Global ETD Search

231	Räumliche Verteilung von Kalziumsignalen in Bergmanngliazellen als Antwort auf neuronale Aktivität Mohrhagen, Kai 18 December 2000 (has links) Bergmann Gliazellen reagieren auf elektrische Stimulation der Parallelfasern in Ihrem Soma Kalziumsignalen. Diese Signale sind sensitiv gegenüber den Antagonisten TTX, kalziumfreie Lösung und Cadmium. Ein Antagonist spannungaktivierter Kaliumkanäle, der synaptische Ereignisse verlängert, führt zu erheblich verstärkten Antworten. Um Kalziumantworten in Bergmann Gliazellsomata auszulösen ist eine erheblich stärkere elektrische Stimulation notwendig, als man für Kalziumantworten im Ausläufer der Zellen benötigt Es wurde eine Methode entwickelt, Raum-Zeit-Bilder von Kalziumantworten in Bergmann Gliazellausläufern auf elektrische Stimulation zu erzeugen. Die Darstellungen zeigen zeitlich und räumlich eingeschränkte Reaktionen auf teilen der Ausläufer. Beispiele für das Fortschreiten einer Kalziumwelle vom Ausläufer in das Zellsoma (oder umgekehrt) ließen sich nicht finden. Die räumlich Ausdehnung der beobachteten Signale unterstützt das in Grosche et al. (Grosche, et al, 1999) entwickelte Konzept von Mikrodomänen in Bergmann Gliazellausläufern. Die gemessenen Kalziumsignale sind nicht von den Kalziumspeichern des endoplasmatischen Retikulums abhängig. Dies schließt die Beteiligung G-Protein gekoppelter Rezeporen, die unter Aktivierung von endoplasmatischen IP3-Rezeptoren zu zytosolischen Kalziumsignalen führen, an der Generierung diese Signale aus. Die Beteiligung der Neurotransmitter Adrenalin, Noradrenalin, Histamin, Endothelin, Adenosin-tri-Phosphat und des Neurotransmitters Glutamat auf dem Wege der Aktivierung metabotroper Glutamatrezeptoren an der Detektion stimulationsvermittelter Kalziumsignale wurde über die Applikation spezifischer Antagonisten ausgeschlossen. Die Rolle von Glutamattransportern konnte nicht abschließend geklärt werden, da der Antagonist bei einer alleinigen Applikation zu einer Reduktion des Signals um 20 % führt. Bei einer Applikation mit geleertem endoplasmatischen Retikulum führt er zu einer Steigerung der Signalamplitude um 31.9 %. Die somatischen Kalziumantworten auf elektrische Stimula tion ließen sich zu einem Prozentsatz von 23.7 % durch den Antagonisten CNQX für ionotrope Glutamatrezeptoren vom AMPA/Kainat-Typ blockieren. In Bergmann Gliazellen sind diese Rezeptoren anders als in Neuronen kalziumpermeabel (Müller et al, 1992), da diese Zelle nicht die Untereinheit GluR2 des Kanals exprimieren. Es wurde eine funktionelle Bedeutung dieser Genexpression in der Detektion synaptischer Aktivität nachgewiesen. / Bergmann glia cells react to electrical stimulation of parallel fibers with calcium signals in their somata. These signals are sensitive against antagonists of neuronal activity, namly TTX calcium free solution and cadmium. An antagonist of voltage activated potassium channels, which is able to prolong synaptic events, leads to increased calcium responses. To elicit calcium responses in Bergmann glia somata much stronger stimulation compared to these required to elicit calcium responses in Bergmann glia processes is needed. A method was developed to get space-time images of calcium responses to electrical responses in Bergmann glia processes. The images show reactions restricted in time and space in parts of the processes. Examples of processing of calcium waves from the processes to the somata (or the other way around) could not be found. The special expansion of the observed signals supports the concept of micro domains as developed by Grosche et al. (Grosche, et al, 1999). Calcium signals measured do not d epend on the calcium stores of the endoplasmatic reticulum. This excludes the involvment of G-protein coupled receptors, which lead to cytosolic calcium signals via IP3-receptors, in the generation of these calcium signals. The involvment of the neurotransmitter adrenalin, noradrenalin, histamin, endothelin and adenosin-tri-phosphate in the generation of stimulation induced calcium signals was additionally excluded by the application of specific antagonists. The roll of glutamate transporter could not be fully clarified. The application of the antagonist l-PDC alone leads to a reduction of 20% of the signals amplitude, while the application in presence of emptied endoplasmatic calcium stores leads to an increase by 31.9%. Somatic calcium responses to electrical stimulation were able to be blocked by 23.7 % using the antagonist CNQX specific for ionotrope glutamate receptors of the AMPA/Kainat-Typ. In Bergmann glia cells these receptors differ from the AMPA/Kainat-Typ receptors on neuron with regard to their c alcium permeability (Müller et al, 1992) as result of leak in expression of the GluR2 subunit. A functionel involvment of this specific gene expression in the detection of synaptic activity by Bergmann glia cells was proved. Bergmannglia Kalzium Neuron-Glia Interaktion elektrische Stimulation Bergmannglia calcium neuron-glia interaction electrical stimulation 610 Medizin und Gesundheit 33 Medizin WW 1620 ddc:610
232	Modeling neuropathogenesis of B virus infection in the macaque ganglia LeCher, Julia 09 May 2016 (has links) B virus is an alphaherpesvirus, endemic to macaque monkeys, capable of deadly human zoonosis with an 80% mortality rate in untreated cases. The macaque monkey is widely used in biomedical research and the threat of B virus poses an occupational hazard to researchers, veterinarians, and animal handlers. B virus establishes a life-long latent infection in sensory neurons of the peripheral nervous system (PNS) in the natural host. In human infections, B virus readily transits to the central nervous system (CNS) and destroys brain tissues. Identifying immune correlates of B virus infection in the PNS of the natural host is critical in understanding viral lethality in the human host. The lack of an accurate animal model and restrictions on handling potentially infected nervous tissue previously limited studies of B virus infection in macaque ganglia. To address this barrier, a long-lived mixed neuron/glia cell culture model was established from macaque DRG explants using a novel methodology that relied on cellular migration from whole tissues. Utilizing this model, the hypothesis tested was that acute B virus infection of macaque ganglia triggers cellular defense networks to promote leukocyte recruitment and impact leukocyte activation. Chemokines were upregulated in B virus-infected cultures and infected cell media induced leukocyte chemotaxis. Leukocytes were less effectively activated by media from infected cells when compared to media from mock-infected cells. To identify factors responsible for this, focused microarrays were performed and cytokine profiles were quantified from B virus and mock-infected culture supernatants. IL-6 protein levels were significantly reduced in B virus infected cultures. This observation led to the hypothesis that IL-6 downregulation impairs leukocyte activation and, indeed, when IL-6 was added to B virus-infected culture supernatants to control levels, these cultures were far more effective at eliciting leukocyte activation when compared with mock-infected cultures. Collectively, these data support the hypothesis that acute B virus infection of macaque ganglia triggers cellular defense networks to promote leukocyte recruitment and impact leukocyte activation and identifies a potential viral mechanism to impair leukocyte functionality. Additionally, this work presents a novel methodology for establishing long-lived mixed neuron/glia cultures from postnatal/adult macaque DRGs. Herpes B virus Macaque monkey Neurovirology DRG Neuron/glia cell culture IL-6
233	When and where will a target go? A behavioural and electrophysiological study of expectation in primates de Hemptinne, Coralie 26 August 2008 (has links) In a rapidly changing visual environment, the delay between perception and action might impair the probability of survival of a prey or the efficiency of a predator. In order to compensate for delays associated with sensory-motor processing, primates often make predictions about future events and initiate anticipatory movements. To prepare an anticipatory movement, an estimation of when and where to a target is likely to move is necessary. Such an internal representation is often termed 'expectation'. The aim of this thesis was to investigate the gradual changes of a subject's expectation at the behavioral and electrophysiological levels. Anticipatory smooth pursuit was used in order to study temporal and directional changes in expectation. We found that temporal uncertainty strongly modulated the latency and the velocity of anticipatory movements suggesting that monkeys could estimate the hazard rate of target motion onset in order to decide when to initiate an anticipatory movement. In addition, we have shown that monkeys could use prior directional information in order to voluntarily initiate anticipatory responses in the direction of expected target motion. This prior directional information significantly affected the latency and velocity of these movements. Finally, we have shown that the majority of recorded supplementary eye field (SEF) neurons encoded expected target motion direction. The presence of a directional cue induced an increase of activity in the preferred direction of the neuron. Moreover, a large sub-population of neurons encoded the direction of future anticipatory movement. These results suggest that the SEF could be involved in the cognitive control of anticipatory pursuit eye movements when prior temporal and directional information is provided. Single neuron recordings Eye movement Rhesus monkey Supplementary eye fields Anticipatory smooth pursuit
234	Noise induced processes in neural systems Roper, Peter January 1998 (has links) Real neurons, and their networks, are far too complex to be described exactly by simple deterministic equations. Any description of their dynamics must therefore incorporate noise to some degree. It is my thesis that the nervous system is organized in such a way that its performance is optimal, subject to this constraint. I further contend that neuronal dynamics may even be enhanced by noise, when compared with their deterministic counter-parts. To support my thesis I will present and analyze three case studies. I will show how noise might (i) extend the dynamic range of mammalian cold-receptors and other cells that exhibit a temperature-dependent discharge; (ii) feature in the perception of ambiguous figures such as the Necker cube; (iii) alter the discharge pattern of single cells. 510
235	Single-Cell Transcriptome Analysis of Olfactory Sensory Neurons Chien, Ming-Shan January 2016 (has links) <p>Olfactory sensory neurons (OSNs), which detect a myriad of odorants, are known to express one allele of one olfactory receptor (OR) gene (Olfr) from the largest gene family in the mammalian genome. The OSNs expressing the same OR project their axons to the main olfactory bulb where they converge to form glomeruli. This “One neuron-one receptor rule” makes the olfactory epithelium (OE), which consists of a vast number of OSNs expressing unique ORs, one of the most heterogeneous cell populations. However, the mechanism of how the single OR allele is chosen remains unclear along with the question of whether one OSN only expresses a single OR gene, a hypothesis that has not been rigorously verified while we performed the experiments. Moreover, failure of axonal targeting to single glomerulus was observed in MeCP2 deficient OSNs where delayed development was proposed as an explanation for the phenotype. How Mecp2 mutation caused this aberrant targeting is not entirely understood.</p><p>In this dissertation, we explored the transcriptomes of single and mature OSNs by single-cell RNA-Seq to reveal their heterogeneity and further studied the OR gene expression from these isolated OSNs. The singularity of sequenced OSNs was ensured by the observation of monoallelic expression of X-linked genes from the hybrid samples from crosses between mice of different strains where strain-specific polymorphisms could be used to track the allelic origins of SNP-containing reads. The clustering of expression profiles from triplicates that originated from the same cell assured that the transcriptomic identities of OSNs were maintained through the experimental process. The average gene expression profiles of sequenced OSNs correlated well to the conventional transcriptome data of FACS-sorted Omp-positive cells, and the top-ranked expression of OR was conceded in the single-OSN transcriptomes. While exploring cellular diversity, in addition to OR genes, we revealed nearly 200 differentially expressed genes among the sequenced OSNs in this study. Among the 36 sequenced OSNs, eight cells (22.2%) showed multiple OR gene expression and the presences of additional ORs were not restricted to the neighbor loci that shared the transcriptional effect of the primary OR expression, suggesting that the “One neuron-one receptor rule” might not be strictly true at the transcription level. All of the inferable ORs, including additional co-expressed ORs, were shown to be monoallelic. Our sequencing of 21 Mecp2308 mutant OSNs, of which 62% expressed more than one OR genes, and the expression levels of the additional ORs were significantly higher than those in the wild-type, suggested that MeCP2 plays a role in the regulation of singular OR gene expression. Dual label in situ hybridization along with the sequence data revealed that dorsal and ventral ORs were co-expressed in the same Mecp2 mutant OSN, further implying that MeCP2 might be involved in regulation of OR territories in the OE. Our results suggested a new role of MeCP2 in OR gene choice and ratified that this multiple-OR expression caused by Mecp2 mutation did not accompany delayed OSN development that has been observed in the previous studies on the Mecp2 mutants.</p> / Dissertation Genetics MeCP2 Olfactory Receptor Olfactory Sensory Neuron Single-cell RNA-Seq
236	Adenovirus biology : receptors and intracellular trafficking / Biologie des Adenovirus : recepteurs et transport intracellulaire Henaff, Daniel 15 December 2010 (has links) Les adénovirus ont une double nature, soit comme pathogène omniprésent qui peuvent occasionnellement causer des maladies soit comme vecteurs utilisés de transfert de gène. À nos connaissances, les 30 premières minutes depuis la liaison au récepteur jusqu'à l'arrivée au pore nucléaire sont identiques pour le pathogène comme pour le vecteur. L'objectif de ma thèse était de comprendre les mécanismes impliqués dans la liaison au récepteur, l'internalisation, l'échappement et le trafic endosomal vers le MTOC. J'ai d'abord étudié le mécanisme impliqué dans l'hémagglutination des virus à tropisme pour CAR et à tropisme pour SA. J'ai identifié la présence de CAR sur les érythrocytes humains et montré qu'il était le principal responsable de l'agglutination induite par les virus à tropisme pour CAR. De plus, j'ai montré que la présence de CAR sur les érythrocytes pouvait piéger le virus dans le sang et ainsi empêcher l'infection au niveau du foie. Dans un deuxième temps, j'ai participé à la caractérisation du rôle de la protéine VI et la translocation du virus au MTOC. Nous avons montré que Nedd4 était impliqué dans le ciblage du virus au MTOC via l'ubiquitination de la protéine VI. Enfin, j'ai travaillé sur le neurotropisme de CAV-2 et caractérisé sa localisa tion subcellulaire au niveau des synapses. J'ai montré qu'une partie de CAR était localisée dans des radeaux lipidiques à la synapse et que CAV-2 entrait via la voie de recyclage des vésicules synaptiques. / Adenoviruses have a dual nature as ubiquitous pathogens that occasionally cause life-threatening disease and their use as gene transfer vectors. To the best of our current knowledge, the first 30 min from binding to nuclear pore docking of both wild-type virus and vector are identical. The goal of my thesis is to understand different mechanisms involved in receptor binding, internalization, endosomal escape and trafficking to the MTOC. First I studied the mechanism involved in hemagglutination of CAR-tropic and SA-tropic viruses. I identified the presence of CAR on human erythrocytes and showed that it was the main responsible for the agglutination mediated by CAR-tropic viruses. Moreover, I show that CAR on erythrocytes can sequester virus in the bloodstream and block liver infection. In a second part I participated to the characterization of the role of the protein VI and the translocation of HAd to the MTOC. We showed that Nedd4 was involved in the targeting of the virus to MTOC through ubiquitination of this protein VI. Finally, I worked on the neurotropism of CAV-2 and characterize its subcellular localization at the synapse. I showed that a part of CAR was localized in lipid raft at the synapse and enter through the synaptic vesicle-recycling pathway. Adenovirus Transport intracelluaire Neurone Synapse Agglutination Adenovirus Intracellualr trafficking Neuron Synapse Agglutination
237	Regulation of RNA Editing : The impact of inosine on the neuronal transcriptome Behm, Mikaela January 2017 (has links) The transcriptome of the mammalian brain is extensively modified by adenosine to inosine (A-to-I) nucleotide conversion by two adenosine deaminases (ADAR1 and ADAR2). As adenosine and inosine have different base pairing properties, A-to-I RNA editing shapes the functional output of both coding and non-coding RNAs (ncRNAs) in the brain. The aim of this thesis was to identify editing events in small regulatory ncRNAs (miRNAs) and to determine their temporal and spatial editing status in the developing and adult mouse brain. To do this, we initially analyzed the editing status of miRNAs from different developmental time points of the mouse brain. We detected novel miRNA substrates subjected to A-to-I editing and found a general increase in miRNA editing during brain development, implicating a more stringent control of miRNAs as the brain matures. Most of the edited miRNAs were found to be transcribed as a single long consecutive transcript from a large gene cluster. However, maturation from this primary miRNA (pri-miRNA) transcript into functional forms of miRNAs is regulated individually, and might be influenced by the ADAR proteins in an editing independent matter. We also found that edited miRNAs were highly expressed at the synapse, implicating a role as local regulators of synaptic translation. We further show that the increase in editing during development is explained by a gradual accumulation of the ADAR enzymes in the nucleus. Specifically for ADAR2, we found a developmentally increasing interaction with two factors, importin-α4 and Pin1, that facilitate nuclear localization of the editing enzyme. We have also found that selectively edited stem loops often are flanked by other long stem loop structures that induce editing in cis. This may explain why multiple pri-miRNAs are edited within the same cluster. In conclusion, this thesis has significantly increased the understanding of the dynamics of both editing substrates and enzymes in the developing and mature brain. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 2: Manuscript.</p> RNA editing ADAR miRNA Neuron Brain development Synapse Cell and Molecular Biology Cell- och molekylärbiologi
238	Molecular mechanisms of acute axonal degeneration in the rat optic nerve Zhang, Jiannan 11 November 2015 (has links) No description available. 570 axonal degeneration calpain cortical neuron CRMP2 microfluidic chamber mitochondrial transport optic nerve Biologie (PPN619462639)
239	Learning, self-organisation and homeostasis in spiking neuron networks using spike-timing dependent plasticity Humble, James January 2013 (has links) Spike-timing dependent plasticity is a learning mechanism used extensively within neural modelling. The learning rule has been shown to allow a neuron to find the onset of a spatio-temporal pattern repeated among its afferents. In this thesis, the first question addressed is ‘what does this neuron learn?’ With a spiking neuron model and linear prediction, evidence is adduced that the neuron learns two components: (1) the level of average background activity and (2) specific spike times of a pattern. Taking advantage of these findings, a network is developed that can train recognisers for longer spatio-temporal input signals using spike-timing dependent plasticity. Using a number of neurons that are mutually connected by plastic synapses and subject to a global winner-takes-all mechanism, chains of neurons can form where each neuron is selective to a different segment of a repeating input pattern, and the neurons are feedforwardly connected in such a way that both the correct stimulus and the firing of the previous neurons are required in order to activate the next neuron in the chain. This is akin to a simple class of finite state automata. Following this, a novel resource-based STDP learning rule is introduced. The learning rule has several advantages over typical implementations of STDP and results in synaptic statistics which match favourably with those observed experimentally. For example, synaptic weight distributions and the presence of silent synapses match experimental data. 006.3
240	Functional genetic analysis of motor neuron disease Bäumer, Dirk January 2010 (has links) Amyotrophic lateral sclerosis (ALS) and spinal muscular atrophy (SMA) are the commonest motor neuron diseases of adult- and childhood onset. Alterations of the RNA binding protein TDP-43 are associated with most cases of ALS, while SMA is caused by deletion of the Survival Motor Neuron (SMN1) gene. SMN has been well characterised in its role in the assembly of the cellular machinery that carries out splicing of pre-mRNA, but is thought to have other functions in RNA metabolism unrelated to pre-mRNA splicing. It is conceivable that specific aspects of RNA handling are disrupted in both SMA and ALS. A variety of genetic, molecular and neuropathological approaches were applied to investigate a potential common pathway in these diseases. The spectrum of genetic mutations underlying motor neuron disorders were explored by screening patient DNA. Cell culture and mouse models were used to test the hypothesis that altered pre-mRNA splicing causes motor neuron death. Human neuropathological specimens were examined for changes in proteins involved in RNA metabolism. The results indicate that altered pre-mRNA splicing is a late occurrence in disease and more likely to be a consequence rather than the cause of motor neuron degeneration. However, the notion that RNA metabolism is highly relevant to motor neuron diseases was strengthened by the discovery of mutations in another RNA binding protein, FUS, in cases of ALS without TDP-43 pathology. Overall the findings highlight the need to consider disruption of mRNA transport and regulation of mRNA translation in future motor neuron disease research. 616.042

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