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Role of NaV1.9 in activity dependent axon growth in embryonic cultured motoneurons / Die Rolle der NaV1.9 in Aktivität abhängig Axonwachstum in embryonalen kultivierten MotoneuronenSubramanian, Narayan January 2011 (has links) (PDF)
Spontaneous neural activity has been shown to regulate crucial events in neurite growth including axonal branching and path finding. In animal models of spinal muscular atrophy (SMA) cultured embryonic mouse motoneurons show distinct defect in axon elongation and neural activity. This defect is governed by abnormal clustering of Ca2+ channels in the axonal regions and the protruding growth cone area. The mechanisms that regulate the opening of calcium channels in developing motoneurons are not yet clear. The question was addressed by blocking neural activity in embryonic cultured motoneurons by pharmacological inhibition of voltage-gated sodium channels (VGSC) by saxitoxin (STX) and tetrodotoxin (TTX). Low dosages of STX resulted in significant reduction of axon growth and neural activity in cultured motoneurons. This pharmacological treatment did not affect survival of motoneurons in comparison to control motoneurons that was grown in the presence of survival neurotrophic factors BDNF and CNTF. It was also found that STX was 10 times more potent than TTX a common inhibitor of VGSC with a reduced activity on the TTX-insensitive sodium channels NaV1.5, NaV1.8 and NaV1.9. Reverse Transcriptase-PCR experiments revealed the presence of NaV1.9 as the likely candidate that begins to express from embryonic stage sixteen in the mouse spinal cord. Immunolabelling experiments showed that the channel is expressed in the axonal compartments and axonal growth cones in cultured motoneurons. Suppression of NaV1.9 in cultured motoneurons by lentivirus mediated short hairpin-RNA (shRNA) resulted in shorter axon length in comparison with uninfected and scrambled constructs. Further, embryonic motoneurons cultured from NaV1.9 knockout mice also showed a significant reduction in neural activity and axon growth. The findings of this work highlight the role of NaV1.9 as an important contender in regulating activity dependent axon growth in embryonic cultured motoneurons. NaV1.9 could therefore be considered as a prospective molecule that could play an important role in regulating axon growth in motoneuron disease models like spinal muscular atrophy (SMA). / Spontane neuronale Aktivität reguliert essentielle Ereignisse im Neuritenwachstum, wie beispielsweise die axonale Verzweigung und die Erkennung des Wachstumspfades. Motoneurone, die aus Tiermodellen der Spinalen Muskelatrophie (SMA) gewonnen werden, zeigen einen auffälligen Defekt im Streckenwachstum von Axonen und in der neuronalen Aktivität. Dieser Defekt wird von anormaler Clusterbildung von Ca2+ Kanälen in axonalen Regionen und in Wachstumskegeln begleitet. Die Mechanismen, die das Öffnen von Kalziumkanälen in embryonalen Motoneuronen in der Entwicklung regulieren, und die für das aktivitätsabhängige Axonwachstum benötigt werden, sind nicht bekannt. Diese Frage wurde in dieser Studie bearbeitet, indem neuronale Aktivität in embryonalen Motoneuronen durch pharmakologische Inhibition von spannungsabhängigen Natriumkanälen durch Saxitoxin (STX) und Tetrodotoxin blockiert wurde. Geringe Dosen von Saxitoxin bewirkten eine deutliche Reduktion des Axonwachstums und der neuronalen Aktivität in kultivierten Motoneuronen. Diese pharmakologische Behandlung beeinflusste nicht das Überleben von Motoneuronen im Vergleich zu Kontroll-Motoneuronen, die in der Anwesenheit der neurotrophen Faktoren BDNF und CNTF kultiviert wurden. Saxitoxin war etwa 5-10-mal potenter als TTX, ein üblicher Blocker spannungsabhängiger Natriumkanäle mit einer verminderte Aktivität auf die TTX-insensitiven Natriumkanäle NaV1.5, NaV1.8, und NaV1.9. Reverse-Transkriptase-PCR Experimente bestätigten die Anwesenheit von NaV1.9 am Tag E16 (embryonaler Tag 16) im Rückenmark der Maus. NaV1.9 ist ein einzigartiger Typus von einem Natriumkanal welcher in der Lage ist neuronale Erregbarkeit in der Nähe des Ruhemembranpotentials zu steuern. Deshalb war NaV1.9 ein guter Kandidat für einen Kanal, der spontane Erregung in Motoneuronen vermittelt. Immunofärbungen zeigten, dass NaV1.9 in axonalen Kompartimenten und axonalen Wachstumskegeln von kultivierten Motoneuronen exprimiert ist. Die Unterdrückung von NaV1.9 in kultivierten Motoneuronen durch lentiviralexprimierte short hairpin-RNA (shRNA) resultierte in kürzerer Axonlänge, im Vergleich zu nicht-infizierten Motoneuronen oder Motoneuronen, die eine sinnlose Kontroll-shRNA Sequenz exprimierten. Embryonale, kultivierte Motoneurone von NaV1.9 knockout Mäusen zeigten eine signifikante Verringerung der neuronalen Aktivität und verkürzte Axone. Diese Ergebnisse weisen auf eine Bedeutung von NaV1.9 im aktivitätsabhängigen Axonwachstum hin
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Transcriptional Control of Photoreceptor Axon Growth and Targeting in Drosophila melanogasterKniss, Jonathan, Kniss, Jonathan January 2012 (has links)
The nervous system is required for human cognition, motor function, and sensory interaction. A complex network of neuronal connections, or synapses, carries out these behaviors, and defects in neural connectivity can result in developmental and degenerative diseases. In vertebrate nervous systems, synapses most commonly occur at axon terminals. Upon reaching their synaptic targets, growth cones lose their motility and become boutons specialized for neurotransmitter release. I am studying this process in R7 photoreceptors in the
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The role of TrkB and NaV1.9 in activity-dependent axon growth in motoneurons / Die Rolle von TrkB und NaV1.9 in aktivitätsabhängigem Axonwachstum von MotoneuronenWetzel, Andrea January 2013 (has links) (PDF)
Während der Entwicklung des Nervensystems lassen sich bei Motoneuronen aktivitätsabhängige Kalziumströme eobachten, die das Axonwachstum regulieren. Diese Form der neuronalen Spontanaktivität sowie das Auswachsen von Axonen sind bei Motoneuronen, die aus Tiermodellen der Spinalen Muskelatrophie isoliert werden, gestört. Experimente aus unserer Arbeitsgruppe haben gezeigt, dass spontane Erregbarkeit und aktivitätsabhängiges Axonwachstum von kultivierten Motoneuronen auch unter Verwendung von Toxinen beeinträchtigt sind, welche die Aktivität von spannungsabhängigen Natriumkanälen
blockieren. In diesen Versuchen war die Wirkung von Saxitoxin effizienter als die Wirkung von Tetrodotoxin. Wir identifizierten den Saxitoxin-sensitiven/Tetrodotoxin-insensitiven spannungsabhängigen Natriumkanal NaV1.9 als Trigger für das Öffnen spannungsabhängiger Kalziumkanäle. Die Expression von NaV1.9 in Motoneuronen konnte über
quantitative RT-PCR nachgewiesen werden und antikörperfärbungen offenbarten eine Anreicherung des Kanals im axonalen Wachstumskegel sowie an Ranvier'schen
Schnürringen von isolierten Nervenfasern wildtypischer Mäuse. Motoneurone von NaV1.9 knock-out Mäusen zeigen reduzierte Spontanaktivität und eine Reduktion des
Axonwachstums, welche durch NaV1.9 Überexpression normalisiert werden kann. In Motoneuronen von Smn-defizienten Mäusen konnte keine Abweichung der NaV1.9
Proteinverteilung nachgewiesen werden.
Kürzlich wurden Patienten identifiziert, die eine missense-Mutation im NaV1.9 kodierenden SCN11A Gen tragen. Diese Patienten können keinerlei Schmerz empfinden und leiden zudem an Muskelschwäche in Kombination mit einer verzögerten motorischen Entwicklung.
Im Rahmen dieser Doktorarbeit konnten molekularbiologische Untersuchungen an Mäusen,
welche die Mutation im orthologen Scn11a Gen tragen, zur Aufklärung des Krankheitsmechanismus beitragen. Die Kooperationsstudie zeigte, dass eine gesteigerte
Funktion von NaV1.9 diese spezifische Kanalerkrankung auslöst, was die Wichtigkeit von NaV1.9 in menschlichen Motoneuronen unterstreicht.
Eine frühere Studie beschrieb an hippocampalen Neuronen, dass die Rezeptortyrosinkinase tropomyosin receptor kinase B (TrkB) den NaV1.9 Kanal öffnen kann. Im Wachstumskegel von Motoneuronen ist TrkB nachweisbar und folglich in räumlicher Nähe zu NaV1.9 zu finden.
Um zu prüfen, ob TrkB in die spontane Erregbarkeit von Motoneuronen involviert ist, wurden TrkB knock-out Mäuse untersucht. Isolierte Motoneurone von TrkB knock-out Mäusen weisen eine Reduktion der Spontanaktivität und eine Verringerung des Axonwachstums auf.
Ob TrkB und NaV1.9 hierbei funktionell gekoppelt sind, ist Gegenstand künftiger Forschung. / During development of the nervous system, spontaneous Ca2+ transients are observed that regulate the axon growth of motoneurons. This form of spontaneous neuronal activity is reduced in motoneurons from a mouse model of spinal muscular atrophy and this defect correlates with reduced axon elongation. Experiments from our group demonstrated that voltage-gated sodium channel pore blockers decrease spontaneous neuronal activity and
axon growth in cultured motoneurons, too. In these experiments, saxitoxin was more potent than tetrodotoxin. We identified the saxitoxin-sensitive/tetrodotoxin-insensitive voltage-gated sodium channel NaV1.9 as trigger for the opening of voltage-gated calcium channels. In motoneurons, expression of NaV1.9 was verified via quantitative RT-PCR. Immuno labelling
experiments revealed enrichment of the channel in axonal growth cones and at the nodes of Ranvier of isolated nerve fibres from wild type mice. Motoneurons from NaV1.9 knock-out mice show decreased spontaneous activity and reduced axonal elongation. This growth defect can be rescued by NaV1.9 overexpression. In motoneurons from Smn-deficient mice, NaV1.9 distribution appeared to be normal.
Recently, patients carrying a missense mutation in the NaV1.9-encoding gene SCN11A were identified. These patients are not able to feel pain and suffer from muscular weakness and a delayed motor development. Molecular biological work during this dissertation supported the analysis of this mutation in a mouse model carrying the orthologous alteration in the Scn11a
locus. The cooperation study confirmed that a gain-of-function mechanism underlies the NaV1.9-mediated channelopathy, thus suggesting a functional role of NaV1.9 in human motoneurons.
An earlier study showed in hippocampal neurons that the receptor tyrosine kinase tropomyosin receptor kinase B (TrkB) can open the NaV1.9 channel. TrkB is localized in
growth cones of motoneurons and subsequently found in close proximity to NaV1.9. In order to proof whether TrkB is involved in spontaneous excitability in motoneurons, TrkB knock-out mice were analysed. Isolated motoneurons from TrkB knock-out mice show a reduced spontaneous activity and axon elongation. It remains to be studied whether TrkB and NaV1.9 are functionally connected.
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Whole transcriptome profiling of compartmentalized motoneurons / Globale Transkriptomanalyse von kompartimentierten MotoneuronenSaal, Lena January 2017 (has links) (PDF)
Spinal muscular atrophy and amyotrophic lateral sclerosis are the two most common devastating motoneuron diseases. The mechanisms leading to motoneuron degeneration are not resolved so far, although different hypotheses have been built on existing data. One possible mechanism is disturbed axonal transport of RNAs in the affected motoneurons. The underlying question of this study was therefore to characterize changes in transcript levels of distinct RNAs in cell culture models of spinal muscular atrophy and amyotrophic lateral sclerosis, especially in the axonal compartment of primary motoneurons.
To investigate this in detail we first established compartmentalized cultures of Primary mouse motoneurons. Subsequently, total RNA of both compartments was extracted
separately and either linearly amplified and subjected to microarray profiling or whole transcriptome amplification followed by RNA-Sequencing was performed. To make
the whole transcriptome amplification method suitable for compartmentalized cultures, we adapted a double-random priming strategy. First, we applied this method
for initial optimization onto serial dilutions of spinal cord RNA and later on to the compartmentalized motoneurons.
Analysis of the data obtained from wildtype cultures already revealed interesting results. First, the RNA composition of axons turned out to be highly similar to the somatodendritic compartment. Second, axons seem to be particularly enriched for transcripts related to protein synthesis and energy production. In a next step we
repeated the experiments by using knockdown cultures. The proteins depleted hereby are Smn, Tdp-43 and hnRNP R. Another experiment was performed by knocking down the non-coding RNA 7SK, the main interacting RNA of hnRNP R.
Depletion of Smn led to a vast number of deregulated transcripts in the axonal and somatodendritic compartment. Transcripts downregulated in the axons upon Smn depletion were especially enriched for GOterms related to RNA processing and encode proteins located in neuron projections including axons and growth cones.
Strinkingly, among the upregulated transcripts in the somatodendritic compartment we mainly found MHC class I transcripts suggesting a potential neuroprotective role.
In contrast, although knockdown of Tdp-43 also revealed a large number of downregulated transcripts in the axonal compartment, these transcripts were mainly
associated with functions in transcriptional regulation and RNA splicing. For the hnRNP R knockdown our results were again different. Here, we observed
downregulated transcripts in the axonal compartment mainly associated with regulation of synaptic transmission and nerve impulses. Interestingly, a comparison between deregulated transcripts in the axonal compartment of both hnRNP R and 7SK knockdown presented a significant overlap of several transcripts suggesting
some common mechanism for both knockdowns.
Thus, our data indicate that a loss of disease-associated proteins involved in axonal RNA transport causes distinct transcriptome alterations in motor axons. / Spinale Muskelatrophie und Amyotrophe Lateralsklerose zählen zu den beiden häufigsten und schwersten Motoneuronerkrankungen. Der zugrunde liegende
Mechanismus beider Krankheiten ist bis heute nicht geklärt, dennoch werden verschiedene Theorien diskutiert. Ein möglicher Grund ist ein gestörter axonaler
Transport von RNAs in den betroffenen Motoneuronen. Daraus folgernd ergab sich die zugrunde liegende Frage dieser Arbeit, ob Veränderungen in den
Transkriptleveln bestimmter RNAs unter krankheitsähnlichen Bedingungen vor allem im axonalen Kompartiment von primären Maus-Motoneuronen beobachtet werden können.
Um die Fragestellung genauer zu untersuchen, etablierten wir zuerst kompartimentierte Kulturen von primären Motoneuronen. Darauffolgend haben wir die totale RNA aus beiden Kompartimenten separat extrahiert und entweder diese linear amplifiziert und zur Microarrayanalyse gegeben oder wir führten eine Amplifikation des kompletten Transkriptoms mit anschließender RNA-Sequenzierung durch. Um die Amplifikation des kompletten Transkriptoms auch für die kompartimentierten Kulturen geeignet zu machen, verwendeten wir eine doublerandom
priming Strategie und haben diese entsprechend angepasst. Zuerst wendeten wir die Methode an Serienverdünnungen von RNA aus dem Rückenmark an, um die Methode zu optimisieren. Später benutzten wir die Methode ebenfalls für kompartimentierte Motoneurone.
Schon die Analyse der Wildtyp-Daten lieferte interessante Ergebnisse. Erstens, die Zusammensetzung der RNA in Axonen war höchst ähnlich zu der im somatodendritischen Kompartiment. Zweitens, in Axonen scheinen speziell
Transkripte angereichert zu sein, welche mit Proteinsynthese und Energieproduktion in Verbindung stehen. In einem nächsten Schritt wurden dann die Experimente unter Verwendung von Knockdown-Kulturen wiederholt. Die Proteine, die dabei vermindert
wurden waren Smn, Tdp-43 und hnRNP R. Ein weiteres Experiment wurde durchgeführt indem die nicht-codierende RNA 7SK verringert wurde. Die Depletion
von Smn führte zu einer hohen Anzahl an deregulierten Transkripten sowohl im axonalen, als auch im somatodendritischen Kompartiment. Transkripte, die im
axonalen Kompartiment nach Smn Depletion verringert waren, waren überwiegend für GOTerms angereichert, welche mit RNA Prozessierung in Verbindung stehen oder welche Proteine codieren, die in neuronalen Fortsätzen, einschließlich Axon und Wachstumskegel lokalisiert sind. Bemerkenswert ist, dass wir unter den
hochregulierten Transkripten im somatodendritischen Kompartiment überwiegend MHC Klasse I Transkripte gefunden haben. Dies könnte eine mögliche
neuroprotektive Rolle dieser Transkripte annehmen lassen. Im Gegensatz zu den Ergebnissen beim Smn Knockdown fanden wir beim Tdp-43 Knockdown ebenfalls eine große Anzahl an herunterregulierten Transkripten im axonalen Kompartiment,
diese sind allerdings überwiegend mit Funktionen in der Transkriptionsregulierung und beim RNA Splicing assoziiert. Die Ergebnisse des hnRNP R Knockdowns waren
ebenfalls unterschiedlich. Bei diesem fanden wir die herunteregulierten Transkripte im axonalen Kompartiment überwiegend mit einer Regulierung der synaptischen
Übertragung sowie mit Nervenimpulsen assoziiert. Interessanterweise zeigte ein Vergleich der deregulierten Transkripte sowohl im axonalen Kompartiment vom
hnRNP R Knockdown, als auch vom 7SK Knockdown eine signifikante Übereinstimmung mehrerer Transkripte. Dies lässt einen teilweise gemeinsamen Mechanismus für beide Genprodukte vermuten.
Somit deuten unsere Daten darauf hin, dass ein Verlust von krankheitsassoziierten Proteinen, die eine Rolle beim axonalen RNA-Transport spielen, zu verschiedenen
Transkriptomveränderungen in Axonen von Motoneuronen führt.
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Molecular Mechanisms Regulating Developmental Axon PruningSingh, Karun 01 August 2008 (has links)
The formation of neural connections in the mammalian nervous system is a complex process. During development, axons are initially overproduced and compete for limited quantities of target-derived growth factors. Axons which participate in functional circuits and secure appropriate amounts of growth factors are stabilized, while those axons that are either inappropriately connected or do not obtain sufficient concentrations of growth factors are eliminated in a process termed ‘axon pruning’. In this thesis, I examined the mechanisms that regulate pruning of peripheral, NGF-dependent sympathetic neurons that project to the eye. I determined that pruning of these projections in vivo requires the p75 neurotrophin receptor (p75NTR) and synthesis of brain-derived neurotrophic factor (BDNF) from the activity-dependent exon IV promoter. Furthermore, analysis of an in vitro model of axon competition, which is regulated by the interplay between nerve growth factor (NGF) and neuronal activity, revealed that p75NTR and BDNF are also essential for axon competition in culture. In this model, in the presence of NGF, neural activity confers a competitive growth advantage to stimulated, active axons by enhancing downstream TrkA (NGF receptor) signaling locally in axons. More interestingly, the unstimulated, inactive axons deriving from the same and neighboring neurons acquire a "growth disadvantage" due to secreted BDNF acting through p75NTR, which induces axon degeneration by suppressing TrkA signaling that is essential for axonal integrity. These data support a model where, during developmental axon competition, successful axons secrete BDNF in an activity-dependent fashion which activates p75NTR on unsuccessful neighboring axons, suppressing TrkA signaling, and ultimately promoting pruning by a degenerative mechanism.
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Molecular Mechanisms Regulating Neurite Growth, Innervation and SurvivalPark, Katya 16 March 2011 (has links)
The establishment of correct neural circuitry in the nervous system requires the interplay, integration, and coordination of a diverse set of cells and signals during development and in the adult. Two important events are the regulated initiation and growth of dendrites that receive and process synaptic information, and the establishment and maintenance of appropriate neural connectivity. The goals of this study are to identify the molecular mechanisms underlying dendrite growth and initiation, and to understand how neural connectivity is maintained in the adult nervous system.
I first identified a novel intracellular signal transduction pathway involving two kinases important in regulating dendrite development. I showed that the ILK-GSK3beta pathway is required for dendrite growth and initiation in both peripheral and central nervous system neurons.
I then asked how neural connectivity is maintained in the adult nervous system by examining the role of myelin in the intact nervous system. My results indicate that when myelin contacts aberrantly growing axons, it activates on those axons the p75 neurotrophin receptor (p75NTR), which in turn causes the local degeneration of those axons. I further identified the signal transduction pathway required for axon degeneration consisting of p75NTR and intracellular signaling proteins activated by this receptor, Rho-GDI, Rho, and caspase 6. This data establishes p75NTR as an important regulator of neural connectivity and identifies for the first time a degeneration-inducing signal transduction pathway activated by myelin. It also provides an explanation for why myelin inhibits regeneration of injured central nervous system axons.
Taken together, I identified a new signaling pathway important for regulating dendrite initiation and growth, and a novel role for myelin in maintaining neural connectivity. Both of these findings contribute to our knowledge of how such connectivity is established during development and maintained in the adult nervous system.
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Molecular Mechanisms Regulating Developmental Axon PruningSingh, Karun 01 August 2008 (has links)
The formation of neural connections in the mammalian nervous system is a complex process. During development, axons are initially overproduced and compete for limited quantities of target-derived growth factors. Axons which participate in functional circuits and secure appropriate amounts of growth factors are stabilized, while those axons that are either inappropriately connected or do not obtain sufficient concentrations of growth factors are eliminated in a process termed ‘axon pruning’. In this thesis, I examined the mechanisms that regulate pruning of peripheral, NGF-dependent sympathetic neurons that project to the eye. I determined that pruning of these projections in vivo requires the p75 neurotrophin receptor (p75NTR) and synthesis of brain-derived neurotrophic factor (BDNF) from the activity-dependent exon IV promoter. Furthermore, analysis of an in vitro model of axon competition, which is regulated by the interplay between nerve growth factor (NGF) and neuronal activity, revealed that p75NTR and BDNF are also essential for axon competition in culture. In this model, in the presence of NGF, neural activity confers a competitive growth advantage to stimulated, active axons by enhancing downstream TrkA (NGF receptor) signaling locally in axons. More interestingly, the unstimulated, inactive axons deriving from the same and neighboring neurons acquire a "growth disadvantage" due to secreted BDNF acting through p75NTR, which induces axon degeneration by suppressing TrkA signaling that is essential for axonal integrity. These data support a model where, during developmental axon competition, successful axons secrete BDNF in an activity-dependent fashion which activates p75NTR on unsuccessful neighboring axons, suppressing TrkA signaling, and ultimately promoting pruning by a degenerative mechanism.
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Molecular Mechanisms Regulating Neurite Growth, Innervation and SurvivalPark, Katya 16 March 2011 (has links)
The establishment of correct neural circuitry in the nervous system requires the interplay, integration, and coordination of a diverse set of cells and signals during development and in the adult. Two important events are the regulated initiation and growth of dendrites that receive and process synaptic information, and the establishment and maintenance of appropriate neural connectivity. The goals of this study are to identify the molecular mechanisms underlying dendrite growth and initiation, and to understand how neural connectivity is maintained in the adult nervous system.
I first identified a novel intracellular signal transduction pathway involving two kinases important in regulating dendrite development. I showed that the ILK-GSK3beta pathway is required for dendrite growth and initiation in both peripheral and central nervous system neurons.
I then asked how neural connectivity is maintained in the adult nervous system by examining the role of myelin in the intact nervous system. My results indicate that when myelin contacts aberrantly growing axons, it activates on those axons the p75 neurotrophin receptor (p75NTR), which in turn causes the local degeneration of those axons. I further identified the signal transduction pathway required for axon degeneration consisting of p75NTR and intracellular signaling proteins activated by this receptor, Rho-GDI, Rho, and caspase 6. This data establishes p75NTR as an important regulator of neural connectivity and identifies for the first time a degeneration-inducing signal transduction pathway activated by myelin. It also provides an explanation for why myelin inhibits regeneration of injured central nervous system axons.
Taken together, I identified a new signaling pathway important for regulating dendrite initiation and growth, and a novel role for myelin in maintaining neural connectivity. Both of these findings contribute to our knowledge of how such connectivity is established during development and maintained in the adult nervous system.
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The effect of intravenous administration of 6-hydroxydopamine¡]6-OHDA¡^on plasma leakage in rat airwaysLin, Pei-Lu 07 August 2002 (has links)
Vagal and spinal sensory afferent innervation are responsible for to regulation of neurogenic inflammation in the airways. Neurogenic inflammation is a complex process involving vasodilatation,plasma protein extravasation and edema,glandular secretion and immunoinflammatory cell chemotaxis and activation. Plasma extravasation is the result of the activation of sensory nerve endings and the subsequent prodution of neuropeptides, namely, tachykinins such as substance P, neurokinin A and neurokinin B. SP was more potent than NKA or NKB in increasing microvascular permeability, which indicate that tachykinin NK-1 receptors are mainly involved in neurogenic inflammation in the airways of rat.
When 6-hydroxydopamine¡]6-OHDA¡^was infused into the tracheal lumen,it causes plasma extravasation in the tracheal mucosa mediated by sensory nerve axons. Local application of 6-OHDA to stellate ganglion, had no effect on neurogenic inflammation and SP-IR innervation in the airways.The present study was to investigate the effect of intravenous injection of 6-OHDA on plasma leakage in the airways.This study also used the NK-1 receptor antagonist L-732,138 to investigate if 6-OHDA-induced plasma leakage in the airways was related to NK-1 receptors. India ink was used as tracer dye to label the leaky microvessels to evaluate the magnitude of inflammation .
We found that 6-OHDA in the doses of 25 mg/kg and 50 mg/kg caused an extensive increase in plasma extravasation in the trachea and bronchi. But the vehicle¡]1 ¢ML-ascorbic acid and 0.4 ¢MNaCl, pH 3.4¡^caused a slight plasma leakage. Intravenous administration of L-732,138 decrease 6-OHDA induced plasma leakage. But one week after vagal transection, 6-OHDA-induced plasma extravasation in the ipsilateral airways was not significatly reduced. It is suggested that intravenous 6-OHDA stimulated bronchopulmonary C-fibers and resulted in vagal C-fiber release of tachykinins that produced acute inflammation in the lower airways. Intravenous application of L-732,138 significantly reduced the 6-OHDA-induced plasma leakage, suggesting that NK-1 receptors in the venular endothelial cells mediate the inflammatory response in the layynx,trachea,bronchi.and esophagus of the rat .
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Pathfinding of motor axons in facial nerve regeneration of the rat : influence of predegeneration of the proximal nerve stump /Mohammed, Barham. January 2008 (has links)
Zugl.: Giessen, University, Diss., 2008.
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