Global ETD Search

211	Étude ultrastructurale et développementale du récepteur EphA4 dans l’hippocampe du rat Tremblay, Marie-Eve 03 1900 (has links) Afin de mieux comprendre l’évolution des fonctions du récepteur EphA4 pendant le développement du système nerveux central (SNC), nous avons étudié sa localisation cellulaire et subcellulaire dans l’hippocampe du rat, d’abord chez l’adulte, puis pendant le développement postnatal, ainsi que ses rôles potentiels dans la genèse, la migration ou la maturation des cellules granulaires dans l’hippocampe adulte. Pour ce faire, nous avons utilisé la méthode d’immunocytochimie en microscopie photonique, électronique et confocale. En microscopie photonique, une forte immunoréactivité (peroxydase/DAB) pour EphA4 est observée aux jours 1 et 7 suivant la naissance (P1 et P7) dans les couches de corps cellulaires, avec un marquage notamment associé à la surface des corps cellulaires des cellules granulaires et pyramidales, ainsi que dans les couches de neuropile du gyrus dentelé et des secteurs CA3 et CA1. L’intensité du marquage diminue progressivement dans les couches de corps cellulaires, entre P7 et P14, pour devenir faible à P21 et chez l’adulte, tandis qu’elle persiste dans les couches de neuropile, sauf celles qui reçoivent des afférences du cortex entorhinal. En microscopie électronique, après marquage à la peroxydase/DAB, EphA4 décore toute la surface des cellules pyramidales et granulaires, du corps cellulaire jusqu’aux extrémités distales, entre P1 et P14, pour devenir confiné aux extrémités synaptiques, c’est-à-dire les terminaisons axonales et les épines dendritiques, à P21 et chez l’adulte. À la membrane plasmique des astrocytes, EphA4 est redistribué comme dans les neurones, marquant le corps cellulaire et ses prolongements proximaux à distaux, à P1 et P7, pour devenir restreint aux prolongements périsynaptiques distaux, à partir de P14. D’autre part, des axones en cours de myélinisation présentent souvent une forte immunoréactivité punctiforme à leur membrane plasmique, à P14 et P21. En outre, dans les neurones et les astrocytes, le réticulum endoplasmique, l’appareil de Golgi et les vésicules de transport, organelles impliquées dans la synthèse, la modification posttraductionnelle et le transport des protéines glycosylées, sont aussi marqués, et plus intensément chez les jeunes animaux. Enfin, EphA4 est aussi localisé dans le corps cellulaire et les dendrites des cellules granulaires générées chez l’adulte, au stade de maturation où elles expriment la doublecortine (DCX). De plus, des souris adultes knockouts pour EphA4 présentent des cellules granulaires DCX-positives ectopiques, c’est-à-dire positionnées en dehors de la zone sous-granulaire, ce qui suggère un rôle d’EphA4 dans la régulation de leur migration. Ces travaux révèlent ainsi une redistribution d’EphA4 dans les cellules neuronales et gliales en maturation, suivant les sites cellulaires où un remodelage morphologique s’effectue : les corps cellulaires lorsqu’ils s’organisent en couches, les prolongements dendritiques et axonaux pendant leur croissance, guidage et maturation, puis les épines dendritiques, les terminaisons axonales et les prolongements astrocytaires distaux associés aux synapses excitatrices, jusque chez l’adulte, où la formation de nouvelles synapses et le renforcement des connexions synaptiques existantes sont exercés. Ces localisations pourraient ainsi correspondre à différents rôles d’EphA4, par lesquels il contribuerait à la régulation des capacités plastiques du SNC, selon le stade développemental, la région, l’état de santé, ou l’expérience comportementale de l’animal. / To gain more insight into the various functions of EphA4 receptor during the development of the central nervous system (CNS), we have characterized its cellular and subcellular localization in the rat hippocampus, first in the adult, and second during the postnatal development. We have also examined its potential roles in the genesis, migration, or maturation of the granule cells in the adult hippocampus. For that purpose, we have used immunocytochemistry in light, electron, and confocal microscopy. At the light microsocpic level, a strong EphA4 immunoreactivity (peroxidase/DAB) is observed at postnatal days 1 and 7 (P1 and P7) in the cell body layers, with a labeling notably associated with the surface of pyramidal and granule cell bodies, as well as in the neuropil layers of CA3, CA1, and dentate gyrus regions. The intensity of the labeling diminishes progressively in the cell body layers, between P7 and P14, to become weak at P21 and in the adult, while it persists in the neuropil layers, except in those receiving inputs from the entorhinal cortex. At the electron microscopic level, after peroxidase/DAB labeling, EphA4 covers the entire surface of pyramidal and granule cells, from the cell body to the distal extremities, between P1 and P14, but becomes restricted to the synaptic extremities, i.e. the axon terminals and dendritic spines, at P21 and in the adult. At the plasma membrane of astrocytes, EphA4 is redistributed as in neurons, from the cell body and proximal to distal processes, at P1 and P7, to the distal perisynaptic processes, at P14 and older ages. In addition, axons in the process of myelination present strong punctiform immunoreactivity at their plasma membrane, at P14 and P21. Moreover, in neurons and astrocytes, the endoplamic reticulum, Golgi apparatus, and transport vesicles, organelles involved in the synthesis, post-translational modifications, and transport of glycosylated proteins, are also labeled, and also more intensely in younger animals. Lastly, EphA4 is located in the cell body and dendrites of adult-generated granule cells, at the stage of maturation where they express doublecortin (DCX). In addition, EphA4 adult knockout mice display DCX-positive granule cells in an ectopic position, outside of the subgranular zone, suggesting a role for EphA4 in the regulation of their migration. This work thus reveals a redistribution of EphA4 in neuronal and glial cells, in the cellular sites where cellular motility occurs during their maturation: the cell bodies when they position and organize themselves into layers, the dendritic and axonal processes during their growth, guidance, and maturation, and the dendritic spines, axon terminals, and distal astrocytic processes when synapses are formed or strengthened. These locations could thus reflect different roles for EphA4, similarly associated with the regulation of plasticity in the CNS, according to the stage of development, the region, the CNS integrity, or the behavioural experience of an animal. migration cellulaire guidage axonal synaptogenèse plasticité synaptique neurogenèse myélinisation interactions neurone-glie immunocytochimie microscopie électronique microscopie confocale cell migration axon guidance synaptogenesis synaptic plasticity neurogenesis myelination neuron-glia interactions immunocytochemistry electron microscopy confocal microscopy
212	Olfactory ensheathing cell mediated mechanisms of neurite outgrowth and axon regeneration Witheford Richter, Miranda 11 1900 (has links) The capacity of the olfactory neuraxis to undergo neuronal replacement and axon targeting following injury, has led to scrutiny concerning the molecular and physical determinants of this growth capacity. This is because injury to the central nervous system, in contrast, leads to permanent disconnection of neurons with targets. Olfactory ensheathing cells (OECs), a specialized glial cell, may contribute to olfactory repair, and have been used to promote recovery from spinal cord injury. However, there mechanisms underlying OEC-induced regeneration are poorly appreciated. To understand these mechanisms, OECs from the lamina propria (LP OECs) or olfactory bulb (OB OECs) were transplanted into a lesion of the dorsolateral funiculus. While both cells demonstrated reparative capacities, LP and OB OECs differentially promoted spinal fibre growth; large-diameter neurofilament-positive, CGRP-positive, and serotonergic fibres sprouted in response to both LP and OB OEC transplantation, whereas substance-P and tyrosine hydroxylase-positive neurons grew more extensively following OB or LP OEC transplantation, respectively. To further understand the growth of spinal cord neurons in response to OECs, a proteomic analysis of OEC secreted factors was performed, identifying secreted protein acidic and rich in cysteines (SPARC) as a mediator of OEC-induced outgrowth in vitro. To test the contributions of SPARC to spinal cord repair after OEC transplantation, cultures of LP OECs from SPARC null and wildtype (WT) mice were transplanted into a crush of the dorsolateral funiculus. Substance P and tyrosine hydroxylase positive axon sprouting was significantly reduced in SPARC null OEC-treated animals, suggesting that individual factors may contribute to OEC-promoted regeneration. To investigate the effect of OECs on corticospinal (CST) neurons, an in vitro assay was developed using postnatal day 8 CST neurons. Coculture of CST neurons with OB OECs produced extensive axon elongation. Application of OB OEC secreted factors increased CST neurite branching, but did not increase axon elongation. In contrast, plating of CST neurons on OB OEC plasma membrane resulted in extensive axon elongation. Furthermore, the OB OEC plasma membrane could overcome CST neurite outgrowth inhibition induced by an outgrowth inhibitor. Together these findings provide insight into OEC mechanisms of neurite outgrowth and axon regeneration. Spinal cord injury Transplantation Corticospinal Axon guidance Nervous system Proteomics Cell adhesion molecules Plasma membrane Astrocytes Glia Rubrospinal Lesion Angiogenesis Tyrosine hydroxylase Regeneration Olfactory system Osteonectin In vitro
213	Study of the blood-brain interface and glial cells during sepsis-associated encephalopathy : from imaging to histology / Etude de l'interface sang-cerveau et des cellules gliales au cours de l'encéphalopathie associée au sepsis : de l'imagerie à l'histologie Dhaya, Ibtihel 20 December 2017 (has links) L'encéphalopathie associée au sepsis (EAS) est définie comme un dysfonctionnement cérébral diffus induit par une réponse systémique à une infection. Chez les patients septiques, l'imagerie par résonance magnétique (IRM) a indiqué à la fois des anomalies de la substance grise (SG) et blanche (SB) associées à des troubles cognitifs graves, y compris le delirium. Pour améliorer notre compréhension des changements hémodynamiques, métaboliques et structuraux associés au sepsis, différentes séquences d'IRM ont été réalisées chez des rats ayant subi une injection ip de solution saline ou de lipopolysaccharide bactérien (LPS) 2,5h plus tôt ou une ligature et ponction caecale 24h plus tôt. Après ip LPS, l'IRM de contraste de phase a été réalisée pour étudier le flux des artères cérébrales antérieures et moyennes et le marquage des spins artériels (ASL) pour étudier la perfusion des structures cérébrales de la SB et SG. Des séquences d'imagerie par diffusion pondérée (DWI) ont été utilisées pour évaluer les changements structurels. Après la chirurgie CLP, ASL a été utilisé pour étudier les changements de la microcirculation. L'imagerie pondérée en T2, l'imagerie du tenseur de diffusion (DTI) et les statistiques spatiales basées sur les faisceaux (TBSS) ont été réalisées pour caractériser les événements structurels dans différentes structures cérébrales. Après imagerie, les animaux ont été sacrifiés et leur cerveau a été traité pour l'histologie afin de détecter l'enzyme synthétisant les prostaglandines vasoactives cyclooxygénase-2 (COX-2) et le canal hydrique astrocytaire aquaporin-4 (AQP4) dont l'expression peut être régulée à la hausse, évaluer la présence d'immunoglobulines périvasculaires (Ig) indiquant une rupture de la barrière hémato-encéphalique (BHE) et étudier la morphologie des glies puisque la microglie et l’astroglie changent de morphologie lors des conditions inflammatoires. L'IRM n'a indiqué aucun changement hémodynamique dans la substance grise après l'administration de ip LPS, alors qu'une perfusion cérébrale accrue a été montrée au niveau du corps calleux comme indiqué par l'ASL. DTI a indiqué une augmentation de la diffusion des molécules d’eau parallèlement aux fibres du corps calleux. Ces changements étaient accompagnés d'une dégradation de BHE dans la SB ainsi que la substance grise corticale et striatale adjacente tel est indiqué par la présence périvasculaire d'IgG, sans aucun changement majeur de COX-2 vasculaire ou de morphologie des glies du coprs calleux. Le dysfonctionnement du SNC induit par le sepsis a résulté en une augmentation du contraste pondéré en T2 dans le cortex, le striatum et la base du cerveau, une diminution de la perfusion sanguine dans le cortex et une augmentation de la diffusion hydrique du corps calleux et du striatum ventral. Ces changements ont été associés dans la SB à des modifications de la morphologie des glies et dans la substance grise à une expression constitutive de COX-2 et AQP4 plus faible dans le cortex cérébral. La comparaison entre CLP ayant subit ou non une IRM sous anesthésie à l'isoflurane a montré une réponse inflammatoire réduite tel est indiqué par l'expression de COX- 2, une activation réduite des glies ainsi qu’une lésion réduite de la BHE dans le CLP subissant une IRM sous anesthésie. Collectivement, nos résultats suggèrent que des changements hémodynamiques peuvent survenir en l'absence de flux altéré dans les artères irriguant le cerveau antérieur. Ensuite, l'altération de la structure de la SB est une étape précoce de la pathogenèse de l’EAS qui peut résulter soit de la dégradation de la BHE, soit de l'activation des glies. Cette étude sous-tend l'effet délétère d'une seule exposition à l'anesthésie à l'isoflurane qui peut être atténuée par une seconde exposition chez les rats ayant subi une laparotomie ainsi que les effets de l'inflammation systémique induite par le CLP sur les glies pouvant être atténués par imagerie sous anesthésie à l'isoflurane. / Sepsis-associated encephalopathy (SAE) refers to central nervous system dysfunction during the systemic inflammatory response to infection. In septic patients with encephalopathy MRI has indicated both gray and white matter abnormalities that were associated with worse cognitive outcome including delirium. To improve our understanding of sepsis-associated hemodynamic, metabolic, and structural changes, different MRI sequences were performed in rats that either underwent an i.p injection of saline or bacterial lipopolysaccharide (LPS) 2.5h earlier or cecal ligation and puncture (CLP) 24h earlier. After ip LPS, phase contrast MRI was performed to study anterior and middle cerebral arteries flow and Arterial Spin Labeling (ASL) to study perfusion of white and grey matter brain structures. Diffusion Weighted Imaging (DWI) sequences was used to assess structural changes. After CLP surgery, ASL was used to study microcirculation changes. T2-Weighted Imaging, Diffusion Tensor Imaging (DTI) and tract-based spatial statistics (TBSS) were performed to characterize structural events in different brain structures. After imaging, animals were sacrificed and their brains processed for histology to detect the vasoactive prostaglandin-synthesizing enzyme cyclooxygenase-2 (COX-2) and the astrocytic aquaporin-4 water channel (AQP4) the expression of which can be upregulated during inflammation, to assess the presence of perivascular immunoglobulins (Ig) indicating blood-brain barrier (BBB) leakage and to study glia cell morphology as both microglia and astrocytes are known to change their morphology in inflammatory conditions. Magnetic resonance rat brain imaging indicated no hemodynamic changes in the grey matter after ip LPS administration while an increased CBF was shown in corpus callosum white matter as indicated by ASL. DTI indicated increased water diffusion parallel to fibers of the corpus callosum white matter. These changes were accompanied by BBB breakdown in the white matter and adjacent cortical and striatal grey matter as indicated by the perivascular presence of IgG, but no major changes in vascular COX-2 or white matter glia cell morphology. CLP induced sepsis-associated CNS dysfunction resulted in higher T2-weighted contrast intensities in the cortex, striatum and base of the brain, decreased blood perfusion distribution to the cortex and increased water diffusion in the corpus callosum and ventral striatum compared to sham surgery. These changes were associated in the white matter with modifications in glia cells morphology and in the grey matter with lower expression of constitutive COX-2 expression and AQP4 in the cerebral cortex. The comparison between CLP that underwent or not MRI under isoflurane anesthesia indicated reduced inflammatory response as indicated by COX-2 expression, reduced glia activation and reduced BBB damage in CLP that underwent MRI under isoflurane anesthesia. Collectively, our results suggest that hemodynamic changes may occur in the absence of altered flow in forebrain irrigating arteries. Then, altered white matter structure is an early step in SAE pathogenesis that may result either from BBB breakdown or glial cells activation. This study underlies the deleterious effects of a single exposure to isoflurane anesthesia that may be mitigated by a second exposure in sham-operated rats and the effects of CLP-induced systemic inflammation on glial cells that can be attenuated by imaging under isoflurane anesthesia. Barrière hémato-encéphalique Diffusion hydrique Flux sanguin cérébral Glie Ligature et ponction de cecum Marquage des spins artériels Sepsis Arterial spin labeling Blood-brain barrier Cecal ligation and puncture Cerebral blood flow Diffusion magnetic resonance imaging Glia Sepsis
214	Olfactory ensheathing cell mediated mechanisms of neurite outgrowth and axon regeneration Witheford Richter, Miranda 11 1900 (has links) The capacity of the olfactory neuraxis to undergo neuronal replacement and axon targeting following injury, has led to scrutiny concerning the molecular and physical determinants of this growth capacity. This is because injury to the central nervous system, in contrast, leads to permanent disconnection of neurons with targets. Olfactory ensheathing cells (OECs), a specialized glial cell, may contribute to olfactory repair, and have been used to promote recovery from spinal cord injury. However, there mechanisms underlying OEC-induced regeneration are poorly appreciated. To understand these mechanisms, OECs from the lamina propria (LP OECs) or olfactory bulb (OB OECs) were transplanted into a lesion of the dorsolateral funiculus. While both cells demonstrated reparative capacities, LP and OB OECs differentially promoted spinal fibre growth; large-diameter neurofilament-positive, CGRP-positive, and serotonergic fibres sprouted in response to both LP and OB OEC transplantation, whereas substance-P and tyrosine hydroxylase-positive neurons grew more extensively following OB or LP OEC transplantation, respectively. To further understand the growth of spinal cord neurons in response to OECs, a proteomic analysis of OEC secreted factors was performed, identifying secreted protein acidic and rich in cysteines (SPARC) as a mediator of OEC-induced outgrowth in vitro. To test the contributions of SPARC to spinal cord repair after OEC transplantation, cultures of LP OECs from SPARC null and wildtype (WT) mice were transplanted into a crush of the dorsolateral funiculus. Substance P and tyrosine hydroxylase positive axon sprouting was significantly reduced in SPARC null OEC-treated animals, suggesting that individual factors may contribute to OEC-promoted regeneration. To investigate the effect of OECs on corticospinal (CST) neurons, an in vitro assay was developed using postnatal day 8 CST neurons. Coculture of CST neurons with OB OECs produced extensive axon elongation. Application of OB OEC secreted factors increased CST neurite branching, but did not increase axon elongation. In contrast, plating of CST neurons on OB OEC plasma membrane resulted in extensive axon elongation. Furthermore, the OB OEC plasma membrane could overcome CST neurite outgrowth inhibition induced by an outgrowth inhibitor. Together these findings provide insight into OEC mechanisms of neurite outgrowth and axon regeneration. / Medicine, Faculty of / Graduate Spinal cord injury Transplantation Corticospinal Axon guidance Nervous system Proteomics Cell adhesion molecules Plasma membrane Astrocytes Glia Rubrospinal Lesion Angiogenesis Tyrosine hydroxylase Regeneration Olfactory system Osteonectin In vitro
215	A Glia-Mediated Feedback Mechanism for the Termination of Drosophila Visual Response: A Dissertation Guo, Peiyi 09 September 2010 (has links) High temporal resolution of vision relies on the rapid kinetics of the photoresponse in the light-sensing photoreceptor neurons. It is well known that the rapid recovery of photoreceptor membrane potential at the end of light stimulation depends on timely deactivation of the visual transduction cascade within photoreceptors. Whether any extrinsic factor contributes to the termination speed of the photoresponse is unknown. In this thesis, using Drosophilaas a model system, I show that a feedback circuit mediated by both neurons and glia in the visual neuropile lamina is required for rapid repolarization of the photoreceptor at the end of the light response. In the first part of my thesis work, I provide evidence that lamina epithelial glia, the major glia in the visual neuropile, is involved in a retrograde regulation that is critical for rapid repolarization of the photoreceptor at the end of light stimulation. I identified the gene affected in a slrp (slow receptor potential) mutant that is defective in photoreceptor response termination, and found it needs to be expressed in both neurons and epithelial glia to rescue the mutant phenotype. The gene product SLRP, an ADAM (a disintegrin and metalloprotease) protein, is localized in a special structure of epithelial glia, gnarl, and is required for gnarl formation. This glial function of SLRP is independent of the metalloprotease activity. In the second part of my thesis work, I demonstrate that glutamatergic transmission from lamina intrinsic interneurons, the amacrine cells, to the epithelial glia is required for the rapid repolarization of photoreceptors at the end of the light response. From an RNAi-based screen, I identified a vesicular glutamate transporter (vGluT) in amacrine cells as an indispensable factor for the rapid repolarization of the photoreceptor, suggesting a critical role of glutamatergic transmission from amacrine cells in this retrograde regulation. Further, I found that loss of a glutamate-gated chloride channel GluCl phenocopies vGluT downregulation. Cell specific knockdown indicates that GluCl functions in both neurons and glia. In the lamina, a FLAG-tagged GluCl colocalized with the SLRP protein in the gnarl-like structures, and this localization pattern of GluCl depends on SLRP, suggesting that lamina epithelial glia receive glutamatergic input from amacrine cells through GluCl at the site of gnarl. Since the amacrine cell itself is innervated by photoreceptors, these observations suggest that a photoreceptor — amacrine cell — epithelial glia — photoreceptor feedback loop facilitates rapid repolarization of photoreceptors at the end of the light response. In summary, my thesis research has revealed a feedback regulation mechanism that helps to achieve rapid kinetics of photoreceptor response. This visual regulation contributes to the temporal resolution of the visual system, and may be important for vision during movement and for motion detection. In addition, this work may also advance our understanding of glial function, and change our concept about the effect of glutamatergic transmission. Drosophila visual response glia Neuroglia Photoreceptor Cells Invertebrate Feedback Physiological Kinetics Vision Ocular Animal Experimentation and Research Cells Nervous System Neuroscience and Neurobiology Psychological Phenomena and Processes Sense Organs
216	Magnetic Nanoparticle Hyperthermia-Mediated Clearance of Beta-amyloid Plaques: Implications in the Treatment of Alzheimer’s Disease Dyne, Eric D. 20 April 2021 (has links) No description available. Biomedical Engineering Biomedical Research Nanotechnology Nanoscience Neurobiology Neurosciences Neurology Nanoparticles microglia Alzheimers disease beta amyloid electron microscopy glia neurodegeneration biomedical engineering immunology alternating magnetic field heat shock protein autophagy endocytosis morphology neuroinflammation
217	Organisation anatomique et rôle du couplage astrocytaire dans l’activité rythmique du noyau sensoriel du trijumeau Couillard-Larocque, Marc 04 1900 (has links) De nombreuses fonctions cérébrales dépendent de la capacité de réseaux de neurones à générer une activité rythmique. Les réseaux neuronaux, nommés générateurs de patron centraux (GPCs), contrôlant les patrons de mouvements répétitifs comme la locomotion, la respiration et la mastication en sont un exemple important. Des travaux antérieurs ont montré que le noyau sensoriel principal du trijumeau (NVsnpr), qui fait partie du GPC de la mastication, contient des neurones qui peuvent décharger de façon rythmique et que les astrocytes et leur protéine S100ß étaient nécessaires pour cette rythmogénèse neuronale. Cependant, l’effet de l’activation directe des astrocytes sur la décharge des neurones du NVsnpr n’a jamais été investigué. De plus, comme les astrocytes forment des réseaux bien définis dans le NVsnpr, nous avons émis l’hypothèse que l’activation de ces réseaux pourrait contribuer à synchroniser l’activité rythmique de groupes de neurones. Pour investiguer ces deux questions, nous avons utilisé des enregistrements en mode cellules entières de neurones et d’astrocytes du NVsnpr lors de stimulations optogénétiques des astrocytes chez des souris transgéniques. Différentes lignées de souris transgéniques ont été utilisées pour exprimer des protéines photosensibles comme la channelrhodopsin (ChR2) ou le récepteur adrénergique α-1 dans les astrocytes du NVsnpr dans le but de pouvoir les stimuler par l’exposition à la lumière. De ces lignées, seul le croisement de souris S100β-Cre à des souris ChR2-lox donna des réponses significatives. Ces résultats démontrent que la stimulation optogénétique des astrocytes du NVsnpr cause divers effets sur la décharge neuronale, dont la genèse de bouffées rythmiques. Cependant, l’enregistrement de paires de neurones n’a pas permis de confirmer l’implication des astrocytes dans la synchronisation de l’activité rythmique des neurones de NVsnpr. Ces résultats permettent d’affiner les méthodes d’études des astrocytes dans le système trigéminal ainsi que de confirmer l’implication des astrocytes dans une activité rythmique, une implication qui pourrait potentiellement être observée dans d’autres structures du système nerveux central comme les GPCs de la locomotion ou de la respiration. / Several cerebral functions depend on the capacity of neural network to generate a rhythmic activity. One prominent example of this is the neural networks, named central pattern generators (CPGs), controlling repetitive movements patterns like locomotion, breathing and chewing. Previous studies have shown that the trigeminal main sensory nucleus (NVsnpr), which is part of the masticatory CPG, contains neurons that can rhythmically discharge and that the astrocytes and their protein, S100β, were essential for this neuronal rhythmogenesis. However, the effect of the activation of astrocytes on neuronal discharge of the NVsnpr remains uninvestigated. Additionally, since astrocytes form well-defined networks in the NVsnpr, we hypothesized that the activation of these networks could help synchronize the rhythmic activity of groups of neurons. To investigate these questions, we used whole cell recordings of neurons and astrocytes of the NVsnpr during optogenetic stimulation of astrocytes in transgenic mice. Different mice strains have been used to express photosensitive proteins such as channelrhodopsin (ChR2) or the α-1 adrenegic receptor in NVsnpr astrocytes to enable their stimulation with light. Of all these strains, only the S100β-Cre X ChR2-lox hybrids provided significant responses. Optogenetic stimulation of NVsnpr astrocytes produced various effects on neuronal discharge, including the genesis of rhythmic bursts. However, the recording of pairs of neurons did not confirm the involvement of astrocytes in the synchronization of the rhythmic activity of NVsnpr neurons. These results contribute to the refinement of methods used to study astrocytes in the trigeminal system and confirm the involvement of astrocytes in rhythmogenesis, an involvement that could be observed in other structures of the central nervous system such as the CPGs for respiration or locomotion. Mastication Générateurs de patrons centraux Communication neurone-glie Noyau sensoriel principal du trijumeau S100β Optogénétique Central pattern generator Neuron-Glia Communication Trigeminal main sensory nucleus Optogenetic
218	Regeneration and plasticity of descending propriospinal neurons after transplantation of Schwann cells overexpressing glial cell line-derived neurotrophic factor following thoracic spinal cord injury in adult rats Deng, Lingxiao 18 May 2015 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / After spinal cord injury (SCI), poor axonal regeneration of the central nervous system, which mainly attributed to glial scar and low intrinsic regenerating capacity of severely injured neurons, causes limited functional recovery. Combinatory strategy has been applied to target multiple mechanisms. Schwann cells (SCs) have been explored as promising donors for transplantation to promote axonal regeneration. Among the central neurons, descending propriospinal neurons (DPSN) displayed the impressive regeneration response to SCs graft. Glial cell line-derived neurotrophic factor (GDNF), which receptor is widely expressed in nervous system, possesses the ability to promote neuronal survival, axonal regeneration/sprouting, remyelination, synaptic formation and modulate the glial response. We constructed a novel axonal permissive pathway in rat model of thoracic complete transection injury by grafting SCs over-expressing GDNF (SCs-GDNF) both inside and caudal to the lesion gap. Behavior evaluation and histological analyses have been applied to this study. Our results indicated that tremendous DPSN axons as well as brain stem axons regenerated across the lesion gap back to the caudal spinal cord. In addition to direct promotion on axonal regeneration, GDNF also significantly improved the astroglial environment around the lesion. These regenerations caused motor functional recovery. The dendritic plasticity of axotomized DPSN also contributed to the functional recovery. We applied a G-mutated rabies virus (G-Rabies) co-expressing green fluorescence protein (GFP) to reveal Golgi-like dendritic morphology of DPSNs and its response to axotomy injury and GDNF treatment. We also investigated the neurotransmitters phenotype of FluoroGold (FG) labeled DPSNs. Our results indicated that over 90 percent of FG-labeled DPSNs were glutamatergic neurons. DPSNs in sham animals had a predominantly dorsal-ventral distribution of dendrites. Transection injury resulted in alterations in the dendritic distribution, with dorsal-ventral retraction and lateral-medial extension of dendrites. Treatment with GDNF significantly increased the terminal dendritic length of DPSNs. The density of spine-like structures was increased after injury and treatment with GDNF enhanced this effect. Axonal regeneration Descending propriospinal tract G-rabies virus Schwann cell Spinal cord injury Central nervous system -- regeneration Axons -- physiology Central nervous system -- Physiology Nervous system -- Regeneration Spinal cord -- Wounds and injuries Neuroglia
219	The Development and Regeneration of the Serotonergic System Hawthorne, Alicia Lynn 06 July 2010 (has links) No description available. Biology Biomedical Research Cellular Biology Neurology Scientific Imaging Surgery serotonin 5-HT migration somal translocation chondroitin sulfate proteoglycan ischemia sprouting glia GAP-43 beta1 integrin laminin dynamin non-muscle myosin II kinesin slice culture Pet-1 growth cone
220	Regulation of mammalian spinal locomotor networks by glial cells Acton, David January 2017 (has links) Networks of interneurons within the spinal cord coordinate the rhythmic activation of muscles during locomotion. These networks are subject to extensive neuromodulation, ensuring appropriate behavioural output. Astrocytes are proposed to detect neuronal activity via Gαq-linked G-protein coupled receptors and to secrete neuromodulators in response. However, there is currently a paucity of evidence that astrocytic information processing of this kind is important in behaviour. Here, it is shown that protease-activated receptor-1 (PAR1), a Gαq-linked receptor, is preferentially expressed by glia in the spinal cords of postnatal mice. During ongoing locomotor-related network activity in isolated spinal cords, PAR1 activation stimulates release of adenosine triphosphate (ATP), which is hydrolysed to adenosine extracellularly. Adenosine then activates A1 receptors to reduce the frequency of locomotor-related bursting recorded from ventral roots. This entails inhibition of D1 dopamine receptors, activation of which enhances burst frequency. The effect of A1 blockade scales with network activity, consistent with activity-dependent production of adenosine by glia. Astrocytes also regulate activity by controlling the availability of D-serine or glycine, both of which act as co-agonists of glutamate at N-methyl-D-aspartate receptors (NMDARs). The importance of NMDAR regulation for locomotor-related activity is demonstrated by blockade of NMDARs, which reduces burst frequency and amplitude. Bath-applied D-serine increases the frequency of locomotor-related bursting but not intense synchronous bursting produced by blockade of inhibitory transmission, implying activity-dependent regulation of co-agonist availability. Depletion of endogenous D-serine increases the frequency of locomotor-related but not synchronous bursting, indicating that D-serine is required at a subset of NMDARs expressed by inhibitory interneurons. Blockade of the astrocytic glycine transporter GlyT1 increases the frequency of locomotor-related activity, but application of glycine has no effect, indicating that GlyT1 regulates glycine at excitatory synapses. These results indicate that glia play an important role in regulating the output of spinal locomotor networks.

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