Littérature scientifique sur le sujet « Crête neurale – métabolisme »
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Articles de revues sur le sujet "Crête neurale – métabolisme"
de La Dure-Molla, Muriel, Céline Gaucher, Nicolas Dupré, Agnès Bloch Zupan, Ariane Berdal et Catherine Chaussain. « La dent : un marqueur d’anomalies génétiques du développement ». médecine/sciences 40, no 1 (janvier 2024) : 16–23. http://dx.doi.org/10.1051/medsci/2023190.
Texte intégralThèses sur le sujet "Crête neurale – métabolisme"
Nekooie, Marnany Nioosha. « The Intersection of Metabolism and Neural Crest Cell Development ». Electronic Thesis or Diss., Paris 12, 2022. http://www.theses.fr/2022PA120066.
Texte intégralMetabolism as a keystone of stem cells' fate not only supplies demands for energy and precursor molecules but also has roles in chromatin remodeling. In vertebrate embryos, neural crest (NC) cells constitute a remarkable population of embryonic progenitors, which upon delamination from dorsal neural tube, extensive migration and differentiation give rise to both neural/neuronal and mesenchymal derivatives. The developmental potential of NC cells necessitates epigenetic remodeling and environmental cues. Accordingly, the intersection of metabolism and NC plasticity will provide critical insights into the regulation of NC cell identity and development. Thus, I intended to figure out the metabolism role in the developmental aspect of one sub-population of NC cells, trunk type. The first part of my study resulted in a general view of the metabolic impacts on all developmental NC steps. I evidenced that glucose oxidation is a pivotalmetabolic profile governing NC delamination, adhesion, migration, proliferation, maintenance of stemness, and widespread differentiation. Given the incidence of G1/S transition upon EMT in trunk NC cells, the inhibition of pentose phosphate pathway (PPP) was unable to influence the NC delamination, suggesting a metabolic adaptation to maintain developmental steps and survival. Hence, In the next step, I sought to appreciate how metabolic pathways integrate into the NC delamination. The rewiring of glycolysis pathway under PPP suppression in delaminating stage provided support for multi metabolic pathways recruited by NC progenitors in response to the metabolic stress. My study also elucidated the metabolic reprograming from PPP to glucose oxidation in trunk NC cells, aligned with delaminating to migratory transition of these cells. Additionally, besides glucose, glutamine had a prominent role in pluripotent acquisition anddelamination of NC progenitors that triggers the nuclear localization of glutaminase (GLS) upon EMT step. Therefore, the nuclear GLS localization of pre-migratory NC cells in delaminating stage suggests the gene regulatory function for GLS. Altogether, my results indicated the intersection of metabolism and NC reprograming from pluripotent step to the NC commitment, defined respectively by promoted PPP and nuclear localization of GLS to glucose-based OXPHOSphenotype with cytoplasmic GLS localization. Moreover, the possible interaction between GLS and B-catenin fostered the new concept about the contribution of GLS to Wnt signaling, holding promise for understanding the etiology of many neurocristopathies
Pegoraro, Caterina. « Finding novel Neural Crest regulators : Pfkfb4, a key glycolysis partner, controls Neural Crest early patterning in Xenopus laevis ». Thesis, Paris 11, 2012. http://www.theses.fr/2012PA112374.
Texte intégralNeural Crest (NC) is a transient population of multipotent cells that arises at the border between neural and non-neural ectoderm, in a region named the neural border (NB). As the neural border elevates to form the neural tube, NC cells undergo an Epithelial-To-Mesenchymal Transition (EMT), migrate extensively into the whole body to reach their final destinations and differentiate. They give rise to multiple derivatives: neurons and glia, head cartilage, bones and connective tissue, pigment cells, sympatho-adrenal cells. All these processes are regulated by the concerted actions of several genes that form a complex Gene Regulatory Network (GRN), in which many interactions have been elucidated, but even more relationships still need to be understood. Misregulation of genes normally involved in NC formation causes birth defects called neurocristopathies. Moreover, the EMT that NC cells undergo before migration also takes place when cancer cells become metastatic: the molecular events and many of the genes involved in EMT and migration are shared between NC development and cancer. The links with metastasis, neurocristopathies and the fact that still little is known about the earliest steps of NC formation, highlight the importance and the interest in understanding the Gene Regulatory Network (GRN) leading to NC formation and EMT.In the laboratory, we are interested in the early steps of NC induction and specification. In order to identify genes preferentially involved in early NC development compared to genes involved in neural and non-neural ectoderm formation, a transcriptome screen on different microdissected embryonic tissues has been performed. The validation of the results of the screen revealed several interesting genes with a potential function in NC formation. We focused particularly on two of them, due to their original function compared to the majority of the genes involved in NC development: serca1 and pfkfb4, a calcium homeostasis regulator and a glycolysis regulator respectively. We analysed the expression patterns of serca and pfkfb family genes during Xenopus laevis development. Then, due to its specific expression in NC, we studied more in details the role of pfkfb4 in NC formation. This analysis revealed that pfkfb4 is necessary for neural and neural crest specification. However, despite its known role in glycolysis, pfkfb4 morphant phenotype in Xenopus laevis embryos is not due to an alteration of the glycolytic pathway.In conclusion, our results reveal a novel extra-glycolytic role for Pfkfb4 during Xenopus laevis embryonic development
Borges, Figueiredo Ana Leonor. « Control of cell specification and migration during early frog development by PFKFB4, a key glycolysis regulator ». Thesis, Paris 11, 2015. http://www.theses.fr/2015PA112107.
Texte intégralEmbryonic ectoderm becomes specified into non-neural ectoderm, neural plate and neural border at the end of gastrulation. Neural border cells are the progenitors of the neural crest and placodes. The neural crest is a transient population of multipotent cells, which forms during neurulation. As the neural border elevates to form the neural tube, neural crest cells undergo an epithelial to mesenchymal transition, migrate extensively into the whole body to reach their final destinations and differentiate. Neural crest gives rise to multiple derivatives such as neurons and glia, facial cartilage, bones, melanocytes and sympatho-adrenal cells. A complex interplay of signaling and transcriptional regulations orchestrates these early patterning events. However, the first steps leading to NC formation and early specification at the NB are less understood. We analysed the NC transcriptome of frog embryos, to look for novel regulators of the early steps of NC formation. We found that the well-known glycolysis regulator PFKFB4, is expressed in early gastrula dorsal ectoderm, and in neurula neural crest cells. Here, we demonstrate that PFKFB4 regulates ectoderm specification via Akt signaling independently of glycolysis, thus demonstrating the first non-glycolytic function of PFKFB enzymes. Moreover, this regulation is essential to allow ectoderm embryonic progenitors to be patterned into neural plate, neural crest, placodes and definitive ectoderm, highlighting a novel developmental checkpoint. Moreover, we also demonstrate that PFKFB4 regulates later steps of neural crest formation. Our work highlights that regulators of cell metabolism accumulate non-metabolic related functions to control developmental steps during embryonic development
Leroux-Berger, Margot. « Différenciation des cellules de crêtes neurales céphaliques et maintien de leurs dérivés : de l'embryon à la pathologie adulte ». Paris 6, 2010. http://www.theses.fr/2010PA066206.
Texte intégralRadu, Anca Gabriela. « Nouvelles régulations métaboliques exercées par la signalisation LKB1 dans les cellules polarisées : conséquences pour l’ontogénie tissulaire ». Thesis, Université Grenoble Alpes (ComUE), 2018. http://www.theses.fr/2018GREAV011/document.
Texte intégralThe tumor suppressor LKB1 codes for a serine/threonine kinase. It acts as a key regulator of cell polarity and energy metabolism partly through the activation of the AMP-activated protein kinase (AMPK), a sensor that adapts energy supply to the nutrient demands of cells facing situations of metabolic stress. To achieve metabolic adaptations, AMPK phosphorylates numerous substrates which inhibit anabolic processes while activating catabolic reactions. In particular, AMPK inhibits the mammalian target of rapamycin (mTOR).During my PhD, based on genetically engineered mouse models, I uncovered that Lkb1 signaling is essential for neural crest cells (NCC) formation. NCC are multipotent cells that originate from the neural tube and give rise to various derivatives including bones and cartilage of the face, pigmented cells in the skin and glial and neural cells in peripheral nerves and the enteric nervous system. I demonstrated that Lkb1 is essential for vertebrate head formation and for the differentiation and maintenance of NCC-derivatives in the peripheral nervous system. I also emphasized that LKB1 is acetylated on lysine 48 by the acetyltransferase GCN5 and that this acetylation could regulates cranial NCC ontogeny and head formation. Furthermore, I discovered that Lkb1 controls NCC-derived glial differentiation through metabolic regulations involving amino acid biosynthesis coupled to pyruvate-alanine cycling upstream of mTOR signaling.Phenotypes due to Lkb1 loss in NCC recapitulate clinical features of human disorders called neurocristopathies and therefore suggest that aberrant Lkb1 metabolic signaling underlies the etiology of these pathologies. Abnormal activation of the tumor suppressor p53 has been described in some NCC disorders and p53 inactivation in neurocristopathy mouse models rescues the pathological phenotype. By using a NCC line that can be cultivated as progenitors or differentiated in glial cells in vitro, I demonstrated that Lkb1 expression in NCC-derivatives controls p53 activation by limiting oxidative DNA damage and prevents the formation of lysosomes filled with oxidized proteins and lipids called lipofuscin granules. Interestingly, activation of mTOR and LKB1/AMPK pathways is governed by amino acid sensors and takes place at the lysosome surface. Lysosomes have been proposed as a signaling hub controlling proteolysis and aging. Thus Lkb1 and p53 signaling could converge especially through lysosome homeostasis thereby potentially impacting cellular aging.Strikingly, Sertoli cells, that are epithelial somatic cells, located in seminiferous tubules in testes, and which govern germ cells maturation and whole testis homeostasis, share similar metabolic functions with glial cells. For example, they secrete lactate and alanine to fuel mitochondria of neighboring cells (germ cells or neurons respectively) to control their survival and maturation. During my PhD, we highlighted that Lkb1 is essential for testis homeostasis and spermatogenesis by regulating Sertoli cell polarity and, as observed in glial cells, energy metabolism through pyruvate-alanine cycling. These data suggest that this particular Lkb1 metabolic regulation is conserved in tissues with similar function.Taken together, these studies reveal the underlying molecular mechanisms that coordinately regulate energy metabolism and cell fate. They provide new insights into NCC development and expand our understanding of the role of LKB1 as an energy metabolic regulator. Finally, my PhD projects uncover the existence of a crosstalk between Lkb1 and p53 and underline its importance in NCC disorders