Elijah Shelton scite author profile

Just as in clay moulding or glass blowing, physically sculpting biological structures requires the constituent material to locally flow like a fluid while maintaining overall mechanical integrity like a solid. Disordered soft materials, such as foams, emulsions and colloidal suspensions, switch from fluid-like to solid-like behaviours at a jamming transition. Similarly, cell collectives have been shown to display glassy dynamics in 2D and 3D and jamming in cultured epithelial monolayers, behaviours recently predicted theoretically and proposed to influence asthma pathobiology and tumour progression. However, little is known about whether these seemingly universal behaviours occur in vivo and, specifically, whether they play any functional part during embryonic morphogenesis. Here, by combining direct in vivo measurements of tissue mechanics with analysis of cellular dynamics, we show that during vertebrate body axis elongation, posterior tissues undergo a jamming transition from a fluid-like behaviour at the extending end, the mesodermal progenitor zone, to a solid-like behaviour in the presomitic mesoderm. We uncover an anteroposterior, N-cadherin-dependent gradient in yield stress that provides increasing mechanical integrity to the presomitic mesoderm, consistent with the tissue transiting from a wetter to a dryer foam-like architecture. Our results show that cell-scale stresses fluctuate rapidly (within about 1 min), enabling cell rearrangements and effectively 'melting' the tissue at the growing end. Persistent (more than 0.5 h) stresses at supracellular scales, rather than cell-scale stresses, guide morphogenetic flows in fluid-like tissue regions. Unidirectional axis extension is sustained by the reported rigidification of the presomitic mesoderm, which mechanically supports posterior, fluid-like tissues during remodelling before their maturation. The spatiotemporal control of fluid-like and solid-like tissue states may represent a generic physical mechanism of embryonic morphogenesis.

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Spatiotemporal variation of endogenous cell-generated stresses within 3D multicellular spheroids

Lucio

Mongera

Shelton

et al. 2017

Sci Rep

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Multicellular spheroids serve as an excellent platform to study tissue behavior and tumor growth in a controlled, three-dimensional (3D) environment. While molecular and cellular studies have long used this platform to study cell behavior in 3D, only recently have studies using multicellular spheroids shown an important role for the mechanics of the microenvironment in a wide range of cellular processes, including during tumor progression. Despite the well-established relevance of mechanical cues to cell behavior and the numerous studies on mechanics using 2D cell culture systems, the spatial and temporal variations in endogenous cellular forces within growing multicellular aggregates remain unknown. Using cell-sized oil droplets with controlled physicochemical properties as force transducers in mesenchymal cell aggregates, we show that the magnitude of cell-generated stresses varies only weakly with spatial location within the spherical aggregate, but it increases considerably over time during aggregate compaction and growth. Moreover, our results indicate that the temporal increase in cellular stresses is due to increasing cell pulling forces transmitted via integrin-mediated cell adhesion, consistent with the need for larger intercellular pulling forces to compact cell aggregates.

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Geometrical characterization of fluorescently labelled surfaces from noisy 3D microscopy data

Shelton

Serwane

Campàs

2017

Journal of Microscopy

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Modern fluorescence microscopy enables fast 3D imaging of biological and inert systems alike. In many studies, it is important to detect the surface of objects and quantitatively characterize its local geometry, including its mean curvature. We present a fully automated algorithm to determine the location and curvatures of an object from 3D fluorescence images, such as those obtained using confocal or light-sheet microscopy. The algorithm aims at reconstructing surface labelled objects with spherical topology and mild deformations from the spherical geometry with high accuracy, rather than reconstructing arbitrarily deformed objects with lower fidelity. Using both synthetic data with known geometrical characteristics and experimental data of spherical objects, we characterize the algorithm's accuracy over the range of conditions and parameters typically encountered in 3D fluorescence imaging. We show that the algorithm can detect the location of the surface and obtain a map of local mean curvatures with relative errors typically below 2% and 20%, respectively, even in the presence of substantial levels of noise. Finally, we apply this algorithm to analyse the shape and curvature map of fluorescently labelled oil droplets embedded within multicellular aggregates and deformed by cellular forces.

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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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Elijah Shelton

A fluid-to-solid jamming transition underlies vertebrate body axis elongation

Spatiotemporal variation of endogenous cell-generated stresses within 3D multicellular spheroids

Geometrical characterization of fluorescently labelled surfaces from noisy 3D microscopy data

Stress-driven tissue fluidization physically segments vertebrate somites

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