Global ETD Search

101	Mécanismes moléculaires de polarisation des projections neuronales dans l'axe droite-gauche / Molecular mechanisms of polarisation of neuronal projections in the left-right axis Charoy, Camille 10 June 2014 (has links) Les circuits nerveux s'organisent autour des grands axes de polarité du corps. Au cours du développement, la navigation ainsi que l'arrangement spatial des projections au sein de leurs territoires cibles sont contrôlés par de nombreux facteurs de guidage. Pendant ma thèse je me suis intéressée à deux modèles de formation des circuits neuronaux présentant une polarité dans l'axe droite-gauche. Le premier concerne la mise en place des projections des interneurones commissuraux de la moelle épinière, un modèle de navigation orientée et le second, porte sur l'innervation des motoneurones phréniques, un modèle d'organisation asymétrique dans le territoire cible. Les mouvements comme la marche, la course ou la nage font intervenir des circuits neuronaux particuliers dédiés à la coordination des deux côtés du corps. Ces circuits sont formés majoritairement par les projections des interneurones commissuraux de la moelle épinière. Au cours du développement, ces interneurones élaborent un axone qui traverse la ligne médiane partageant les deux moitiés du système nerveux central pour se connecter aux motoneurones ou à d'autres interneurones de l'hémi-moelle opposée. De nombreux travaux ont porté sur les mécanismes de traversée de la ligne médiane et ont mis en évidence un rôle fondamental de facteurs de guidage comme la Nétrine, les Slit et les Sémaphorines. Ces molécules sont secrétées par les cellules de la plaque du plancher (PP) environnant la ligne médiane ventrale. Lors de leur traversée les axones commissuraux sont tout d'abord attirés par les signaux attractifs secrétés par les cellules de la PP. Une fois que les axones ont traversé la ligne médiane, ils perdent leur sensibilité aux facteurs attractifs et développent des nouvelles sensibilités pour des facteurs répulsifs qui les guident hors de la PP. Une étude menée par mon équipe a permis de montrer que les axones commissuraux acquièrent une réponse à la Sémaphorine3B seulement après avoir traversé la ligne médiane. Dans cette étude, l'équipe a montré que pendant la phase qui précède la traversée de la PP, une protéase, la Calpaine-1, dégrade la Plexine-A1, le corécepteur de Sema3B (Nawabi et al., 2010). L'inhibition de cette voie pendant la traversée de la PP conduit à la stabilisation de la PlexineA1 à la surface du cône de croissance et la formation d'un complexe récepteur de Sema3B fonctionnel composé de la Plexine-A1 et de la sous-unité de liaison de Sema3B, la Neuropiline2. La suppression de l'activité Calpaine est contrôlée par des signaux de la PP dont la nature n'était pas connue. Au cours de ma thèse j'ai identifié et caractérisé les contributions fonctionnelles de deux signaux de la PP qui sont responsables de la suppression de l'activité Calpaine et la sensibilisation des axones à Sema3B après la traversée. Ces résultats ont permis d'élargir les fonctions du facteur neurotrophique gdnf, et d'apporter de nouveaux éléments sur les voies de contrôle de la signalisation Sémaphorine, les processus de traversée et les modulations post-traductionnelles des récepteurs Plexines. Dans un deuxième projet, je me suis intéressée aux asymétries droite-gauche du système nerveux, par l'étude d'un nouvel exemple de circuit neuronal asymétrique : l'innervation motrice du diaphragme. Le diaphragme est un muscle indispensable à la respiration, il est composé d'une région centrale tendineuse et de deux muscles latéraux. Ces muscles sont innervés par un groupe particulier de motoneurones provenant de la moelle épinière cervicale, qui forment les nerfs phréniques droits (D) et gauches (G). Malgré une position centrale dans l'organisme et une morphologie apparente symétrique, nous avons découvert que le diaphragme présente une asymétrie musculaire ainsi qu'une asymétrie nerveuse. Etonnamment les motoneurones phréniques établissent un motif de connexion typique et différent sur les muscles droit et gauche du diaphragme [etc...] / The nervous circuits have stereotype positions within the major body axes. During development, axonal navigation and special positioning of the axon tracts in the target territories are regulated by many axon guidance factors. During my thesis I have been interested in two models of neuronal circuit formation that present a leftright polarity. The first one concerns the formation of the spinal commissural neurons projections, a model of oriented navigation along the left-right axis and the second one is the innervation of the phrenic motoneurons, a novel model of left-right asymmetric innervation pattern. Rhythmic locomotor movements like walking, running or swimming require neuronal circuits ensuring left-right coordination. Central components of these circuits are commissural neurons of the spinal cord. During development theses neurons are projecting axons across the midline that divides the nervous system in two parts, which connect the contralateral side of the spinal cord. Extensive work focused on the mechanisms controlling midline crossing. These study revealed a fundamental role of guidance factors secreted by floor plate cells at the ventral midline such as Netrins, Slits and Semaphorins. They also revealed that before crossing, axons are attracted towards the floor plate, and navigating by the floor plate they lose responsiveness to these attractive factors and develop a new sensitivity to repulsive cues that drive them out of the floor plate. In a previous study, my team showed that commissural axons gain response to Sema3B only after floor plate crossing (Nawabi et al., 2010). Before crossing, Plexin-A1 the Sema3B receptor is processed by a protease: the Calpain1. During crossing suppression of this pathway enable Plexin-A1 expression at growth cone surface, leading to sensitization to Sema3B. The suppression of Calpain activity was found controlled by floor plate signals, which remained unknown. During my thesis I have identified and characterized the functional contribution of two floor plate signals that are responsible for the inhibition of Calpain activity and axon sensitization to Sema3B after midline crossing: the neurotrophic factor gdnf and the cell adhesion molecule NrCAM. My results bring new elements on the control of midline crossing processes, Semaphorin signaling, and post-translational modifications of the Plexins receptors. In my second project, I have been interested in left-right asymmetries of the nervous system through the study of a new model of left-right asymmetry: the diaphragm innervation. The diaphragm is a muscle essential for breathing, it is composed of one central tendinous region and two lateral muscles. These muscles are innervated by a subset of cervical spinal cord motoneurons which forms the left and right phrenic nerves. Despite its central disposition in the organism and its apparent symmetry, we noticed that the diaphragm presents nervous and muscular asymmetries. Surprisingly phrenic motoneurons present typical and different nerve patterns on the left and right diaphragm muscles. Diverse left-right characteristic have been documented in the brain but none concerned yet the spinal cord or peripheral projections. My thesis work has been dedicated to the identification of the mechanisms that control the asymmetry of the diaphragm innervation. My work showed that this asymmetry is set up very early during development via a molecular pathway that is known to control the visceral organ asymmetry. This work opens numerous perspectives and brings new information on the molecular diversity of spinal neurons that could shed a new light on the mechanisms of motoneuron physiopathology Développement Moelle épinière Neurones Guidage axonal Neurones commissuraux Moto-neurones Diaphragme Nerfs phrénique Development Spinal cord Neuron Axon guidance Commissural neuron Motor-neuron Diaphragm Phrenic nerves 570
102	Crossed Wires: PKMζ Antagonizes Apkc And The Par Complex To Regulate Morphological Polarity Parker, Sara Shannon January 2015 (has links) A cell's composition is not uniform, but is comprised of many molecular gradients to compartmentalize functions into specialized subcellular domains. This organization is called polarity–the asymmetry of morphology and composition. Though it's a feature of nearly all prokaryotic and eukaryotic cells, polarity is plastic and highly dynamic, and is continuously instructed by the crosstalk between extracellular cues and internal effector pathways. One of the master regulators of polarity is the Par complex, canonically comprised of Cdc42, Par6, Par3 and atypical protein kinase C (aPKC). The Par complex defines the apical domain of epithelia and the neuronal axon, directs cell migration and the assembly of cell junctions, and restricts other polarity complexes to their respective domains. We have identified a novel polarity protein that counteracts the activities of the Par complex in cells. PKMζ, a truncated isoform of aPKC normally found in neurons, competes with full-length aPKC for substrate interactions. This competition results in the disruption of the canonical Par complex and its instruction of cell polarity, manifesting as a block in axon specification in developing neurons, or as a loss of the apical-basal axis of epithelial polarity. By eliminating PKMζ's ability to compete with aPKC for interaction with Par3, the effect on polarity is mitigated, while RNAi-mediated reduction of Par3 levels similarly rescues PKMζ-associated defects. We further report that PKMζ is aberrantly transcribed in certain epithelial cancers, and its expression correlates with grade. Malignant epithelial phenotypes are driven by PKMζ's Par3-dependent disruption of polarity, and its Par3- independent promotion of anoikis resistance. We demonstrate that PKMζ, as the catalytic fragment of aPKC, is surprisingly competent to influence polarity independently of its kinase activity, while other aPKC isoforms require their catalytic function to permit apical development. Together, this body of work presents PKMζ as an endogenous inhibitor of Par complex function, whose presence provides bistability to the dynamics of symmetry-breaking. axon epithelia morphogenesis neuron polarity Cell Biology & Anatomy apical
103	Investigation of the interactions of DVAP-33A, the orthologue of human VAPB Parry, Katherine Elizabeth January 2011 (has links) Amyotrophic Lateral Sclerosis is the most common type of motor neuron disease, characterized by progressive degeneration of the upper and lower motor neurons. Sufferers present with symptoms of muscle weakness and this quickly develops on to paralysis and finally death due to respiratory failure within 5 years of disease onset. Although the majority of cases are sporadic, about 10% are familial and it is hoped that through the investigation of these few cases a greater understanding of the disease process, the reasons for its delayed onset and vulnerability of motor neurons will be achieved. Recently a novel mutation linked to ALS was discovered in an evolutionary conserved protein named Vesicle associated membrane protein (VAMP) associated protein B (VAPB). VAPB is an integral type II membrane protein localised at the Endoplasmic Reticulum and thought to have a role in protein transport. The orthologue in Drosophila has been shown to be involved in the homeostatic regulation of bouton formation at the Neuromuscular Junction through an association with the microtubule network. To elucidate the mechanism through which this protein causes ALS, Pennetta et al have created a Drosophila model of the disease by expressing the mutated orthologue in the fly. To complement this model, I have undertaken a number of biochemical experiments to look for potential interactors of the VAP proteins. The yeast two hybrid system utilises the yeast GAL4 transcriptional activator to indicate a protein interaction within a yeast cell and can be used to test a cDNA library for interactors. Through this technique a number of interesting binding partners have been found that may play crucial roles in the progression of the disease. 616.8
104	Functional Stability and Learning in the Dorsolateral Prefrontal Cortex Greenberg, Paul Arthur January 2005 (has links) "Stable multi-day recordings from chronically implanted microelectrodes within the dorsolateral prefrontal cortex of two monkeys performing three Go/NoGo visual discrimination tasks (one requiring well-learned responses, two requiring learning) demonstrated that the majority of prefrontal neurons were 'functionally stable'. Action potentials of 94 neurons were stable over 2-9 days; 66/94 (70%) of these cells responded each day, 22/94 (23%) never responded significantly, and 6/94 (6%) responded one day but not the next. Of 66 responsive neurons, 55 were selective for either Go or NoGo trials, individual stimuli, or eye movements." (Greenberg and Wilson, 2004) Selectivity was maintained, for 46/55 neurons across all recording days. Response strength (baseline vs. post-stimulation firing rates) and event-related response timing also displayed stability. Stability generalized across neuronal response type suggesting that functional stability is a general property. Long-term recordings from other studies supported similar conclusions suggesting that neurons throughout the brain are functionally stable. Single-day recordings from different neurons within the same cortical regions demonstrated neuronal response flexibility while monkeys learned associations among visual cues, and Go/NoGo behavioral responses. Of 116 neurons, 57 (49%) displayed significant change points in firing rates during novel learning (n=18), reversal learning (n=12), or both tasks (n=27). Six of 57(10.5%) neurons had firing rates changes prior to learning and might have been causally related to the monkeys' behavioral changes. However, only 18/152 (12%) of the total number of firing rate changes occurred prior to the monkeys' learning meaning that most appeared to be the consequences of learning rather than the causes. Functional Stability Visual Discrimination Learning Prefrontal Cortex Single Neuron
105	Analysis of the kisir mutation in Drosophila melanogaster Carhan, Ahmet January 1999 (has links) No description available. 572.8
106	Mapping of Loa : a mouse motor deficit gene Nicholson, Sharon Joycelyn January 2000 (has links) No description available. 572.8 Motor neuron disease; Legs at odd angles
107	Planar Cell Polarity Genes prkl-1 and dsh-1 Polarize C. Elegans Motorneurons during Organogenesis Sánchez-Alvarez, Leticia 16 November 2012 (has links) The correct polarity of a neuron underlies its ability to integrate precise circuitries in the nervous system. The goal of my thesis was to investigate the pathways that establish and maintain neuron polarity/orientation in vivo. To accomplish this, I used bipolar VC4/5 motor neurons, which innervate the C. elegans egg-laying musculature, as a model system. Vulval proximal VC4/5 neurons extend axons in the left-right (LR) orientation, around the vulva; whereas vulval distal VC1-3,6 neurons extend axons along the anterior-posterior (AP) axis. A previous study showed that vang-1, a core planar cell polarity (PCP) gene, suppresses AP axon growth in VC4/5 neurons. In order to identify new components of this pathway we performed genetic screens for mutants with abnormal VC4/5 polarity/morphology. We isolated and mapped alleles of farnesyl transferase b (fntb-1) and of core PCP genes, prickle- 1 (prkl-1) and dishevelled-1 (dsh-1); all of which display tripolar VC4/5 neurons, similar to vang-1 lof. In prkl-1 and dsh-1 mutants, primary LR and ectopic AP VC4/5 axons are born simultaneously, suggesting an early role in establishing polarity. In addition, prkl-1 and dsh-1 act persistently to maintain neuron morphology/orientation. Genetic analysis of double mutants suggests that prkl-1 interacts with vang-1 in a common PCP pathway to prevent AP axon growth, while dsh-1 also acts in a parallel pathway. Furthermore, prkl-1 functions cell autonomously in neurons, whereas dsh-1 acts both cell autonomously and cell nonautonomously in epithelial cells. Notably, prkl-1 overexpression results in unipolar VC4/5 neurons, in a dose-dependent manner. In contrast, dsh-1 overexpression in VC4/5 neurons results in a lof phenotype, similar to vang-1 lof and overexpression phenotype. Remarkably, prkl-1 overexpression restores normal VC4/5 polarity in dsh-1 and vang-1 mutants, which is suggestive of a downstream role for prkl-1. Both PRKL-1 and DSH-1 are expressed in iii uniformly distributed puncta at the plasma membrane of VC4/5, similar to VANG-1; suggesting that their asymmetric distribution is not critical for neuron polarity. Furthermore, we found that the vulva epithelium induces prkl-1 expression in VC4/5; indicating a functional relationship between the egg-laying organ and neuron morphology. Moreover, a structure-function analysis of PRKL-1 revealed that the conserved PET domain and the Cterminal region are crucial to prevent AP axon growth, whereas the three LIM domains are dispensable for this role. In addition, we showed that dsh-1 also regulates the morphology of AP-oriented PDE neurons. dsh-1 promotes the formation of PDE posterior axons, contrary to its function in VC5 neurons; which indicates a context-dependent role for dsh-1 in neuronal polarity. Altogether, this thesis implicates the PCP signalling pathway in a previously unknown role, in establishing and maintaining neuronal polarity, by controlling AP axon growth in response to organ-derived polarizing cues. neuron polarity C. elegans Prkl-1 Dsh-1
108	A Structure/Function Analysis of Nhsl1b in Facial Branchiomotor Neurons Ojumu, John 01 January 2015 (has links) The goal of this study was to identify critical regions of a novel gene, Nance-Horan syndrome-like 1b (nhsl1b). It was previously discovered that C-terminal truncation of the Nhsl1b protein in nhsl1b mutants resulted in a loss of migration in the facial motor neurons of the hindbrain (Walsh et al. 2011). As nhsl1b expresses many isoforms, multiple targets were investigated in order to determine which transcript bears the largest impact on the motor neurons. Using confocal microscopy to observe immunostained embryos, we examined a mutation in an nhsl1b transcript that encodes a WHD, a domain that is known to function within the actin nucleation and polymerization pathways. In situ hybridization and injection of antisense morpholino oligonucleotides indicate that it is not the WHD but another transcript (ex1bnhsl1b) that is necessary for migration. The control experiments for rescuing the mutant phenotype have successfully been performed, but inducing expression of full length nhsl1b in the nhsl1b mutants is proving difficult. neuron migration Nance-Horan Syndrome zebrafish Developmental Neuroscience
109	Zpracování zvuku v emulátoru kochleárního implantátu / Sound Processing in an Emulator of Cochlear Implant Tóth, Peter January 2011 (has links) The time accuracy of the auditory neuronal pathway in its sound localization branch is high, compared to other sensory systems. The time differences in the sound arrival between the left and right ear are distinguished by the neural circuit in this branch. The accuracy achieved here is in the order of tens of microseconds. This phenomenon has not yet been definitively clarified. In this master thesis, a model of a neuron central to this neural circuit is presented. This neuron is called binaural (neuron of the two ears) and is located in the medial superior olive (MSO) neural nucleus. The properties of the MSO neuron are described. Specifically, the neuron acts as a coincidence detector, and this is necessary for the circuit functioning. Main result of the thesis is the theory explaining how the function of the coincidence detector can be described based on the interaction of the post-synaptic potentials on the spike-response model neuron. Generality and implications for the auditory pathway are then discussed.
110	Towards a Better Understanding of miRNA Function in Neuronal Plasticity : implications in Synaptic Homeostasis and Maladaptive Plasticity in Bone Cancer Pain Condition / MicroRNAs et Plasticité Neuronale : rôle dans l’Homéostasie Synaptique et la Plasticité Dysfonctionnelle en Condition de Douleur Cancéreuse Elramah, Sara 22 November 2013 (has links) Les micro-ARNs (miRNAs) sont de petits ARNs (20-25 nt) qui ont un rôle important dans les mécanismes d'interférence ARN. Les miRNAs sont des inhibiteurs de l'expression génique qui interviennent au niveau post-traductionnel en s'hybridant à des sites spécifiques de leurs ARNm cibles. Ce mécanisme induit la dégradation de l'ARNm ou l'inhibition de sa traduction. Puisque l'hybridation partielle du miRNA est suffisante pour induire une inhibition, chaque miRNA peut avoir des centaines de cibles. Les miRNAs sont impliqués dans de nombreuses fonctions biologiques et en particulier dans processus neuronaux. Plus de la moitié des miRNAs connus sont exprimés dans le cerveau de mammifère avec une distribution spécifique du miRNA considéré. A l'échelle sub-cellulaire il y a également une distribution hétérogène des miRNAs. De plus, il a été montré récemment une implication des miRNAs dans la régulation de la traduction locale dans les neurones. En effet, des miRNAs et des protyeines impliquées dans la biogenèse et la fonction des miRNAs ont été retrouvés dans le soma, les dendrites et les axones. Il a été montré que la dérégulation des miRNAs été impliquée dans de nombreux mécanismes pathologiques. Cette thèse a pour objectif de révéler le rôle des miRNAs dans la plasticité synaptique. Nous avons étudié l'implication des miRNAs dans les mécanismes de la plasticité synaptique homéostatique et dans la plasticité dysfonctionnelle rencontrée en condition de douleur cancéreuse.Notre hypothèse était que la régulation de la traduction locale des récepteurs AMPA dans les dendrites en condition d'homéostasie synaptique implique les miRNAs. Par bio-informatique, qRT-PCR et test luciférase, nous avons identifié le miRNA miR-92a comme régulateur de la traduction de l'ARNm de GluA1. Des immunomarquages des récepteurs AMPA et des enregistrements des courants miniatures AMPA montrent que miR-92a régule spécifiquement l'incorporation synaptique de nouveau récepteurs AMPA contenant GluA1 en réponse à un blocage de l'activité synaptique. La douleur est un symptôme très fréquemment associé au cancer et constitue un challenge pour les médecins puisque aucun traitement spécifique et efficace n'existe. C'est sans doute le résultat d'un manque de connaissances des mécanismes moléculaires responsables de la douleur cancéreuse. En combinant les screening des miRNA et des ARNm, nous avons mis en évidence une voie de régulation impliquant miR-124, un miRNA enrichi dans le système nerveux. Ainsi, dans un modèle de douleur cancéreuse chez la souris, la diminution de miR-124 est associée à une augmentation de ces cibles : calpain 1, synaptopodine et tropomyosine 4. Toutes ces protéines ont précédemment été identifiées comme des molécules clef de la fonction et de la plasticité synaptique. Des experiences in vitro ont confirmé que miR-124 exercait une inhibition multiple de calpain 1, synaptopodine et tropomyosine 4. La pertinence clinique de cette découverte a été vérifiée par le screening du liquide cérébro-spinal de patients souffrant de douleur cancéreuse qui montre également une diminution de miR-124. Ce résultat suggère un fort potentiel thérapeutique du ciblage de miR-124 dans les douleurs cancéreuses. Enfin, l'injection intrathécale de miR-124 dans des souris cancéreuses a permis de normaliser l'expression de la synaptopodine et de stopper la douleur cancéreuse lors de la phase initiale de la maladie. / MicroRNAs (miRNAs) are a type of small RNA molecules (21-25nt), with a central role in RNA silencing and interference. MiRNAs function as negative regulators of gene expression at the post-transcriptional level, by binding to specific sites on their targeted mRNAs. A process results in mRNA degradation or repression of productive translation. Because partial binding to target mRNA is enough to induce silencing, each miRNA has up to hundreds of targets. miRNAs have been shown to be involved in most, if not all, fundamental biological processes. Some of the most interesting examples of miRNA activity regulation are coming from neurons. Almost 50% of all identified miRNAs are expressed in the mammalian brain. Furthermore, miRNAs appear to be differentially distributed in distinct brain regions and neuron types. Importantly, miRNAs are reported to be differentially distributed at the sub-cellular level. Recently, miRNAs have been suggested to be involved in the local translation of neuronal compartments. This has been derived from the observations reporting the presence of miRNAs and the protein complexes involved in miRNA biogenesis and function in neuronal soma, dendrites, and axons. Deregulation of miRNAs has been shown to be implicated in pathological conditions. The present thesis aimed at deciphering the role of miRNA regulation in neuronal plasticity. Here we investigated the involvement of miRNA in synaptic plasticity, specifically in homeostatic synaptic plasticity mode. In addition, we investigated the involvement of miRNAs in the maladaptive nervous system state, specifically, in bone cancer pain condition.We hypothesized that local regulation of AMPA receptor translation in dendrites upon homeostatic synaptic scaling may involve miRNAs. Using bioinformatics, qRT-PCR and luciferase reporter assays, we identified several brain-specific miRNAs including miR-92a, targeting the 3’UTR of GluA1 mRNA. Immunostaining of AMPA receptors and recordings of miniature AMPA currents in primary neurons showed that miR-92a selectively regulates the synaptic incorporation of new GluA1-containing AMPA receptors during activity blockade.Pain is a very common symptom associated with cancer and is still a challenge for clinicians due to the lack of specific and effective treatments. This reflects the crucial lack of knowledge regarding the molecular mechanisms responsible for cancer-related pain. Combining miRNA and mRNA screenings we were able to identify a regulatory pathway involving the nervous system-enriched miRNA, miR-124. Thus, miR-124 downregulation was associated with an upregulation of its predicted targets, Calpain 1, Synaptopodin and Tropomyosin 4 in a cancer-pain model in mice. All these targets have been previously identified as key proteins for the synapse function and plasticity. Clinical pertinence of this finding was assessed by the screening of cerebrospinal fluid from cancer patient suffering from pain who presented also a downregulation of miR-124, strongly suggesting miR-124 as a therapeutic target. In vitro experiments confirmed that miR-124 exerts a multi-target inhibition on Calpain 1, Synaptopodin and Tropomyosin 4. In addition, intrathecal injection of miR-124 was able to normalize the Synaptopodin expression and to alleviate the initial phase of cancer pain in mice. MicroARN Douleur Plasticité synaptique Neurones MicroRNA Pain Synaptic plasticity Neuron

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