Architecture and migration of an epithelium on a cylindrical wire

Yevick, Hannah; Duclos, Guillaume; Bonnet, Isabelle; Silberzan, Pascal

doi:10.1073/pnas.1418857112

Cited by 103 publications

(123 citation statements)

References 53 publications

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“…In many biological processes, cell motion takes place on curved surfaces, as in cell renewal and repair in the highly folded intestine [85] and the shaping of the early limb bud in developing embryos [86]. The effect of curvature on the dynamics of epithelial cells is beginning to be explored in vitro by examining collective cell migration on cylindrical capillaries of varying radii [21]. While cylinders have zero Gaussian curvature, which would not yield topologically protected states, these experiments clearly demonstrate that curvature affects cell morphology and dynamics by enhancing cell speed and cell extrusion.…”

Section: Discussionmentioning

confidence: 99%

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Topological Sound and Flocking on Curved Surfaces

2017

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Active systems on curved geometries are ubiquitous in the living world. In the presence of curvature, orientationally ordered polar flocks are forced to be inhomogeneous, often requiring the presence of topological defects even in the steady state because of the constraints imposed by the topology of the underlying surface. In the presence of spontaneous flow, the system additionally supports long-wavelength propagating sound modes that get gapped by the curvature of the underlying substrate. We analytically compute the steady-state profile of an active polar flock on a two-sphere and a catenoid, and show that curvature and active flow together result in symmetry-protected topological modes that get localized to special geodesics on the surface (the equator or the neck, respectively). These modes are the analogue of edge states in electronic quantum Hall systems and provide unidirectional channels for information transport in the flock, robust against disorder and backscattering.

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Section: Discussionmentioning

confidence: 99%

“…Recent in vitro work has demonstrated a direct effect of substrate curvature on cytoskeletal alignment and cell motility in epithelial cells [21]. Understanding the behavior of active matter on curved surfaces or confined by curved boundaries is therefore timely.…”

Section: Introductionmentioning

confidence: 99%

Topological Sound and Flocking on Curved Surfaces

2017

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“…An interesting observation was made in [16] (and more recently in [18]), where the cell monolayer was found to propagate faster within the thinner stripes. This observation has remained an open puzzle ever since, and we aim to explain it in this paper.…”

Section: Introductionmentioning

confidence: 91%

Modeling collective cell migration in geometric confinement

Tarle

Gauquelin

Vedula³

et al. 2017

Phys. Biol.

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“…This suggests a predominantly tissue-guided migration that is dictated by physical principles, including haptotaxis and contact guidance. By depicting the complexity of structural microenvironments in vivo, that study also provides the basis for bio-inspired engineered microdevices to probe cell migration in defined environments that simulate space restrictions, surface topography and geometry in the physiological range encountered by cells in tissues (Stroka et al, 2014;Yevick et al, 2015). Taken together, THG combined with SHG-or fluorescence-based microscopy can provide important anatomical context in three dimensions and so yield a framework of cause-consequence relationships in tumor progression, cell migration and the associated remodeling of the microenvironment.…”

Section: Tumor-stroma Interfacementioning

confidence: 99%

Third harmonic generation microscopy of cells and tissue organization

Weigelin

Bakker

Friedl

2016

Journal of Cell Science

164

143

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The interaction of cells within their microenvironmental niche is fundamental to cell migration, positioning, growth and differentiation in order to form and maintain complex tissue organization and function. Third harmonic generation (THG) microscopy is a label-free scatter process that is elicited by water-lipid and water-protein interfaces, including intra-and extracellular membranes, and extracellular matrix structures. In applied life sciences, THG delivers a versatile contrast modality to complement multi-parameter fluorescence, second harmonic generation and fluorescence lifetime microscopy, which allows detection of cellular and molecular cell functions in threedimensional tissue culture and small animals. In this Commentary, we review the physical and technical basis of THG, and provide considerations for optimal excitation, detection and interpretation of THG signals. We further provide an overview on how THG has versatile applications in cell and tissue research, with a particular focus on analyzing tissue morphogenesis and homeostasis, immune cell function and cancer research, as well as the emerging applicability of THG in clinical practice.

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Architecture and migration of an epithelium on a cylindrical wire

Cited by 103 publications

References 53 publications

Topological Sound and Flocking on Curved Surfaces

Topological Sound and Flocking on Curved Surfaces

Modeling collective cell migration in geometric confinement

Third harmonic generation microscopy of cells and tissue organization

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