Embryonic Tissues as Active Foams

Kim, Sang Woo; Pochitaloff, Marie; Stooke‐Vaughan, Georgina A.; Campàs, Otger

doi:10.1101/2020.06.17.157909

Cited by 33 publications

(52 citation statements)

References 41 publications

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“…These observations reveal spatiotemporal changes in the somite physical state over the course of somitogenesis, with the fluidization of the tissue adjacent to the posterior boundary occurring as the tissue surrounding the anterior boundary rigidifies. Together with previous measurements of stress relaxation in the paraxial mesoderm 30,40 , our results indicate that at the timescales of somite formation (30 minutes) both the interior of the somite and its anterior boundary are in a solid state (albeit with a more rigid anterior boundary), while the posterior boundary is transiently fluidized during the physical segmentation of the PSM.…”

Section: Resultssupporting

confidence: 85%

Stress-driven tissue fluidization physically segments vertebrate somites

Shelton

et al. 2021

Preprint

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Shaping functional structures during embryonic development requires both genetic and physical control. During somitogenesis, cell-cell coordination sets up genetic traveling waves in the presomitic mesoderm (PSM) that orchestrate somite formation. While key molecular and genetic aspects of this process are known, the mechanical events required to physically segment somites from the PSM remain unclear. Combining direct mechanical measurements during somite formation, live imaging of cell and tissue structure, and computer simulations, here we show that somites are mechanically sectioned off from the PSM by a large, actomyosin-driven increase in anisotropic stress at the nascent somite-somite boundary. Our results show that this localized increase in stress drives the regional fluidization of the tissue adjacent to the forming somite border, enabling local tissue remodeling and the shaping of the somite. Moreover, we find that active tension fluctuations in the tissue are optimized to mechanically define sharp somite boundaries while minimizing somite morphological defects. Altogether, these results indicate that mechanical changes at the somite-somite border and optimal tension fluctuations in the tissue are essential physical aspects of somite formation.

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Section: Resultssupporting

confidence: 85%

Stress-driven tissue fluidization physically segments vertebrate somites

Shelton

et al. 2021

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“…Active fluctuations in tension and shape can help to overcome these energy barriers and promote the ability of a tissue to remodel and flow-tissue fluidity. Indeed, recent experimental studies point toward exactly such a role for active fluctuations in promoting fluidity within tissues (40,41). Future studies of the biophysics of cell rearrangements in the germband will be needed to explore further how active fluctuations might contribute to oriented cell rearrangements in both wild-type and mutant embryos.…”

Section: Discussionmentioning

confidence: 99%

“…Fluctuations or pulses in myosin accumulation and associated changes in apical cell shape have been described in many epithelia and are thought to play key roles in diverse cellular processes during morphogenesis, including apical cell constriction and cell intercalation (1,67). Moreover, active fluctuations in cell shape and actomyosin accumulation have been proposed to play key roles in promoting cell rearrangement and tissue fluidity in some contexts (40,41). While cell area fluctuations have been reported in the germband during axis elongation (34,37,66), their role in the process remains unclear.…”

Section: The Magnitudes Of Cell Area Fluctuations Are Tuned By Optogementioning

confidence: 99%

“…In addition to junctional actomyosin, a dynamic actomyosin meshwork in the medial-apical domain of germband cells exhibits polarized flows and pulsatile behaviors that are thought to contribute to pulsatile fluctuations in cell junctions and apical cell areas and to cell intercalation (34)(35)(36)(37)(38)(39). Recent theoretical and experimental studies point toward important roles both for active fluctuations in cell shape and junctions (40,41) and for details of cellular packings within tissues (42)(43)(44)(45) in the physics of cell rearrangements and the ability of a tissue to remodel and flow, i.e. tissue fluidity.…”

Section: Introductionmentioning

confidence: 99%

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Using optogenetics to link myosin patterns to contractile cell behaviors during convergent extension

Herrera-Perez

Cupo

Allan

et al. 2021

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Distinct spatiotemporal patterns of actomyosin contractility are often associated with particular epithelial tissue shape changes during development. For example, a planar polarized pattern of myosin II localization regulated by Rho1 signaling during Drosophila body axis elongation is thought to drive the cell behaviors that contribute to convergent extension. However, it is not well understood how specific aspects of a myosin localization pattern influence the multiple cell behaviors — including cell intercalation, cell shape changes, and apical cell area fluctuations — that simultaneously occur within a tissue during morphogenesis. Here, we use optogenetic activation (optoGEF) and deactivation (optoGAP) of Rho1 signaling to perturb the myosin pattern in the germband epithelium during Drosophila axis elongation and analyze the effects on contractile cell behaviors within the tissue. We find that uniform photoactivation of optoGEF or optoGAP is sufficient to rapidly override the endogenous myosin pattern, abolishing myosin planar polarity and reducing cell intercalation and convergent extension. However, these two perturbations have distinct effects on junctional and medial myosin localization, apical cell area fluctuations, and cell packings within the germband. Activation of Rho1 signaling in optoGEF embryos increases myosin accumulation in the medial-apical domain of germband cells, leading to increased amplitudes of apical cell area fluctuations. This enhanced contractility is translated into heterogeneous reductions in apical cell areas across the tissue, disrupting cellular packings within the germband. Conversely, inactivation of Rho1 signaling in optoGAP embryos decreases both medial and junctional myosin accumulation, leading to a dramatic reduction in cell area fluctuations. These results demonstrate that the level of Rho1 activity and the balance between junctional and medial myosin regulate apical cell area fluctuations and cellular packings in the germband, which have been proposed to influence the biophysics of cell rearrangements and tissue fluidity.

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“…collective solidification) caused by changes in density or cell mechanics, or instead by a decrease in active stress fluctuations in a material that remains fluid-like. Particle-based models for tissues predict decreased cell motion arising from reduced interstitial space at increased cell density (12, 22, 23, 35). In contrast, vertex models predict that the cell density is not a direct control parameter for cell dynamics (24).…”

Section: Introductionmentioning

confidence: 99%

Cell cycle-dependent active stress drives epithelia remodeling

Devany

Sussman

Yamamoto

et al. 2019

Preprint

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Epithelia have distinct cellular architectures, which are established in development, re-established after wounding, and maintained during tissue homeostasis despite cell turnover and mechanical perturbations. In turn, cell shape also controls tissue function as a regulator of cell differentiation, proliferation, and motility. Here we investigate cell shape changes in a model epithelial monolayer. After the onset of confluence, cells continue to divide and change shape over time, eventually leading to a final steady state characterized by arrested motion and more regular cell shapes. Such monolayer remodeling is robust, with qualitatively similar changes in cell shape and dynamics observed in a variety of conditions. However, quantitative differences in monolayer remodeling dynamics reveal underlying order parameters controlling epithelial architecture. For instance, for monolayers formed atop extracellular matrix with varied stiffness, the cell density varies significantly but the relationship between cell shape and motility remain similar. In contrast, pharmacological perturbations can alter the cell shape at which their motility is arrested. Remarkably, across all of these experimental conditions the final cell shape is well correlated to the cell division rate. Furthermore, inhibition of the cell cycle immediately arrests both cell motility and shape change, demonstrating that active stress from cell divisions contributes significantly to monolayer remodeling. Thus, the architecture and mechanics of epithelial tissue can arise from an interplay between cell mechanics and stresses arising from cell division. Bi D, LopezJH, Schwarz JM, Manning ML (2015) A density-independent rigidity transition in biological tissues. Nat Phys 11(12):1074-1079. 30. Lecuit T, Lenne P-F (2007) Cell surface mechanics and the control of cell shape, tissue patterns and morphogenesis. Nat Rev Mol Cell Biol 8(8):633-644. 31. Bi D, Yang X, Marchetti MC, Manning ML (2016) Motility-driven glass and jamming transitions in biological tissues. Phys Rev X 6(2). 32. Yang X, et al. (2017) Correlating cell shape and cellular stress in motile confluent tissues. Proc Natl Acad Sci U S A 114(48):12663-12668. 33. Ng MR, Besser A, Danuser G, Brugge JS (2012) Substrate stiffness regulates cadherindependent collective migration through myosin-II contractility. J Cell Biol 199(3):545-563. 34. Trepat X, et al. (2009) Physical forces during collective cell migration. Nat Phys 5:426-430. 35. De Pascalis C, et al. (2018) Intermediate filaments control collective migration by restricting traction forces and sustaining cell-cell contacts. J Cell Biol 217(9):3031-3044. 36. Sussman DM (2017) cellGPU: Massively parallel simulations of dynamic vertex models. Comput Phys Commun 219:400-406. 37. Sussman DM, Paoluzzi M, Cristina Marchetti M, Lisa Manning M (2018) Anomalous glassy dynamics in simple models of dense biological tissue. EPL 121(3):36001. 38. Doyle AD, Carvajal N, Jin A, Matsumoto K, Yamada KM (2015) Local 3D matrix microenvironment regulates cell migrat...

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Embryonic Tissues as Active Foams

Cited by 33 publications

References 41 publications

Stress-driven tissue fluidization physically segments vertebrate somites

Stress-driven tissue fluidization physically segments vertebrate somites

Using optogenetics to link myosin patterns to contractile cell behaviors during convergent extension

Cell cycle-dependent active stress drives epithelia remodeling

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