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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Role of Protocadherins in Zebrafish Neural Development

Biswas, Sayantanee 20 December 2012 (has links)
No description available.
2

Protocadherin-17 Function in Zebrafish Retina Development

Chen, Yun 11 December 2012 (has links)
No description available.
3

Gamma-protocadherin Cis- and Trans-interactions regulate the development of dendrite arbors and synapses in the cerebral cortex

Molumby, Michael Jacob 01 August 2017 (has links)
The alpha-, beta-, and gamma-Protocadherins (gamma-Pcdhs) are cadherin superfamily adhesion molecules encoded by clustered gene families. The 22 gamma-Pcdhs are combinatorially expressed in the central nervous system (CNS) by neurons and astrocytes, and play critical roles in synaptogenesis, dendrite arborization, and the survival of subsets of neurons. The gamma-Pcdhs promiscuously form cis-multimers that interact strictly homophilically in trans (Molumby et al., 2016; Schreiner and Weiner, 2010); the alpha- and beta-Pcdhs were subsequently shown to interact in a similar homophilic manner (Rubinstein et al., 2015; Thu et al., 2014). The Pcdh gene clusters thus have the potential to generate millions of distinct adhesive interfaces, providing CNS cells with molecular identities that shape neuronal morphology. We demonstrated previously that, in mice lacking the gamma-Pcdhs in the cerebral cortex, pyramidal neurons exhibit severely reduced dendrite arborization (Garrett et al., 2012a). This, combined with many studies of gamma-Pcdh interactions in vitro, suggests that homophilic, adhesive gamma-Pcdh interactions between neurons, and between neurons and glia, provide a positive signal for dendrite growth. However, in retinal starburst amacrine cells and cerebellar Purkinje cells, loss of the gamma-Pcdhs resulted in aberrant dendrite fasciculation and self-crossing (Lefebvre et al., 2012), suggesting that these molecules can mediate repulsive self-avoidance between a neuron’s own dendrites. In Chapter I of this thesis I utilized transgenic mice to manipulate expression in vivo, to show that the complexity of a cortical neuron’s dendritic arbor is determined by homophilic gamma-Pcdh isoform matching with other cells. Expression of the same single isoform in a neuron can result in either exuberant, or minimal, dendrite complexity depending on whether surrounding cells express the same isoform. Additionally, loss of gamma-Pcdh in astrocytes, or induced astrocyte-neuron mis-matching, reduces dendrite complexity cell non-autonomously. This indicates a neuron’s pattern of connectivity is indeed regulated by specific interactions between cells that are distinct from the repulsive self-avoidance seen in isoneuronal processes of planar cell types. In addition to modulating dendrite branch development, the gamma-Pcdhs have been shown to regulate the progression of spinal cord synaptogenesis (Garrett and Weiner, 2009). A role for these molecules in cortical dendritic spines and synapses, however, had yet not been examined. In Chapter II of this thesis, I provide evidence that the gamma-Pcdhs negatively regulate synapse formation and spine morphogenesis in forebrain neurons. Mice lacking all gamma-Pcdhs in the cortex exhibit significantly increased spine and synapse density in vivo, while spine density is significantly decreased in mice overexpressing one of the 22 gamma-Pcdh isoforms. To explain this functional result, we present in vitro evidence to show that gamma-Pcdhs physically and functionally interact with the synaptic cell adhesion molecule neuroligin-1. This work suggests a potential new mechanism by which gamma-Pcdhs regulate the “choice” between dendrite arbor growth and formation and/or stabilization of dendritic spines and synapses in the developing brain. Given that disruptions in the pattern and density of dendritic arbors and spines are a hallmark of neurodevelopmental disorders such as autism and Down, Rett, and fragile X syndromes, my work may provide the basic science foundation for future therapeutic approaches focused on Pcdhs and their associated signaling pathways.
4

PCNS: A novel protocadherin involved during convergent extension movements,cranial neural crest migration and somite morphogenesis in Xenopus

Rangarajan, Janaki 02 August 2007 (has links)
No description available.
5

Towards Understanding the Cell Adhesion Mediated by Non-clustered Non-classical Protocadherins

Gray, Michelle Elizabeth 09 September 2021 (has links)
No description available.
6

Adhesion and Mechanics in the Cadherin Superfamily of Proteins

Neel, Brandon Lowell January 2021 (has links)
No description available.
7

The auditory mechano-electrical transduction machinery : components and interactions / La machinerie de la transduction mécano-électrique auditive : composants et interactions

Pepermans, Elise 25 September 2014 (has links)
La (Pcdh15) est localisée dans les touffes ciliaires des cellules ciliées internes et externes de la cochlée. Elle forme des liens interstéréociliaires entre les différents stéréocils, des protrusions riches en actine qui forment ensemble la touffe ciliaire. L’absence de Pcdh15 entraîne la désorganisation des touffes ciliaires et la perte de la mécanotransduction auditive. Pcdh15 forme en effet la partie basse du lien de bout de cil (en anglais tip-link), le lien contrôlant l’ouverture du canal de transduction, qui se situe au point d’insertion inferieur de ce lien. Il existe trois isoformes de Pcdh15 (CD1, CD2 et CD3). J’ai étudié la distribution de ces isoformes dans la touffe ciliaire à différents stades de sa maturation. Différents modèles murins « KO conditionnel » ont été générés, ils m’ont permis d’analyser les conséquences de l’absence de chacune des isoformes individuellement, ainsi que celles de l’absence de Pcdh15-CD2 et Pcdh15-CD3, et celles de l’absence simultanée des trois isoformes. J’ai ainsi pu conclure que Pcdh15-CD2 est la seule isoforme essentielle pour la formation des tip-links dans les cellules ciliées matures. Dans les touffes ciliaires matures, Pcdh15 joue également un rôle dans l’interaction entre les touffes ciliaires et la membrane tectoriale, dans le contrôle de la taille des stéréocils, et dans la formation des liens interstéréociliaires apicaux. Pour ces fonctions, mais pas pour la formation du tip-link, Pcdh15-CD1 et Pcdh15-CD2 (les isoformes présentes dans la touffe ciliaire mature) sont redondantes. Cependant, Pcdh15-CD1 ne peut compenser que partiellement l’absence de Pcdh15-CD2 et Pcdh15-CD3. Pour étudier comment Pcdh15 interagit avec les autres protéines impliquées dans le syndrome de Usher, les interactions avec l’harmonine et la whirline (deux protéines d’échafaudage qui sont colocalisées avec Pcdh15 à l’apex des stéréocils) ont été analysées in vitro. / Protocadherin-15 (Pcdh15 is located in the stereociliary hair bundles of inner and outer hair cells (IHCs and OHCs) of the cochlea, where it forms fibrous links between different stereocilia. Absence of Pcdh15 leads to deafness due to the disorganization of hair bundles and absence of mechano-electrical transduction. The latter is explained as Pcdh15 forms the lower component of the tip-link, that gate hair cell mechano-electrical transduction channels. There are three different splice isoforms of Pcdh15 (CD1, CD2 and CD3), I studied their distribution in the developing and mature auditory hair cells. Different conditional Pcdh15 knockout mouse models were generated, permitting analysis of the absence of each of the different Pcdh15 isoforms individually, of the combined absence of Pcdh15-CD2 and Pcdh15-CD3, and of the absence of all isoforms. I was able to conclude that Pcdh15-CD2 is essential for the formation of tip-links in mature hair cells. In mature hair bundles Pcdh15 also plays a role in the coupling of the hair bundles to the tectorial membrane, in the control of the size of the stereocilia, and in the formation of apical links between stereocilia. The different Pcdh15 isoforms present in mature hair bundles (Pcdh15-CD1 and Pcdh15-CD2) are functionally redundant for these functions, but not for tip-link formation. In immature hair bundles, the different Pcdh15 isoforms are functionally redundant, although Pcdh15-CD1 can only partially compensate the absence of Pcdh15-CD2 and Pcdh15-CD3. To discover how Pcdh15 interacts with other proteins implicated in Usher syndrome, interactions with harmonin and whirlin were analyzed by biophysical techniques.
8

Etude du rôle de protéines apparentées aux cadhérines dans le développement des interneurones du cortex auditif / Study of the role of cadherin-related proteins in the development of auditory cortex interneurons

Libé-Philippot, Baptiste 16 June 2017 (has links)
L'éminence ganglionnaire médiale (MGE) produit la grande majorité des interneurones GABAergiques corticaux synthétisant la parvalbumine. Les neuroblastes issus de la MGE migrent sur une longue distance avant d'atteindre leur destination finale. A ce jour, on ne sait pas s'il existe des mécanismes moléculaires les guidant vers des régions corticales données. Je montre que deux protéines apparentées aux cadhérines, cdhr23 et cdhr15, ont un rôle déterminant dans le développement d'interneurones du cortex auditif et de manière spécifique. Chez la souris et le macaque, ces deux protéines sont co-synthétisées par des neuroblastes issus de la MGE pendant leur migration. Chez les souris déficientes pour Cdhr23 ou Cdhr15, les neuroblastes synthétisant cdhr15 ou cdhr23 s'accumulent dans le télencéphale basal, ne parviennent pas à pénétrer dans le néocortex et présentent in vitro des défauts de polarité cellulaire. Cdhr15 intervient dans la survie des précurseurs d'interneurones à parvalbumine pendant la première semaine postnatale. Les souris mutantes pour Cdhr23 ou Cdhr15 présentent à trois semaines un nombre réduit d'interneurones à parvalbumine dans leur cortex auditif mais pas dans les cortex avoisinants. Cette diminution est associée à une disposition aux crises audiogènes. Mes résultats indiquent que des précurseurs d'interneurones du cortex auditif sont équipés de protéines d'adhérence déterminantes pour leur migration et leur intégration dans le cortex auditif. Ils suggèrent l'existence d'un possible mécanisme moléculaire général fondé sur un " code d'adhérence " qui déterminerait les neuroblastes GABAergiques dès leur naissance à intégrer une aire corticale donnée. / The medial ganglionic eminence (MGE) gives rise to the majority of cortical GABAergic interneurons that synthetize parvalbumin. Neuroblasts born in the MGE undergo a long distance migration before reaching their final target. Up to now, it is unknown whether any molecular mechanism guides them to specific cortical regions. I show that two cadherin-related proteins, cdhr23 and cdhr15, have a critical role in the development of interneurons of the auditory cortex, specifically. In mice and macaque, the two proteins are co-synthetized in neuroblasts from the MGE during their migration. In mouse mutants for Cdhr23 or Cdhr15, neuroblasts synthetizing cdhr15 or cdhr23 accumulate in the basal telencephalon, fail to enter the neocortex and present in vitro cell polarity defects. Cdhr15 is involved in the survival of parvalbumin interneuron precursors during the first postnatal week. Mutant mice for Cdhr23 and Cdhr15 show at three weeks a reduced number of parvalbumin interneurons in the mouse auditory cortex but not the neighbouring ones. This decrease is associated with a susceptibility to audiogenic seizures. My results reveal that interneuron precursors of the auditory cortex are endowed by specific adhesion proteins critically involved in their migration and integration in the auditory cortex. They suggest a possible general molecular mechanism based on an "adhesion code” that would determine GABAergic neuroblasts from their birth to a specific cortical region.
9

Expression of Selected Cadherins in Adult Zebrafish Visual System and Regenerating Retina, and Microarray Analysis of Gene Expression in Protocadherin-17 Morphants

Marlowe, Alicja 28 July 2022 (has links)
No description available.

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