AI Article Synopsis
- Researchers are investigating how cell collectives in embryos move and arrange themselves, focusing on the role of chemical gradients in this process.
- New findings in zebrafish show that cells can respond to uniform chemical signals, suggesting that they can still organize despite a lack of directional cues.
- The study proposes a mechanism for these cells to create movement patterns, identifying an optimal distance for effective tissue velocity and suggesting experiments to test this model.
Article Abstract
How cell collectives move and deposit subunits within a developing embryo is a question of outstanding interest. In many cases, a chemotactic mechanism is employed, where cells move up or down a previously generated attractive or repulsive gradient of signalling molecules. Recent studies revealed the existence of systems with isotropic chemoattractant expression in the lateral line primordium of zebrafish. Here we propose a mechanism for a cell collective, which actively modulates an isotropically expressed ligand and encodes an initial symmetry breaking in its velocity. We derive a closed solution for the velocity and identify an optimal length that maximizes the tissues' velocity. A length dependent polar gradient is identified, its use for pro-neuromast deposition is shown by simulations and a critical time for cell deposition is derived. Experiments to verify this model are suggested.
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| http://dx.doi.org/10.1088/1478-3975/8/4/045004 | DOI Listing |
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