Global ETD Search

141	Caractérisation de divers effets biologiques provoqués par la gastrine au niveau de gliomes et de gliosarcomes expérimentaux Lefranc, Florence 31 January 2005 (has links) Les gliomes malins sont caractérisés par une prolifération importante, une migration diffuse des astrocytes tumoraux dans le parenchyme cérébral et un taux important de néo-angiogenèse. La gastrine appartient à la famille des peptides apparentés à la cholécystokinine et cette dernière est présente en abondance dans le cerveau. De plus la gastrine est capable de modifier le comportement biologique d’un certain nombre de tumeurs. Le groupe de recherche au sein duquel j’ai réalisé mon travail de thèse fut le premier à suggérer le rôle potentiel de la gastrine au niveau des taux de prolifération et de migration des astrocytes tumoraux. Nous avons précisé dans le présent travail divers effets biologiques provoqués par la gastrine au niveau de gliomes et de gliosarcome expérimentaux.<p>Nous avons au préalable tenté de caractériser par une technique de RT-PCR l’expression d’ARN pour divers récepteurs à la gastrine au sein de tumeurs du système nerveux central et périphérique (comprenant des gliomes, des méningiomes et des schwannomes), au sein de gliomes et d’un gliosarcome expérimentaux, et au sein de cellules endothéliales humaines de veines ombilicales HUVEC et de manchons vasculaires obtenus par microdissection au laser d’un glioblastome humain. Nous avons également développé un modèle de neurochirurgie expérimentale chez le rat consistant en la résection microchirurgicale de la tumeur cérébrale après un bilan iconographique par IRM. Nous avons ainsi montré que l’administration de gastrine dans le foyer opératoire après résection tumorale augmente significativement la période de survie de rats immunodéficients porteurs du modèle de gliome humain U373 et de rats conventionnels porteurs du modèle C6 de rat. In vitro, nous avons montré grâce au test colorimétrique MTT que la gastrine induit une diminution significative du taux global de croissance de ces deux modèles avec une accumulation des astrocytes tumoraux dans la phase G1 de leur cycle cellulaire. Par la technique de Western blotting nous avons également montré que la gastrine induit une diminution significative des taux protéiques du complexe cycline D3-Cdk4 dans les deux modèles expérimentaux. Nous avons montré que la gastrine est capable de réduire significativement l’invasion des modèles C6 de rat, U373 humain et de gliosarcome 9L de rat au travers d’une matrice de collagène et de réduire l’invasion des cellules U373 en chambre de Boyden. La gastrine modifie également significativement la motilité des cellules C6 et U373 et l’organisation de leur cytosquelette d’actine.<p>Nous avons découvert que la gastrine administrée en intracérébral dans le foyer tumoral U373 augmente significativement le taux d’angiogenèse au sein de la tumeur. Nous avons alors investigué l’effet de la gastrine et des antagonistes des récepteurs à cholécystokinine sur le taux d’angiogenèse in vitro en utilisant le modèle des cellules HUVEC cultivées sur Matrigel. L’effet pro-angiogénique in vitro et in vivo de la gastrine est significativement contrecarré par le produit L365,260, un antagoniste relativement spécifique du récepteur CCK-B de la gastrine. La gastrine est chémoattractante sur les cellules HUVEC et augmente significativement leur sécrétion d’IL-8. Toutefois l’effet pro-angiogénique de la gastrine serait en partie dépendant de la modification du taux d’expression des sélectines par les cellules HUVEC, et non de la sécrétion d’IL-8. Nous avons réalisé une revue de la littérature pour tenter de comprendre pourquoi les astrocytes tumoraux migrants sont résistants à la chimiothérapie conventionnelle. A la fin du chapitre Discussion, dans le sous-chapitre intitulé « Quels sont les espoirs thérapeutiques dans le cas des gliomes dits diffus? », nous tentons d’analyser les implications thérapeutiques potentielles qu’il serait possible de tirer du présent travail. <p><p><p> / Doctorat en sciences médicales / info:eu-repo/semantics/nonPublished Médecine pathologie humaine Gastrin Cholecystokinin Gliomas Astrocytomas Neuroglia Nervous system -- Tumors Gastrine Cholécystokinine Gliome Astrocytomes Névroglie Système nerveux -- Tumeurs gliomes malins gastrine
142	Role of CG9650 in Neuronal Development And Function of Drosophila Melanogaster Murthy, 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. Drosophila melanogaster Neurons Developmental Neurology CG9650 Gene Neural Stem Cells Drosophila Neurogenesis Neuronal Development Glial Cells Neuroglia D. melanogaster Molecular Biology
143	The Drosophila Homolog of the Intellectual Disability Gene ACSL4 Acts in Glia to Regulate Morphology and Neuronal Activity: A Dissertation Quigley, Caitlin M. 15 July 2016 (has links) Recent developments in neurobiology make it clear that glia play fundamental and active roles, in the adult and in development. Many hereditary cognitive disorders have been linked to developmental defects, and in at least two cases, Rett Syndrome and Fragile X Mental Retardation, glia are important in pathogenesis. However, most studies of developmental disorders, in particular intellectual disability, focus on neuronal defects. An example is intellectual disability caused by mutations in ACSL4, a metabolic enzyme that conjugates long-chain fatty acids to Coenzyme A (CoA). Depleting ACSL4 in neurons is associated with defects in dendritic spines, a finding replicated in patient tissue, but the etiology of this disorder remains unclear. In a genetic screen to discover genes necessary for visual function, I identified the Drosophila homolog of ACSL4, Acsl, as a gene important for the magnitude of neuronal transmission, and found that it is required in glia. I determined that Acsl is required in a specific subtype of glia in the Drosophila optic lobe, and that depletion of Acsl from this population causes morphological defects. I demonstrated that Acsl is required in development, and that the phenotype can be rescued by human ACSL4. Finally, I discovered that ACSL4 is expressed in astrocytes in the mouse hippocampus. This study is highly significant for understanding glial biology and neurodevelopment. It provides information on the role of glia in development, substantiates a novel role for Acsl in glia, and advances our understanding of the potential role that glia play in the pathogenesis of intellectual disability. Drosophila intellectual disability ACSL4 Dissertations, UMMS Coenzyme A Ligases Developmental Disabilities Intellectual Disability Neuroglia Neurons Developmental Neuroscience Nervous System Diseases
144	Molecular Pathways Mediating Glial Responses during Wallerian Degeneration: A Dissertation Lu, Tsai-Yi 14 May 2015 (has links) Glia are the understudied brain cells that perform many functions essential to maintain nervous system homeostasis and protect the brain from injury. If brain damage occurs, glia rapidly adopt the reactive state and elicit a series of cellular and molecular events known as reactive gliosis, the hallmark of many neurodegenerative diseases. However, the molecular pathways that trigger and regulate this process remain poorly defined. The fruit fly Drosophila melanogaster has glial cells that are strikingly similar to mammalian glia, and which also exhibit reactive responses after neuronal injury. By exploiting its powerful genetic toolbox, we are uniquely positioned to identify the genes that activate and execute glial responses to neuronal injury in vivo. In this dissertation, I use Wallerian degeneration in Drosophila as a model to characterize molecular pathways responsible for glia to recognize neural injury, become activated, and ultimately engulf and degrade axonal debris. I demonstrate a novel role for the GEF (guanine nucleotide exchange factors) complex DRK/DOS/SOS upstream of small GTPase Rac1 in glial engulfment activity and show that it acts redundantly with previously discovered Crk/Mbc/dCed-12 to execute glial activation after axotomy. In addition, I discovered an exciting new role for the TNF receptor associated factor 4 (TRAF4) in glial response to axon injury. I find that interfering with TRAF4 and the downstream kinase misshapen (msn) function results in impaired glial activation and engulfment of axonal debris. Unexpectedly, I find that TRAF4 physically associates with engulfment receptor Draper – making TRAF4 only second factor to bind directly to Draper – and show it is essential for Draper-dependent activation of downstream engulfment signaling, including transcriptional activation of engulfment genes via the JNK and STAT transcriptional cascades. All of these pathways are highly conserved from Drosophila to mammals and most are known to be expressed in mouse brain glia, suggesting functional conservation. My work should therefore serve as an excellent starting point for future investigations regarding their roles in glial activation/reactive gliosis in various pathological conditions of the mammalian central nervous system. Axons Drosophila melanogaster Neuroglia Neurodegenerative Diseases Neurons Wallerian Degeneration Guanine Nucleotide Exchange Factors TNF Receptor-Associated Factor 4 Dissertations, UMMS Molecular and Cellular Neuroscience Neuroscience and Neurobiology
145	Cellular and Molecular Mechanisms Driving Glial Engulfment of Degenerating Axons: A Dissertation Doherty, Johnna E. 14 November 2011 (has links) The nervous system is made up of two major cell types, neurons and glia. The major distinguishing feature between neuronal cells and glial cells is that neurons are capable of transmitting action potentials while glial cells are electrically incompetent. For over a century glial cells were neglected and it was thought they existed merely to provide trophic and structural support to neurons. However, in the past few decades it has become increasingly clear that glial cell functions underlie almost all aspects of nervous system development, maintenance, and health. During development, glia act as permissive substrates for axons, provide guidance cues, regulate axon bundling, facilitate synapse formation, refine synaptic connections, and promote neuronal survival. In the mature nervous system glial cells regulate adult neurogenesis through phagocytosis, act as the primary immune cell, and contribute to complex processes such as learning and memory. In recent years, glial cells have also become a primary focus in the study of neurodegenerative diseases. Mounting evidence shows that glial cells exert both beneficial as well as detrimental effects in the pathology of several nervous system disorders, and modulation of glial activity is emerging as a viable therapeutic strategy for many diseases. Although glial cells are critical to the proper development and functioning of the nervous system, there is still relatively little known about the molecular mechanisms used by glial cells, how they exert their effects on neurons, and how glia and neurons communicate. Despite the relative simplicity and small size of the Drosophila nervous system, glial cell organization and function in flies shows a remarkable complexity similar to vertebrate glial cells. In this study I use Drosophila as a model organism to study cellular and molecular mechanisms of glial clearance of axonal debris after acute axotomy. In chapter two of this thesis, I characterize three distinct subtypes of glial cells in the adult brain; cell body glia which ensheath neuronal cell bodies in the cortex region of the brain, astrocyte like glial cells which bear striking morphological similarity to mammalian astrocytes and share common molecular components, and ensheathing glial cells which I show act as the primary phagocytic cell type in the neuropil region of the brain. In addition, I identify dCed-6, the ortholog of mammalian GULP, as a necessary component of the glial phagocytic machinery. In chapter three of this thesis, I perform a candidate based, in vivo, RNAi screen to identify novel genes involved in the glial engulfment of degenerating axon material. The Gal4/UAS system was used to drive UAS-RNAi for approximately 300 candidate genes with the glial specific repo-Gal4 driver. Two assays were used as a readout in this screen, clearance of axon material five days after injury, and Draper upregulation one day after maxillary palp or antennal injury. Overall, I identified 20 genes which, when knocked down specifically in glial cells, result in axon clearance defects after injury. Finally, in chapter four I identify Stat92E as a novel glial gene required for glial phagocytic function. I show that Stat92E regulates both basal and injury induced Draper expression. Injury-induced Draper expression is transcriptionally regulated through a Stat92E dependent non-canonical signaling mechanism whereby signaling through the Draper receptor activates Stat92E which in turn transcriptionally activates draper through a binding site located in the first intron of Draper. Draper represents only the second receptor known to positively regulate Stat92E transcriptional activity under normal physiological conditions. Neuroglia Neurons Drosophila Proteins Axons Amino Acids, Peptides, and Proteins Animal Experimentation and Research Cells Nervous System Neuroscience and Neurobiology
146	A Role for c-Jun Kinase (JNK) Signaling in Glial Engulfment of Degenerating Axons: A Dissertation MacDonald, Jennifer M. 07 June 2012 (has links) The central nervous system (CNS) is composed of two types of cells: neurons that send electrical signals to transmit information throughout the animal and glial cells. Glial cells were long thought to be merely support cells for the neurons; however, recent work has identified many critical roles for these cells during development and in the mature animal. In the CNS, glial cells act as the resident immune cell and they are responsible for the clearance of dead or dying material. After neuronal injury or death, glial cells become reactive, exhibiting dramatic changes in morphology and patterns of gene expression and ultimately engulfing neuronal debris. This rapid clearance of degenerating neuronal material is thought to be crucial for suppression of inflammation and promotion of functional recovery, but molecular pathways mediating these engulfment events remain poorly defined. Drosophila melanogaster is a genetically tractable model system in which to study glial biology. It has been shown that Drosophila glia rapidly respond to axonal injury both morphologically and molecularly and that they ultimately phagocytose the degenerating axonal debris. This glial response to axonal debris requires the engulfment receptor Draper and downstream signaling molecules dCed-6, Shark, and Rac1. However, much remains unknown about the molecular details of this response. In this thesis I show that Drosophila c-Jun kinase (dJNK) signaling is a critical in vivo mediator of glial engulfment activity. In response to axotomy, glial dJNK signals through a cascade involving the upstream MAPKKKs Slipper and TAK1, the MAPKK MKK4, and ultimately the Drosophila AP-1 transcriptional complex composed of JRA and Kayak to initiate glial phagocytosis of degenerating axons. Interestingly, loss of dJNK also blocked injury-induced up-regulation of Draper levels in glia and glial-specific over-expression of Draper was sufficient to rescue phenotypes associated with loss of dJNK signaling. I have identified the dJNK pathway as a novel mediator of glial engulfment activity and show that a primary role for the glial Slipper/Tak1→MKK4→dJNK→dAP-1 signaling cascade is activation of draper expression after axon injury. Neuroglia Axons Phagocytosis Nerve Degeneration JNK Mitogen-Activated Protein Kinases Drosophila melanogaster Amino Acids, Peptides, and Proteins Animal Experimentation and Research Cells Enzymes and Coenzymes Nervous System Neuroscience and Neurobiology
147	Role of Glia in Sculpting Synaptic Connections at the Drosophila Neuromuscular Junction: A Dissertation Fuentes Medel, Yuly F. 27 January 2012 (has links) Emerging evidence in both vertebrates and invertebrates is redefining glia as active players in the development and integrity of the nervous system. The formation of functional neuronal circuits requires the precise addition of new synapses. Mounting evidence implicates glial function in synapse remodeling and formation. However, the precise molecular mechanisms governing these functions are poorly understood. My thesis work begins to define the molecular mechanisms by which glia communicate with neurons at the Drosophila neuromuscular junction (NMJ). During development glia play a critical role in remodeling neuronal circuits in the CNS. In order to understand how glia remodel synapses, I manipulated a key component of the glial engulfment machinery, Draper. I found that during normal NMJ growth presynaptic boutons constantly shed membranes or debris. However, a loss of Draper resulted in an accumulation of debris and ghost boutons, which inhibited synaptic growth. I found that glia use the Draper pathway to engulf these excess membranes to sculpt synapses. Surprisingly, I found that muscle cells function as phagocytic cells as well by eliminating immature synaptic ghost boutons. This demonstrates that the combined efforts of glia and muscle are required for the addition of synapses and proper growth. My work establishes that glia play a crucial role in synapse development at the NMJ and suggests that there are other glial-derived molecules that regulate synapse function. I identified one glial derived molecule critical for the development of the NMJ, a TGF-β ligand called Maverick. Presynaptically, Maverick regulates the activation of BMP pathway confirmed by reducing the transcription of the known target gene Trio. Postsynaptically, it regulates the transcription of Glass bottom boat (Gbb) in the muscle suggesting that glia modulate the function of Gbb and consequently the activation of the BMP retrograde pathway at NMJ. Surprisingly, I also found that glial Maverick regulates the transcription of Shaker potassium channel, suggesting that glia potentially could regulate muscle excitability and consequently modulate synaptic transmission. Future work will elucidate such hypothesis. My work has demonstrated two novel roles for glia at the NMJ. First is that glia engulfing activity is important for proper synaptic growth. Second is that the secretion of glial-derived molecules are required to orchestrate synaptic development. This further supports that glia are critical active players in maintaining a functional nervous system. Drosophila Drosophila Proteins Neuroglia Neuromuscular Junction Presynaptic Terminals Synapses Synaptic Transmission Amino Acids, Peptides, and Proteins Animal Experimentation and Research Cells Nervous System Neuroscience and Neurobiology
148	La galectine-1 influence fortement les caractéristiques biologiques des cellules gliales tumorales humaines / Galectin-1 strongly affects the biological caracteristics of human glial tumor cells. Le Mercier, Marie 20 May 2009 (has links) Comme décrit dans la partie But du Travail, les tumeurs gliales sont particulièrement agressives d’un point de vue clinique. Le glioblastome, qui correspond au grade de malignité le plus élevé des gliomes, est associé à un pronostic très sombre car aucun patient atteint de ce cancer n’a pu être guéri à ce jour. Ces tumeurs envahissent de manière diffuse (par essaimage de cellules tumorales isolées) le parenchyme cérébral, ce qui empêche une résection chirurgicale complète de la tumeur. De plus, les cellules tumorales gliales d’origine astrocytaire sont souvent résistantes à l’apoptose et donc aux thérapies adjuvantes telles que la chimiothérapie et la radiothérapie. La galectine-1 est une petite protéine intervenant directement dans les processus migratoires des cellules gliales tumorales. Nous avons donc poursuivi la caractérisation des rôles biologiques que pourrait exercer la galectine-1 au sein des gliomes.<p>Nous avons tout d’abord montré que la galectine-1 est impliquée dans la chimiorésistance des gliomes. En effet, nous avons démontré que la diminution du taux d’expression de la galectine-1, au moyen d’un siRNA au sein d’un modèle de gliome expérimental, permet d’augmenter le bénéfice thérapeutique du témozolomide in vivo sans toutefois induire d’apoptose, d’autophagie ou de perméabilisation de la membrane des lysosomes. Nous avons également montré que la diminution du taux d’expression de la galectine-1 au sein de ce modèle de gliome expérimental affecte les processus d’angiogenèse in vivo et de « vasculogenic mimicry » in vitro. Nous avons identifié la protéine ORP150 comme l’une des principales cibles de l’effet pro-angiogénique de la galectine-1, sachant que la protéine ORP150 contrôle la maturation du facteur VEGF. Nous avons ensuite montré que le rôle de la galectine-1 dans la chimiorésistance des gliomes et dans l’angiogenèse est directement lié à l’implication de la galectine-1 dans le processus de réponse au stress du réticulum endoplasmique. Via ce processus, la galectine-1 modulerait l’expression d’un certain nombre de gènes tels que ATF3, DUSP5 et HERP, qui sont impliqués dans la chimiorésistance et des gènes tels que ORP150 et MDG1 qui sont impliqués dans l’angiogenèse. <p>Enfin, nous avons également montré que la galectine-1 régule l’expression du gène BEX2 et que celui-ci joue un rôle important dans la biologie des gliomes, notamment dans les processus d’angiogenèse et de migration cellulaire. <p>En conclusion, notre travail suggère que l’étiquette « biomarqueur » pourrait être attribuée à la galectine-1 pour qualifier l’agressivité biologique des gliomes malins et que la galectine-1 pourrait représenter une nouvelle cible thérapeutique dans le combat contre les gliomes malins en général, et le glioblastome en particulier.<p> / Doctorat en Sciences biomédicales et pharmaceutiques / info:eu-repo/semantics/nonPublished Sciences pharmaceutiques Neuroglia -- Tumors Gliomas Drug resistance Lectins Névroglie -- Tumeurs Gliome Résistance aux médicaments Lectines BEX2 gliomes Galectine-1 chimiorésistance angiogenèse
149	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
150	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

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