Your search keyword '"Alexandre Kabla"' showing total 17 results

1. Tissue mechanics

Author

Alexandre, Kabla, Benoît, Ladoux, and Jean-Marc, Di Meglio

Subjects

Biophysics, General Materials Science, Surfaces and Interfaces, General Chemistry, Biotechnology

Published

2022

2. Strain maps characterize the symmetry of convergence and extension patterns during zebrafish gastrulation

Author

Alexandre Kabla, Dipanjan Bhattacharya, Sahar Tavakoli, Paul Matsudaira, Jun Zhong, Kabla, Alexandre [0000-0002-0280-3531], and Apollo - University of Cambridge Repository

Subjects

Embryo, Nonmammalian, Intravital Microscopy, Pyridines, Science, Biophysics, Benzeneacetamides, Epiboly, Geometry, Rotation, Article, Cell Movement, Developmental biology, Animals, Segmentation, Compression (geology), Zebrafish, Body Patterning, Physics, 631/57, Multidisciplinary, Gastrulation, Embryo, Strain rate, Zebrafish Proteins, Wnt Proteins, Neurulation, Medicine, Symmetry (geometry), 631/136, Blastoderm

Abstract

Funder: Mechanobiology Institute, Singapore; doi: http://dx.doi.org/10.13039/501100007672, During gastrulation of the zebrafish embryo, the cap of blastoderm cells organizes into the axial body plan of the embryo with left–right symmetry and head–tail, dorsal–ventral polarities. Our labs have been interested in the mechanics of early development and have investigated whether these large-scale cell movements can be described as tissue-level mechanical strain by a tectonics-based approach. The first step is to image the positions of all nuclei from mid-epiboly to early segmentation by digital sheet light microscopy, organize the surface of the embryo into multi-cell spherical domains, construct velocity fields from the movements of these domains and extract strain rate maps from the change in density of the domains. During gastrulation, tensile/expansive and compressive strains in the axial and equatorial directions are detected as anterior and posterior expansion along the anterior–posterior axis and medial–lateral compression across the dorsal–ventral axis and corresponds to the well characterized morphological movements of convergence and extension. Following gastrulation strain is represented by localized medial expansion at the onset of segmentation and anterior expansion at the onset of neurulation. In addition to linear strain, symmetric patterns of rotation/curl are first detected in the animal hemispheres at mid-epiboly and then the vegetal hemispheres by the end of gastrulation. In embryos treated with C59, a Wnt inhibitor that inhibits head and tail extension, the axial extension and vegetal curl are absent. By analysing the temporal sequence of large-scale movements, deformations across the embryo can be attributed to a combination of epiboly and dorsal convergence-extension.

Published

2021

3. The Piezo channel is used by migrating cells to sense compressive load

Author

David Traynor, Alexandre Kabla, Robert R. Kay, and Nishit Srivastava

Subjects

biology, Cell, chemistry.chemical_element, Calcium, biology.organism_classification, Dictyostelium, Cortex (botany), Contractility, medicine.anatomical_structure, chemistry, Sense (molecular biology), Myosin, medicine, Biophysics, Pseudopodia

Abstract

Migrating cells face varied mechanical and physical barriers in physiological environments, but how they sense and respond to them remains to be fully understood. We used a custom-built ‘cell squasher’ to apply uniaxial pressure to Dictyostelium cells migrating under soft agarose. Within 10 seconds of application, loads of as little as 100 Pa cause cells to move using blebs instead of pseudopods. Cells lose volume and surface area under pressure and their actin dynamics are perturbed. Myosin-II is recruited to the cortex, potentially increasing contractility and so driving blebbing. The blebbing response depends on extra-cellular calcium, is accompanied by increased cytosolic calcium and largely abrogated in null mutants of the Piezo stretch-operated channel. We propose that migrating cells sense mechanical force through mechano-sensitive channels, leading to an influx of calcium and cortical recruitment of myosin, thus re-directing the motile apparatus to produce blebs rather than pseudopods.

Published

2019

4. Stress relaxation in epithelial monolayers is controlled by actomyosin

Author

Buzz Baum, José J. Muñoz, Jonathan Fouchard, Andrew R. Harris, Amina Yonis, Alexandre Kabla, Guillaume Charras, Nina Asadipour, Yasuyuki Fujita, Payman Mosaffa, Mark Miodownik, and Nargess Khalilgharibi

Subjects

0303 health sciences, Chemistry, Morphogenesis, Stress (mechanics), 03 medical and health sciences, 0302 clinical medicine, Rheology, Monolayer, Stress relaxation, Biophysics, Relaxation (physics), Cytoskeleton, Intermediate filament, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Epithelial monolayers are one-cell thick tissue sheets that separate internal and external environments. As part of their function, they withstand extrinsic mechanical stresses applied at high strain rate. However, little is known about how monolayers respond to mechanical deformations. In stress relaxation tests, monolayers respond in a biphasic manner and stress dissipation is accompanied by an increase in monolayer resting length, pointing to active remodelling of cell architecture during relaxation. Consistent with this, actomyosin remodels at a rate commensurate with mechanical relaxation and governs the rate of monolayer stress relaxation – as in single cells. By contrast, junctional complexes and intermediate filaments form stable connections between cells, enabling monolayers to behave rheologically as single cells. Together, these data show actomyosin cytoskeletal dynamics govern the rheological properties of monolayers by enabling active, ATP-dependent changes in the resting length. These findings have far-reaching consequences for our understanding of developmental morphogenesis and tissue response to mechanical stress.

Published

2018

5. Probing the effect of uniaxial compression on cell migration

Author

Robert R. Kay, Nishit Srivastava, and Alexandre Kabla

Subjects

0303 health sciences, Materials science, biology, 030302 biochemistry & molecular biology, Stiffness, Uniaxial compression, Cell migration, biology.organism_classification, Dictyostelium, 03 medical and health sciences, Live cell imaging, medicine, Biophysics, Pseudopodia, Bleb (cell biology), medicine.symptom, Mechanotransduction, Simulation, 030304 developmental biology

Abstract

The chemical, physical and mechanical properties of the extra-cellular environment have a strong effect on cell migration. Aspects such as pore-size or stiffness of the matrix influence the selection of the mechanism used by cells to propel themselves, including pseudopod or blebbing. How a cell perceives its environment, and how such a cue triggers a change in behaviour are largely unknown, but mechanics is likely to be involved. Because mechanical conditions are often controlled by modifying the composition of the environment, separating chemical and physical contributions is difficult and requires multiple controls. Here we propose a simple method to impose a mechanical compression on individual cells without altering the composition of the gel. Live imaging during compression provides accurate information about the cell’s morphology and migratory phenotype. UsingDictyosteliumas a model, we observe that a compression of the order of 500 Pa flattens the cells under gel by up to 50%. This uniaxial compression directly triggers a transition in the mode of migration, from primarily pseudopodial to bleb driven, in less than 30 sec. This novel device is therefore capable of influencing cell migration in real time and offers a convenient approach to systematically study mechanotransduction in confined environments.

Published

2016

6. Myosin II controls junction fluctuations to guide epithelial tissue ordering

Author

Jasper Bathmann, Scott Curran, Guillaume Salbreux, Alexandre Kabla, Marc de Gennes, Charlotte Strandkvist, Buzz Baum, Kabla, Alexandre [0000-0002-0280-3531], and Apollo - University of Cambridge Repository

Subjects

junction fluctuations, vertex model, Cell division, Myosin, Morphogenesis, morphogenesis, Article, Epithelium, 03 medical and health sciences, 0302 clinical medicine, medicine, Animals, Drosophila Proteins, neighbor exchange, 030304 developmental biology, Myosin Type II, 0303 health sciences, Chemistry, Dynamics (mechanics), epithelia, Actomyosin, Adherens Junctions, Cadherins, cadherin, Drosophila melanogaster, medicine.anatomical_structure, Order (biology), tissue refinement, tissue mechanics, Biophysics, Drosophila, Epithelial tissue, Gradual increase, 030217 neurology & neurosurgery

Abstract

Summary Under conditions of homeostasis, dynamic changes in the length of individual adherens junctions (AJs) provide epithelia with the fluidity required to maintain tissue integrity in the face of intrinsic and extrinsic forces. While the contribution of AJ remodeling to developmental morphogenesis has been intensively studied, less is known about AJ dynamics in other circumstances. Here, we study AJ dynamics in an epithelium that undergoes a gradual increase in packing order, without concomitant large-scale changes in tissue size or shape. We find that neighbor exchange events are driven by stochastic fluctuations in junction length, regulated in part by junctional actomyosin. In this context, the developmental increase of isotropic junctional actomyosin reduces the rate of neighbor exchange, contributing to tissue order. We propose a model in which the local variance in tension between junctions determines whether actomyosin-based forces will inhibit or drive the topological transitions that either refine or deform a tissue., Graphical Abstract, Highlights • Fluctuations in junction length cause neighbor exchange events without morphogenesis • The variance in junction tension determines how actomyosin influences T1 rates • Globally increasing junctional actomyosin levels inhibits neighbor exchange • A developmental increase in isotropic junction tension refines cellular packing, Curran et al. investigate adherens junction remodeling in the fly notum, where differences in actomyosin levels drive fluctuations in junction length and neighbor exchange, but not morphogenesis. A developmental increase in global junctional tension reduces, rather than drives, neighbor exchange to promote tissue ordering.

Published

2016

7. Method to study cell migration under uniaxial compression

Author

Robert R. Kay, Nishit Srivastava, Alexandre Kabla, Kabla, Alexandre [0000-0002-0280-3531], and Apollo - University of Cambridge Repository

Subjects

0301 basic medicine, Mechanotransduction, Cellular, Extracellular matrix, Weight-Bearing, 03 medical and health sciences, Live cell imaging, Cell Movement, medicine, Methods, Dictyostelium, Bleb (cell biology), Pseudopodia, Mechanotransduction, Molecular Biology, biology, Stiffness, Cell migration, Cell Biology, Articles, Weights and Measures, biology.organism_classification, Extracellular Matrix, 030104 developmental biology, Biophysics, Stress, Mechanical, medicine.symptom

Abstract

A method is described for imposing mechanical compression on individual cells while monitoring their morphology and migratory phenotype. A compression of the order of 500 Pa flattens the cells by up to 50% and triggers a transition in the mode of migration. This approach is convenient for studying mechanotransduction in confined environments., The chemical, physical, and mechanical properties of the extracellular environment have a strong effect on cell migration. Aspects such as pore size or stiffness of the matrix influence the selection of the mechanism used by cells to propel themselves, including by pseudopods or blebbing. How a cell perceives its environment and how such a cue triggers a change in behavior are largely unknown, but mechanics is likely to be involved. Because mechanical conditions are often controlled by modifying the composition of the environment, separating chemical and physical contributions is difficult and requires multiple controls. Here we propose a simple method to impose a mechanical compression on individual cells without altering the composition of the matrix. Live imaging during compression provides accurate information about the cell's morphology and migratory phenotype. Using Dictyostelium as a model, we observe that a compression of the order of 500 Pa flattens the cells under gel by up to 50%. This uniaxial compression directly triggers a transition in the mode of migration from primarily pseudopodial to bleb driven in

Published

2016

8. The dynamic mechanical properties of cellularised aggregates

Author

Nargess Khalilgharibi, Pierre Recho, Alexandre Kabla, Jonathan Fouchard, Guillaume Charras, Kabla, Alexandre [0000-0002-0280-3531], and Apollo - University of Cambridge Repository

Subjects

0301 basic medicine, Cell physiology, Cells, Morphogenesis, Cell Biology, Biology, 01 natural sciences, Cell junction, Models, Biological, Cell aggregation, Biomechanical Phenomena, Extracellular matrix, Stress (mechanics), 03 medical and health sciences, 030104 developmental biology, 0103 physical sciences, Biophysics, Animals, Humans, 010306 general physics, Cytoskeleton, Rheology, Cell Aggregation

Abstract

Cellularised materials are composed of cells interfaced through specialised intercellular junctions that link the cytoskeleton of one cell to that of its neighbours allowing for transmission of forces. Cellularised materials are common in early development and adult tissues where they can be found in the form of cell sheets, cysts, or amorphous aggregates and in pathophysiological conditions such as cancerous tumours. Given the growing realisation that forces can regulate cell physiology and developmental processes, understanding how cellularised materials deform under mechanical stress or dissipate stress appear as key biological questions. In this review, we will discuss the dynamic mechanical properties of cellularised materials devoid of extracellular matrix.

Published

2016

9. Development of Strain during Zebrafish Gastrulation

Author

Jun Zhong, Alexandre Kabla, Dipanjan Bhattacharya, and Paul Matsudaira

Subjects

Gastrulation, Multicellular organism, Neurulation, biology, Convergent extension, Biophysics, Morphogenesis, Embryo, Anatomy, Deformation (engineering), biology.organism_classification, Zebrafish, Cell biology

Abstract

Morphogenetic movement plays a key role in early embryogenesis in multicellular organisms. An important morphogenetic event during early embryo development is the convergence and extension at mid-gastrulation stage, where cells collectively move from the ventral side of the embryo towards the dorsal axis, underlying the neural tube formation as well as the somatogenesis. However, the mechanics of early development is intensively studied at the cellular level but due to the technical challenge for quantifying the force and deformation the global mechanics at the tissue level remains unknown. Here we combine in-toto imaging by light-sheet microscopy and computational methods to calculate the strain map of zebrafish development from 7-12 hpf, representing the tissue deformation, during mid-gastrulation. Key parameters for the dynamics include: 1. vector field of collective cell migrations, 2. mechanical curl of sheets of cells, which describes the domain rotation, and 3. strain, which measures the tissue deformation, have been calculated over the entire embryo. Furthermore, based on these results we have identified strain associated with convergent extension and pre-somatogenesis events. The strain maps are a first step in the quantitation of the mechanical forces that power morphogenesis.

Published

2017

10. A kinetic mechanism for cell sorting based on local variations in cell motility

Author

Alexandre Kabla, Charlotte Strandkvist, Tom Duke, Buzz Baum, and Jeppe Juul

Subjects

Cell type, Mechanism (biology), media_common.quotation_subject, Biomedical Engineering, Biophysics, Motility, Bioengineering, Articles, Cell sorting, Biology, Biochemistry, Asymmetry, Cell biology, Biomaterials, Minimal model, Biological system, Scaling, Biotechnology, media_common, Potts model

Abstract

Our current understanding of cell sorting relies on physical difference, either in the interfacial properties or motile force, between cell types. But is such asymmetry a prerequisite for cell sorting? We test this using a minimal model in which the two cell populations are identical with respect to their physical properties and differences in motility arise solely from how cells interact with their surroundings. The model resembles the Schelling model used in social sciences to study segregation phenomena at the scale of societies. Our results demonstrate that segregation can emerge solely from cell motility being a dynamic property that changes in response to the local environment of the cell, but that additional mechanisms are necessary to reproduce the envelopment behaviour observedin vitro. The time course of segregation follows a power law, in agreement with the scaling reported from experiment and in other models of motility-driven segregation.

Published

2014

11. Focal Adhesions are Composed of Filamentous Subunits Whose Length and Dynamics Depend on the Cell Spreading Area

Author

Yee Han Tee, Alexandre Kabla, Alexander D. Bershadsky, Pascal Hersen, and Shiqiong Hu

Subjects

Extracellular matrix, Fibronectin, Focal adhesion, biology, biology.protein, Ultrastructure, Biophysics, Cell migration, Cell morphology, Actin, Paxillin, Cell biology

Abstract

The cells ability to adhere to the extracellular matrix (ECM) is a fundamental feature of many higher eukaryotic cells and is required for cell migration, proliferation, and differentiation. At the scale of single cells, the primary patterns of adhesion to the ECM are called focal adhesions (FAs). They are thought to serve as mechano-sensor units. Recent progress in super resolution techniques opened the door to study ultrastructure of focal adhesions. However the dynamics of their spatial structure has not been studied yet. Here, we combine structured illumination microscopy (SIM) with total internal reflection fluorescence microscopy (TIRF) to study focal adhesions at high spatial resolution in live cells. We studied REF52 fibroblasts spread on fibronectin disks to avoid the variability of focal adhesions properties due to variable cell morphology and migratory status. We observed the formation of many focal adhesions localized at the lamellipodium-lamellum interface. We further show that (i) focal adhesions are formed by filaments subunits which grow retrograde and then shrink in ∼ 20 mins, (ii) that their formation depends on the spreading area of the cell and (iii) that each filament connects to a single actin cable, therefore linking the internal structure of focal adhesions to the maturation process through actin pulling on the focal complex. Thus our study reveals the ultrastructure and dynamics of focal adhesion and is a first step towards a better understanding of the formation of FAs with respect to the cell mechanical state.Keywords: focal adhesions, filamentous unit, SIM, retrograde flow, spreading area, paxillin.

Published

2014

12. Generating suspended cell monolayers for mechanobiological studies

Author

Andrew R. Harris, Buzz Baum, Tom P. J. Wyatt, Guillaume Charras, Alexandre Kabla, Julien Bellis, and Nargess Khalilgharibi

Subjects

Scaffold, Materials science, Tissue Scaffolds, Cell Culture Techniques, Suspension culture, Models, Biological, General Biochemistry, Genetics and Molecular Biology, law.invention, Biomechanical Phenomena, Cell Line, Dogs, Optical microscope, law, Cell culture, Monolayer, Collagenase, medicine, Biophysics, Animals, Collagen, Micromanipulator, Cell adhesion, medicine.drug

Abstract

Cell monolayers line most of the surfaces and cavities in the human body. During development and normal physiology, monolayers sustain, detect and generate mechanical stresses, yet little is known about their mechanical properties. We describe a cell culture and mechanical testing protocol for generating freely suspended cell monolayers and examining their mechanical and biological response to uniaxial stretch. Cells are cultured on temporary collagen scaffolds polymerized between two parallel glass capillaries. Once cells form a monolayer covering the collagen and the capillaries, the scaffold is removed with collagenase, leaving the monolayer suspended between the test rods. The suspended monolayers are subjected to stretching by prying the capillaries apart with a micromanipulator. The applied force can be measured for the characterization of monolayer mechanics. Monolayers can be imaged with standard optical microscopy to examine changes in cell morphology and subcellular organization concomitant with stretch. The entire preparation and testing protocol requires 3-4 d.

Published

2013

13. Guidance of collective cell migration by substrate geometry

Author

Chwee Teck Lim, Benoit Ladoux, Sri Ram Krishna Vedula, Hiroaki Hirata, Nir S. Gov, Alexandre Kabla, Kevin W. Doxzen, and Man Chun Leong

Subjects

Collective behavior, Epithelial-Mesenchymal Transition, Population, Biophysics, Morphogenesis, Cell Culture Techniques, Angular velocity, Biology, Rotation, Biochemistry, Madin Darby Canine Kidney Cells, Adherens junction, Extracellular matrix, Dogs, Cell Movement, Cell Line, Tumor, Cell Adhesion, Animals, Humans, Computer Simulation, education, education.field_of_study, Cell Membrane, Epithelial Cells, Adhesion, Fibronectins, Monte Carlo Method

Abstract

Collective behavior refers to the emergence of complex migration patterns over scales larger than those of the individual elements constituting a system. It plays a pivotal role in biological systems in regulating various processes such as gastrulation, morphogenesis and tissue organization. Here, by combining experimental approaches and numerical modeling, we explore the role of cell density (‘crowding’), strength of intercellular adhesion (‘cohesion’) and boundary conditions imposed by extracellular matrix (ECM) proteins (‘constraints’) in regulating the emergence of collective behavior within epithelial cell sheets. Our results show that the geometrical confinement of cells into well-defined circles induces a persistent, coordinated and synchronized rotation of cells that depends on cell density. The speed of such rotating large-scale movements slows down as the density increases. Furthermore, such collective rotation behavior depends on the size of the micropatterned circles: we observe a rotating motion of the overall cell population in the same direction for sizes of up to 200 μm. The rotating cells move as a solid body, with a uniform angular velocity. Interestingly, this upper limit leads to length scales that are similar to the natural correlation length observed for unconfined epithelial cell sheets. This behavior is strongly altered in cells that present a downregulation of adherens junctions and in cancerous cell types. We anticipate that our system provides a simple and easy approach to investigate collective cell behavior in a well-controlled and systematic manner.

Published

2013

14. Collective cell migration: leadership, invasion and segregation

Author

Alexandre Kabla

Subjects

Cell signaling, In silico, Population, Cell, Biomedical Engineering, Biophysics, Motility, Bioengineering, Cell Communication, Biology, 01 natural sciences, Biochemistry, Biomaterials, 03 medical and health sciences, Cell Movement, 0103 physical sciences, Cell polarity, medicine, Computer Simulation, Neoplasm Invasiveness, 010306 general physics, education, Research Articles, 030304 developmental biology, Cell Size, 0303 health sciences, education.field_of_study, Cell Polarity, Epithelial Cells, Cell sorting, Cell biology, Active matter, medicine.anatomical_structure, Biotechnology, Signal Transduction

Abstract

A number of biological processes, such as embryo development, cancer metastasis or wound healing, rely on cells moving in concert. The mechanisms leading to the emergence of coordinated motion remain however largely unexplored. Although biomolecular signalling is known to be involved in most occurrences of collective migration, the role of physical and mechanical interactions has only been recently investigated. In this study, a versatile framework for cell motility is implementedin silicoin order to study the minimal requirements for the coordination of a group of epithelial cells. We find that cell motility and cell–cell mechanical interactions are sufficient to generate a broad array of behaviours commonly observedin vitroandin vivo. Cell streaming, sheet migration and susceptibility to leader cells are examples of behaviours spontaneously emerging from these simple assumptions, which might explain why collective effects are so ubiquitous in nature. The size of the population and its confinement appear, in particular, to play an important role in the coordination process. In all cases, the complex response of the population can be predicted from the knowledge of the correlation length of the velocity field measured in the bulk of the epithelial layer. This analysis provides also new insights into cancer metastasis and cell sorting, suggesting, in particular, that collective invasion might result from an emerging coordination in a system where single cells are mechanically unable to invade.

Published

2012

15. Emerging modes of collective cell migration induced by geometrical constraints

Author

Pascal Hersen, Man Chun Leong, Tan Lei Lai, Chwee Teck Lim, Benoit Ladoux, Sri Ram Krishna Vedula, and Alexandre Kabla

Subjects

Cell engineering, Cell signaling, Population, Nanotechnology, Cell Communication, Models, Biological, Collective migration, Cell Line, Dogs, Cell Movement, Animals, education, Cell Engineering, Cell sheet, Physics, Feed back, education.field_of_study, Multidisciplinary, Tractive force, Collective cell migration, Epithelial Cells, Biological Sciences, Biomechanical Phenomena, Fibronectins, Biophysics, Rheology

Abstract

The role of geometrical confinement on collective cell migration has been recognized but has not been elucidated yet. Here, we show that the geometrical properties of the environment regulate the formation of collective cell migration patterns through cell–cell interactions. Using microfabrication techniques to allow epithelial cell sheets to migrate into strips whose width was varied from one up to several cell diameters, we identified the modes of collective migration in response to geometrical constraints. We observed that a decrease in the width of the strips is accompanied by an overall increase in the speed of the migrating cell sheet. Moreover, large-scale vortices over tens of cell lengths appeared in the wide strips whereas a contraction-elongation type of motion is observed in the narrow strips. Velocity fields and traction force signatures within the cellular population revealed migration modes with alternative pulling and/or pushing mechanisms that depend on extrinsic constraints. Force transmission through intercellular contacts plays a key role in this process because the disruption of cell–cell junctions abolishes directed collective migration and passive cell–cell adhesions tend to move the cells uniformly together independent of the geometry. Altogether, these findings not only demonstrate the existence of patterns of collective cell migration depending on external constraints but also provide a mechanical explanation for how large-scale interactions through cell–cell junctions can feed back to regulate the organization of migrating tissues.

Published

2012

16. Strain-induced alignment in collagen gels

Author

David A. Vader, Lakshminarayanan Mahadevan, David A. Weitz, and Alexandre Kabla

Subjects

Materials science, Polymers, Biophysics, FOS: Physical sciences, lcsh:Medicine, 02 engineering and technology, Plasticity, Condensed Matter - Soft Condensed Matter, Models, Biological, Physics/Interdisciplinary Physics, 03 medical and health sciences, Species Specificity, Rheology, Cell Line, Tumor, Image Processing, Computer-Assisted, Humans, Fiber, Anisotropy, lcsh:Science, Microscale chemistry, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Condensed Matter - Materials Science, Microscopy, Confocal, Models, Statistical, Multidisciplinary, lcsh:R, Materials Science (cond-mat.mtrl-sci), Computational Biology, Physics/Condensed Matter, Polymer, 021001 nanoscience & nanotechnology, Extracellular Matrix, Cross-Linking Reagents, chemistry, Soft Condensed Matter (cond-mat.soft), Biophysics/Experimental Biophysical Methods, lcsh:Q, Collagen, Biotechnology/Bioengineering, Deformation (engineering), 0210 nano-technology, Gels, Biological network, Research Article

Abstract

Collagen is the most abundant extracellular-network-forming protein in animal biology and is important in both natural and artificial tissues, where it serves as a material of great mechanical versatility. This versatility arises from its almost unique ability to remodel under applied loads into anisotropic and inhomogeneous structures. To explore the origins of this property, we develop a set of analysis tools and a novel experimental setup that probes the mechanical response of fibrous networks in a geometry that mimics a typical deformation profile imposed by cells in vivo. We observe strong fiber alignment and densification as a function of applied strain for both uncrosslinked and crosslinked collagenous networks. This alignment is found to be irreversibly imprinted in uncrosslinked collagen networks, suggesting a simple mechanism for tissue organization at the microscale. However, crosslinked networks display similar fiber alignment and the same geometrical properties as uncrosslinked gels, but with full reversibility. Plasticity is therefore not required to align fibers. On the contrary, our data show that this effect is part of the fundamental non-linear properties of fibrous biological networks., 12 pages, 7 figures. 1 supporting material PDF with 2 figures

Published

2009

17. Stress relaxation in epithelial monolayers is controlled by the actomyosin cortex

Author

José J. Muñoz, Nina Asadipour, Maria Duda, Mark Miodownik, Alessandra Bonfanti, Nargess Khalilgharibi, Yasuyuki Fujita, Payman Mosaffa, Andrew R. Harris, Alexandre Kabla, Yanlan Mao, Buzz Baum, Amina Yonis, Ricardo Barrientos, Jonathan Fouchard, Guillaume Charras, Universitat Politècnica de Catalunya. Departament de Matemàtiques, and Universitat Politècnica de Catalunya. LACÀN - Mètodes Numèrics en Ciències Aplicades i Enginyeria

Subjects

Engineering, Civil, Càlculs numèrics, Engineering, Multidisciplinary, General Physics and Astronomy, Matemàtiques i estadística::Matemàtica aplicada a les ciències [Àrees temàtiques de la UPC], 01 natural sciences, Article, 010305 fluids & plasmas, Stress (mechanics), Rheology, 0103 physical sciences, Monolayer, Stress relaxation, Engineering, Ocean, 010306 general physics, Intermediate filament, Cytoskeleton, Engineering, Aerospace, Engineering, Biomedical, Physics, Dynamics (mechanics), Numerical calculations, Computer Science, Software Engineering, Engineering, Marine, Engineering, Manufacturing, Engineering, Mechanical, Engineering, Industrial, Biophysics, Relaxation (physics)

Abstract

Epithelial monolayers are one-cell-thick tissue sheets that line most of the body surfaces, separating internal and external environments. As part of their function, they must withstand extrinsic mechanical stresses applied at high strain rates. However, little is known about how monolayers respond to mechanical deformations. Here, by subjecting suspended epithelial monolayers to stretch, we find that they dissipate stresses on a minute timescale and that relaxation can be described by a power law with an exponential cut-off at timescales larger than about 10 s. This process involves an increase in monolayer length, pointing to active remodelling of cellular biopolymers at the molecular scale during relaxation. Strikingly, monolayers consisting of tens of thousands of cells relax stress with similar dynamics to single rounded cells, and both respond similarly to perturbations of the actomyosin cytoskeleton. By contrast, cell–cell junctional complexes and intermediate filaments do not relax tissue stress, but form stable connections between cells, allowing monolayers to behave rheologically as single cells. Taken together, our data show that actomyosin dynamics governs the rheological properties of epithelial monolayers, dissipating applied stresses and enabling changes in monolayer length. Stress relaxation in cell monolayers shows remarkable similarities with that of single cells, suggesting the rheology of epithelial tissues is mediated by the actomyosin cortex—with dynamics reminiscent of those on a cellular level.