Global ETD Search

151	Vliv stochastického chování iontových kanálů na přenos signálu a informace na excitabilních neuronálních membránách / The influence of stochastic behaviour of ion channels on the signal and information transfer at excitable neuronal membranes Šejnová, Gabriela January 2017 (has links) The stochastic behavior of voltage-gated ion channels causes fluctuations of conductances and voltages across neuronal membranes, contributing to the neuronal noise which is ubiquitous in the nervous system. While this phenomenon can be observed also on other parts of the neuron, here we concentrated on the axon and the way the channel noise influences axonal input-output characteristics. This was analysed by working with our newly created computational compartmental model, programmed in Matlab environment, built up using the Hodgkin-Huxley mathematical formalism and channel noise implemented via extended Markov Chain Monte Carlo method. The model was thoroughly verified to simulate plausibly a mammalian axon of CA3 neuron. Based on our simulations, we confirmed quantitatively the findings that the channel noise is the most prominent on membranes with smaller number of Na+ and K+ channels and that it majorly increases the variability of travel times of action potentials (APs) along axons, decreasing thereby the temporal precision of APs. The simulations analysing the effect of axonal demyelination and axonal diameter correlated well with other finding referred in Literature. We further focused on spike pattern and how is its propagation influenced by inter-spike intervals (ISI). We found, that APs fired...
152	Myélinisation des projections corticales visuelles de la souris Roy, Jolanie 10 1900 (has links) La gaine de myéline qui entoure les axones joue plusieurs rôles, comme l’accélération de la propagation de l’influx nerveux, la synchronisation des aires corticales, la plasticité, un support métabolique, etc. Sa dégénérescence lors de certaines pathologies, comme la sclérose en plaques, cause d’importants problèmes dont des déficits de la coordination motrice et de la démence. C’est pourquoi il est important de comprendre l’origine et la nature des axones myélinisés. L’objectif de ce mémoire est de voir si les axones des projections sensorielles corticocorticales sont myélinisés. Pour ce faire, des injections de Phaseolus vulgaris leucoagglutinine (Phal), un traceur neuronal antérograde, ont été faites dans le cortex visuel primaire de la souris. Les axones marqués et la gaine de myéline ont été révélés avec de l’immunohistochimie dirigée contre le Phal et la protéine de base de la myéline (MBP) respectivement. Les coupes ont été observées au microscope confocal pour chercher la colocalisation de Phal et MBP, qui indiquerait la présence d’axones myélinisés. Plusieurs axones corticocorticaux ipsilatéraux cheminent dans la matière grise. De ces axones, étonnamment peu d’axones myélinisés ont été trouvés. La myélinisation des axones qui s’engageaient dans la matière blanche a été plus difficile à déterminer avec certitude. Certains segments d’axones Phal+ clairement sans myéline ont été observés. Puisque la densité de MBP de la matière blanche était trop élevée, il était impossible de déterminer la colocalisation du Phal et MBP sur des axones individuels. La microscopie électronique a permis de voir des axones marqués individuellement myélinisés dans la matière blanche. / Myelin that ensheathes neuronal axons plays many roles. It increases propagation speed of action potentials and contributes to synchronizing activity between cortical areas. Myelin is plastic and provides a metabolic support for axons. Many diseases, like multiple sclerosis, are linked to the loss of the myelin sheath around axons. For that, it is important to better understand the nature of myelinated axons. Our objective here is to determine whether axons of sensory cortico-cortical projections, are myelinated. To achieve this goal, injections of the anterograde neuronal tracer, leucoagglutinin of Phaseolus vulgaris (Phal) were made in the primary visual cortex of mice. Double immunohistochemistry was used to reveal axons labeled with Phal combined with visualisation of the myelin basic protein (MBP). Sections were observed under a confocal microscope to find colocalization of Phal and MBP staining. Many ipsilateral corticocortical axons travel in the gray matter. Of these, surprisingly few myelinated axons were seen. Determining myelination of Phal labeled axons within the white matter tracts and external capsule was more difficult. The MBP staining of white matter was too dense to allow to unambiguously determine whether individual axons were myelinated. However, some clearly unmyelinated axons were observed therein. To solve this ambiguity, electron microscopic analysis was performed. Myelinated Phal-labeled axons were observed in the EC with electron microscopy. Cortex visuel Myéline Phaseolus vulgaris leucoagglutinine Souris Axones Traçage Myéloarchitecture MBP Visual cortex Myelin Phaseolus vulgaris leucoagglutinin Mice Axons Tracing Myeloarchitecture
153	Dissecting Signaling Pathways that Regulate Axonal Guidance Effects of Sonic Hedgehog: A Dissertation Guo, Daorong 24 March 2011 (has links) During development, axons respond to a variety of guidance cues in the environment to navigate to the proper targets. Sonic hedgehog (Shh), a classical morphogen, has been shown to function as a guidance factor that directly acts on the growth cones of various types of axons. We previously found that Shh affects retinal ganglion cell (RGC) axonal growth and navigation in a concentration-dependent manner. However, the signaling pathways that mediate such events are still unclear. In this thesis, we show that high concentrations of Shh induce growth cone collapse and repulsive turning of the chick RGC through rapid increase of Ca2+ in the growth cone, and specific activation of PKCα and Rho signaling pathways. We further found that integrin linked kinase (ILK) acts as an immediate downstream effector of PKCα. PKCα directly phosphorylates ILK in vitro at two previously unidentified sites threonine-173 and -181. Inhibition of PKCα, Rho, and ILK by pharmacological inhibitors and/or dominant-negative approaches abolished the negative effects of high-concentration of Shh. We provide evidence that Rho likely functions downstream of PKC and suggest that PKC, Rho and ILK may cooperatively mediate the negative effects of high concentrations of Shh. Furthermore, retroviral expression of dominant-negative constructs of PKCα (DN-PKCα) and ILK-double mutants (ILK-DM) resulted in misguidance of RGC axons at the optic chiasm in vivo. These results demonstrate that new signaling pathways composed of PKCα, Rho, and ILK play an important role in Shh-induced axonal chemorepulsion. In contrast, we show that attractive axonal turning in response to low concentrations of Shh is independent of PKCα, but requires the activity of cyclic nucleotides cAMP. Taken together, our results suggest that the opposing effects of Shh on axon guidance are mediated by different signaling pathways. Hedgehog Proteins Axons Retinal Ganglion Cells Amino Acids, Peptides, and Proteins Cell and Developmental Biology Cells Enzymes and Coenzymes Sense Organs
154	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
155	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
156	Axon Death Prevented: Wld<sup>s</sup> and Other Neuroprotective Molecules: A Dissertation Avery, Michelle A. 13 December 2010 (has links) A common feature of many neuropathies is axon degeneration. While the reasons for degeneration differ greatly, the process of degeneration itself is similar in most cases. Axon degeneration after axotomy is termed ‘Wallerian degeneration,’ whereby injured axons rapidly fragment and disappear after a short period of latency (Waller, 1850). Wallerian degeneration was thought to be a passive process until the discovery of the Wallerian degeneration slow (Wlds) mouse mutant. In these mice, axons survive and function for weeks after nerve transection. Furthermore, when the full-length protein is inserted into mouse models of disease with an axon degeneration phenotype (such as progressive motor neuronopathy), Wlds is able to delay disease onset (for a review, see Coleman, 2005). Wlds has been cloned and was found to be a fusion event of two neighboring genes: Ube4b, which encodes an ubiquitinating enzyme, and NMNAT-1 (nicotinamide mononucleotide adenylyltransferase-1), which encodes a key factor in NAD (nicotinamide adenine dinucleotide) biosynthesis, joined by a 54 nucleotide linker span (Mack et al., 2001). To address the role of Wlds domains in axon protection and to characterize the subcellular localization of Wlds in neurons, our lab developed a novel method to study Wallerian degeneration in Drosophila in vivo (MacDonald et al., 2006). Using this method, we have discovered that mouse Wlds can also protect Drosophila axons for weeks after acute injury, indicating that the molecular mechanisms of Wallerian degeneration are well conserved between mouse and Drosophila. This observation allows us to use an easily manipulated genetic model to move the Wlds field forward; we can readily identify what Wlds domains give the greatest protection after injury and where in the neuron protection occurs. In chapter two of this thesis, I identify the minimal domains of Wlds that are needed for protection of severed Drosophila axons: the first 16 amino acids of Ube4b fused to Nmnat1. Although Nmnat1 and Wlds are nuclear proteins, we find evidence of a non-nuclear role in axonal protection in that a mitochondrial protein, Nmnat3, protects axons as well as Wlds. In chapter 3, I further explore a role for mitochondria in Wlds-mediated severed axon protection and find the first cell biological changes seen in a Wlds-expressing neuron. The mitochondria of Wlds- and Nmnat3-expressing neurons are more motile before injury. We find this motility is necessary for protection as suppressing the motility with miro heterozygous alleles suppresses Wldsmediated axon protection. We also find that Wlds- and Nmnat3- expressing neurons show a decrease in calcium fluorescent reporter, gCaMP3, signal after axotomy. We propose a model whereby Wlds, through production of NAD in the mitochondria, leads to an increase in calcium buffering capacity, which would decrease the amount of calcium in the cytosol, allowing for more motile mitochondria. In the case of injury, the high calcium signal is buffered more quickly and so cannot signal for the axon to die. Finally, in chapter 4 of my thesis, I identify a gene in an EMS-based forward genetic screen which can suppress Wallerian degeneration. This mutant is a loss of function, which, for the first time, definitively demonstrates that Wallerian degeneration is an active process. The mammalian homologue of the gene encodes a mitochondrial protein, which in light of the rest of the work in this thesis, highlights the importance of mitochondria in neuronal health and disease. In conclusion, the work presented in this thesis highlights a role for mitochondria in both Wlds-mediated axon protection and Wallerian degeneration itself. I identified the first cell biological changes seen in Wlds-expressing neurons and show that at least one of these is necessary for its protection of severed axons. I also helped find the first Wallerian degeneration loss-of-function mutant, showing Wallerian degeneration is an active process, mediated by a molecularly distinct axonal degeneration pathway. The future of the axon degeneration field should focus on the mitochondria as a potential therapeutic target. Nerve Tissue Proteins Neuroprotective Agents Axons Wallerian Degeneration Mitochondria Drosophila Drosophila Proteins Amino Acids, Peptides, and Proteins Animal Experimentation and Research Nervous System Neuroscience and Neurobiology
157	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
158	Genes Required for Wallerian Degeneration Also Govern Dendrite Degeneration: A Dissertation Rooney, Timothy M. 03 April 2015 (has links) Neurons comprise the main information processing cells of the nervous system. To integrate and transmit information, neurons elaborate dendritic structures to receive input and axons to relay that information to other cells. Due to their intricate structures, dendrites and axons are susceptible to damage whether by physical means or via disease mechanisms. Studying responses to axon injury, called Wallerian degeneration, in the neuronal processes of Drosophila melanogaster has allowed the identification of genes that are required for injury responses. Screens in Drosophila have identified dsarm and highwire as two genes required for axon degeneration; when these genes are mutated axons fail to degenerate after injury, even when completely cut off from the neuronal cell body. We found that these genes are also required for dendrite degeneration after injury in vivo. Further, we reveal differences between axon and dendrite injury responses using in vivo timelapse recordings and GCaMP indicators of intracellular and mitochondrial calcium transients. These data provide insights into the neuronal responses to injury, and better define novel targets for the treatment of neurodegenerative diseases. Wallerian degeneration dendrite degeneration nervous system Dissertations, UMMS Axons Dendrites Drosophila melanogaster Neurites Neurodegenerative Diseases Neurons Wallerian Degeneration Genetics and Genomics Molecular and Cellular Neuroscience Neuroscience and Neurobiology
159	Physiological and molecular functions of the murine receptor protein tyrosine phosphatase sigma (RPTP[sigma]) Chagnon, Mélanie J., 1977- January 2008 (has links) No description available. Mice, Knockout. Axons -- physiology. Spinal Cord Injuries -- metabolism. Nerve Regeneration. Mice. Mice, Inbred BALB C.
160	Unveiling the Impact of the “-opathies”: Axonopathy, Dysferopathy, and Synaptopathy in Glaucomatous Neurodegeneration. Smith, Matthew Alan January 2017 (has links) No description available. Neurosciences Aging Biomedical Research glaucoma retinal ganglion cell node of ranvier superior colliculus axons g-ratio electron microscopy DBA axonopathy synaptopathy immunofluorescence caspr sodium channels

Search results