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Showing 71 to 80 of 84 (0.033 seconds)Spelling suggestions: "subject:"excitation""
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Expression and function of PSD-93 isoforms in hippocampal synapses / Expression und Funktion der PSD-93 Isoformen in Synapsen im HippocampusKrüger, Juliane Marie 09 August 2010 (has links)
No description available.
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Impact du genre et du modèle sur les mécanismes d’épileptogénèse dans le cerveau immatureFoadjo Awoume, Berline 04 1900 (has links)
Les modèles kainate et pentylènetétrazole représentent deux modèles d’épilepsie du lobe temporal dont les conséquences à long terme sont différentes. Le premier est un modèle classique d’épileptogénèse avec crises récurrentes spontanées tandis que le second se limite aux crises aigües. Nous avons d’abord caractérisé les différents changements survenant dans les circuits excitateurs et inhibiteurs de l’hippocampe adulte de rats ayant subi des crises à l’âge immature. Ensuite, ayant observé dans le modèle fébrile une différence du pronostic lié au genre, nous avons voulu savoir si cette différence était aussi présente dans des modèles utilisant des neurotoxines.
L’étude électrophysiologique a démontré que les rats KA et PTZ, mâles comme femelles, présentaient une hyperactivité des récepteurs NMDA au niveau des cellules pyramidales du CA1, CA3 et DG. Les modifications anatomiques sous-tendant cette hyperexcitabilité ont été étudiées et les résultats ont montré une perte sélective des interneurones GABAergiques contenant la parvalbumine dans les couches O/A du CA1 des mâles KA et PTZ. Chez les femelles, seul le DG était légèrement affecté pour les PTZ tandis que les KA présentaient, en plus du DG, des pertes importantes au niveau de la couche O/A. Les évaluations cognitives ont démontré que seuls les rats PTZ accusaient un déficit spatial puisque les rats KA présentaient un apprentissage comparable aux rats normaux. Cependant, encore une fois, cette différence n’était présente que chez les mâles. Ainsi, nos résultats confirment qu’il y a des différences liées au genre dans les conséquences des convulsions lorsqu’elles surviennent chez l’animal immature. / Kainate and pentylenetetrazole models represent two animal models of temporal lobe epilepsy in which long-term consequences differ. The first model is a classical model of epileptogenesis with spontaneous recurrent seizures while the second one is limited to acute seizures. We wanted to characterize the difference in changes which occur in excitatory and inhibitory systems of the hippocampus of adult males and females having suffered an episode of status epilepticus during the immature stage of life. Besides having noticed a difference between genders in the febrile model, our second objective was to see if this difference was also present in models using neurotoxins.
Electrophysiology recordings indicated that KA and PTZ rats (both male and female) showed a hyperactivity of NMDA receptors in CA1, CA3 and DG pyramidal cells. Anatomical modifications causing hyperactivity were studied and results show a selective loss of specific GABA interneurons PV in the O/A layer of CA1 region of the hippocampus in KA and PTZ male rats. However in female rats, only the DG layer was slightly affected in PTZ while female KA presented losses in both DG and O/A layers.
Cognitive evaluation indicated that only PTZ rats showed a spatial impairment since KA rats had a similar learning pattern as controls. However, once again, that difference was observed only in males and not in females.
In summary, our results confirmed that there is a difference between genders regarding brain damages after having suffered an episode of status epilepticus during the immature stage.
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Estudo da atividade antinociceptiva e anti-inflamatória do monoterpeno a,b-Epoxi-carvona e seu efeito sobre a neurotransmissão glutamatérgica / Study of antinociceptive and antiinflammatory monoterpene a,b-epoxy-carvone and its effect on glutamatergic neurotransmission.Rocha, Marilene Lopes da 08 July 2010 (has links)
Made available in DSpace on 2015-05-14T13:00:16Z (GMT). No. of bitstreams: 1
arquivototal.pdf: 1182383 bytes, checksum: 1ff4fac23517aa4b22351ae87d21b4be (MD5)
Previous issue date: 2010-07-08 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - CAPES / The a, b-epoxy-carvone (EC) monoterpene is found in many essential oils from
plants, but can also be obtained through organic synthesis from the R-(-)-carvone.
Previous studies have demonstrated that this compound exerts depressant effect on
central nervous system (CNS), and is also known to have anticonvulsant effects,
antioxidant and antimicrobial activities. This study investigated the antinociceptive
and antiinflammatory effects of EC in adult male Swiss mice, as well as, its effect on
glutamatergic neurotransmission in rats using behavioral tests, vascular permeability
test, measurement of paw edema and electrophysiological recordings in vitro,
respectively. Intraperiotoneal administration (ip) of EC at doses of 200 or 300 mg/kg
provided a significant antinociceptive effect as shown in the writhing test induced by
acetic acid. The EC also caused a reduction in formalin-induced nociception in the
first (at 300 mg/ g) and second phase (at 200 or 300 mg/kg). In the hot plate test an
increase in latency was found at 30 min (at 200 or 300 mg/kg) and 60 min (300
mg/kg) after administration of EC, the effect that was reversed by naloxone, an opioid
receptor antagonist. After administration of EC (300 mg / kg), the increased vascular
permeability induced by acetic acid was reduced, as well as the paw edema induced
by carrageenan. The EC reduced by 70% the excitatory postsynaptic potentials
(EPSP) field, as well as the glutamatergic EPSP of the pyramidal neurons from the
CA1 hippocampal region and the neurons from the nucleus of the solitary tract
(NTS). These results suggest that EC has peripheral and central antinociceptive
activity in mice, probably related to opioid system activation and inhibition of acute
inflammatory reaction. In addition, EC has depressant effects on excitatory
postsynaptic neurotransmission. / A a,b-epoxy-carvona (EC) é um monoterpeno encontrado em muitos óleos
essenciais (OE s) de plantas, mas também pode ser obtida por meio da síntese
orgânica a partir da R-(-)-carvona. Estudos prévios demonstraram que esse
composto exerce efeito depressor no sistema nervoso central (SNC), e é também
conhecida por ter efeitos anticonvulsivantes, antioxidante e antimicrobial. O presente
estudo investigou os efeitos antinociceptivo e anti-inflamatório da EC, em
camundongos suíços machos adultos, bem como seu efeito sobre a
neurotransmissão glutamatérgica em ratos usando testes comportamentais, teste da
permeabilidade vascular, medida de edema de pata e registros eletrofisiológicos in
vitro, respectivamente. A administração intraperiotoneal (i.p.) da EC nas doses de
200 ou 300 mg/kg promoveu um efeito antinociceptivo significante como mostrado
no teste das contorções abdominais induzidas pelo ácido acético. A EC também
provocou redução na nocicepção induzida pela formalina na primeira (300 mg/kg) e
na segunda fase (200 e 300 mg/kg). No teste da placa quente foi encontrado um
aumento da latência aos 30 min (nas doses de 200 ou 300 mg/kg) e aos 60 min (na
dose de 300 mg/kg) após a administração da EC, um efeito que foi revertido pela
naloxona, um antagonista do receptor opióide. Após a administração da EC (300
mg/kg), o aumento da permeabilidade vascular provocado pelo ácido acético foi
reduzido, bem como, o edema de pata em camundongos provocada pela
carragenina. A EC reduziu em 70% os potenciais pós-sinápticos excitatórios (PEPS)
de campo como também os PEPS glutamatérgicos dos neurônios piramidais da
região CA1 do hipocampo e dos neurônios do núcleo do trato solitário (NTS). Estes
resultados sugerem que EC apresenta atividade antinociceptiva periférica e central
em camundongos, provavelmente associada à ativação do sistema opioidérgico, e
inibição da reação inflamatória aguda. Além disso, EC exerce efeito depressor na
neurotransmissão pós-sináptica excitatória.
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Spike-Timing-Dependent Plasticity at Excitatory Synapses on the Rat Subicular Pyramidal NeuronsPandey, Anurag January 2014 (has links) (PDF)
The subiculum is a structure that forms a bridge between the hippocampus and the entorhinal cortex (EC) in the brain, and plays a major role in the memory consolidation process. It consists of different types of pyramidal neurons. Based on their firing behavior, these excitatory neurons are classified into strong burst firing (SBF), weak burst firing (WBF) and regular firing (RF) neurons. In the first part of the work, morphological differences in the different neuronal subtypes was explored by biocytin staining after classifying the neurons based on the differences in electrophysiological properties. Detailed morphological properties of these three neuronal subtypes were analyzed using Neurolucida neuron reconstruction method. Unlike the differences in their electrophysiological properties, no difference was found in the morphometric properties of these neuronal subtypes.
In the second part of the thesis, experimental results on spike- timing- dependent plasticity (STDP) at the proximal excitatory inputs on the subicular pyramidal neurons of the juvenile (P15-P19) rat are described. The STDP was studied in the WBF and RF neurons. Causal pairing of a single EPSP with a single back propagating action potential (bAP) at a time interval of 10 ms failed to induce plasticity. However, increasing the number of bAPs in such EPSP-bAP pair to three at 50 Hz (bAP burst) induced LTD in both, the RF, as well as the WBF neurons. Increasing the frequency of action potentials to 150 Hz in the bAP burst during causal pairing also induced LTD in both the neuronal subtypes. However, all other STDP related experiments were performed only with the bAP bursts consisting of 3 bAPs evoked at 50 Hz. Amplitude of the causal pairing induced LTD decreased with increasing time interval between EPSP and the bAP burst. Reversing the order of the EPSP and the bAP burst in the pair induced LTP only with a short time interval of 10 ms. This finding is in contrast to most of the reports on excitatory synapses, wherein the pre-before post (causal) pairing induced LTP and vice-versa. The results of causal and anti-causal pairing were used to plot the STDP curve for the WBF neurons. In the STDP curve observed in these synapses, LTD was observed upto a causal time interval of 30 ms, while LTP was limited to 10 ms time interval. Hence, the STDP curve was biased towards LTD. These results reaffirm the earlier observations that the relative timing of the pre- and
postsynaptic activities can lead to multiple types of STDP curves. Next, the mechanism of non-Hebbian LTD was studied in both, the RF and WBF neurons. The involvement of calcium in the postsynaptic neuron in plasticity induction was studied by chelating intracellular calcium with BAPTA. The results indicate that the LTD induction in WBF neurons required postsynaptic calcium, while LTD induction in the RF neurons was independent of postsynaptic calcium. Paired pulse ratio (PPR) experiments suggested the involvement of a presynaptic mechanism in the induction of LTD in the RF neurons, and not in the WBF neurons since the PPR was unaffected by the induction protocol only in the WBF neurons. LTD induction in the WBF neurons required activity of the NMDA receptors since LTD was not observed in the presence of the NMDA receptor blocker in the WBF neurons, while it was unaffected in the RF neurons. However, the RF neurons required the activity of L-type calcium channels for plasticity induction, since LTD was affected in the presence of the L-type calcium channel blockers, although the WBF neurons did not require the L-type calcium channel activity for plasticity induction. Hence, in addition to a non-Hebbian STDP curve, a novel mechanism of LTD induction has been reported, where L-type calcium channels are involved in a synaptic plasticity that is expressed via change in the release probability. The findings on the STDP in subicular pyramidal neurons may have strong implications in the memory consolidation process owing to the central role of the subiculum and LTD in it.
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Molecular Players in Preserving Excitatory-Inhibitory Balance in the BrainMao, Wenjie 07 December 2017 (has links)
Information processing in the brain relies on a functional balance between excitation and inhibition, the disruption of which leads to network destabilization and many neurodevelopmental disorders, such as autism spectrum disorders. One of the homeostatic mechanisms that maintains the excitatory and inhibitory balance is called synaptic scaling: Neurons dynamically modulate postsynaptic receptor abundance through activity-dependent gene transcription and protein synthesis. In the first part of my thesis work, I discuss our findings that a chromatin reader protein L3mbtl1 is involved in synaptic scaling. We observed that knockout and knockdown of L3mbtl1 cause a lack of synaptic downscaling of glutamate receptors in hippocampal primary neurons and organotypic slice cultures. Genome-wide mapping of L3mbtl1 protein occupancies on chromatin identified Ctnnb1 and Gabra2 as downstream target genes of L3mbtl1-mediated transcriptional regulation. Importantly, partial knockdown of Ctnnb1 by itself prevents synaptic downscaling. Another aspect of maintaining E/I balance centers on GABAergic inhibitory neurons. In the next part of my thesis work, we address the role of the scaffold protein Shank1 in excitatory synapses onto inhibitory interneurons. We showed that parvalbumin-expressing interneurons lacking Shank1 display reduced excitatory synaptic inputs and decreased levels of inhibitory outputs to pyramidal neurons. As a consequence, pyramidal neurons in Shank1 mutant mice exhibit increased E/I ratio. This is accompanied by a reduced expression of an inhibitory synapse scaffolding protein gephyrin. These results provide novel insights into the roles of chromatin reader molecules and synaptic scaffold molecules in synaptic functions and neuronal homeostasis.
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Riluzole elevates GLT-1 activity and levels in striatal astrocytesCarbone, M., Duty, S., Rattray, Marcus January 2012 (has links)
No / Drugs which upregulate astrocyte glutamate transport may be useful neuroprotective compounds by preventing excitotoxicity. We set up a new system to identify potential neuroprotective drugs which act through GLT-1. Primary mouse striatal astrocytes grown in the presence of the growth-factor supplement G5 express high levels of the functional glutamate transporter, GLT-1 (also known as EAAT2) as assessed by Western blotting and (3)H-glutamate uptake assay, and levels decline following growth factor withdrawal. The GLT-1 transcriptional enhancer dexamethasone (0.1 or 1 muM) was able to prevent loss of GLT-1 levels and activity following growth factor withdrawal. In contrast, ceftriaxone, a compound previously reported to enhance GLT-1 expression, failed to regulate GLT-1 in this system. The neuroprotective compound riluzole (100 muM) upregulated GLT-1 levels and activity, through a mechanism that was not dependent on blockade of voltage-sensitive ion channels, since zonasimide (1 mM) did not regulate GLT-1. Finally, CDP-choline (10 muM-1 mM), a compound which promotes association of GLT-1/EAAT2 with lipid rafts was unable to prevent GLT-1 loss under these conditions. This observation extends the known pharmacological actions of riluzole, and suggests that this compound may exert its neuroprotective effects through an astrocyte-dependent mechanism.
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SUMOylation and phosphorylation of GluK2 regulate kainate receptor trafficking and synaptic plasticityChamberlain, S.E., Gonzàlez-Gonzàlez, I.M., Wilkinson, K.A., Konopacki, F.A., Kantamneni, Sriharsha, Henley, J.M., Mellor, J.R. January 2012 (has links)
No / Phosphorylation or SUMOylation of the kainate receptor (KAR) subunit GluK2 have both individually been shown to regulate KAR surface expression. However, it is unknown whether phosphorylation and SUMOylation of GluK2 are important for activity-dependent KAR synaptic plasticity. We found that protein kinase C-mediated phosphorylation of GluK2 at serine 868 promotes GluK2 SUMOylation at lysine 886 and that both of these events are necessary for the internalization of GluK2-containing KARs that occurs during long-term depression of KAR-mediated synaptic transmission at rat hippocampal mossy fiber synapses. Conversely, phosphorylation of GluK2 at serine 868 in the absence of SUMOylation led to an increase in KAR surface expression by facilitating receptor recycling between endosomal compartments and the plasma membrane. Our results suggest a role for the dynamic control of synaptic SUMOylation in the regulation of KAR synaptic transmission and plasticity.
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Genetically modified peripheral neurons transplant aided activity maintenance and secretome modulation: a novel strategy for spinal cord injury treatmentHingorani Jai Prakash, Sonia 29 July 2024 (has links)
[ES] El sistema nervioso forma una red de circuitos neuronales esenciales para la locomoción. El sistema nervioso central (cerebro y médula espinal) transmite información a los músculos. Mientras el sistema nervioso periférico puede regenerarse, el central tiene una capacidad regenerativa limitada. Por ello, las lesiones en el sistema nervioso central son críticas y a menudo carecen de cura. Una de ellas es la lesión de la médula espinal, una condición devastadora sin tratamiento eficaz. Una lesión interrumpe la entrada supraespinal en la médula espinal, conduciendo a disfunción locomotora debajo de la lesión. La relación alterada entre excitación e inhibición, con un aumento en la inhibición y la limitada regeneración de los tractos neuronales afectados, limitan la función locomotora. Como resultado, puede ocurrir parálisis completa incluso en pacientes con lesiones incompletas.
Esta tesis doctoral define una terapia combinada para tratar la lesión de la médula espinal. Hipotetizamos que, para ayudar a la regeneración de los tractos, un trasplante neuronal periférico (ganglios de la raíz dorsal, DRG) que retiene la capacidad de regeneración puede ser efectivo. Para alterar la inhibición y mejorar la supervivencia del trasplante, se empleó la sobreexpresión del canal de sodio bacteriano, NaChBac. Finalmente, para mejorar la regeneración axonal, utilizamos medicamentos que modulan el citoesqueleto.
En el Capítulo 1, validamos nuestra hipótesis con estudios in vitro. Observamos el efecto de Epothilone B y Blebbistatin en la longitud de las neuritas in vitro. Mientras Blebbistatin aumenta la longitud de las neuritas, la combinación con Epothilone la disminuye. Luego, describimos el efecto de NaChBac en los DRG y las células Neuro-2A. En las DRG, NaChBac aumenta la actividad y secreción de factores neurotróficos, promoviendo la señalización pro-supervivencia y anti-apoptótica en las Neuro-2A. Finalmente, describimos cómo la expresión de NaChBac y Blebbistatin mejora la longitud de las neuritas in vitro.
En el Capítulo 2, evaluamos la supervivencia y eficacia del trasplante de DRG con el tracto corticoespinal, el más importante en la locomoción, en un estudio in vivo. Encontramos una adecuada integración del trasplante en el tejido huésped. La expresión de NaChBac aumenta la supervivencia de las células trasplantadas y mejora la preservación del tracto corticoespinal.
En el Capítulo 3, evaluamos el tratamiento combinado en un escenario de lesión crónica y severa. La combinación del trasplante que expresa NaChBac y Blebbistatin limita la recuperación funcional, mientras que el trasplante que expresa NaChBac mejora significativamente la función locomotora en ratones. Los animales trasplantados con DRGs que expresan NaChBac tenían un aumento de fibras neuronales positivas para tubulina, con mayor preservación de mielina, aunque las fibras descendentes serotonérgicas y corticoespinales no mostraron cambios significativos entre los grupos. El trasplante de DRGs que expresan NaChBac aumentó significativamente el input excitatorio neto, determinado por el aumento de contactos de VGLUT2 y la disminución de VGAT en los somas de las neuronas inmediatamente caudales a las lesiones.
Esta tesis sugiere que el trasplante de DRGs que expresan NaChBac rescata parte de la función motora perdida, manteniendo la actividad neuronal excitatoria caudal a la zona lesionada, destacando la relevancia del mantenimiento de la actividad neuronal como estrategia terapéutica para el rescate funcional de lesiones medulares severas. / [CA] El sistema nerviós forma una xarxa organitzada de circuits neuronals que són essencials per la locomoció. El sistema nerviós central (cervell i la medul·la espinal) rep i transmet informació de manera eficaç que és transmesa pel sistema nerviós perifèric als músculs, que comporta a moviment. El sistema nerviós perifèric té capacitat de regeneració, però el central té limitacions. Per això, les lesions en el sistema nerviós central sovint manquen de cura. Una d'elles és la lesió de la medul·la espinal, una condició debilitant que manca d'una cura eficaç. Una lesió resulta en una interrupció de l'entrada supraespinal en la medul·la espinal i conduïx a una disfunció locomotora. La relació alterada entre excitació i inhibició, un augment en la inhibició, juntament amb la capacitat limitada de regeneració endògena, limiten encara més la funció locomotora. Com a resultat, la paràlisi completa pot ocórrer fins i tot en pacients amb lesions anatòmicament incompletes. En esta tesi, ens centrem en estes idees principals per a definir una teràpia combinada. Hipotetizamos que, per a ajudar a la capacitat limitada de regeneració dels tractes, un trasplantament neuronal perifèric (ganglis de l'arrel dorsal, DRG) que reté la capacitat intrínseca de regeneració pot ser efectiva. Per a alterar la inhibició, millorar la supervivència i integració del trasplantament en els circuits, es va a emprar la sobreexpresió del canal de sodi, NaChBac. Finalment, per a dirigir i millorar la regeneració axonal, utilitzem medicaments que modulen el citoesquelet per a millorar la longitud axonal. Esta tesi estudia els efectes d'esta estratègia combinada.
En el Capítol 1, estudiem l'efecte sinèrgic dels medicaments que modulen el citoesquelet Epothilone B i Blebbistatin en la longitud de les neurites in vitro i observem que el tractament individual amb Blebbistatin augmenta la longitud dels neurites, la combinació amb Epothilone conduïx a una morfologia del con de creixement alterada que resulta en disminució de la longitud dels neurites. Després, descrivim l'efecte de l'expressió de NaChBac en els DRG i les cèl·lules Neuro-2A. En les DRG, l'expressió de NaChBac conduïx a un augment en l'activitat intrínseca i la secreció de factors neurotrófics, promovent la senyalització pro-supervivència i la senyalització anti-apoptótic en les cèl·lules Neuro-2A. Finalment, descrivim com l'efecte combinat de l'expressió de NaChBac i Blebbistatin millora la longitud dels neurites.
En el Capítol 2, avaluem la supervivència i interacció del trasplantament de DRG amb el tracte corticoespinal. Trobem una integració i supervivència adequada del trasplantament. A més, vam mostrar que l'expressió de NaChBac augmenta la supervivència del nombre total de cèl·lules trasplantades, així com millora la preservació del tracte corticoespinal després de la lesió.
En el Capítol 3, avaluem l'efecte del tractament combinat en una lesió crònica i severa. Vam demostrar que la combinació del trasplantament que expressa NaChBac i Blebbistatin limita la recuperació funcional, mentres que el trasplantament que expressa NaChBac millora significativament la funció locomotora en ratolins. Per tant, descrivim que els animals trasplantats amb DRGs que expressen NaChBac tenien un augment en la fibra neuronal positiva per a tubulina i la preservació de la mielina, mentres que les fibres descendents serotonérgics i corticoespinales van romandre sense alteració. Trobem que el trasplantament de DRGs que expressen NaChBac va augmentar l'entrada neuronal excitatoria, com es va observar per l'augment en el nombre de contactes de VGLUT2 i la disminució en els contactes de VGAT cabals a les lesions. Així, la tesi suggereix que el trasplantament de DRGs amb NaChBac rescata la funció motora en lesions de la medul·la espinal en retindre una activitat de relé neuronal excitatoria cabal a les lesions en un model sever de lesió i destaca la importància del manteniment de l'activitat com a teràpia efectiva. / [EN] The nervous system forms specialized neuronal circuitry and organization that are essential for locomotion. The central nervous system (brain, spinal cord) receives and relays information, delivered by the peripheral nervous system to muscles to achieve locomotion. It is known that the peripheral nervous system retains its ability to regenerate, the central nervous system has little to no regenerative capacity in adult stages. Therefore, injuries to the central nervous system are critical and lack cure. One such is spinal cord injury; a debilitating condition that lacks an effective treatment. An injury results in severing of supraspinal input into the spinal cord, leading to locomotor dysfunction beneath the injury. Altered excitation inhibition ratio after an injury, increase in inhibition and limited endogenous regeneration capacity of the affected neuronal tracts limit locomotor function. As a result, complete paralysis may occur in patients with anatomically incomplete injuries. In this thesis, we focus on these points to devise a combinatory approach as an effective treatment strategy. We hypothesized that to aid the limited regeneration capacity of the tracts, a peripheral neuronal transplant (dorsal root ganglia, DRG) which retains the intrinsic ability to regenerate can be effective. To overcome inhibition, improve survival and integration of the transplant into circuits, the overexpression of NaChBac sodium channel was employed. Finally, to target and improve the axonal regeneration of endogenous and transplanted cells, we use cytoskeleton modulating drugs to enhance axonal length. This thesis studies the effects of this combinatory approach to treat spinal cord injury.
In Chapter 1, we study the synergistic effect of cytoskeleton modulating drugs Epothilone B and Blebbistatin on neurite length and find that individual treatment with Blebbistatin increases neurite length, combination with Epothilone leads to an altered splayed morphology of the growth cone and decreased neurite length. Next, we describe the effect of NaChBac expression in DRGs and Neuro-2A cells. In DRGs, NaChBac expression leads to an increase in intrinsic activity and secretion of neurotrophic factors, promoting pro-survival signaling and anti-apoptotic signaling in Neuro-2A cells. Finally, we describe the combinatory effect of NaChBac expression and Blebbistatin further improves neurite length in vitro.
In Chapter 2, we evaluate the survival, efficacy, and interaction of the DRG transplant with the corticospinal tract, the most important tract involved in locomotion in a short-term in vivo study. We report a satisfactory integration and survival of the transplant. We also show that NaChBac expression increases the survival of the total number of transplanted cells, as well as improves preservation of the corticospinal tract after the injury.
In Chapter 3, we study the effect of the combinatory treatment in a chronic, severe injury scenario. We find that the combination of the transplant expressing NaChBac and Blebbistatin limits functional recovery, while that of transplant expressing NaChBac significantly improved locomotor function in mice. Therefore, focusing on this, we report that animals transplanted with NaChBac-expressing DRGs had increased tubulin-positive neuronal fiber and myelin preservation, while serotonergic and corticospinal descending fibers remained unaffected. We found that transplantation of NaChBac-expressing DRGs increased the neuronal excitatory input, seen by increased number of VGLUT2 contacts and decrease in VGAT contacts immediately caudal to the injuries. Together, the work in this thesis suggests that the transplantation of NaChBac-expressing dissociated DRGs rescues significant motor function by retaining an excitatory neuronal relay activity immediately caudal to injuries in a severe injury model and highlights the importance of maintenance of activity as an effective therapy for spinal cord injury. / Hingorani Jai Prakash, S. (2024). Genetically modified peripheral neurons transplant aided activity maintenance and secretome modulation: a novel strategy for spinal cord injury treatment [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/206738
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Role of the cotransporter KCC2 in cortical excitatory synapse development and febrile seizure susceptibilityAwad, Patricia Nora 08 1900 (has links)
Le co-transporteur KCC2 spécifique au potassium et chlore a pour rôle principal de réduire la concentration intracellulaire de chlore, entraînant l’hyperpolarisation des courants GABAergic l’autorisant ainsi à devenir inhibiteur dans le cerveau mature. De plus, il est aussi impliqué dans le développement des synapses excitatrices, nommées aussi les épines dendritiques. Le but de notre projet est d’étudier l’effet des modifications concernant l'expression et la fonction de KCC2 dans le cortex du cerveau en développement dans un contexte de convulsions précoces.
Les convulsions fébriles affectent environ 5% des enfants, et ce dès la première année de vie. Les enfants atteints de convulsions fébriles prolongées et atypiques sont plus susceptibles à développer l’épilepsie. De plus, la présence d’une malformation cérébrale prédispose au développement de convulsions fébriles atypiques, et d’épilepsie du lobe temporal. Ceci suggère que ces pathologies néonatales peuvent altérer le développement des circuits neuronaux irréversiblement. Cependant, les mécanismes qui sous-tendent ces effets ne sont pas encore compris. Nous avons pour but de comprendre l'impact des altérations de KCC2 sur la survenue des convulsions et dans la formation des épines dendritiques.
Nous avons étudié KCC2 dans un modèle animal de convulsions précédemment validé, qui combine une lésion corticale à P1 (premier jour de vie postnatale), suivie d'une convulsion induite par hyperthermie à P10 (nommés rats LHS). À la suite de ces insultes, 86% des rats mâles LHS développent l’épilepsie à l’âge adulte, au même titre que des troubles d’apprentissage. À P20, ces animaux presentent une augmentation de l'expression de KCC2 associée à une hyperpolarisation du potentiel de réversion de GABA. De plus, nous avons observé des réductions dans la taille des épines dendritiques et l'amplitude des courants post-synaptiques excitateurs miniatures, ainsi qu’un déficit de mémoire spatial, et ce avant le développement des convulsions spontanées. Dans le but de rétablir les déficits observés chez les rats LHS, nous avons alors réalisé un knock-down de KCC2 par shARN spécifique par électroporation in utero. Nos résultats ont montré une diminution de la susceptibilité aux convulsions due à la lésion corticale, ainsi qu'une restauration de la taille des épines. Ainsi, l’augmentation de KCC2 à la suite d'une convulsion précoce, augmente la susceptibilité aux convulsions modifiant la morphologie des épines dendritiques, probable facteur contribuant à l’atrophie de l’hippocampe et l’occurrence des déficits cognitifs.
Le deuxième objectif a été d'inspecter l’effet de la surexpression précoce de KCC2 dans le développement des épines dendritiques de l’hippocampe. Nous avons ainsi surexprimé KCC2 aussi bien in vitro dans des cultures organotypiques d’hippocampe, qu' in vivo par électroporation in utero. À l'inverse des résultats publiés dans le cortex, nous avons observé une diminution de la densité d’épines dendritiques et une augmentation de la taille des épines. Afin de confirmer la spécificité du rôle de KCC2 face à la région néocorticale étudiée, nous avons surexprimé KCC2 dans le cortex par électroporation in utero. Cette manipulation a eu pour conséquences d’augmenter la densité et la longueur des épines synaptiques de l’arbre dendritique des cellules glutamatergiques. En conséquent, ces résultats ont démontré pour la première fois, que les modifications de l’expression de KCC2 sont spécifiques à la région affectée. Ceci souligne les obstacles auxquels nous faisons face dans le développement de thérapie adéquat pour l’épilepsie ayant pour but de moduler l’expression de KCC2 de façon spécifique. / The potassium-chloride cotransporter KCC2 decreases intracellular Cl- levels and renders GABA responses inhibitory. In addition, it has also been shown to modulate excitatory synapse development. In this project, we investigated how alterations of KCC2 expression levels affect these two key processes in cortical structures of a normal and/or epileptic developing brain.
First, we demonstrate that KCC2 expression is altered by early-life febrile status epilepticus. Febrile seizures affect about 5% of children during the first year of life. Atypical febrile seizures, particularly febrile status epilepticus, correlate with a higher risk of developing cognitive deficits and temporal lobe epilepsy as adults, suggesting that they may permanently change the developmental trajectory of neuronal circuits. In fact, the presence of a cerebral malformation predisposes to the development of atypical febrile seizures and temporal lobe epilepsy. The mechanisms underlying these effects are not clear. Here, we investigated the functional impact of this alteration on subsequent synapse formation and seizure susceptibility.
We analyzed KCC2 expression and spine density in the hippocampus of a well-established rodent model of atypical febrile seizures, combining a cortical freeze lesion at post-natal day 1 (P1) and hyperthermia-induced seizure at P10 (LHS rats). 86% of these LHS males develop epilepsy and learning and memory deficits in adulthood. At P20, we found a precocious increase in KCC2 protein levels, accompanied by a negative shift of the reversal potential of GABA (EGABA) by gramicidin-perforated patch. In parallel, we observed a reduction in dendritic spine size by DiI labelling and a reduction of miniature excitatory postsynaptic current (mEPSC) amplitude in CA1 pyramidal neurons, as well as impaired spatial memory. To investigate whether the premature expression of KCC2 played a role in these alterations in the LHS model, and on seizure susceptibility, we reduced KCC2 expression in CA1 pyramidal neurons by in utero electroporation of shRNA using a triple-probe electrode. This approach lead to reduced febrile seizure susceptibility, and rescued spine size shrinkage in LHS rats. Our results show that an increase of KCC2 levels induced by early-life insults affect seizure susceptibility and spine development and may be a contributing factor to the occurrence of hippocampal atrophy and associated cognitive deficits in LHS rats.
Second, we investigated whether KCC2 premature overexpression plays a role in spine alterations in the hippocampus. We overexpressed KCC2 in hippocampal organotypic cultures by biolistic transfection and in vivo by in utero electroporation. In contrast to what was previously published, we observed that both manipulations lead to a decrease in spine density in the hippocampus, as well as an increase in spine head size in vivo. In fact, it has been previously shown that overexpressing KCC2 leads to an increase of spine density in the cortex in vivo. To prove that this discrepancy is due to brain regional differences, we overexpressed KCC2 in the cortex by in utero electroporation, and similarly found an increase in spine density and length. Altogether, our results demonstrate for the first time, that alterations of KCC2 expression are brain circuit-specific. These findings highlights the obstacles we will face to find adequate pharmacological treatment to specifically modulate KCC2 in a region-specific and time-sensitive manner in epilepsy.
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Survey of Selective NeurotoxinsKostrzewa, Richard M. 01 January 2014 (has links)
There has been an awareness of nerve poisons from ancient times. At the dawn of the twentieth century, the actions and mechanisms of these poisons were uncovered by modern physiological and biochemical experimentation. However, the era of selective neurotoxins began with the pioneering studies of R. Levi-Montalcini through her studies of the neurotrophin "nerve growth factor" (NGF), a protein promoting growth and development of sensory and sympathetic noradrenergic nerves. An antibody to NGF, namely, anti-NGF - developed in the 1950s in a collaboration with S. Cohen - was shown to produce an "immunosympathectomy" and virtual lifelong sympathetic denervation. These Nobel Laureates thus developed and characterized the first identifiable selective neurotoxin. Other selective neurotoxins were soon discovered, and the compendium of selective neurotoxins continues to grow, so that today there are numerous selective neurotoxins, with the potential to destroy or produce dysfunction of a variety of phenotypic nerves. Selective neurotoxins are of value because of their ability to selectively destroy or disable a common group of nerves possessing (1) a particular neural transporter, (2) a unique set of enzymes or vesicular transporter, (3) a specific type of receptor or (4) membranous protein, or (5) other uniqueness. The era of selective neurotoxins has developed to such an extent that the very definition of a "selective" neurotoxin has warped. For example, (1) N-methyl-D- aspartate receptor (NMDA-R) antagonists, considered to be neuroprotectants by virtue of their prevention of excitotoxicity from glutamate receptor agonists, actually lead to the demise of populations of neurons with NMDA receptors, when administered during ontogenetic development. The mere lack of natural excitation of this nerve population, consequent to NMDA-R block, sends a message that these nerves are redundant - and an apoptotic cascade is set in motion to eliminate these nerves. (2) The rodenticide rotenone, a global cytotoxin that acts mainly to inhibit complex I in the respiratory transport chain, is now used in low dose over a period of weeks to months to produce relatively selective destruction of substantia nigra dopaminergic nerves and promote alpha-synuclein deposition in brain to thus model Parkinson's disease. Similarly, (3) glial toxins, affecting oligodendrocytes or other satellite cells, can lead to the damage or dysfunction of identifiable groups of neurons. Consequently, these toxins might also be considered as "selective neurotoxins," despite the fact that the targeted cell is nonneuronal. Likewise, (4) the dopamine D2-receptor agonist quinpirole, administered daily for a week or more, leads to development of D2-receptor supersensitivity - exaggerated responses to the D2-receptor agonist, an effect persisting lifelong. Thus, neuroprotectants can become "selective" neurotoxins; nonspecific cytotoxins can become classified as "selective" neurotoxins; and receptor agonists, under defined dosing conditions, can supersensitize and thus be classified as "selective" neurotoxins. More examples will be uncovered as the area of selective neurotoxins expands. The description and characterization of selective neurotoxins, with unmasking of their mechanisms of action, have led to a level of understanding of neuronal activity and reactivity that could not be understood by conventional physiological observations. This chapter will be useful as an introduction to the scope of the field of selective neurotoxins and provide insight for in-depth analysis in later chapters with full descriptions of selective neurotoxins.
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