Global ETD Search

11	Elucidating the pathomechanism behind the neurocristopathy CHARGE syndrome Freese, Luisa 26 June 2017 (has links) No description available. 610 CHARGE syndrome CHD7 neurocristopathy neural crest cells semaphorins SEMA3A Kallmann syndrome Medizin (PPN619874732) Humangenetik (PPN619875267)
12	In vivo regeneration of rat laryngeal cartilage with mesenchymal stem cells derived from human induced pluripotent stem cells via neural crest cells / 神経堤細胞を介して誘導したヒトiPS細胞由来間葉系幹細胞を用いたラット喉頭軟骨再生 Yoshimatsu, Masayoshi 26 July 2021 (has links) 京都大学 / 新制・課程博士 / 博士(医学) / 甲第23417号 / 医博第4762号 / 新制\|\|医\|\|1052(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授松田秀一特定拠点, 教授妻木範行, 教授安達泰治 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM iPS cells regeneration laryngotracheal cartilage mesenchymal stem cells neural crest cells hyaline cartilage 490
13	The effect of all-trans retinoic acid on the migration of avian neural crest cells in vitro an in vivo Tshabalala, Vincent Abie Thabiso 15 February 2007 (has links) Student Number : 9502128Y - MSc dissertation - School of Anatomical Sciences - Faculty of Science / Retinoic acid, the active metabolite of Vitamin A is known to play a major role in embryonic growth and differentiation during development. It has been shown that either excess or deficiency of retinoic acid during embryogenesis can be teratogenic. In order to study the teratogenic effects of retinoic acid, the aim of the present study was therefore to investigate the effect of all-trans retinoic acid on the migration and fate of neural crest cells in vitro and in vivo. In addition, the study investigated the effect of retinoic acid on the cytoskeletal elements of neural crest cells and on Rac and Rho, two members of the Rho family of GTPases. The neural tubes containing neural crest cells of quail embryos were removed at cranial levels and cultured on fibronectin as a substrate. The neural tubes were cultured in either Dulbecco’s minimal essential medium (DMEM) or in DMEM+Dimethylsulphoxide (DMSO) as controls. In order to test the effect of retinoic acid, the neural tubes were cultured in 10-5M all-trans retinoic acid (RA) which was reconstituted in DMSO. The distance of migration of the cultured quail neural crest cells was measured and compared between the controls and the experimentals. To study the effect of RA on the cell actin cytoskeleton in vitro, cultured neural crest cells were stained with rhodamine phalloidin. In addition, following 24 hours of culture, the quail neural crest cells were brought into suspension and micro-injected into 36 hour-old chick hosts. While the migration of neural crest cells was extensive in the control cultures in vitro, migration was inhibited in the retinoic acid-treated neural crest cells. In addition, retinoic-acid treated neural crest cells showed pigmentation and neuronal processes earlier than did the control neural crest cells. Retinoic acid-treated neural crest cells showed a disarray of the cytoskeletal elements as they were devoid of stress fibres and focal adhesions. In addition, retinoic acid appears to decrease the expression of Rac and Rho of cultured quail neural crest cells. Following micro-injection of cultured control and RA-treated quail neural crest into the cranial region of chick hosts, the control cells populated the beak area, whereas the retinoic acid-treated quail neural crest cells migrated to the retina of the eye, a region they normally do not populate. These results suggest that retinoic acid disturbs the migration of neural crest cells. It appears to do this by affecting the cytoskeletal elements of neural crest cells and the genes that are involved in forming these elements. Retinoic acid embryonic growth embryogenesis teratogenic effects neural crest cells in vitro in vivo cytoskeletal elements
14	Études des interactions fonctionnelles entre l'endothéline-3, les intégrines beta1 et les propriétés élastiques du tissu embryonnaire au cours du développement du système nerveux entérique / Functional interactions between endotheline-3, beta1 integrines and the elastic properties of the embryonic gut tissu during enteric nervous system development Gazquez, Elodie 21 September 2016 (has links) Le système nerveux entérique (SNE) provient des cellules de crête neurale entériques (CCNEs) qui migrent au sein de l'intestin embryonnaire, prolifèrent et se différencient en cellules gliales et neurones formant des ganglions interconnectés. Mon projet de thèse vise à comprendre comment les propriétés biochimiques et mécaniques de l'intestin embryonnaire influencent la colonisation et la différenciation des ccnes. L'absence d'endothéline-3 (EDN3), un facteur biochimique exprimé dans la paroi intestinale, est une des causes de la maladie de hirschsprung, caracterisée par une aganglionose du côlon distal. Nous montrons pour la première fois que l'EDN3 stimule l'adhésivité des CCNEs en augmentant leurs adhérences focales dépendantes des intégrines beta1 ainsi que la dynamique de leurs protrusions membranaires. De plus, nous avons mis en évidence l'existence d'une interaction génétique entre Edn3 et Itgb1 gouvernant le développement du SNE. Par ailleurs, les propriétés mécaniques du microenvironnement influençant la migration et la différenciation cellulaire , nous avons analysé par des approches biophysiques les propriétés élastiques de l'intestin embryonnaire et leurs impacts sur les comportements des ccnes. Nous avons montré que l'intestin embryonnaire se rigidifie au cours de son developpement et que la migration en 3D des CCNEs est inhibée lorsque la rigidité de l'environnement dépasse un certain seuil. Enfin, nous avons démarré l'analyse de l'effet de l'élasticité sur la différenciation des progéniteurs entériques. L'ensemble de nos résultats permettent de mieux comprendre les mécanismes contrôlant le développement du SNE. / The enteric nervous system (ENS) is derived from enteric neural crest cells (ENCC) that migrate along the length of the intestine through the gut mesenchyme. During this process, ENCC proliferate and differentiate into glial cells and neurons, which aggregate into ganglia. The aim of my thesis is to study how biochemical and mechanical properties of the gut tissue influence ENCC colonization and fate during embryogenesis. The absence of endothelin-3 (EDN3), a small peptide trapped in the embryonic gut mesenchyme, is one of the causes leading to hirschsprung disease, characterized by an aganglionosis of the distal colon. We highlighted for the first time that EDN3 increases ENCC adhesion properties throught 1-integrins focal adhesions and modulates their protrusion dynamics. Moreover, we evidenced a genetic interaction between Edn3 and Itgb1 during ENS development. Also, it is now well established that mechanical properties of the microenvironment influence fundamental mechanisms such as cell migration and cell fate determination. Thus, we analysed whether the mechanical properties of the ENCC’s environment influence their behaviours. Using biophysical approaches, we evidenced a physiological stiffening of the embryonic gut during its development and showed that ENCC migration in 3D is inhibited above a certain rigidity threshold. Finally, we begun to analyse the influence of the elastic properties of the environment onto enteric progenitor cells differenciation, taking advantage of the neurosphere culture system. All together, our results contribute to the understanding of the molecular and cellular mechanisms driving physiological and pathological ENS ontogenesis. Cellules de crêtes neurales entérique Endotheline-3 Integrine beta1 Migration Biomécanique Élasticité tissulaire Neural crest cells Migration Enteric nervous system 571.6
15	Role transkripčních faktorů Meis v embryonálním vývoji zebřičky Danio rerio / Role of transcription factors Meis during embryogenesis Danio rerio Brežinová, Veronika January 2020 (has links) Meis transcription factors belong to the group of TALE (three amino acids loop extension) homeodomain proteins. Meis2 proteins have a potential role in regulation of neural crest cells development and in differentiation of their derivates. Zebrafish genome has two paralogues of meis2 gene, meis2a and meis2b. CRISPR/Cas9 technology was used to prepare mutant lines of both paralogues, meis2a and meis2b, for the purpose of study of function of Meis2 transcription factors. Specific morpholinos that reduce the expression of meis2a and meis2b were used as controls. Craniofacial and cardiac development in mutant fish was analyzed in the meis2a line by RNA in situ hybridization, histological cartilage staining, and computed tomography. While we observed impaired craniofacial and cardiac development after injection of specific Morpholinos, we did not detect similar changes in the meis2a KO line. Our genetic approach has not clearly shown that the meis2a paralogue itself plays an important role in craniofacial development and cardiac development. For more detailed analysis, further experiments on fish lines with combined meis2a and meis2b knock-outs are needed. Key words Mutagenesis CRISPR, Danio rerio, neural crest cells, Meis2, transcription factor
16	ANTERIOR SEGMENT DYSGENESIS AND GLAUCOMATOUS FEATURES OBSERVED FOLLOWING CONDITIONAL DELETION OF AP-2β IN THE NEURAL CREST CELL POPULATION / AP-2β IN THE DEVELOPMENT OF THE ANTERIOR SEGMENT OF THE EYE Martino, Vanessa 20 November 2015 (has links) Glaucoma is a heterogeneous group of diseases that is currently considered to be the leading cause of irreversible blindness worldwide. Of the identified risk factors, elevated intraocular pressure remains the only modifiable risk factor that can be targeted clinically. Ocular hypertension is often a result of dysregulation of aqueous humour fluid dynamics in the anterior eye segment. Aqueous humour drainage is regulated by structures located in the anterior chamber of the eye. In some circumstances dysregulation occurs due to developmental abnormalities of these structures. The malformation of structures in the anterior segment is thought to be due to a defect in the differentiation and/or migration of the periocular mesenchyme during development. Unique to vertebrates, the neural crest cell (NCC) population contributes to the periocular mesenchyme and is instrumental to the proper development of structures in the anterior segment. For many years our laboratory has examined the role of the Activating Protein-2 (AP-2) transcription factors that are expressed in the neural crest and vital during the development of the eye. The purpose of this research project is to investigate the role of AP-2β in the NCC population during the development of the anterior segment of the eye. Conditional deletion of AP-2β expression in the NCC population demonstrated that mutants have dysgenesis of structures in the anterior segment including defects of the corneal endothelium, corneal stroma, ciliary body and a closed iridocorneal angle. Loss of retinal ganglion cells and their axons was also observed, likely due to the disruption of aqueous outflow, suggesting the development of glaucoma. The data generated from this research project will be critical in elucidating the role of AP-2β in the genetic cascade dictating the development of the anterior eye segment in addition to providing scientific research with a novel model of glaucomatous optic neuropathy. / Thesis / Master of Science (MSc) Eye Development Glaucoma Transcription Factors AP-2B Anterior Segment Dysgenesis Conditional Deletion Mouse Model Cre LoxP Neural Crest Cells
17	The origin and early development of the intrinsic innervation in the foetal mouse lung Tollet, Cecilia Jenny January 2003 (has links) In this study, the origin and development of the intrinsic innervation in the foetal mouse lung is described and experimental evidence is provided to support the involvement of glial cell line-derived neurotrophic factor (GDNF) in the guidance of nerves and neuronal precursors in the developing lung. Antibodies were used to stain for neuronal precursors, neurones, nerve fibres, primordial epithelium and smooth muscle. These structures were revealed in whole mounts of foetal mouse lungs by immunofluorescence and confocal microscopy, and their spatial and temporal distribution was mapped from the onset of lung development and through the pseudoglandular period. The results showed that neuronal precursors, positive for neural crest cell markers, were present in the vagal tract of the foregut at embryonic day 10 (E10), the time of the evagination of the lung buds. These neural crest-derived cells (NCC) migrated into the lung at E11, along nerve processes directed from the vagus to the smooth musclecovered trachea and emerging lobar bronchi. During E11-E14, a network of nerves and ganglia became established along the dorsal trachea, and large ganglia formed a plexus at the ventral hilum. Nerve trunks issued from these ganglia, travelled along the smooth muscle-covered bronchi, providing a pathway for migrating NCC. To investigate the role of GDNF in the innervation of the lung, an in vitro model of left lung lobes was established. Lung growth and tubule branching was comparable to that in vivo, and neural tissue and smooth muscle continued to grow and thrive. A significant increase in nerve growth occurred when explants were cultured with GDNF compared to controls. Nerves extended, and NCC migrated towards GDNF-impregnated beads suggesting that GDNF may be the molecule guiding nerve fibres and NCC in the lung. The migrating NCC were negative for GDNF-family receptor α1 (GFRα1) during their migration into the lung while the nerves were positive. Since GDNF needs to be associated with its binding receptor, GFRα1, for cellular signalling, GDNF may induce the migration of the NCC if they migrate along the GFRα1-positive nerve fibres. It is concluded that neural tissue and smooth muscle become integral components of the lung shortly after the onset of lung development. The results show that the migration of neural crest-derived cells into the lung and the establishment of the innervation requires coordinated cross-talk between NCC, nerves and smooth muscle throughout development. Lungs -- Innervation Fetal nerve tissue Mice -- Nervous system Confocal microscopy Organ culture Lung development Foetal mouse Neural crest cells Neural development Airway smooth muscle GDNF
18	Analyse du rôle de la paire de gènes A830082K12Rik/Nr2f1 dans la gliogenèse du système nerveux entérique Charrier, Baptiste 01 1900 (has links) No description available. Système nerveux entérique Cellules de la crête neurale Gliogenèse lncRNA Enteric Nervous System Neural Crest Cells Gliogenesis
19	OPTICAL IMAGING OF EMBRYONIC CARDIAC CONDUCTION Ma, Pei 13 September 2016 (has links) No description available. Biomedical Engineering
20	Genetische Analyse entwicklungsbiologischer Funktionen des Neuregulin-1/ErbB Signalsystems Britsch, Stefan 10 November 2004 (has links) Neureguline (NDF, Heregulin, GGF ARIA, oder SMDF) sind EGF-ähnliche, extrazelluläre Signalmoleküle, die mit transmembranären Tyrosinkinaserezeptoren der ErbB-Familie interagieren. Neuregulin-1/ErbB Signale steuern während der Embryonalentwicklung und im adulten Organismus vielfältige zelluläre Prozesse, wie z. B. Proliferation, Migration und Differenzierung. In der vorliegenden Arbeit wurde die Rolle des Neuregulin-1/ErbB Signalsystems in der Entwicklung von Neuralleistenzellen und sich daraus entwickelnden Komponenten des peripheren Nervensystems (sympathisches Nervensystem und periphere Glia) untersucht. Neuregulin-1 Signale werden in Neuralleistenzellen und ihren Gliaderivaten durch ErbB2/ErbB3 Rezeptor-Heterodimere übertragen. Mit Hilfe von Mäusen mit gezielter Mutation (knock-out) des Neuregulin-1, ErbB2 oder ErbB3 Gens wurde gezeigt, daß Neuregulin-1/ErbB2/3 Signale die Migration sympathogener Neuralleistenzellen steuern. Mutante Tiere entwickeln daher eine hochgradige Hypoplasie des sympathischen Nervensystems. Neuregulin-1 Signale kontrollieren darüber hinaus die Entwicklung von Schwann Zellen. Die Unterbrechung des Neuregulin-1/ErbB2/3 Signalwegs in mutanten Mäusen führt zum Verlust von Schwann Zellen während der Embryogenese. Es wurde außerdem gezeigt, daß der Transkriptionsfaktor Sox10 die Expression von ErbB3 in Neuralleistenzellen kontrolliert. Sox10 und ErbB3 Mutanten besitzen daher übereinstimmende Defekte in der Neuralleistenzellentwicklung. Neben den ErbB3-abhängigen Funktionen von Sox10 wurde eine ErbB3-unabhängige Schlüsselfunktion von Sox10 bei der Differenzierung von Neuralleistenzellen zu peripherer Glia identifiziert. Das Neuregulin-1/ErbB2/3 Signalsystem und der Transkriptionsfaktor Sox10 besitzen also gemeinsam zentrale Funktionen in der Entwicklung peripherer Glia, steuern diesen Prozess aber über unterschiedliche Mechanismen und während unterschiedlicher Entwicklungsphasen. Sox10, ErbB2 und ErbB3 mutante Mäuse entwickeln neben dem Verlust von Schwann Zellen eine sekundäre Degeneration begleitender sensorischer und motorischer Neurone. Dies zeigt, daß periphere Glia Signale generiert, die essentiell sind für Integrität und Überleben begleitender Neurone. / Neuregulins (NDF, heregulin, GGF ARIA, or SMDF) are EGF-like growth and differentiation factors that signal through tyrosine kinase receptors of the erbB family. The neuregulin-1 proteins and their receptors play essential roles during embryonic development and in the adult. Functions of the neuregulin/erbB signaling system in developing neural crest cells and their derivatives (sympathetic nervous system, peripheral glial cells) were analyzed in mice with targeted mutations in the erbB2, erbB3, or neuregulin-1 genes. All three mutations cause severe hypoplasia of the primary sympathetic ganglion chain, and migration of sympathogenic neural crest cells to their target sites, where they differentiate into sympathetic neurons, depends on neuregulin-1 and its receptors. Neuregulin-1 signals are also essential for the development of Schwann cells. As a consequence, mice with targeted mutations in the neuregulin-1/erbB signaling system completely lack Schwann cells. Moreover, the HMG-box transcription factor sox10 is shown to control expression of erbB3 in neural crest cells. In accordance, sox10 and erbB3 mutant mice share phenotypes in the developing neural crest. Additionally, a novel, erbB3-independent developmental function of sox10 was identified: Sox10 is a key regulator for glial fate determination in undifferentiated neural crest cells. Thus, the transcription factor sox10 and the neuregulin-1/erbB signalling system both serve critical functions during development of peripheral glial cells. However, they act via different cellular mechanisms and during different developmental stages. At later developmental stages lack of peripheral glial cells in sox10, erbB2 and erbB3 mutant mice results in a severe degeneration of sensory and motor neurons. The comparison of the mutant phenotypes demonstrates, that peripheral glial cells generate essential signals for the survival and maintenance of accompanying neurons. Neuregulin ErbB Tyrosinkinaserezeptor Sox10 Neuralleistenzellen Gliazellen Migration Peripheres Nervensystem Entwicklung Neuregulin erbB tyrosine kinase receptor sox10 neural crest cells glial cells migration peripheral nervous system development 610 Medizin 33 Medizin WC 6570 YG 3604 WW 4120 ddc:610

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