Engineering poly (ethylene glycol) hydrogels to regulate smooth muscle cell migration and proliferation

Lin, Lin

02 September 2014

No description available.

Biomedical Engineering

Polymers

Smooth muscle cells

PEG hydrogels

3D cell migration

3D cell proliferation

biomimetic

Contrôle de l’invasion tumorale par la matrice extracellulaire : étude du rôle de la ténascine-x / Regulation of cell signalling in the control of tumor cell invasion by tenascin-X, an extracellular matrix glycoprotein

Margaron, Yoran

11 December 2009

La ténascine-X (TNX) est une glycoprotéine de la matrice extracellulaire. Son expression est fortement réprimée dans de nombreux cancers et l’invasion tumorale est accrue chez des souris TNX-/-. La TNX apparaît donc comme un répresseur potentiel du développement des tumeurs. L’objectif de notre travail est d’étudier cet effet présumé et d’en comprendre les mécanismes, en analysant in vitro le rôle de la TNX sur la croissance et la migration de cellules de fibrosarcome HT-1080 dans des modèles de culture bi- et surtout tridimensionnels, plus représentatifs de l’environnement cellulaire in vivo. Nos résultats montrent que la TNX inhibe la croissance des cellules tumorales, sans induire de mort apoptotique ou nécrotique. Des observations par microscopie confocale ont montré que la présence de TNX réduit l’étalement des cellules ainsi que leur efficacité de migration. Nous avons pu mettre en évidence que la TNX provoque un ralentissement de la migration des cellules tumorales ainsi qu’une diminution de la directionnalité de leurs trajectoires. L’observation de la protéolyse du collagène de type I par les cellules en migration montre qu’elle est inhibée en présence de TNX. Par ailleurs, la TNX réduit l’expression et l’activation des MMP 2, MMP-9, et MT1 MMP. Certaines voies de signalisation associées ont été étudiées : la TNX inhibe la phosphorylation de FAK sur sa tyrosine 397, ainsi que l’activation des GTPases RhoA et Rac, sans affecter celle de Cdc42. Par une régulation fine de ces molécules, qui sont impliquées dans le contrôle de la croissance et de la migration cellulaire, la TNX se caractérise comme un inhibiteur extracellulaire de l’invasion tumorale / Tenascin-X (TNX) is involved not only in the organisation of the extracellular matrix architecture but also in the regulation of cell behaviour. This matrix glycoprotein is down-regulated in many tumor types, while tumor invasion is promoted in TNX-deficient mice. In order to decipher the mechanisms by which TNX modulates tumor cell growth and migration, we compared the behaviour of HT1080 fibrosarcoma cells in conventionnal 2D culture model or embedded in 3D collagen gels, both containing or not recombinant TNX. Some experimentations have permit us to demonstrate that TNX inhibits tumor cells growth, without inducing apoptotic or necrotic cell death. Laser confocal microscopy observations demonstrated that the presence of TNX reduces cell spreading and migration efficency. Moreover, video time-lapse analysis showed that TNX reduces both velocity and directionnality of cell migration. This result is partly due to a decrease of pericellular proteolysis, as observed in situ using FITC-collagen-containing gels. Besides, we showed that TNX led to a decrease of MMP 2, MMP-9, MT1 MMP expression and activity. Then, we determined that both FAK phosphorylation on tyrosine 397 and activation of Rac1/2/3 and RhoA small GTPases were inhibited in TNX conditions. An inactivation of these small GTPases of the Rho family is known to deregulate cell cycle and highly decrease tumor cell spreading and migration efficiency in 3D environment. Taken together, these results indicate that TNX is an extracellular inhibitor of cell invasion, which acts by downregulating the main signalling pathways responsible for cell growth and motility in 3D-collagen gels

Migration cellulaire en matrice 3D

Ténascine

Invasion tumorale

Signalisation cellulaire

3D cell migration

Tenascin

Tumor invasion

Cell signalling

572.69

<b>Computational modeling of cellular-scale mechanics</b>

Brandon Matthew Slater (18431502)

29 April 2024

<p dir="ltr">During many biological processes, cells move through their surrounding environment by exerting mechanical forces. The mechanical forces are mainly generated by molecular interactions between actin filaments (F-actins) and myosin motors within the actin cytoskeleton. Forces are transmitted to the surrounding extracellular matrix via adhesions. In this thesis, we employed agent-based computational models to study the interactions between F-actins and myosin in the motility assay and the cell migration process. In the first project, the myosin motility assay was employed to study the collective behaviors of F-actins. Unlike most of the previous computational models, we explicitly represent myosin motors. By running simulations under various conditions, we showed how the length, bending stiffness, and concentration affect the collective behavior of F-actins. We found that four distinct structures formed: homogeneous networks, flocks, bands, and rings. In addition, we showed that mobile motors lead to the formation of distinct F-actin clusters that were not observed with immobile motors. In the second project, we developed a 3D migration model to define how cells mechanically interact with their 3D environment during migration. Unlike cells migrating on a surface, cells within 3D extracellular matrix (ECM) must remodel the ECM and/or squeeze their body through the ECM, which causes 3D cell migration to be significantly more challenging than 2D migration. Our model describes realistic structural and rheological properties of ECM, cell protrusion, and focal adhesions between cells and the ECM.</p>

Biomechanical engineering

Computational physiology

Mechanobiology

Computational Biomechanics

Agent-based modeling

3D Cell Migration

Mechanobiology

Cyclic contractions contribute to 3D cell motility / Les cycles de contraction-relaxation sont impliqués dans la mobilité cellulaire à 3 dimensions

Godeau, Amélie

27 September 2016

La motilité des cellules est un phénomène fondamental en biologie souvent étudié sur des surfaces planes, conditions peu physiologiques. Nous avons analysé la migration cellulaire dans une matrice cellulaire 3D contenant de la fibronectine fluorescente. Nous démontrons que les cellules y sont confinées, et déforment leur environnement de manière cyclique avec une période de ~14 min avec deux centres de contractions à l’avant et à l’arrière de la cellule qui contractent avec un déphasage de ~3.5 min. Une perturbation de ces cycles entraîne une réduction de la motilité. Par l’utilisation d’inhibiteurs spécifiques, nous avons identifié l’acto-myosine comme étant l’acteur principal de ce phénomène. En imposant des contractions-relaxations locales par ablations laser, nous avons déclenché la motilité cellulaire ce qui confirme notre hypothèse. L’ensemble de cette étude met en évidence un nouveau mécanisme fondamental de dynamique cellulaire impliqué dans le mouvement des cellules. / Cell motility is an important process in Biology. It is mainly studied on 2D planar surfaces, whereas cells experience a confining 3D environment in vivo. We prepared a 3D Cell Derived Matrix (CDM) labeled with fluorescently labeled fibronectin, and strikingly cells managed to deform the matrix with specific patterns : contractions occur cyclically with two contraction centers at the front and at the back of the cell, with a period of ~14 min and a phase shift of ~3.5 min. These cycles enable cells to optimally migrate through the CDM, as perturbation of cycles led to reduced motility. Acto-myosin was established to be the driving actor of these cycles, by using specific inhibitors. We were able to trigger cell motility externally with local laser ablations, which supports this framework of two alternating contractions involved in motion. Altogether, this study reveals a new mechanism of dynamic cellular behaviour linked to cell motility.

Migration cellulaire 3D

Matrice extracellulaire

Oscillations

Cytosquelette

Mécanique cellulaire

3D cell migration

Cell derived matrix

Oscillations

Cytoskeleton

Cell mechanics

571.4

571.6