Tissue self-organization underlies morphogenesis of the notochord.
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2018-09
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Abstract
The notochord is a conserved axial structure that in vertebrates serves as a hydrostatic scaffold for embryonic axis elongation and, later on, for proper spine assembly. It consists of a core of large fluid-filled vacuolated cells surrounded by an epithelial sheath that is encased in extracellular matrix. During morphogenesis, the vacuolated cells inflate their vacuole and arrange in a stereotypical staircase pattern. We investigated the origin of this pattern and found that it can be achieved purely by simple physical principles. We are able to model the arrangement of vacuolated cells within the zebrafish notochord using a physical model composed of silicone tubes and water-absorbing polymer beads. The biological structure and the physical model can be accurately described by the theory developed for the packing of spheres and foams in cylinders. Our experiments with physical models and numerical simulations generated several predictions on key features of notochord organization that we documented and tested experimentally in zebrafish. Altogether, our data reveal that the organization of the vertebrate notochord is governed by the density of the osmotically swelling vacuolated cells and the aspect ratio of the notochord rod. We therefore conclude that self-organization underlies morphogenesis of the vertebrate notochord.This article is part of the Theo Murphy meeting issue on 'Mechanics of development'.
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Norman, James, Emma L Sorrell, Yi Hu, Vaishnavi Siripurapu, Jamie Garcia, Jennifer Bagwell, Patrick Charbonneau, Sharon R Lubkin, et al. (2018). Tissue self-organization underlies morphogenesis of the notochord. Philosophical transactions of the Royal Society of London. Series B, Biological sciences, 373(1759). p. 20170320. 10.1098/rstb.2017.0320 Retrieved from https://hdl.handle.net/10161/31150.
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Patrick Charbonneau
Professor Charbonneau studies soft matter. His work combines theory and simulation to understand the glass problem, protein crystallization, microphase formation, and colloidal assembly in external fields.
Michel Bagnat
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