Abstract
BackgroundThe anterior-posterior axis of the vertebrate embryo undergoes a dramatic elongation during early development. Convergence and extension of the mesoderm, occurring during gastrulation, initiates the narrowing and lengthening of the embryo. However the lengthening of the axis continues during post-gastrula stages in the tailbud region, and is thought to involve convergent extension movements as well as other cell behaviors specific to posterior regions.ResultsWe demonstrate here, using a semi-dominant N-cadherin allele, that members of the classical cadherin subfamily of cell-cell adhesion molecules are required for tailbud elongation in the zebrafish. In vivo imaging of cell behaviors suggests that the extension of posterior axial mesodermal cells is impaired in embryos that carry the semi-dominant N-cadherin allele. This defect most likely results from a general loss of cell-cell adhesion in the tailbud region. Consistent with these observations, N-cadherin is expressed throughout the tailbud during post-gastrulation stages. In addition, we show that N-cadherin interacts synergistically with vang-like 2, a member of the non-canonical Wnt signaling/planar cell polarity pathway, to mediate tail morphogenesis.ConclusionWe provide the first evidence here that N-cadherin and other members of the classical cadherin subfamily function in parallel with the planar cell polarity pathway to shape the posterior axis during post-gastrulation stages. These findings further highlight the central role that adhesion molecules play in the cellular rearrangements that drive morphogenesis in vertebrates and identify classical cadherins as major contributors to tail development.
Highlights
The anterior-posterior axis of the vertebrate embryo undergoes a dramatic elongation during early development
N-cadherin mutants display a range of tail phenotypes Fifteen N-cad mutant alleles have so far been generated in forward genetics screens in the zebrafish [54,55,56,57,58], suggesting that this locus is a hot spot for mutation
The most pronounced posterior phenotype is observed in the N-cadm117 homozygous mutant that contains a substitution of the Tryptophan 2 (Trp2), the second amino acid at the N-terminus of the Cadherin, by Glycine [59]
Summary
The anterior-posterior axis of the vertebrate embryo undergoes a dramatic elongation during early development. The lengthening of the axis continues during post-gastrula stages in the tailbud region, and is thought to involve convergent extension movements as well as other cell behaviors specific to posterior regions. The shape of the vertebrate embryo changes dramatically, as the embryo narrows along the mediolateral axis and simultaneously lengthens along the anterior-posterior (A-P) axis. These morphological changes are brought about by cellular rearrangements, known as convergent extension (CE) movements, that have been studied extensively in the frog and fish embryo (reviewed in [1,2,3]). The mechanisms of posterior body formation in vertebrates involve movements and behaviors that are similar to CE and others that are unique to the posterior body [8,9,10,11]
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