Global ETD Search

41	Untersuchungen zur Bedeutung der Serin-Phosphorylierung des Zelladhäsionsmoleküls L1 für das Neuritenwachstum Schultheis, Martina. Unknown Date (has links) (PDF) Universiẗat, Diss., 2004--Bonn.
42	Die Bedeutung NCAM-vermittelter Signaltransduktion für Endozytose und Neuritenwachstum Quade, Reinhild. Unknown Date (has links) (PDF) Universiẗat, Diss., 2004--Bonn.
43	Identifizierung und Charakterisierung von AST-1 in C. elegans, einem ETS-Transkriptionsfaktor, der die axonale Wegfindung reguliert Schmid, Christina S. Unknown Date (has links) (PDF) Universiẗat, Diss., 2004--Heidelberg.
44	Experimental modelling and molecular mechanisms of Wallerian degeneration in traumatic axonal injury Hill, Ciaran January 2018 (has links) Traumatic brain injury (TBI) is a common event that can lead to profound consequences for the individual involved, and a considerable socio-economic cost. The initial injury event triggers a series of secondary brain injury mechanisms that lead to further mortality and contribute to morbidity. One classical injury pathology is termed traumatic axonal injury (TAI), which in clinical settings produces the picture of diffuse axonal injury. TAI occurs both as a primary insult, and as a consequence of secondary mechanisms. One secondary injury mechanism that worsens TAI may be Wallerian degeneration (WD), a cell-autonomous axonal death pathway. The relationship between traumatic axonal injury and WD is poorly characterised. This thesis explores the basic mechanisms by which a physical axonal trauma can lead to WD, and how modulation of the WD pathway can affect the cellular responses to a traumatic injury. This involves the development and characterisation of in vitro and in vivo models of traumatic axonal injury. These models are then used to explore the response of cellular cultures to injury when treated with pharmacological and genetic modulators of WD. Using a primary neuronal stretch-injury system we demonstrate that rates of neurite degeneration are altered by modulators of the WD pathway but that a purported neuroprotective compound ‘P7C3-A20’ did not protect primary cultures in vivo and did not act via a WD dependent mechanism. An organotypic hippocampal slice stretch injury model was then used to demonstrate genetic rescue of cellular death, and used to assess amyloidogenic responses to injury. Next we established a TBI model using Drosophila Melanogaster, and demonstrated that a loss of function mutation in a key WD gene ‘highwire’ which controls NMNAT levels, was capable of rescuing premature death and a range of behavioral deficits after a high impact trauma. The injury caused dopaminergic neuronal loss and this was rescued by highwire mutation. Furthermore, this dopaminergic neuronal protection extended to a genetic PINK1 model of Parkinsonism. Together these results help establish WD as an important secondary injury mechanism in TBI, and provide evidence that modulation of the WD pathways can improve outcomes in various model systems. This provides a foundation for future translational research into the fields of WD and TBI.
45	Maturation and synapse formation of olfactory sensory neurons after injury Yarid, Colin R, Chapman, Rudy T, Rodriguez-Gil, Diego J. 12 April 2019 (has links) The olfactory system is a great model to ask questions related to neuronal regeneration, axon guidance and synapse formation. Processing of smell begins in the olfactory epithelium where sensory neurons are present and the olfactory bulb is the first stop in processing odor information in the central nervous system. While the olfactory bulb has neurons that regenerate as well, we are interested in the regeneration that occurs in the olfactory epithelium after being injured because it possesses a source of neural stem cells – something unique to the rest of the body. Earlier studies have proven that the introduction of methimazole will effectively damage the olfactory sensory neurons while keeping the neural stem cells intact. By using a fate mapping technique involving Cre-ERT2 mice, we are able to track the regeneration of these sensory neurons after a methimazole induced injury. Using immunohistochemistry in combination with ImageJ software analysis, we are able to pinpoint the colocalization of markers of new olfactory sensory neurons (green fluorescent protein (GFP)) with markers of neuron maturation (olfactory marker protein (OMP)) and synapse formation (tyrosine hydroxylase (TH) and synaptophysin). Analysis of maturation was done in the olfactory epithelium by studying the colocalization of the protein OMP and GFP. Data shows that after regeneration, neurons coexpress both markers 11 days after lesion. In the olfactory bulb, we characterized the recovery of synaptic markers TH and synaptophysin after axons reached the olfactory bulb, where olfactory sensory neuron axons make synaptic contacts with dendrites of projection neurons. Overall, these data are the first one to establish a timeline for axonal regeneration and synapse formation after injury in the olfactory system. Olfactory Neurogenesis Axon Regeneration Synapse Nervous System
46	Mitochondrial response to axonal injury Kedra, Joseph January 2020 (has links) The failure of axonal regeneration is due to myriad reasons both cell intrinsic and extrinsic. In this thesis, I sought to investigate an intrinsic reason for regeneration failure in the CNS. Specifically, I investigated the role of axonal mitochondria in the axonal response to injury. A viral vector (AAV) containing a mitochondrially targeted fluorescent protein (mitoDsRed) as well as fluorescently tagged LC3 (GFP-LC3), an autophagosomal marker, was injected into primary motor cortex, to label the corticospinal tract (CST), of adult rats. The axons of the CST were then injured by dorsal column lesion at C4-C5. We found that mitochondria in injured CST axons near the injury site are fragmented and fragmentation of mitochondria persists for two weeks before returning to pre-injury lengths. Fragmented mitochondria have consistently been shown to be dysfunctional and detrimental to cellular health. Interestingly, transection of axons within the sciatic nerve resulted in mitochondrial fission but did not result in the fragmentation of mitochondria. Inhibition of Drp1, the GTPase responsible for mitochondrial fission, using a specific pharmacological inhibitor (mDivi-1) blocked fragmentation. Additionally, it was determined that there is increased mitophagy in CST axons following spinal cord injury based on increased colocalization of mitochondria and LC3. In vitro models revealed that mitochondrial calcium uptake is necessary for injury induced mitochondrial fission, as inhibiting mitochondrial calcium uptake using RU360, a mitochondrial calcium uniporter inhibitor, prevented injury induced fission. This phenomenon was also observed in vivo. These studies indicate that following injury, both in vivo and in vitro, axonal mitochondria undergo increased fission, which may result in an ATP deficit that contributes to the lack of regeneration seen in CNS neurons. / Biomedical Sciences Neurosciences Axon Mitochondria Spinal cord injury
47	The Effect of Local Heating on the Concentration of Interstitial ATP in Human Skin Gifford, Jayson R. 08 August 2011 (has links) (PDF) Skin blood flow (SKBF) demonstrates a biphasic response to innocuous, local heating. Much about the mechanism of the first phase is unknown. A type of ion channel (TRPV3) sensitive to and increasingly activated by temperatures from ~33 to ~45°C may be involved. TRPV3 channels are abundantly located in the keratinocytes and are believed to elicit the release of ATP, a putative cutaneous vasodilator, upon activation. This study investigated the possibility that TRPV3 channels and ATP have a role in the first phase of the SBKF response to local heat. Fifteen young, healthy subjects participated in the study. Two microdialysis probes were inserted into the dermis on the forearm. Using a peltier module, the skin above the probes (3cm x 3cm) was heated to 31, 35, 39, and 43°C to manipulate the level of activation of TRPV3 channels for eight minutes each. The probes were perfused with 0.9% saline at 2µl/min. Dialysate from each phase was analyzed for the concentration of ATP ([ATP]d). Cutaneous vascular conductance (CVC), measured by laser Doppler flowmetry, was monitored throughout. The [ATP]d decreased significantly when the skin was heated to temperatures known to strongly activate TRPV3 channels (i.e 39 and 43°C). [ATP]d demonstrated no relationship with CVC and only a very weak relationship with peltier temperature (r2 = 0.02, p<0.05). These data indicate that local heating and presumably heat-induced activation of the TRPV3 channels results in the decrease, not increase, of the release of ATP in human skin, and that the [ATP]d is not related to changes in skin blood flow. Significant dilation was observed at 35°C. This threshold, which is several degrees lower than the threshold previously reported, suggests that the TRPV3 channels may be involved in the dilator response in some way independent of interstitial ATP. hyperemia thermosensation axon reflex Exercise Science
48	ARHGAP4 is a spatially regulated RhoGAP that inhibits NIH/3T3 cell migration and dentate granule cell axon outgrowth Vogt, Daniel L. 06 July 2007 (has links) No description available. RhoGAP FCH Hippocampus Cell migration Axon outgrowth
49	Der Einfluß der Ribosomale S6 Kinase 2 (RSK2) auf das Neuriten- und Synapsenwachstum in vivo und in Zellkultur / Der Einfluß der Ribosomalen S6 Kinase 2 (RSK2) auf das Neuriten- und Synapsenwachstum in vivo und in Zellkultur Fischer, Matthias January 2010 (has links) (PDF) In dieser Arbeit sollte die Funktion der Ribosomalen S6 Kinase 2 (RSK2) auf neuronaler Ebene untersucht werden. Dahingehend gab es, z.B. auf Grund der Phänotypen von Fliegen und Mäusen mit Mutationen im entsprechenden Gen oder von Patienten mit Coffin-Lowry-Syndrom (CLS) nur Vermutungen. Es bestand letztlich die Hoffnung, einen Beitrag zur Aufklärung der Pathophysiologie des CLS zu leisten. Es stellte sich auf Grund von Experimenten sowohl in vivo als auch in vitro in verschiedenen Modellsystemen in dieser Arbeit heraus, daß RSK2 einen negativen Einfluß auf das Neuriten- und Synapsenwachstum hat. In kultivierten Motoneuronen führte der KO von RSK2 zu längeren Axonen und die Überexpression eines konstitutiv aktiven RSK2-Konstrukts zu kürzeren Axonen. In PC12-Zellen führte die Expression von konstitutiv aktiven RSK2 Konstrukten zur Verkürzung der Neuriten und die Expression eines Kinase-inaktiven RSK2 Konstrukts zu längeren Neuriten. In vivo war die neuromuskuläre Synapse bei RSK2-KO Mäusen vergrößert und hatte bei Drosophila rsk Mutanten mehr Boutons. Das RSK2-Protein ist in Motoneuronen der Maus und in überexprimierter Form in den Boutons der neuromuskulären Synapse bei Drosophila nachweisbar. Damit wurde zum ersten Mal die Funktion von RSK2 auf neuronaler Ebene beschrieben. Bezüglich des Mechanismus, wie RSK2 das Nervenwachstum beeinflußt gab es deutliche Hinweise, die dafür sprechen, daß RSK2 dies über eine in der Literatur schon häufiger beschriebene Hemmung der MAPK ERK1/2 erreicht. Für diese Hypothese spricht die Tatsache, daß die ERK-Phosphorylierung in murinen Motoneuronen und im Rückenmark embryonaler Mäuse der RSK2-Mutante erhöht ist und der Axonwachstumsdefekt durch eine Hemmung von MEK/ERK behoben werden kann. Auch ist die ERK-Phosphorylierung an der murinen Muskel-Endplatte in der Mutante erhöht. Zudem zeigen genetische Epistasis-Experimente in Drosophila, daß RSK die Bouton-Zahl über ERK/RL hemmt. RSK scheint also in Drosophila von der Funktion her der RSK2-Isoform in Wirbeltieren sehr ähnlich zu sein. Ein weiteres wichtiges Ergebnis ist die Beobachtung, daß RSK2 bei Motoneuronen keinen wesentlichen Einfluß auf das Überleben der Zellen in Gegenwart neurotropher Faktoren hat. Möglicherweise spielen hier redundante Funktionen der RSK Familienmitglieder eine Rolle. Ein bislang unerklärter Befund ist die reduzierte Frequenz spontaner Depolarisationen bzw. damit einhergehender Ca2+ Einströme bei RSK2-KO Motoneuronen in Zellkultur. Die Häufigkeit und Dichte von Ca2+-Kanälen und aktive Zonen Proteinen war in Motoneuronen nicht von der Anwesenheit des RSK2-Proteins abhängig. Im Hippocampus konnte außerdem das RSK2-Protein präsynaptisch in den Moosfaser-Boutons der CA3 Region nachgewiesen werden. Es befindet sich auch in den Pyramidenzellen, aber nicht in den Pyramidenzell-Dendriten in CA3. Bezüglich der Bedeutung dieser Befunde für die Aufklärung der Pathologie des CLS ist zu folgern, daß der neuro-psychologische Phänotyp bei CLS Patienten wahrscheinlich nicht durch reduziertes Überleben von Neuronen, sondern eher durch disinhibiertes Axonwachstum oder Synapsenwachstum bedingt ist. Dies kann grob sowohl für die peripheren als auch die zentralen Defekte gelten, denn die Synapsen im ZNS und am Muskel sind in ihrer molekularen Ausstattung z.B. im Bereich der Vesikel, der aktiven Zonen oder der Transmitterausschüttung sehr ähnlich. Weiterhin könnte eine veränderte synaptische Plastizität u.a. an der Moosfaser-Pyramidenzell-Synapse in der CA3 Region des Hippocampus eine Rolle bei den kognitiven und mnestischen Einschränkungen der Patienten spielen. Die Entdeckung, daß aktiviertes ERK bei den beobachteten Effekten eine Rolle spielt kann für die Entwicklung von Therapiestrategien eine wertvolle Erkenntnis sein. / In this thesis the function of the Ribosomal S6 Kinase 2 (RSK2) on the neuronal level should be investigated. Due to the phenotypes of flies and mice with mutations in the respective gene or of Coffin-Lowry-Syndrome (CLS) patients there existed only rough speculations. An aim was to make a contribution to the elucidaton of the pathophysiology of the CLS. In this thesis it could be shown by experiments in vivo as well as in vitro in different model systems, that RSK2 has a negative influence on neurite- and synapse growth. In cultivated motoneurons the KO of RSK2 increased the length of axons and the overexpression of a constitutive acitve RSK2-construct reduced axon length. In PC12 cells expression of constitutive active RSK2-constructs reduced neurite-length and expression of a kinase-dead RSK2-construct increased neurite-length. In vivo the size of the neuromuscular synapse of RSK2-KO mice and the bouton number at the Drosophila neuromuscular junction was increased. The RSK2-Protein could be found in mouse motoneurons and, if overexpressed, in boutons at the Drosophila neuromuscular junction. These results show for the first time, which function RSK2 has on the neuronal level. With respect to the mechanism, how RSK2 influences neurite growth, there was evidence, that RSK2 does this by inhibition of the MAPK ERK1/2. The latter has been described in literature before. Arguments for this are the findings, that ERKphosphorylation in mouse motoneurons and in embryonal spinal cord of the RSK2 mouse mutant is increased and that the axon-growth defect can be rescued by inhibition of MEK/ERK. Besides this, ERK-phosphorylation at the neuosmuscular endplate of RSK2-KO mice is increased. Moreover, genetic epistasis experiments in Drosophila show, that RSK inhibits bouton numbers via ERK/RL. So, Drosophila RSK seems to resemble, according to its function, the vertebrate RSK2-isoform. A further important result is the observation, that RSK2 has no effect on survival of motoneurons in the presence of neurotrophic factors. Possibly redundant functions of RSK family members are responsible for this. A so far unexplained finding is the reduced frequency of spontaneous depolarisations with concomitant Ca2+ Influx in cultured RSK2-KO Motoneurons. The amount and density of Ca2+ channels and active zone proteins was not dependent on the presence of the RSK2-Protein in motoneurons. In the hippocampus the RSK2-Protein could be found presynaptically in mossy-fiber boutons in the CA3 region. Moreover, it is localized in pyramidal cells, but not in the pyramidal cell dendrites in the CA3 region. With respect to the impact of these findings on the understanding of the CLS pathology, it is, according to the results of this thesis, probably not caused by reduced survival of neurons, but by disinhibited axon and synapse growth. This may account roughly for peripheral as well as central defects, because synapses in the central nervous system and at the muscle are very similar with respect to the molecular organization for example of vesicles, the active zone or transmitter release. Furthermore, a change in synaptic plasticity for example at the mossy-fiber pyramidal cell synapse in the CA3 region of the hippocampus could lead to the cognitive and mnestic deficits in CLS patients. The finding that activated ERK plays a role in the observed effects can guide the way for new therapeutic strategies. Ribosom Kinasen Axon Wachstum ddc:570
50	Role of the microtubulin-associated molecule tau in inflammatory-mediated axonal damage / Die Rolle des Mikrotubuli-assoziierten Proteins Tau in entzündungsbedingten axonalen Schäden Gorlovoy, Philipp 17 January 2007 (has links) No description available. 570 Biowissenschaften, Biologie WHC 000 Mathematics and Natural Science Tau Mikrotubulin Axon tau microtubulin axon 42.15

Search results