TMEM132A ensures mouse caudal neural tube closure and regulates integrin-based mesodermal migration.

Coordinated migration of the mesoderm is essential for accurate organization of the body plan during embryogenesis. However, little is known about how mesoderm migration influences posterior neural tube closure in mammals. Here, we show that spinal neural tube closure and lateral migration of the caudal paraxial mesoderm depend on transmembrane protein 132A (TMEM132A), a single-pass type I transmembrane protein, the function of which is not fully understood. Our study in Tmem132a-null mice and cell models demonstrates that TMEM132A regulates several integrins and downstream integrin pathway activation as well as cell migration behaviors. Our data also implicates mesoderm migration in elevation of the caudal neural folds and successful closure of the caudal neural tube. These results suggest a requirement for paraxial mesodermal cell migration during spinal neural tube closure, disruption of which may lead to spina bifida.

Phosphorylation of serine residues S252, S268/S269, and S879 in p120 catenin activates migration of presomitic mesoderm in gastrulating zebrafish embryos.

BACKGROUND: Cadherin-associated protein p120 catenin regulates cell adhesion and migration in cell cultures and is required for axial elongation in embryos. Its roles in adhesion and cell migration are regulated by phosphorylation. We determined the effects of phosphorylation of six serine and three threonine residues in p120 catenin during zebrafish (Danio rerio) embryogenesis. RESULTS: We knocked down endogenous p120 catenin-δ1 with an antisense RNA-splice-site morpholino (Sp-MO) causing defects in axis elongation. These defects were rescued by co-injections of mRNAs for wildtype mouse p120 catenin-δ1-3A or various mutated forms. Several mRNAs containing serine or threonine codons singly or doubly mutated to phosphomimetic glutamic acid rescued, and some nonphosphorylatable mutants did not. CONCLUSIONS: We discovered that phosphorylation of serine residue S252 or S879 is required for convergent extension of zebrafish embryos, since rescue occurred only when these residues were mutated to glutamic acid. In addition, the phosphorylation of either S268 or S269 is required, not both, consistent with the presence of only a single one of these residues in two isoforms of zebrafish and Xenopus laevis. In summary, phosphorylation of multiple serine and threonine residues of p120 catenin activates migration of presomitic mesoderm of zebrafish embryos facilitating elongation of the dorsal axis.

Lithium induces dorsal-type migration of mesodermal cells in the entire marginal zone of urodele amphibian embryos.

The effect of lithium (Li+) on gastrulation movements was investigated during the development of the urodele amphibianPleurodeles waltl. Attention was focused on mesodermal cell migration. Under conditions of Li+ treatment providing a maximal enhancement of dorsoanterior structures, it was found that the dorsoventral polarity of gastrulation was abolished. In particular, vital staining and scanning electron microscopy observations on embryo fractures showed that mesodermal cells migrated radially after Li+ treatment, which led to the formation of rounded embryos. Epiboly movements thus were accelerated. Nevertheless, contrasting with the precocious disappearance of the early-formed yolk plug, archenteron invagination was constantly retarded and commenced with a delay of several hours as compared to control gastrulae. Cell-lineage analysis of the progenies from ventral or dorsal equatorial blastomeres of 32-cell-stage embryos provided evidence that both dorsal and ventral mesoderm contributed to notochordal tissue after Li+ treatment. Dorsalization of the entire marginal zone was confirmed by the ability of the entire mesoderm rudiment to behave as a dorsal organiser after Li+ treatment. Comparison of the migratory behaviour of isolated animal hemispheres from Li+-treated or control embryos cultured on fibronectin-coated substrate indicated that all marginal cells acquired the autonomous capacity for migration of dorsal marginal cells under the action of lithium.