Stiffness of MDCK II Cells Depends on Confluency and Cell Size

Nehls, Stefan; Nöding, Helen; Karsch, Susanne; Ries, Franziska; Janshoff, Andreas

doi:10.1016/j.bpj.2019.04.028

Cited by 36 publications

(22 citation statements)

References 44 publications

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“…Individual MDCK-II cells show mechanoresponse in the between 0.6 to 5 kPa, while no signicant dierences were noted on 11, 20, 34 kPa [34]. That coincides with the range reported for in vivo stiness of kidneys [66,67] and stiness of MDCK-II cells themselves [68]. This range also coincides with the range at which we observe major changes in tissue organization and mechanoresponse.…”

Section: Macroscopic Organisation On Soft Gelssupporting

confidence: 89%

On the mechanical regulation of epithelial tissue homeostasis

Kaliman

Hubert

Wollnik

et al. 2021

Preprint

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Despite recent efforts to understand homeostasis in epithelial tissues, there are many unknowns surrounding this steady state. It is considered to be regulated by mechanoresponse, but unlike for single cells, this remains heavily debated for tissues. Here, we show that changes in matrix stiffness induce a non-equilibrium transition from tubular to squamous Madin-Darby Canine Kidney II tissues. Nonetheless, despite different cell morphologies and densities, all homeostatic tissues display equivalent topologies, which, hence, must be actively targeted and regulated. On the contrary, the mechanoresponse induces dramatic changes in the large-scale organization of the colonies. On stiff gels, this yields an unreported cooperative state of motile cells displaying higher densities than in the arrested homeostatic state. This suggests a more complex relation between cell density and motility than previously anticipated. Our results unequivocally relate the mechanosensitive properties of individual cells to the evolving macroscopic structures, an effect that could be important for understanding the emergent pathologies of living tissues.

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Section: Macroscopic Organisation On Soft Gelssupporting

confidence: 89%

On the mechanical regulation of epithelial tissue homeostasis

Kaliman

Hubert

Wollnik

et al. 2021

Preprint

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“…In HeLa cells, treatment with the myosin II inhibitor blebbistatin fully rescued protrusion formation of S. flexneri that produces IpaC R362W (Figures 3C and 3D) but did not affect protrusion formation by bacteria producing WT IpaC, demonstrating that protrusion formation requires IpaC-mediated reduction in membrane tension. The membrane tension of cells is inversely proportional to their density in a monolayer (Nehls et al, 2019). We therefore hypothesized that the role of IpaC R362 in protrusion formation might be more pronounced in sub-confluent cells than in confluent cells.…”

Section: Cell-cell Tension Is Reduced By S Flexneri In An Ipac-depenmentioning

confidence: 99%

Shigella flexneri Disruption of Cellular Tension Promotes Intercellular Spread

et al. 2020

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“…With time, the area of growing or winner cells becomes larger than the neighbouring or loser cells (Figure 10B). Stefan et al (Nehls et al, 2019) reported that the stiffness of MDCK cells depends upon their size, i.e., big cells have high stiffness, and small cells have less stiffness. Therefore, it suggests that the winner cells of the colonies have higher stiffness compared to the loser cells.…”

Section: Discussionmentioning

confidence: 99%

Mechanism of tissue expansion in the early stage of the migration

Kiran

Kumar

Mehandia

2021

Preprint

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The collective cell migration is observed in many biological processes such as wound healing, embryogenesis, and cancer metastasis. Despite extensive theoretical and experimental studies on collective cell motion, there is no unified mechanism to explain it. In this work, we experimentally report the collectively growing cell colonies in the sub-marginal region of a freely expanding cell monolayer. These colonies could be responsible for the highly aligned collective cell migration observed in front cell rows. Our results provide a basic framework to understand the physical mechanism responsible for collective cell migration in the freely expanding monolayer.

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Stiffness of MDCK II Cells Depends on Confluency and Cell Size

Cited by 36 publications

References 44 publications

On the mechanical regulation of epithelial tissue homeostasis

On the mechanical regulation of epithelial tissue homeostasis

Shigella flexneri Disruption of Cellular Tension Promotes Intercellular Spread

Mechanism of tissue expansion in the early stage of the migration

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