and shed light on gene regulatory networks associated with extracellular matrix organization and contraction that seemed to directly impact healing outcomes. © 2018 The Authors. JBMR Plus is published by Wiley Periodicals, Inc. on behalf of the American Society for Bone and Mineral Research.

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“…Although the mechanism is unclear, it is likely that cells at the periphery of the tissue engage α5β1 integrins to interact with the full-length fibronectin; this activates downstream RhoA-Rockmyosin-II signaling, thus increasing contractility as well as adhesion maturation and stability (da Rocha-Azevedo et al, 2013;Schiller et al, 2013). We speculate that localization of cells to the periphery could be due to multiple factors -haptotactic sensing of the higher peripheral levels of fibronectin, a preference for the strongly aligned ECM fibers at the periphery versus less-aligned ECM in the tissue core -perhaps due to tensional remodeling (Abhilash et al, 2014) -or even a durotactic preference for increased ECM stiffness at the periphery due to changes in ECM alignment, composition or crosslinking (Baker et al, 2015;Pelham and Wang, 1997;Plotnikov et al, 2012). Thus, the use of a microtissue system could provide insights into how gradients in provisional matrix assembly lead to changes in cell and matrix distribution.…”

Section: Tissue Architecture In Stromal Microtissuesmentioning

confidence: 99%

3D culture models of tissues under tension

Eyckmans

Chen

2016

Journal of Cell Science

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Cells dynamically assemble and organize into complex tissues during development, and the resulting three-dimensional (3D) arrangement of cells and their surrounding extracellular matrix in turn feeds back to regulate cell and tissue function. Recent advances in engineered cultures of cells to model 3D tissues or organoids have begun to capture this dynamic reciprocity between form and function. Here, we describe the underlying principles that have advanced the field, focusing in particular on recent progress in using mechanical constraints to recapitulate the structure and function of musculoskeletal tissues.

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Remodeling of Fibrous Extracellular Matrices by Contractile Cells: Predictions from Discrete Fiber Network Simulations

Cited by 182 publications

References 29 publications

Multiscale model predicts increasing focal adhesion size with decreasing stiffness in fibrous matrices

Multiscale model predicts increasing focal adhesion size with decreasing stiffness in fibrous matrices

The Interaction of BMP2‐Induced Defect Healing in Rat and Fixator Stiffness Modulates Matrix Alignment and Contraction

3D culture models of tissues under tension

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