scholarly journals Intercellular adhesion stiffness moderates cell decoupling on stiff substrates

2019 ◽  
Author(s):  
D. A. Vargas ◽  
T. Heck ◽  
B. Smeets ◽  
H. Ramon ◽  
H. Parameswaran ◽  
...  
Keyword(s):  
Extracellular Matrix ◽  
Focal Adhesions ◽  
Substrate Stiffness ◽  
Intercellular Interactions ◽  
Cell Pair ◽  
Patterned Substrate ◽  
Cell Substrate ◽  
A Cell ◽  
Cell Collective ◽  
Cell Cell

AbstractThe interplay between cell-cell and cell-substrate interactions is complex yet necessary for the formation and well-functioning of tissues. The same mechanosensing mechanisms used by the cell to sense its extracellular matrix, also play a role in intercellular interactions. We used the discrete element method to develop a computational model of a deformable cell that includes subcellular components responsible for mechanosensing. We modeled a cell pair in 3D on a patterned substrate, a simple laboratory setup to study intercellular interactions. We explicitly modeled focal adhesions between the cells and the substrate, and adherens junctions between cells. These mechanosensing adhesions matured; their disassembly rate was dictated by the force they carry. We also modeled stress fibers which bind the discrete adhesions and contract. The mechanosensing fibers strengthened upon stalling and exerted higher forces. Traction exerted on the substrate was used to generate maps displaying the magnitude of the tractions along the cell-substrate interface. Simulated traction maps are compared to experimental maps obtained via traction force microscopy. The model recreates the dependence on substrate stiffness of the tractions’ spatial distribution across the cell-substrate interface, the contractile moment of the cell pair, the intercellular force, and the number of focal adhesions. It also recreates the phenomenon of cell decoupling, in which cells exert forces separately when substrate stiffness increases. More importantly, the model provides viable molecular explanations for decoupling. It shows that the implemented mechanosensing mechanisms are responsible for competition between different fiber-adhesion configurations present in the cell pair. The point at which an increasing substrate stiffness becomes as high as that of the cell-cell interface is the tipping point at which configurations that favor cell-substrate adhesion dominate over those favoring cell-cell adhesion. This competition is responsible for decoupling. Additionally, we learn that extent of decoupling is modulated by adherens junction maturation.Statement of SignificanceCells are sensitive to mechanical factors of their extracellular matrix while simultaneously in contact with other cells. This creates complex intercellular interactions that depend on substrate stiffness and play a role in processes such as development and diseases like cardiac arrhythmia, asthma, and cancer. The simplest cell collective system in vitro is a cell pair on a patterned substrate. We developed a computational model of this system which explains the role of molecular adhesions and contractile fibers in the dynamics of cell-cell interactions on substrates with different stiffness. It is one of the first models of a deformable cell collective based on mechanical principles. It recreates cellular decoupling, a phenomenon in which cells exert forces separately, when substrate stiffness increases.

scholarly journals Diverse cell junctions with unique molecular composition in tissues of a sponge (Porifera)

EvoDevo ◽  
2019 ◽  
Vol 10 (1) ◽  
Author(s):  
Jennyfer M. Mitchell ◽  
Scott A. Nichols
Keyword(s):  
Extracellular Matrix ◽  
Focal Adhesion ◽  
Adherens Junction ◽  
Focal Adhesions ◽  
Molecular Composition ◽  
Cell Junctions ◽  
Adhesion Proteins ◽  
Focal Adhesion Proteins ◽  
Junction Protein ◽  
Cell Cell

Abstract The integrity and organization of animal tissues depend upon specialized protein complexes that mediate adhesion between cells with each other (cadherin-based adherens junctions), and with the extracellular matrix (integrin-based focal adhesions). Reconstructing how and when these cell junctions evolved is central to understanding early tissue evolution in animals. We examined focal adhesion protein homologs in tissues of the freshwater sponge, Ephydatia muelleri (phylum Porifera; class Demospongiae). Our principal findings are that (1) sponge focal adhesion homologs (integrin, talin, focal adhesion kinase, etc.) co-precipitate as a complex, separate from adherens junction proteins; (2) that actin-based structures resembling focal adhesions form at the cell–substrate interface, and their abundance is dynamically regulated in response to fluid shear; (3) focal adhesion proteins localize to both cell–cell and cell–extracellular matrix adhesions, and; (4) the adherens junction protein β-catenin is co-distributed with focal adhesion proteins at cell–cell junctions everywhere except the choanoderm, and at novel junctions between cells with spicules, and between cells with environmental bacteria. These results clarify the diversity, distribution and molecular composition of cell junctions in tissues of E. muelleri, but raise new questions about their functional properties and ancestry.

scholarly journals Focal adhesion-generated cues in extracellular matrix regulate cell migration by local induction of clathrin-coated plaques

2018 ◽  
Author(s):  
Delia Bucher ◽  
Markus Mukenhirn ◽  
Kem A. Sochacki ◽  
Veronika Saharuka ◽  
Christian Huck ◽  
...  
Keyword(s):  
Extracellular Matrix ◽  
Cell Migration ◽  
Focal Adhesions ◽  
Plaque Formation ◽  
Cell Contact ◽  
Coated Pits ◽  
Independent Manner ◽  
A Cell ◽  
And Function ◽  
Topographical Cues

AbstractClathrin is a unique scaffold protein, which forms polyhedral lattices with flat and curved morphology. The function of curved clathrin-coated pits in forming endocytic structures is well studied. On the contrary, the role of large flat clathrin arrays, called clathrin-coated plaques, remains ambiguous. Previous studies suggested an involvement of plaques in cell adhesion. However, the molecular origin leading to their formation and their precise functions remain to be determined. Here, we study the origin and function of clathrin-coated plaques during cell migration. We revealed that plaque formation is intimately linked to extracellular matrix (ECM) modification by focal adhesions (FAs). We show that in migrating cells, FAs digest the ECM creating extracellular topographical cues that dictate the future location of clathrin-coated plaques. We identify Eps15 and Eps15R as key regulators for the formation of clathrin-coated plaques at locally remodelled ECM sites. Using a genetic silencing approach to abrogate plaque formation and 3D-micropatterns to spatially control the location of clathrin-coated plaques, we could directly correlate cell migration directionality with the formation of clathrin-coated plaques and their ability to recognize extracellular topographical cues. We here define the molecular mechanism regulating the functional interplay between FAs and plaques and propose that clathrin-coated plaques act as regulators of cell migration promoting contact guidance-mediated collective migration in a cell-to-cell contact independent manner.

scholarly journals Stick-Slip Dynamics of Migrating Cells on Viscoelastic Substrates

2019 ◽  
Author(s):  
Partho Sakha De ◽  
Rumi De
Keyword(s):  
Focal Adhesions ◽  
Traction Force ◽  
Reaction Diffusion ◽  
Substrate Stiffness ◽  
Retrograde Flow ◽  
Stick Slip ◽  
Cell Substrate ◽  
Elastic Substrates ◽  
Individual Bond ◽  
Stick Slip Motion

Stick-slip motion, a common phenomenon observed during crawling of cells, is found to be strongly sensitive to the substrate stiffness. Stick-slip behaviours have previously been investigated typically using purely elastic substrates. For a more realistic understanding of this phenomenon, we propose a theoretical model to study the dynamics on a viscoelastic substrate. Our model based on a reaction-diffusion framework, incorporates known important interactions such as retrograde flow of actin, myosin contractility, force dependent assembly and disassembly of focal adhesions coupled with cell-substrate interaction. We show that consideration of a viscoelastic substrate not only captures the usually observed stick-slip jumps, but also predicts the existence of an optimal substrate viscosity corresponding to maximum traction force and minimum retrograde flow which was hitherto unexplored. Moreover, our theory predicts the time evolution of individual bond force that characterizes the stick-slip patterns on soft versus stiff substrates. Our analysis also elucidates how the duration of the stick-slip cycles are affected by various cellular parameters.

Cell Shape Control and Related Focal Adheshion Dynamics on Aligned Fiber Networks

2012 ◽  
Author(s):  
Kevin Sheets ◽  
Amrinder Nain
Keyword(s):  
Optical Tweezers ◽  
Shape Control ◽  
Focal Adhesions ◽  
Physical Nature ◽  
Health State ◽  
Cellular Behavior ◽  
Cell Substrate ◽  
A Cell ◽  
Cell Shape Control ◽  
External Stimuli

Cellular elasticity, a measure of a cell’s resistance to changing its shape in response to external stimuli, has been shown in the recent past to be a potential indicator of cell health [1]. A variety of methods including AFM techniques [1, 2], magnetic/optical tweezers [3, 4], and micropillar arrays [6–8] have been used to quantify cellular elasticity to identify cell disease state, including stages of progression in cancerous cells. Since cellular behavior is heavily dependent on the physical nature of the surrounding extracellular matrix (ECM), understanding mechanical cell-substrate interactions may lead to connections between the elasticity of a cell and the cell’s health state [1]. In this study, the STEP (Spinneret-based Tunable Engineered Parameters) technique is used to create suspended nanofibrous polystyrene substrates with tight control on fiber diameter and spacing in single and multiple layers. As cells interact with these various substrates, they take on repeatable configurations and allow the probing of biophysical traits. Specifically, cytoskeletal arrangements provide information on the behavior of the cell nucleus, f-actin stress fibers, and focal adhesions via paxillin staining, which allow for calculation of cellular elasticity.

scholarly journals Stiffness Sensing and Cell Motility: Durotaxis and Contact Guidance

2018 ◽  
Author(s):  
Jingchen Feng ◽  
Herbert Levine ◽  
Xiaoming Mao ◽  
Leonard M. Sander
Keyword(s):  
Mechanical Properties ◽  
Cell Migration ◽  
Cell Motility ◽  
Prior Knowledge ◽  
Focal Adhesions ◽  
Lattice Models ◽  
Vital Role ◽  
Substrate Stiffness ◽  
Contact Guidance ◽  
A Cell

AbstractMechanical properties of the substrate plays a vital role in cell motility. Cells are shown to migrate up stiffness gradient (durotaxis) and along aligned fibers in the substrate (contact guidance). Here we present a simple mechanical model for cell migration, by placing a cell on lattice models for biopolymer gels and hydrogels. In our model cells attach to the substrate via focal adhesions (FAs). As the cells contract, forces are generated at the FAs, determining their maturation and detachment. At the same time, the cell also allowed to move and rotate to maintain force and torque balance. Our model, in which the cells only take the information of forces at the FAs, without a prior knowledge of the substrate stiffness or geometry, is able to reproduce both durotaxis and contact guidance.

scholarly journals Correlation of cellular traction forces and dissociation kinetics of adhesive protein zyxin revealed by multi-parametric live cell microscopy

PLoS ONE ◽  
2021 ◽  
Vol 16 (5) ◽  
pp. e0251411
Author(s):  
Lorena Sigaut ◽  
Micaela Bianchi ◽  
Catalina von Bilderling ◽  
Lía Isabel Pietrasanta
Keyword(s):  
Extracellular Matrix ◽  
Residence Time ◽  
Focal Adhesion ◽  
Focal Adhesions ◽  
Traction Force ◽  
Correlation Spectroscopy ◽  
Substrate Stiffness ◽  
Dissociation Kinetics ◽  
Traction Forces ◽  
Cellular Division

Cells exert traction forces on the extracellular matrix to which they are adhered through the formation of focal adhesions. Spatial-temporal regulation of traction forces is crucial in cell adhesion, migration, cellular division, and remodeling of the extracellular matrix. By cultivating cells on polyacrylamide hydrogels of different stiffness we were able to investigate the effects of substrate stiffness on the generation of cellular traction forces by Traction Force Microscopy (TFM), and characterize the molecular dynamics of the focal adhesion protein zyxin by Fluorescence Correlation Spectroscopy (FCS) and Fluorescence Recovery After Photobleaching (FRAP). As the rigidity of the substrate increases, we observed an increment of both, cellular traction generation and zyxin residence time at the focal adhesions, while its diffusion would not be altered. Moreover, we found a positive correlation between the traction forces exerted by cells and the residence time of zyxin at the substrate elasticities studied. We found that this correlation persists at the subcellular level, even if there is no variation in substrate stiffness, revealing that focal adhesions that exert greater traction present longer residence time for zyxin, i.e., zyxin protein has less probability to dissociate from the focal adhesion.

scholarly journals Mitochondria tether to Focal Adhesions during cell migration and regulate their size

2019 ◽  
Author(s):  
Redaet Daniel ◽  
Abebech Mengeta ◽  
Patricia Bilodeau ◽  
Jonathan M Lee
Keyword(s):  
Extracellular Matrix ◽  
Cell Migration ◽  
Energy Production ◽  
Focal Adhesions ◽  
Leading Edge ◽  
Energy Requirements ◽  
Integrin Receptors ◽  
Cellular Energy ◽  
A Cell ◽  
Atp Generation

AbstractMitochondria are the key generators of ATP in a cell. Visually, they are highly dynamic organelles that undergo cellular fission and fusion events in response to changing cellular energy requirements. Mitochondria are now emerging as regulators of mammalian cell motility. Here we show that mitochondria infiltrate the leading edge of NIH3T3 fibroblasts during migration. At the leading edge, we find that mitochondria move to and tether to Focal Adhesions (FA). FA regulate cell migration by coupling the cytoskeleton to the Extracellular Matrix through integrin receptors. Importantly, we find that inhibition of mitochondrial ATP generation concomitantly inhibits FA size. This suggests that mitochondrial energy production regulates migration through FA control.

scholarly journals Extracellular matrix stiffness regulates force transmission pathways in multicellular ensembles of human airway smooth muscle cells

2018 ◽  
Author(s):  
Samuel R. Polio ◽  
Suzanne E Stasiak ◽  
Ramaswamy Krishnan ◽  
Harikrishnan Parameswaran
Keyword(s):  
Extracellular Matrix ◽  
Smooth Muscle ◽  
Focal Adhesions ◽  
Critical Factor ◽  
Fluorescent Imaging ◽  
Airway Smooth Muscle Cells ◽  
Force Transmission ◽  
Transmission Pathways ◽  
Cell Ensemble ◽  
Cell Cell

AbstractFor an airway or a blood vessel to narrow, there must be a connected path that links the smooth muscle (SM) cells with each other, and transmits forces around the organ, causing it to constrict. Currently, we know very little about the mechanisms that regulate force transmission pathways in a multicellular SM ensemble. Here, we used extracellular matrix (ECM) micropatterning to study force transmission in a two-cell ensemble of SM cells. Using the two-SM cell ensemble, we demonstrate (a) that ECM stiffness acts as a switch that regulates whether SM force is transmitted through the ECM or through cell-cell connections. (b) Fluorescent imaging for adherens junctions and focal adhesions show the progressive loss of cell-cell borders and the appearance of focal adhesions with the increase in ECM stiffness (confirming our mechanical measurements). (c) At the same ECM stiffness, we show that the presence of a cell-cell border substantially decreases the overall contractility of the SM cell ensemble. Our results demonstrate that connectivity among SM cells is a critical factor to consider in the development of diseases such as asthma and hypertension.

scholarly journals Functional mapping of cytotactin: proteolytic fragments active in cell-substrate adhesion.

1988 ◽  
Vol 107 (6) ◽  
pp. 2329-2340 ◽  
Author(s):  
D R Friedlander ◽  
S Hoffman ◽  
G M Edelman
Keyword(s):  
Extracellular Matrix ◽  
Polyclonal Antibody ◽  
Limited Proteolysis ◽  
Cell Binding ◽  
Fab Fragments ◽  
Substrate Adhesion ◽  
Cell Substrate ◽  
A Cell ◽  
Fraction I ◽  
Cell Substrate Adhesion

Cytotactin is an extracellular matrix glycoprotein with a restricted distribution during development. In electron microscopic images, it appears as a hexabrachion with six arms extending from a central core. Cytotactin binds to other extracellular matrix proteins including a chondroitin sulfate proteoglycan (CTB proteoglycan) and fibronectin. Although cytotactin binds to a variety of cells including fibroblasts and neurons, in some cases it causes cells in culture to round up and it inhibits their migration. To relate these various effects of cytotactin on cell behavior to its binding regions, we have examined its ability to support cell-substrate adhesion and have mapped its cell-binding function onto its structure. In a cell-substrate adhesion assay, fibroblasts bound to cytotactin but remained round. In contrast, they both attached and spread on fibronectin. Neither neurons nor glia bound to cytotactin in this assay. In an assay in which cell-substrate contact was initiated by centrifugation, however, neurons and glia bound well to cytotactin; this binding was blocked by specific anti-cytotactin antibodies. The results suggest that neurons and glia can bind to cytotactin-coated substrates and that these cells, like fibroblasts, possess cell surface ligands for cytotactin. After applying methods of limited proteolysis and fractionation, these assays were used to map the binding functions of cytotactin onto its structure. Fragments produced by limited proteolysis were fractionated into two major pools: one (fraction I) contained disulfide-linked oligomers of a 100-kD fragment and two minor related fragments, and the second (fraction II) contained monomeric 90- and 65-kD fragments. The 90- and 65-kD fragments in fraction II were closely related to each other and were structurally and immunologically distinct from the fragments in fraction I. Only components in fraction I were recognized by mAb M1, which binds to an epitope located in the proximal portion of the arms of the hexabrachion and by a polyclonal antibody prepared against a 75-kD CNBr fragment of intact cytotactin. A mAb (1D8) and a polyclonal antibody prepared against a 35-kD CNBr fragment of cytotactin only recognized components present in fraction II. In cell-binding experiments, fibroblasts, neurons, and glia each adhered to substrates coated with fraction II, but did not adhere to substrates coated with fraction I. Fab fragments of the antibody to the 35-kD CNBr fragment strongly inhibited the binding of cells to cytotactin, supporting the conclusion that fraction II contains a cell-binding region. In addition, Fab fragments of this antibody inhibited the binding of cytotactin to CTB pr

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