Crest Migration (crest + migration)

Distribution by Scientific Domains

Kinds of Crest Migration

  • cranial neural crest migration
  • neural crest migration


  • Selected Abstracts


    The formation of the superior and jugular ganglia: Insights into the generation of sensory neurons by the neural crest

    DEVELOPMENTAL DYNAMICS, Issue 2 2010
    Hannah Thompson
    Abstract The superior and jugular ganglia (S/JG) are the proximal ganglia of the IXth and Xth cranial nerves and the sensory neurons of these ganglia are neural crest derived. However, it has been unclear the extent to which their differentiation resembles that of the Dorsal Root Ganglia (DRGs). In the DRGs, neural crest cells undergo neuronal differentiation just after the onset of migration and there is evidence suggesting that these cells are pre-specified towards a sensory fate. We have analysed sensory neuronal differentiation in the S/JG. We show, in keeping with previous studies, that neuronal differentiation initiates long after the cessation of neural crest migration. We also find no evidence for the existence of migratory neural crest cells pre-specified towards a sensory phenotype prior to ganglion formation. Rather our results suggest that sensory neuronal differentiation in the S/JG is the result of localised spatiotemporal cues. Developmental Dynamics 239:439,445, 2010. © 2009 Wiley-Liss, Inc. [source]


    Wnt11r is required for cranial neural crest migration

    DEVELOPMENTAL DYNAMICS, Issue 11 2008
    Helen K. Matthews
    Abstract wnt11r is a recently identified member of the Wnt family of genes, which has been proposed to be the true Xenopus homologue to the mammalian wnt11 gene. In this study we have examined the role of wnt11r on neural crest development. Expression analysis of wnt11r and comparison with the neural crest marker snail2 and the noncanonical Wnt, wnt11, shows wnt11r is expressed at the medial or neural plate side of the neural crest while wnt11 is expressed at the lateral or epidermal side. Injection of wnt11r morpholino leads to strong inhibition of neural crest migration with no effect on neural crest induction or maintenance. This effect can be rescued by co-injection of Wnt11r but not by Wnt11 mRNA, demonstrating the specificity of the loss of function treatment. Finally, neural crest graft experiments show that wnt11r is required in a non,cell-autonomous manner to control neural crest migration. Developmental Dynamics 237:3404,3409, 2008. © 2008 Wiley-Liss, Inc. [source]


    Gli3 -deficient mice exhibit cleft palate associated with abnormal tongue development

    DEVELOPMENTAL DYNAMICS, Issue 10 2008
    Xi Huang
    Abstract Palatogenesis depends on appropriate growth, elevation, and fusion of the palatal shelves and aberration in these processes can lead to palatal clefting. We observed a high incidence of palate clefting in mice deficient in Gli3, known for its role as a repressor in the absence of Shh signaling. In contrast with several current mouse models of cleft palate, Meckel's cartilage extension, cranial neural crest migration, palatal shelf proliferation, apoptosis, and key signaling components mediated by Shh, Bmp, Fgf, and Tgf,, appeared unaffected in Gli3,/, mice. Palatal clefting in Gli3,/, mice was consistently associated with tongue abnormalities such as failure to flatten and improper positioning, implicating a critical role of Gli3 and normal tongue morphogenesis for timely palatal shelf elevation and joining. Furthermore, Gli3,/, palatal shelves grown in roller cultures without tongue can fuse suggesting that the abnormal tongue is likely an impediment for palatal shelf joining in Gli3,/, mutants. Developmental Dynamics 237:3079,3087, 2008. © 2008 Wiley-Liss, Inc. [source]


    Synthetic matrix metalloproteinase inhibitor decreases early cardiac neural crest migration in chicken embryos

    DEVELOPMENTAL DYNAMICS, Issue 4 2002
    D.H. Cai
    Abstract During early embryonic development, cardiac neural crest (NC) cells emerge from the forming neural tube, migrate beneath the ectoderm, enter the pharyngeal arches, and subsequently participate in the septation of the heart. Like tumor cells, NC cells penetrate through basement membranes and invade extracellular matrix during their emigration and migration and, therefore, are liable to use similar invasive mechanisms. Matrix metalloproteinases (MMPs) are a family of zinc proteolytic enzymes known to be important in cell migration and invasion of normal and metastatic cells. In an earlier study, we found that the spatial and temporal distribution pattern of MMP-2 positively correlates with cardiac NC migration, suggesting MMP enzymatic activity may be important in mediating cardiac cell NC migration. To test this hypothesis, a synthetic MMP inhibitor, KB8301, was used to block MMP enzymatic activity during in vitro and in vivo cardiac NC cell migration in chick embryos. Injection of KB8301 into the cell-free space adjacent to the neural tube at the level of the second somite before the NC cells emigrated caused major morphologic anomalies in embryos and disrupted cardiac NC morphogenesis. Unilateral injection of KB8301 at lower concentrations, significantly decreased cardiac NC migration on the injected side compared with the noninjected side and compared with that of the injected controls. This decrease correlated with a decrease in MMP activity in the embryos and was not attributable to differences in embryo size or rate of embryonic development after injection. KB8301 also significantly decreased the rate of NC cell motility and distance NC cells migrated from explanted neural tubes and increased cell area and perimeter. These data suggest that MMP enzymatic activity is an important mediator of early cardiac NC migration and that perturbation of endogenous MMP activity may lead to NC-related congenital defects. © 2002 Wiley-Liss, Inc. [source]


    Effect of elevated homocysteine on cardiac neural crest migration in vitro

    DEVELOPMENTAL DYNAMICS, Issue 2 2002
    Philip R. Brauer
    Abstract A positive correlation between elevated maternal homocysteine (Hcys) and an increased risk of neural tube, craniofacial, and cardiac defects is well known. Studies suggest Hcys perturbs neural crest (NC) development and may involve N-methyl-D-aspartate (NMDA) receptors (Rosenquist et al., 1999). However, there is no direct evidence that Hcys alters NC cell behavior. Here, we evaluated the effect of Hcys on cardiac NC cell migratory behavior in vitro. Neural tube segments from chick embryos treated in ovo with or without Hcys were placed in culture and the migratory behavior of emigrating NC cells was monitored. Hcys significantly increased in vitro NC cell motility at all embryonic stages examined. NC cell surface area and perimeter were also increased. However, the relative distance NC cells migrated from their original starting point only increased in NC cells treated in ovo at stage 6 or at the time neural tube segments were cultured. Cysteine had no effect. NMDA mimicked Hcys' effect on NC motility and migration distance but had no effect on cell area or perimeter. The noncompetitive inhibitor of NMDA receptors, MK801+, significantly inhibited NC cell motility, reduced migration distance, and also blocked the effects of NMDA and Hcys on NC motility and migratory distance in vitro. A monoclonal antibody directed against the NMDA receptor immunostained NC cells in vitro and, in western blots, bound a single protein with the appropriate molecular weight for the NMDA receptor in NC cell lysates. These data are consistent with the hypothesis that a Hcys-sensitive NMDA-like receptor is expressed by early emigrating NC cells or their precursors, which is important in mediating their migratory behavior. Perturbation of this receptor may be related to some of the teratogenic effects observed with elevated Hcys. © 2002 Wiley-Liss, Inc. [source]


    Early differentiation and migration of cranial neural crest in the opossum, Monodelphis domestica

    EVOLUTION AND DEVELOPMENT, Issue 2 2003
    Janet L. Vaglia
    SUMMARY Marsupial mammals are born at a highly altricial state. Nonetheless, the neonate must be capable of considerable functional independence. Comparative studies have shown that in marsupials the morphogenesis of many structures critical to independent function are advanced relative to overall development. Many skeletal and muscular elements in the facial region show particular heterochrony. Because neural crest cells are crucial to forming and patterning much of the face, this study investigates whether the timing of cranial neural crest differentiation is also advanced. Histology and scanning electron microscopy of Monodelphis domestica embryos show that many aspects of cranial neural crest differentiation and migration are conserved in marsupials. For example, as in other vertebrates, cranial neural crest differentiates at the neural ectoderm/epidermal boundary and migrates as three major streams. However, when compared with other vertebrates, a number of timing differences exist. The onset of cranial neural crest migration is early relative to both neural tube development and somite formation in Monodelphis. First arch neural crest cell migration is particularly advanced and begins before any somites appear or regional differentiation exists in the neural tube. Our study provides the first published description of cranial neural crest differentiation and migration in marsupials and offers insight into how shifts in early developmental processes can lead to morphological change. [source]


    Cranial neural crest cell migration in the Australian lungfish, Neoceratodus forsteri

    EVOLUTION AND DEVELOPMENT, Issue 4 2000
    Pierre Falck
    SUMMARY A crucial role for the cranial neural crest in head development has been established for both actinopterygian fishes and tetrapods. It has been claimed, however, that the neural crest is unimportant for head development in the Australian lungfish (Neoceratodus forsteri ,), a member of the group (Dipnoi) which is commonly considered to be the living sister group of the tetrapods. In the present study, we used scanning electron microscopy to study cranial neural crest development in the Australian lungfish. Our results, contrary to those of Kemp, show that cranial neural crest cells do emerge and migrate in the Australian lungfish in the same way as in other vertebrates, forming mandibular, hyoid, and branchial streams. The major difference is in the timing of the onset of cranial neural crest migration. It is delayed in the Australian lungfish in comparison with their living sister group the Lissamphibia. Furthermore, the delay in timing between the emergence of the hyoid and branchial crest streams is very long, indicating a steeper anterior-posterior gradient than in amphibians. We are now extending our work on lungfish head development to include experimental studies (ablation of selected streams of neural crest cells) and fate mapping (using fluoresent tracer dyes such as DiI) to document the normal fate as well as the role in head patterning of the cranial neural crest in the Australian lungfish. [source]