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Showing 1 to 10 of 16 (0.128 seconds)Spelling suggestions: "subject:"nervous system development"" "subject:"cervous system development""
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Analysis of the Wnt receptors Ror, Otk and Otk2 during nervous system development in Drosophila melanogasterRipp, Caroline 10 February 2015 (has links)
No description available.
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Conditional activation of NRG1 signaling in the brain modulates cortical circuitryUnterbarnscheidt, Tilmann 05 May 2015 (has links)
No description available.
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Úloha CRMP2 vo vývoji nervového systému. / The role of CRMP2 in the nervous system development.Žiak, Jakub January 2020 (has links)
Regulation of axon guidance and pruning of inappropriate synapses is key to development of neural circuits. Secreted semaphorins are integral part of both processes. Collapsin response mediator protein 2 (CRMP2) has been shown to regulate axon guidance by mediating Semaphorin 3A (Sema3A) signaling, however, nothing is known about its role in the synapse pruning. Similarly, it is also not known if CRMP2 mediates signals from other semaphorins. We herein studied CRMP2 protein and revealed its role in growth and pruning of selected axons and dendrites. In newly generated crmp2-/- and crmp2a-/- mice we demonstrate that CRMP2 has a moderate effect on Sema3A-dependent axon guidance in vivo, and its deficiency leads to a mild defect in axon guidance in peripheral nerves and corpus callosum. CRMP2A isoform is specifically involved in development of callosal axons. Surprisingly, we show that crmp2-/- mice display prominent defects in stereotyped axon pruning in hippocampus and visual cortex and altered dendritic spine remodeling, which are consistent with impaired Sema3F signaling and with models of autism spectrum disorder (ASD). Indeed, we demonstrate that CRMP2 mediates Sema3F signaling in primary neurons and that crmp2-/- mice display ASD-related social behavior changes in early postnatal period as well...
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Serotonergic Neurons of Drosophila melanogaster Larvae: A Study of Their Development and FunctionMoncalvo, Verόnica Gabriela Rodriguez 04 1900 (has links)
Drosophila melanogaster is an attractive model organism for the study of numerous fundamental processes including nervous system development and function. This is due to the power of Drosophila genetics combined with the high degree of similarity between this organism and vertebrate systems, not only at the molecular level but also at the cellular and behavioural levels.
The first part of my thesis focused on trophic interactions occurring in Drosophila larval central nervous system. Specifically, it describes the interaction of serotonin (5HT)-producing neurons with other three groups of neurons: the larval photoreceptors expressing Rhodopsin 5 (Rh5), the photoreceptor subset expressing Rhodopsin 6 (Rh6), and the larval circadian pacemakers (LNv). I found that both Rh5-and Rh6-expressing fibers contact a 5-HT arborization in the larval optic neuropil, where the 5-HT processes also overlaps with the dendrites of the LNv. The results of my experiments also indicate that the Rh6-expressing terminus is the neural process providing the signal required for the outgrowth of the serotonergic arborization. Furthermore, proper branching of this arborization requires normal Rae function. These findings further support the importance of extrinsic and intrinsic signalling for the assembly ofthe nervous system.
The remainder of my studies attempted to investigate candidate neurons modulating Drosophila larval photobehaviour. Using the larval response to light as a behavioural paradigm and neuronal silencing experiments, my results demonstrate that 5HT neurons located in the brain regulate the larval photoresponse during development. In addition, my findings suggest that this modulation occurs at a central level and that is mediated by 5-HT1A(Dro) receptors. These observations provide new insights into the functions of serotonergic neurons in Drosophila as well as how neuromodulators shape neuronal circuit function and ultimately behaviour. / Thesis / Doctor of Philosophy (PhD)
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Genetic mechanisms behind cell specification in the Drosophila CNSBaumgardt, Magnus January 2009 (has links)
The human central nervous system (CNS) contains a daunting number of cells and tremendous cellular diversity. A fundamental challenge of developmental neurobiology is to address the questions of how so many different types of neurons and glia can be generated at the precise time and place, making precisely the right connections. Resolving this issue involves dissecting the elaborate genetic networks that act within neurons and glia, as well as in the neural progenitor cells that generates them, to specify their identities. My PhD project has involved addressing a number of unresolved issues pertaining to how neural progenitor cells are specified to generate different types of neurons and glial cells in different temporal and spatial domains, and also how these early temporal and spatial cues are integrated to activate late cell fate determinants, which act in post-mitotic neural cells to activate distinct batteries of terminal differentiation genes. Analyzing the development of a specific Drosophila melanogaster (Drosophila) CNS stem cell – the neuroblast 5-6 (NB5-6) – we have identified several novel mechanisms of cell fate specification in the Drosophila CNS. We find that, within this lineage, the differential specification of a group of sequentially generated neurons – the Ap cluster neurons – is critically dependent upon the simultaneous triggering of two opposing feed-forward loops (FFLs) within the neuroblast. The first FFL involves cell fate determinants and progresses within the post-mitotic neurons to establish a highly specific combinatorial code of regulators, which activates a distinct battery of terminal differentiation genes. The second loop, which progresses in the neuroblast, involves temporal and sub-temporal genes that together oppose the progression of the first FFL. This leads to the establishment of an alternative code of regulators in late-born Ap cluster neurons, whereby alternative cell fates are specified. Furthermore, we find that the generation and specification of the Ap cluster neurons is modulated along the neuraxis by two different mechanisms. In abdominal segments, Hox genes of the Bithorax cluster integrates with Pbx/Meis factors to instruct NB5-6 to leave the cell cycle before the Ap cluster neurons are generated. In brain segments, Ap cluster neuron equivalents are generated, but improperly specified due to the absence of the proper Hox and temporal code. Additionally, in thoracic segments we find that the specification of the Ap cluster neurons is critically dependent upon the integration of the Hox, Pbx/Meis, and the temporal genes, in the activation of the critical cell fate determinant FFL. We speculate that the developmental principles of (i) feed-forward combinatorial coding; (ii) simultaneously triggered yet opposing feed-forward loops; and (iii) integration of different Hox, Pbx/Meis, and temporal factors, at different axial levels to control inter-segmental differences in lineage progression and specification; might be used widely throughout the animal kingdom to generate cell type diversity in the CNS.
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Varicose/ Senz'Aria, A MAGUK Required for Junctional Assembly During Epithelial Morphogenesis in DrosophilaMoyer, Katherine Ellen 10 1900 (has links)
Scaffolding proteins belonging to the Membrane Associated GUanylate Kinase (MAGUK) superfamily function as adaptors linking cytoplasmic and cell surface proteins to the cytoskeleton to regulate cell-cell adhesion, cell-cell communication and signal
transduction. We have identified a novel Drosophila MAGUK member, Varicose (Vari), the homologue of vertebrate scaffolding protein PALS2. Similar to its vertebrate counterpart, Varicose localizes to pleated Septate Junctions (pSJs) of all embryonic,
ectodermally derived epithelia and peripheral glia. In vari mutants, essential SJ proteins NeurexinIV and FasciclinIII are mislocalized basally and the cells develop a leaky paracellular seal. Localization of SJ protein Discs Large is not affected, indicating Vari is not involved in cell polarization. In addition, vari mutants display irregular tracheal tube diameters and have reduced lumenal protein accumulation suggesting involvement in tracheal morphogenesis. We found that Vari is distributed in the cytoplasm of optic lobe neuroepithelium and is required for proper ommatidial patterning. As well, Vari is expressed in a subset of neuroblasts and differentiated neurons of the nervous system. We also present a novel MAGUK function in wing hair alignment during adult
morphogenesis. We conclude that Varicose is involved in scaffold assembly at the SJ and has a role in patterning adult epithelia and in nervous system development. / Thesis / Doctor of Philosophy (PhD)
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Fatores de transcrição no desenvolvimento inicial do tubo neural posterior. / Transcription factors in the development of the early posterior neural tube.Vieceli, Felipe Monteleone 16 March 2015 (has links)
O início da neurogênese e diferenciação neural no sistema nervoso do embrião é controlado pela expressão orquestrada de fatores de transcrição. A caracterização de novos reguladores transcricionais nestes processos é importante para o entendimento dos mecanismos responsáveis pela formação de neurônios. Neste trabalho, nós investigamos a função do fator de transcrição Scrt2 na medula espinhal do embrião de galinha. Nossos resultados indicam que Scrt2 é expresso imediatamente após a saída do ciclo celular e em conjunto com Ngn2 e NeuroM, sugerindo uma função em neurônios recém-nascidos. Para identificar potenciais alvos de Scrt2, realizamos experimentos de eletroporação in ovo no tubo neural posterior e analisamos os fenótipos transcriptômicos com RNA-Seq. Por fim, apresentamos também uma caracterização do transcriptoma do tubo neural posterior selvagem entre HH18 e HH29 (E6), provendo uma extensa base de dados de expressão gênica para futuras investigações. Com base em nossa experiência, nós discutimos o uso de RNA-Seq em diferentes abordagens experimentais. / The onset of neurogenesis and neural differentiation in the embryonic nervous system is controlled by the coordinated expression of transcription factors. Identification of novel transcriptional regulators in these processes is essential for our understanding of the mechanisms underlying neuronal differentiation. Here, we used the chick embryonic spinal cord to investigate the role of the transcription factor Scrt2. Our results indicate that Scrt2 is expressed in cells that recently exited the mitotic cycle and overlaps with Ngn2 and NeuroM, suggesting a function in newborn neurons. To identify potential gene targets of Scrt2, we performed in ovo electroporation experiments in the posterior neural tube and assessed the transcriptomic phenotypes using RNA-Seq. Finally, we also present the transcriptomic profiles of the wild-type posterior neural tube from HH18 to HH29 (E6), providing an informative gene expression database for future investigations. Based on our experience, we discuss the use of RNA-Seq in distinct experimental approaches.
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Cofilin and drebrin mediated regulation of the neuronal cytoskeleton in development and diseaseHardy, Holly January 2017 (has links)
The brain is a highly complex structure; neurons extend axons which follow precise paths to make connections with their targets. This extension is guided by a specialised and highly motile structure at the axon tip -the growth cone- which integrates guidance cues to steer the axon through the environment. Aberrant pathfinding is likely to result in developmental impairments causing disruption to brain functions underlying emotion learning and memory. Furthermore, pre-existing connections are constantly remodelled, the ability to do so declines with age, and can have huge impacts on quality of life and well-being. Examining how changes in growth cone behaviour triggered by external cues occurs is crucial for understanding processes in both development and disease. Controlled reorganisation of growth cone cytoskeletal components, such as actin filaments, generate membrane protrusions forming lamellipodia and filopodia. Filopodium formation is commonly associated with sensing the mechanical and chemical environment of the cell. Despite our understanding of the guidance choices that can be made, how filopodia transmit information at a molecular level leading to profound changes in morphology, motility and directionality remains largely unknown. Various actin-binding proteins regulate the number, stability and branching of filopodia. They may therefore have a key role in priming or abrogating the ability of the growth cone to respond to a given guidance cue. I have shown that the actin binding proteins drebrin and cofilin, whilst displaying opposing molecular activities on actin filaments, work synergistically in a temporally regulated manner. A fluorescent membrane marker combined with tagged cofilin and drebrin enabled accurate correlation of cofilin and drebrin dynamics with growth cone morphology and filopodial turnover in live neurons. In contrast to previous in vitro experiments, cofilin was found to enhance the effect of drebrin to promote filopodia formation in intact neurons, and that growth cone spread was significantly constrained when cofilin was knocked down. Importantly, this adds to our understanding of how the two actin binding proteins contribute to directed motility in neuronal growth cone filopodia during guidance. Furthermore, following acute treatment with low concentrations of the repulsive guidance cue semaphorin-3A, neuronal growth cones expressing cofilin displayed increased morphological complexity and filopodial stability. This suggests that traditional collapse signals may serve as pause signals allowing neurons to increase the surface area to sense the environment adequately and enable precise wiring decisions. Remodeling of the cytoskeleton is perturbed in a number of degenerative diseases including Alzheimer's, Huntington's, and Amyotrophic Lateral Sclerosis. These conditions are associated with widespread synaptic loss, resulting in memory loss, cognitive impairment, and movement disorders which leads to severe deterioration in quality of life for those afflicted in addition to wider negative socioeconomic impacts. How widespread synaptic loss occurs is poorly understood. One common characteristic is neuronal stress which can be initiated through different conditions such as neuroinflammation, energetic stress, glutamate excitotoxicity, and accumulation of misfolded proteins, all of which have been associated with perturbation of the actin cytoskeleton and the initiation of the cofilin-actin rod stress response. Dysfunction of the cytoskeleton can lead to the disruption of synaptic activity by blocking the delivery of elements such as organelles and proteins required for maintenance of the synapse. Modulating this stress response offers an approach to protecting the integrity of normal synaptic function. Actin interacting protein-1 is a conserved actin binding protein that enhances the filament disassembly activity of cofilin. I have discovered that AIP-1 has a potent ability to prevent the formation of cofilin rods which are thought to contribute to the neuronal dysfunction in several neurodegenerative disorders, even when they are treated with amyloid-β or subjected to metabolic stress. This is the first study to demonstrate a molecular mechanism for preventing rod formation in the presence of a neuronal stressor and has the potential to protect against rod formation by other stressors associated with disease such as inflammation and excitotoxicity. AIP-1 offers the exciting possibility of a means to reverse cofilin rod formation and the subsequent cytoskeletal pathology associated with dementia and has potential for therapeutic exploitation in human disease. Furthermore, it is the first study to demonstrate that AIP-1 localises to areas of rapid actin remodeling in neuronal growth cones. Exploiting the action of AIP-1 therefore represents an exciting and novel therapeutic avenue to tackle neurodegeneration.
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Les fondements neurophysiologiques de la latéralisation motrice : le paradigme des mouvements en miroir / Neurophysiological basis of motor lateralization : the mirror movements paradigmWelniarz, Quentin 13 July 2016 (has links)
Le syndrome des mouvements en miroir congénitaux (MMC) est une maladie génétique caractérisée par l’existence de mouvements involontaires symétriques d’une main qui reproduisent à l’identique les mouvements volontaires de l’autre main. Deux structures sont impliquées dans la physiopathologie de cette maladie : le corps calleux (CC) et le faisceau corticospinal (FCS). Deux gènes ont été liés aux MMC à ce jour : DCC et RAD51. Tandis que DCC joue un rôle crucial dans le guidage des axones commissuraux, RAD51 intervient dans la réparation de l’ADN, et son rôle dans le développement du système moteur était inattendu.Chez la souris, nous avons étudié le rôle de RAD51 et DCC dans le développement du FCS et du CC, ainsi que l’implication de ces deux structures dans la latéralisation du contrôle moteur. Nous avons prouvé que DCC contrôle le guidage du FCS à la ligne médiane de façon indirecte. RAD51 intervient dans le développement du neocortex, mais son rôle précis dans le développement du système moteur demeure inconnu. Nous avons par ailleurs comparé un groupe de patients MMC à des volontaires sains afin d’étudier la latéralisation de l’activité corticale lors de la préparation motrice. L’activation et les interactions inter-hémisphériques des aires motrices sont anormales dès la préparation du mouvement chez les patients MMC. L’inhibition de l’aire motrice supplémentaire (AMS) chez les volontaires sains reproduit les défauts d’interactions inter-hémisphériques observés chez les patients. Ces résultats suggèrent que l’AMS est impliquée dans la préparation des mouvements latéralisés, potentiellement en modulant les interactions entre les deux hémisphères via le CC. / Mirror movements are involuntary symmetrical movements of one side of the body that mirror voluntary movements of the other side. Congenital mirror movements (CMM) is a rare genetic disorder transmitted in autosomal dominant manner, in which mirror movements are the only clinical abnormality. Two structures are involved in the physiopathology of CMM: the corpus callosum (CC) and the corticospinal tract (CST). The two main culprit genes identified so far are DCC and RAD51. While the role of DCC in commissural axons guidance during development is well known, RAD51 is involved in DNA repair, and its link with CMM was totally unexpected. In mice, we investigated the role of RAD51 and DCC in the development of the CC and CST, as well as the role of these two structures in motor lateralization. We showed that DCC controls CST midline crossing in an indirect manner. Our work clarified the role of RAD51 in neocortex development, but how RAD51 influences motor system development remains unknown. We compared a group of CMM patients with healthy volunteers to investigate the lateralization of cortical activity during movement preparation. We showed that activation of motor/premotor areas and interhemispheric interactions during movement preparation differed between the CMM patients and healthy volunteers. Transient inhibition of the supplementary motor area (SMA) in the healthy volunteers resulted in abnormal interhemispheric interactions during movement preparation, reminiscent of the situation observed in the patients. These results suggest the SMA is involved in lateralized movements preparation, potentially by modulating interhemispheric interactions via the CC.
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Role of CG9650 in Neuronal Development And Function of Drosophila MelanogasterMurthy, Smrithi January 2016 (has links) (PDF)
The nervous system is the most complex system in an organism. Functioning of the nervous system requires proper formation of neural cells, as well as accurate connectivity and signaling among them. While the major events that occur during these processes are known, the finer details are yet to be understood. Hence, an attempt was made to look for novel genes that could be involved in them. The focus of the present study is on CG9650, a gene that was uncovered in a misexpression screen, as a possible player in neuronal development in Drosophila melanogaster.
The first chapter of the thesis reviews existing knowledge about neuronal development and function. The first section of this chapter explains in brief the formation and specification of neural stem cells, and their differentiation to neurons and glia. Sections 2 and 3 describe neuronal connectivity and signaling with respect to axon growth, synapse formation, function and plasticity. A comparison of invertebrate and vertebrate neuronal development is provided in section 4 of this chapter. This part also explains the use of Drosophila as a model for neuronal development and function.
Chapter 2 describes the expression pattern of CG9650, which was characterized to gain insights into the possible role it plays during Drosophila neurogenesis.CG9650 is expressed in multiple cell types in the nervous system at the embryonic stage. Some of the cell sub-types have been identified from their morphology and position. Expression was restricted to neurons in the larval stage (except in the optic lobe, where it was expressed in precursors also), and continued in the pupal stage. No expression was seen in adults (except in the optic lobe). CG9650 has a putative DNA binding region, which bears homology to the mouse proteins CTIP1 and CTIP2, implying that CG9650 is possibly a transcription factor.
In order to understand the function of CG9650, the protein was knocked down panneuronally. The resultant animals showed locomotor defects at both larval and adult stages, which have been described in chapter 3. Knock down larvae showed reduced displacement and speed of movement. The number of peristaltic cycles was also reduced in these animals but the cycle period was normal. In adults, movement was uncoordinated and righting reflex was lost, resulting in inability to walk, climb or fly. These results imply a defect in neuronal signaling. Sensory perception was unaffected in these animals. Stage specific knockdown of CG9650 indicated that the requirement for this protein is primarily during the larval stage. All CG9650-expressing neurons in the ventral nerve cord were glutamatergic, implying that its role in controlling locomotor activity is likely through glutamatergic circuits.
Following up on these observations, signaling at the neuromuscular junction was assessed in CG9650 knock down animals. Chapter 4 discusses the signaling defects seen on CG9650 knock down, and the possible role of this protein. Electrophysiological recordings from Dorsal Longitudinal Muscles showed reduced and irregular neuronal firing in the knock down animals. These animals also had reduced bouton and active zone numbers. Moreover, overexpression of BRP, an active zone protein, rescued the locomotor defects caused by knock down of CG9650.
Chapter 5 reports the effect of over expression of CG9650. Pan-neural over expression of CG9650 resulted in embryos with severe axon scaffolding defects, as well as aberrant neuronal and glial pattern. However, the incorrectly positioned glial cells in these embryos did not express CG9650, indicating that their aberrant positioning was probably due to incorrect signaling from the neurons.
In conclusion, this study reports the requirement for CG9650, a hitherto unknown protein, in locomotor activity and signaling, thus ascribing for it a role in neuronal development and function of Drosophila melanogaster.
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