Abstract
AbstractSomitogenesis starts with cyclic waves of expression of segmentation clock genes in the presomitic mesoderm (PSM) and culminates with periodic budding of somites in its anterior-most region. How cyclic clock gene expression is translated into timely morphological somite formation has remained unclear. A posterior to anterior gradient of increasing PSM tissue cohesion correlates with increasing fibronectin matrix complexity around the PSM, suggesting that fibronectin-dependent tissue mechanics may be involved in this transition. Here we address whether the mechanical properties of the PSM tissue play a role in regulating the pathway leading to cleft formation in the anterior PSM. We first interfered with cytoskeletal contractility in the chick PSM by disrupting actomyosin-mediated contractility directly or via Rho-associated protein kinase function. Then we perturbed fibronectin matrix accumulation around the PSM tissue by blocking integrin-fibronectin binding or fibronectin matrix assembly. All four treatments perturbed hairy1 and meso1 expression dynamics and resulted in defective somitic clefts. A model is presented where a gradient of fibronectin-dependent tissue mechanics participates in the PSM wavefront of maturation by ensuring the correct spatio-temporal conversion of cyclic segmentation clock gene expression into periodic somite formation.
Publisher
Cold Spring Harbor Laboratory
Cited by
1 articles.
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