Contraction-Dependent Apoptosis of Normal Dermal Fibroblasts

Niland, Stephan; Cremer, Anja; Fluck, Juliane; Eble, Johannes A.; Krieg, Thomas; Sollberg, Stephan

doi:10.1046/j.1523-1747.2001.01342.x

Cited by 62 publications

(51 citation statements)

References 35 publications

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“…Antibodies to a2b1 integrins prevent the contraction and reduce apoptosis. [97][98][99] Integrin a11 mRNA and protein are up-regulated in attached collagen gel and down-regulated in fibroblasts grown in floating gel. 100 Rat liver MFB utilize a1b1 integrin for collagen matrix contraction as a2 subunit is not expressed in HSC, their precursors in vivo.…”

Section: Floating Matrixmentioning

confidence: 99%

Collagen matrix as a tool in studying fibroblastic cell behavior

Kanta

2015

Cell Adhesion & Migration

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Section: Floating Matrixmentioning

confidence: 99%

Collagen matrix as a tool in studying fibroblastic cell behavior

Kanta

2015

Cell Adhesion & Migration

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“…In fact, studies carried out with various types of cultured cells have confirmed that changes in the balance of mechanical forces between cells and the ECM control all of the key cell behaviors that are responsible for tissue development. For example, cells make entirely different fate decisions, such as whether to grow, differentiate or die (i.e., undergo programmed cell death or "apoptosis"), depending on the adhesivity or mechanical compliance of their ECM substrate and thus, the degree to which they physically extend (Folkman and Moscona, 1978, Ben-Ze'ev et al, 1980, Glowacki et al, 1983, Li et al, 1987, Ben-Ze'ev et al, 1988, Ingber and Folkman, 1989, Opas, 1989, Ingber, 1990, Mooney et al, 1992, Singhvi et al, 1994, Dike et al, 1999, Niland et al, 2001. This can be accomplished by varying the density of immobilized ECM molecules on otherwise non-adhesive dishes; changing the flexibility of ECM gels; or creating planar ECM islands with defined size and shape on the micrometer scale using microfabrication techniques (Fig.…”

Section: Shape-dependent Control Of Cell Fate Switchingmentioning

confidence: 99%

Mechanical control of tissue morphogenesis during embryological development

Ingber¹

2006

Int. J. Dev. Biol.

307

251

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Twenty years ago, we proposed a model of developmental control based on tensegrity architecture, in which tissue pattern formation in the embryo is controlled through mechanical interactions between cells and extracellular matrix (ECM) which place the tissue in a state of isometric tension (prestress). The model proposed that local changes in the mechanical compliance of the ECM, for example, due to regional variations in basement membrane degradation beneath growing epithelium, may result in local stretching of the ECM and associated adherent cells, much like a "run-in-a-stocking". Cell growth and function would be controlled locally though physical distortion of the associated cells, or changes in cytoskeletal tension. Importantly, experimental studies have demonstrated that cultured cells can be switched between different fates, including growth, differentiation, apoptosis, directional motility and different stem cell lineages, by modulating cell shape. Experiments in whole embryonic organ rudiments also have confirmed the tight correlation between basement membrane thinning, cell tension generation and new bud and branch formation during tissue morphogenesis and that this process can be inhibited or accelerated by dissipating or enhancing cytoskeletal tension, respectively. Taken together, this work confirms that mechanical forces generated in the cytoskeleton of individual cells and exerted on ECM scaffolds, play a critical role in the sculpting of the embryo.

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“…For example, it has been found that increases in cell contractility and ECM stiffness promote cell proliferation 1,2 and assembly of focal adhesions, 3,4 whereas reduction in cell contractility and ECM stiffness induces cytoskeleton depolymerization 3 and apoptosis. 5,6 Several technical developments have enabled these recent insights into the role of mechanics in biology. These include the advent of two-dimensional (2D) substrates for cell culture that spans a range of physiologic stiffnesses 3,7 that can be used to apply force to cells, and whose deformations can be used to report cellular forces.…”

Section: Introductionmentioning

confidence: 99%

Magnetic approaches to study collective three-dimensional cell mechanics in long-term cultures (invited)

Zhao

Boudou

Wang

et al. 2014

Journal of Applied Physics

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Contractile forces generated by cells and the stiffness of the surrounding extracellular matrix are two central mechanical factors that regulate cell function. To characterize the dynamic evolution of these two mechanical parameters during tissue morphogenesis, we developed a magnetically actuated micro-mechanical testing system in which fibroblast-populated collagen microtissues formed spontaneously in arrays of microwells that each contains a pair of elastomeric microcantilevers. We characterized the magnetic actuation performance of this system and evaluated its capacity to support long-term cell culture. We showed that cells in the microtissues remained viable during prolonged culture periods of up to 15 days, and that the mechanical properties of the microtissues reached and maintained at a stable state after a fast initial increase stage. Together, these findings demonstrate the utility of this microfabricated bio-magneto-mechanical system in extended mechanobiological studies in a physiologically relevant 3D environment. V C 2014 AIP Publishing LLC.

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Contraction-Dependent Apoptosis of Normal Dermal Fibroblasts

Cited by 62 publications

References 35 publications

Collagen matrix as a tool in studying fibroblastic cell behavior

Collagen matrix as a tool in studying fibroblastic cell behavior

Mechanical control of tissue morphogenesis during embryological development

Magnetic approaches to study collective three-dimensional cell mechanics in long-term cultures (invited)

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