Your search keyword '"Creuzet, Sophie"' showing total 5 results

1. A conserved role for non-neural ectoderm cells in early neural development.

Author

Cajal M, Creuzet SE, Papanayotou C, Sabéran-Djoneidi D, Chuva de Sousa Lopes SM, Zwijsen A, Collignon J, and Camus A

Subjects

Animals, Apoptosis genetics, Apoptosis physiology, Body Patterning genetics, Body Patterning physiology, Chick Embryo, Ectoderm metabolism, Female, Gene Expression Regulation, Developmental genetics, Gene Expression Regulation, Developmental physiology, Mice, Neural Crest embryology, Neural Crest metabolism, Neurogenesis genetics, Neurogenesis physiology, Pregnancy, Prosencephalon embryology, Prosencephalon metabolism, Telencephalon embryology, Telencephalon metabolism, Ectoderm embryology

Abstract

During the early steps of head development, ectodermal patterning leads to the emergence of distinct non-neural and neural progenitor cells. The induction of the preplacodal ectoderm and the neural crest depends on well-studied signalling interactions between the non-neural ectoderm fated to become epidermis and the prospective neural plate. By contrast, the involvement of the non-neural ectoderm in the morphogenetic events leading to the development and patterning of the central nervous system has been studied less extensively. Here, we show that the removal of the rostral non-neural ectoderm abutting the prospective neural plate at late gastrulation stage leads, in mouse and chick embryos, to morphological defects in forebrain and craniofacial tissues. In particular, this ablation compromises the development of the telencephalon without affecting that of the diencephalon. Further investigations of ablated mouse embryos established that signalling centres crucial for forebrain regionalization, namely the axial mesendoderm and the anterior neural ridge, form normally. Moreover, changes in cell death or cell proliferation could not explain the specific loss of telencephalic tissue. Finally, we provide evidence that the removal of rostral tissues triggers misregulation of the BMP, WNT and FGF signalling pathways that may affect telencephalon development. This study opens new perspectives on the role of the neural/non-neural interface and reveals its functional relevance across higher vertebrates., (© 2014. Published by The Company of Biologists Ltd.)

Published

2014

2. The facial neural crest controls fore- and midbrain patterning by regulating Foxg1 expression through Smad1 activity.

Author

Aguiar DP, Sghari S, and Creuzet S

Subjects

Animals, Avian Proteins genetics, Body Patterning, Cell Differentiation, Cell Movement, Chick Embryo, Face embryology, Forkhead Transcription Factors genetics, Hepatocyte Nuclear Factor 3-beta genetics, Mesencephalon physiology, Mesoderm metabolism, Mutation, Nerve Tissue Proteins metabolism, Otx Transcription Factors genetics, Prosencephalon physiology, RNA Interference, Signal Transduction, Telencephalon, Transcription Factors metabolism, Avian Proteins physiology, Forkhead Transcription Factors physiology, Gene Expression Regulation, Developmental, Mesencephalon embryology, Neural Crest metabolism, Prosencephalon embryology, Smad1 Protein metabolism

Abstract

The facial neural crest (FNC), a pluripotent embryonic structure forming craniofacial structures, controls the activity of brain organisers and stimulates cerebrum growth. To understand how the FNC conveys its trophic effect, we have studied the role of Smad1, which encodes an intracellular transducer, to which multiple signalling pathways converge, in the regulation of Foxg1. Foxg1 is a transcription factor essential for telencephalic specification, the mutation of which leads to microcephaly and mental retardation. Smad1 silencing, based on RNA interference (RNAi), was performed in pre-migratory FNC cells. Soon after electroporation of RNAi molecules, Smad1 inactivation abolished the expression of Foxg1 in the chick telencephalon, resulting in dramatic microcephaly and partial holoprosencephaly. In addition, the depletion of Foxg1 activity altered the expression Otx2 and Foxa2 in di/mesencephalic neuroepithelium. However, when mutated forms of Smad1 mediating Fgf and Wnt signalling were transfected into FNC cells, these defects were overcome. We also show that, downstream of Smad1 activity, Dkk1, a Wnt antagonist produced by the FNC, initiated the specification of the telencephalon by regulating Foxg1 activity. Additionally, the activity of Cerberus in FNC-derived mesenchyme synergised with Dkk1 to control Foxg1 expression and maintain the balance between Otx2 and Foxa2., (© 2014. Published by The Company of Biologists Ltd.)

Published

2014

3. Neural crest cell plasticity and its limits.

Author

Le Douarin NM, Creuzet S, Couly G, and Dupin E

Subjects

Animals, Body Patterning, Cell Differentiation, Chick Embryo, Cytokines physiology, Enteric Nervous System cytology, Enteric Nervous System embryology, Facial Bones embryology, Fibroblast Growth Factor 8, Fibroblast Growth Factors physiology, Genes, Homeobox, In Vitro Techniques, Neural Crest embryology, Neuronal Plasticity, Neurons cytology, Peripheral Nerves cytology, Peripheral Nerves embryology, Pluripotent Stem Cells cytology, Quail, Signal Transduction, Neural Crest cytology

Abstract

The neural crest (NC) yields pluripotent cells endowed with migratory properties. They give rise to neurons, glia, melanocytes and endocrine cells, and to diverse 'mesenchymal' derivatives. Experiments in avian embryos have revealed that the differentiation of the NC 'neural' precursors is strongly influenced by environmental cues. The reversibility of differentiated cells (such as melanocytes or glia) to a pluripotent precursor state can even be induced in vitro by a cytokine, endothelin 3. The fate of 'mesenchymal' NC precursors is strongly restricted by Hox gene expression. In this context, however, facial skeleton morphogenesis is under the control of a multistep crosstalk between the epithelia (endoderm and ectoderm) and NC cells.

Published

2004

4. Negative effect of Hox gene expression on the development of the neural crest-derived facial skeleton.

Author

Creuzet S, Couly G, Vincent C, and Le Douarin NM

Subjects

Animals, Animals, Genetically Modified, Coturnix embryology, Face embryology, Genes, Reporter, Green Fluorescent Proteins, Luminescent Proteins genetics, Morphogenesis, Brain embryology, Chick Embryo physiology, Embryo, Nonmammalian physiology, Gene Expression Regulation, Developmental, Genes, Homeobox, Homeodomain Proteins genetics, Neural Crest physiology, Skull embryology

Abstract

Diencephalic, mesencephalic and metencephalic neural crest cells are skeletogenic and derive from neural folds that do not express Hox genes. In order to examine the influence of Hox gene expression on skull morphogenesis, expression of Hoxa2, Hoxa3 and Hoxb4 in conjunction with that of the green fluorescent protein has been selectively targeted to the Hox-negative neural folds of the avian embryo prior to the onset of crest cell emigration. Hoxa2 expression precludes the development of the entire facial skeleton. Transgenic Hoxa2 embryos such as those from which the Hox-negative domain of the cephalic neural crest has been removed have no upper or lower jaws and no frontonasal structures. Embryos subjected to the forced expression of Hoxa3 and Hoxb4 show severe defects in the facial skeleton but not a complete absence of facial cartilage. Hoxa3 prevents the formation of the skeleton derived from the first branchial arch, but allows the development (albeit reduced) of the nasal septum. Hoxb4, by contrast, hampers the formation of the nasal bud-derived skeleton, while allowing that of a proximal (but not distal) segment of the lower jaw. The combined effect of Hoxa3 and Hoxb4 prevents the formation of facial skeletal structures, comparable with Hoxa2. None of these genes impairs the formation of neural derivatives of the crest. These results suggest that over the course of evolution, the absence of Hox gene expression in the anterior part of the chordate embryo was crucial in the vertebrate phylum for the development of a face, jaws and brain case, and, hence, also for that of the forebrain.

Published

2002

5. Interactions between Hox-negative cephalic neural crest cells and the foregut endoderm in patterning the facial skeleton in the vertebrate head.

Author

Couly G, Creuzet S, Bennaceur S, Vincent C, and Le Douarin NM

Subjects

Animals, Chick Embryo, Chickens, Coturnix, Digestive System cytology, Endoderm cytology, Neural Crest cytology, Vertebrates, Body Patterning physiology, Digestive System embryology, Endoderm physiology, Facial Bones embryology, Genes, Homeobox physiology, Neural Crest embryology

Abstract

The vertebrate face contains bones that differentiate from mesenchymal cells of neural crest origin, which colonize the median nasofrontal bud and the first branchial arches. The patterning of individual facial bones and their relative positions occurs through mechanisms that remained elusive. During the early stages of head morphogenesis, an endodermal cul-de-sac, destined to become Sessel's pouch, underlies the nasofrontal bud. Reiterative outpocketings of the foregut then form the branchial pouches. We have tested the capacity of endoderm of the avian neurula to specify the facial skeleton by performing ablations or grafts of defined endodermal regions. Neural crest cells that do not express Hox genes respond to patterning cues produced regionally in the anterior endoderm to yield distinct skeletal components of the upper face and jaws. However, Hox-expressing neural crest cells do not respond to these cues. Bone orientation is likewise dependent on the position of the endoderm relative to the embryonic axes. Our findings thus indicate that the endoderm instructs neural crest cells as to the size, shape and position of all the facial skeletal elements, whether they are cartilage or membrane bones.

Published

2002