4.8 Article

Fluid extraction from the left-right organizer uncovers mechanical properties needed for symmetry breaking

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ELIFE
卷 12, 期 -, 页码 -

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eLIFE SCIENCES PUBL LTD
DOI: 10.7554/eLife.83861

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left-right; Kupffer's vesicle; fluid flow; motile cilia; mechanosensory hypothesis; chemosensory hypothesis; Zebrafish

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Humans and other vertebrates establish left-right asymmetry during early embryo development. The mechanism behind this process is still not fully understood, but it involves symmetry breaking in the left-right organizer (LRO) through motile cilia-generated fluid flow. Recent experiments in zebrafish embryos revealed a specific time window and flow direction for breaking left-right symmetry. The embryos demonstrate a remarkable ability to recover and circulate new LRO fluid, indicating that fluid dynamics play a crucial role in symmetry breaking.
Humans and other vertebrates define body axis left-right asymmetry in the early stages of embryo development. The mechanism behind left-right establishment is not fully understood. Symmetry breaking occurs in a dedicated organ called the left-right organizer (LRO) and involves motile cilia generating fluid-flow therein. However, it has been a matter of debate whether the process of symmetry breaking relies on a chemosensory or a mechanosensory mechanism (Shinohara et al., 2012). Novel tailored manipulations for LRO fluid extraction in living zebrafish embryos allowed us to pinpoint a physiological developmental period for breaking left-right symmetry during development. The shortest critical time-window was narrowed to one hour and characterized by a mild counterclockwise flow. The experimental challenge consisted in emptying the LRO of its fluid, abrogating simultaneously flow force and chemical determinants. Our findings revealed an unprecedented recovery capacity of the embryo to re-fil and re-circulate new LRO fluid. The embryos that later developed laterality problems were found to be those that had lower anterior angular velocity and thus less anterior-posterior heterogeneity. Next, aiming to test the presence of any secreted determinant, we replaced the extracted LRO fluid by a physiological buffer. Despite some transitory flow homogenization, laterality defects were absent unless viscosity was altered, demonstrating that symmetry breaking does not depend on the nature of the fluid content but is rather sensitive to fluid mechanics. Altogether, we conclude that the zebrafish LRO is more sensitive to fluid dynamics for symmetry breaking.

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