Active superelasticity in three-dimensional epithelia of controlled shape

Latorre, Ernest; Kale, Sohan; Casares, Laura; Gómez-González, Manuel; Uroz, Marina; Valon, Léo; Nair, Roshna V.; Garreta, Elena; Montserrat, Núria; Campo, Aránzazu del; Ladoux, Benoît; Arroyo, Marino; Trepat, Xavier

doi:10.1038/s41586-018-0671-4

Cited by 259 publications

(315 citation statements)

References 42 publications

(52 reference statements)

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“…In control experiments, YAP was located in the nucleus of the hMSCs when cultured on the tissue culture plates (TCPS) under both culture conditions (Figure S7, Supporting Information). To further understand the mechanism by cyclic mechanical stimuli to stem cell spheroids, the cell encapsulated in LS hydrogels under the dynamic culture condition were treated with (10 × 10 −6 m ) Y27632, an inhibitor of the RhoA‐associated protein kinase (ROCK), which induced nonmuscle myosin II‐mediated contractility and actin filament levels . As previously shown, YAP translocation was also inhibited upon Y27632 daily during the 20 cycles within growth‐media incubation for both hydrogels under the dynamic culture condition (Figure A,D; Figure S8, Supporting Information).…”

Section: Resultssupporting

confidence: 91%

Dynamic Mechanics‐Modulated Hydrogels to Regulate the Differentiation of Stem‐Cell Spheroids in Soft Microniches and Modeling of the Nonlinear Behavior

Zhang

Yang

Abali

et al. 2019

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Although mechanisms of how physical forces convert into biochemical signals are increasingly understood, it is still unknown how soft cues guide cell behavior. Herein, it is shown that the commitment and differentiation of encapsulating human mesenchymal stem cell (hMSC) spheroids in thermosensitive 3D hydrogels are simply altered by interpenetrating poly(N‐isopropylacrylamide‐co‐2‐hydroxyethyl methacrylate) (NIPAM‐HEMA) nanogel to a gelatin methacryloyl (GelMA) network. This cell‐laden hydrogel provides dynamic mechanics with covalent crosslinking coordinated reversible physical networks, which can regulate hMSCs in situ by reversibly stiffening soft niches via multicyclic temperature changes from 25 to 37 °C. The spreading of hMSC spheroids in the hydrogel is strongly dependent on myosin‐dependent traction stress with dynamic mechanical stimuli through focal adhesion kinase (FAK) signaling. Notably, the dynamic microenvironment gradually influences the expression and distribution from the basal to apical side of nuclear lamin A/C and increases the Yes‐associated protein (YAP) nuclear localization with cycles, which ultimately favors hMSCs undergoing osteogenesis (but not adipogenesis) in the soft microniche. Moreover, it is demonstrated that the viscoelastic behavior of the soft microniche can be guided by temperature through a nonlinear model. These findings highlight the central roles of the dynamic relationship between the biomechanical signals and mechanosensitive transcriptional regulators in cellular mechanosensing.

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Section: Resultssupporting

confidence: 91%

Dynamic Mechanics‐Modulated Hydrogels to Regulate the Differentiation of Stem‐Cell Spheroids in Soft Microniches and Modeling of the Nonlinear Behavior

Zhang

Yang

Abali

et al. 2019

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“…Our study adds to the mechanical processes described in vitro to play a role in tissue folding through proliferation, from mesenchymal constriction (20) to constrained heterogeneous growth (21)(22). It also strengthens the concept that unique physical properties of cells are required during morphogenesis, like superelasticity during growth of epithelium domes (23)(24), or liquid to solid phase transition during elongation of the fish embryo (25). Our in vitro findings establish a buckling mechanism that could participate in many epithelium folding events occurring during embryogenesis.…”

supporting

confidence: 74%

Buckling of epithelium growing under spherical confinement

Trushko

Meglio

Merzouki

et al. 2019

Preprint

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Many organs, such as the gut or the spine are formed through folding of an epithelium. Whereas genetic regulation of epithelium folding has been investigated extensively, the nature of the mechanical forces driving this process remain largely unknown. Here we show that monolayers of identical cells proliferating on the inner surface of elastic spherical shells can spontaneously fold. By measuring the elastic deformation of the shell we inferred the forces acting within the monolayer. Using analytical and numerical theories at different scales, we found that the compressive stresses arising within the cell monolayer through proliferation quantitatively account for the shape of folds observed in experiments. Our study shows that forces arising from epithelium growth are sufficient to drive folding by buckling.

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“…Although each of these mechanisms in isolation can give rise to folding, theoretical and experimental insights suggest that variations of in-plane stresses at the tissue-scale can act in parallel to apical or basal constrictions to define the three-dimensional shape of epithelia (12)(13)(14). Yet, in contrast to the mechanical properties and active forces generated by epithelial monolayers within the plane (11,(15)(16)(17)(18)(19)(20), outof-plane forces and mechanical properties of epithelia (active torques and bending modulus) have not been characterized. Consequently, the relative magnitudes of forces acting inplane and out-of-plane remain unknown, making the contribution of out-of-plane stresses to morphogenesis challenging to assess.…”

Section: Introductionmentioning

confidence: 99%

Curling of epithelial monolayers reveals coupling between active bending and tissue tension

Fouchard

Wyatt

Proag

et al. 2019

Preprint

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Epithelial monolayers are two-dimensional cell sheets which compartmentalise the body and organs of multi-cellular organisms. Their morphogenesis during development or pathology results from patterned endogenous and exogenous forces and their interplay with tissue mechanical properties. In particular, bending of epithelia is thought to results from active torques generated by the polarization of myosin motors along their apico-basal axis. However, the contribution of these out-of-plane forces to morphogenesis remains challenging to evaluate because of the lack of direct mechanical measurement. Here, we use epithelial curling to characterize the out-of-plane mechan ics of epithelial monolayers. We find that curls of high curvature form spontaneously at the free edge of epithelial monolayers devoid of substrate in vivo and in vitro. Curling originates from an enrichment of myosin in the basal domain that generates an active spontaneous curvature. By measuring the force necessary to flatten curls, we can then estimate the active torques and the bending modulus of the tissue. Finally, we show that the extent of curling is controlled by the interplay between in-plane and out-of-plane stresses in the monolayer. Such mechanical coupling implies an unexpected role for in-plane stresses in shaping epithelia during morphogenesis.

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Active superelasticity in three-dimensional epithelia of controlled shape

Cited by 259 publications

References 42 publications

Dynamic Mechanics‐Modulated Hydrogels to Regulate the Differentiation of Stem‐Cell Spheroids in Soft Microniches and Modeling of the Nonlinear Behavior

Dynamic Mechanics‐Modulated Hydrogels to Regulate the Differentiation of Stem‐Cell Spheroids in Soft Microniches and Modeling of the Nonlinear Behavior

Buckling of epithelium growing under spherical confinement

Curling of epithelial monolayers reveals coupling between active bending and tissue tension

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