Tissue Origins and Interactions in the Mammalian Skull Vault

AbstractDuring mammalian evolution, expansion of the cerebral hemispheres was accompanied by expansion of the frontal and parietal bones of the skull vault and deployment of the coronal (fronto-parietal) and sagittal (parietal–parietal) sutures as major growth centres. Using a transgenic mouse with a permanent neural crest cell lineage marker, Wnt1-Cre/R26R, we show that both sutures are formed at a neural crest–mesoderm interface: the frontal bones are neural crest-derived and the parietal bones mesodermal, with a tongue of neural crest between the two parietal bones. By detailed analysis of neural crest migration pathways using X-gal staining, and mesodermal tracing by DiI labelling, we show that the neural crest–mesodermal tissue juxtaposition that later forms the coronal suture is established at E9.5 as the caudal boundary of the frontonasal mesenchyme. As the cerebral hemispheres expand, they extend caudally, passing beneath the neural crest–mesodermal interface within the dermis, carrying with them a layer of neural crest cells that forms their meningeal covering. Exposure of embryos to retinoic acid at E10.0 reduces this meningeal neural crest and inhibits parietal ossification, suggesting that intramembranous ossification of this mesodermal bone requires interaction with neural crest-derived meninges, whereas ossification of the neural crest-derived frontal bone is autonomous. These observations provide new perspectives on skull evolution and on human genetic abnormalities of skull growth and ossification

Retinoic acid specifically downregulates Fgf4 and inhibits posterior cell proliferation in the developing mouse autopod

Retinoic acid, when administered to pregnant mice on d 11.0 of gestation, causes limb skeletal abnormalities consisting of reduced digital number, shortening of the long bones and delayed ossification. We show here that these effects are correlated with a decrease in cell proliferation within 5 h of retinoic acid administration, specifically in the posterior half of the distal limb bud mesenchyme, from which the distal skeletal elements are generated. There is a specific downregulation of Fgf4, a gene known to be involved in limb bud outgrowth and expressed only in the posterior part of the apical ectodermal ridge; Fgf8, which is expressed throughout the apical ectodermal ridge, is unaffected. The reduction in Fgf4 expression is not accompanied by downregulation of Shh, nor of its receptor and downstream target gene Ptc, suggesting that the skeletal reduction defects induced by retinoic acid are mediated specifically by FGF4-induced skeletogenic mesenchymal cell proliferation

Morphogenesis of Doublefoot (Dbf), a mouse mutant with polydactyly and craniofacial defects

We report the morphogenesis of a new mouse mutant, Doublefoot (Dbf). The major phenotypic features involve the limb and craniofacial regions. There is polydactyly of all 4 limbs, with typically 6–8 digits per limb. All of the digits are triphalangeal; some show bifurcations and some are not attached to the carpus/tarsus. The carpus and tarsus are broader than normal, and their elements are partially fused. There are also tibial defects. Mutant embryos show a diencephalic bulge on d 10.0, with older animals exhibiting broadened and bulbous skulls sometimes with an additional midline skeletal element, shortened snouts and bulging eyes. Homozygotes, which do not survive beyond d 15, show midline facial clefting. In this study of the embryonic and fetal development of Dbf animals, we focus on the morphogenesis of the limbs and head, and discuss the possible molecular developmental mechanisms

Effects of the curly tail genotype on neuroepithelial integrity and cell proliferation during late stages of primary neurulation

The curly tail (ct/ct) mouse mutant shows a high frequency of delay or failure of neural tube closure, and is a good model for human neural tube defects, particularly spina bifida. In a previous study we defined distinct domains of gene expression in the caudal region of non-mutant embryos during posterior (caudal) neuropore closure (Gofflot et al. Developmental Dynamics210, 431–445, 1997). Here we use BrdU incorporation into S-phase nuclei to investigate the relationship between cell proliferation and the previously described gene expression domains in ct/ct mutant embryos. The BrdU-immunostained sections were also examined for abnormalities of tissue structure; immunohistochemical detection of perlecan (an extracellular heparan sulphate proteoglycan) was used as an indicator of neuroepithelial basement membrane structure and function. Quantitation of BrdU uptake revealed that at early stages of neurulation, cell proliferation was specifically reduced in the paraxial mesoderm of all ct/ct embryos compared with wild type controls, but at later stages (more cranial levels) it was increased. Those ct/ct embryos with enlarged posterior neuropore (indicating delay of closure) additionally showed an increased BrdU labelling index within the open neuroepithelium at all axial levels; however, this tissue was highly abnormal with respect to cell and nuclear morphology. It showed cell death and loss of cells from the apical surface, basement membrane defects including increased perlecan immunoreactivity, and increased separation from the underlying mesenchyme and notochord. These observations suggest that the mechanism of delay or failure of neuroepithelial curvature that leads to neural tube defects in curly tail embryos involves abnormalities of neuroepithelial-mesenchymal interactions that may be initiated by abnormal cellular function within the neuroepithelium. Minor histological and proliferation abnormalities are present in all ct/ct embryos, regardless of phenotype

Developmental mechanisms underlying polydactyly in the mouse mutant Doublefoot

The pre-axial polydactylous mouse mutant Doublefoot has 6–9 digits per limb but lacks anteroposterior polarity (there is no biphalangeal digit 1). It differs from other polydactylous mutants in showing normal Shh expression, but polarizing activity (shown by mouse-chick grafting experiments) and hedgehog signalling activity (shown by expression of Ptc1) are present throughout the distal mesenchyme. The Dbf mutation has not yet been identified. Here we review current understanding of this mutant, and briefly report new results indicating (1) that limb bud expansion is concomitant with ectopic Ihh expression and with extension of the posterior high cell proliferation rate into the anterior region, and (2) that the Dbf mutation is epistatic to Shh in the limb