Cell behaviour on micropatterned substrata: limits of extracellular matrix geometry for spreading and adhesion

Lehnert, Dirk; Wehrle-Haller, Bernhard; Dávid, Christian; Weiland, Ulrich; Ballestrem, Christoph; Imhof, Beat A.; Bastmeyer, Martin

doi:10.1242/jcs.00836

Cited by 372 publications

(334 citation statements)

References 47 publications

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“…On the other hand, actin-stained images of cells contracting under micro-patterned constraints or micro-needles placed at the corners of square and triangular geometries show distinct actin bundles or stress fibers forming at the edges of the geometry instead of diagonal. 39,51,74 …”

Section: Stress Fiber Patterns From Continuum Modelsmentioning

confidence: 99%

“…It can be argued that the actin staining along the edges of contracting cells 39,51,74 is due to the cortical actin network and not stress fibers. However, the existence of edge or peripheral stress fibers in fibroblasts on rigid surfaces have been documented.…”

Section: Peripheral Stress Fibersmentioning

confidence: 99%

“…18 Experimental observations indicate otherwise: they show the stress fibers forming along the edges in cells under comparable constraints. 39,51,74 The central focus of this paper is to explore, from a continuum mechanics viewpoint, the nature of cytoskeletal actin-myosin interaction and myosin contractility that could lead to band-like stress fiber propagations in cells. We show that the description of myosin contractility in Deshpande et al 18,19 omits a component of the myosin contractile force that is lateral or perpendicular to the direction of cytoskeletal resistance.…”

Section: Introductionmentioning

confidence: 99%

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Band-like Stress Fiber Propagation in a Continuum and Implications for Myosin Contractile Stresses

2009

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Abstract-Stress fibers are band-like features that form with sarcomere-like actin and myosin arrangement between cell regions, resisting myosin contractility. We consider three aspects of stress fiber formation: (1) they form by cytoskeletal actin-myosin interaction when myosin contractile forces are resisted, (2) they propagate in a band-like manner, and (3) they maintain a level of stress and material continuity with the cytoskeleton. This suggests that any description of myosin force should capture the band-like propagation of stress fibers within the constraints of a continuum model. Recent studies describe myosin force as increasing proportional to the cytoskeletal resistance in that direction, but do not capture the band-like propagation of myosin stresses in a continuum. While the spreading of myosin stresses in continuum models is commonly attributed to the elliptic nature of continuum equations, we show that it comes from an incomplete description of the myosin force. Qualitative observations of cytoskeletal actin-myosin interaction indicate the interaction to be 'zipper-like'; myosin contractile forces get transmitted by bending actin filaments in directions away from that of the cytoskeletal resistance. A simple coarse-grained implementation of the lateral myosin forces that arise from the zippering action reproduces band-like stress propagation within a continuum model for the first time. This model also shows actin packing into the stress channel and its propagation along the edge for square and triangular constrained cells; features not captured earlier. Physically, the lateral contractile forces prevent stress spreading by balancing perpendicular shear forces that arise when stress channels through a continuum. Mathematically, these forces render the continuum stress equation hyperbolic. This paper presents a theoretical argument, based on continuum mechanics principles, that it is the zippering actin-myosin action that allows for band-like stress fiber propagation within a coarse-grained cytoskeletal continuum, and that any visualization of the cytoskeletal stress field should account for lateral contractile forces accompanying the much-acknowledged contractile force along a stress fiber.

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Section: Stress Fiber Patterns From Continuum Modelsmentioning

confidence: 99%

Section: Peripheral Stress Fibersmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Band-like Stress Fiber Propagation in a Continuum and Implications for Myosin Contractile Stresses

2009

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“…For example, it has been shown that when cells are organized into square shapes with asymmetric adhesive patterns, cells polarize their mitotic axis in a specific direction based on the matrix pattern [21], suggesting that spindle orientation is largely dependent on spatial distribution of ECM ( Figure 3B). Using subcellular, adhesion-sized ECM islands, investigators have also revealed that controlling adhesion size, shape and density can itself feed back to control the degree of cell spreading and shape ( Figure 3C) [22]. Thus there are multiple scales at which one can use patterning to control cell function.…”

Section: Cell Shape Modulates Signals From the Ecmmentioning

confidence: 99%

Cellular and multicellular form and function☆

Liu

Chen

2007

Advanced Drug Delivery Reviews

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Engineering artificial tissue constructs requires the appropriate spatial arrangement of cells within scaffolds. The introduction of microengineering tools to the biological community has provided a valuable set of techniques to manipulate the cellular environment, and to examine how cell structure affects cellular function. Using micropatterning techniques, investigators have found that the geometric presentation of cell-matrix adhesions are important regulators of various cell behaviors including cell growth, proliferation, differentiation, polarity and migration. Furthermore, the presence of neighboring cells in multicellular aggregates has a significant impact on the proliferative and differentiated state of cells. Using microengineering tools, it will now be possible to manipulate the various environmental factors for practical applications such as engineering tissue constructs with greater control over the physical structure and spatial arrangement of cells within their surrounding microenvironment.

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“…Custom protein distributions created by microcontact printing (lCP) (Chen et al, 1997;Singhvi et al, 1994) have been shown to be useful for studying the mechanisms of cell signaling, adhesion, migration, and neurite outgrowth (Lehnert et al, 2004;Thomas et al, 2002). In lCP, these stamps are first ''inked'' with a solution of molecules (often proteins or thiols), and then brought into contact with a substrate.…”

Section: Introductionmentioning

confidence: 99%

Two-photon fluorescent microlithography for live-cell imaging

Costantino

Heinze

Martínez

et al. 2005

Microsc. Res. Tech.

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Fluorescent dyes added to UV-cure resins allow the rapid fabrication of fluorescent micropatterns on standard glass coverslips by two-photon optical lithography. We use this lithographic method to tailor fiduciary markers, focal references, and calibration tools, for fluorescence and laser scanning microscopy. Fluorescent microlithography provides spatial landmarks to quantify molecular transport, cell growth and migration, and to compensate for focal drift during timelapse imaging. We show that the fluorescent patterned microstructures are biocompatible with cultures of mammalian cell lines and hippocampal neurons. Furthermore, the high-relief topology of the lithographed substrates is utilized as a mold for poly(dimethylsiloxane) stamps to create protein patterns by microcontact printing, representing an alternative to the current etching techniques. We present two different applications of such protein patterns for localizing cell adhesion and guidance of neurite outgrowth. Microsc. Res. Tech. 68:272-276, 2005. V

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Cell behaviour on micropatterned substrata: limits of extracellular matrix geometry for spreading and adhesion

Cited by 372 publications

References 47 publications

Band-like Stress Fiber Propagation in a Continuum and Implications for Myosin Contractile Stresses

Band-like Stress Fiber Propagation in a Continuum and Implications for Myosin Contractile Stresses

Cellular and multicellular form and function☆

Two-photon fluorescent microlithography for live-cell imaging

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