Global ETD Search

61	Estradiol Induced Changes In Neuronal Excitability And Neuron-Astrocyte Signaling In Mixed Hippocampal Cultures Rao, Shilpa P 08 1900 (has links) One of the defining characteristics of the brain is its plasticity, which is the ability to alter and reorganize neuronal circuits. The brain is constantly being shaped and moulded by the external world through endogenous factors like neurotransmitters, growth factors and circulating hormones. 17β-estradiol, which is the most potent estrogen among the group of ovarian steroid hormones, has widespread effects throughout the central nervous system. Apart from its actions on regions of the brain concerned with reproduction, estradiol has profound effects on brain areas not classically associated with reproductive function like cerebral cortex, midbrain, brainstem, hippocampus and spinal cord. This enables the hormone to influence learning and memory, emotions, affective state, cognition, motor coordination and pain sensitivity. Estradiol exerts these effects by regulating gene expression via intracellular estrogen receptors. In addition to this, the hormone interacts with receptors at the cell membrane to rapidly alter the electrical activity of neurons and astrocytes, and regulate second messenger systems. The aim of this study was to investigate the cellular and functional effects of estradiol on neuronal networks and on signaling between neurons and astrocytes in primary mixed hippocampal cultures. Estradiol is proconvulsant; it increases neuronal excitability and decreases the threshold for seizures. This property of estradiol is instrumental in precipitating catamenial seizures in women with epilepsy. These are epileptic seizures influenced by cyclical hormone changes and occur in over one-third to half of women with epilepsy. In the first part of the work, the effects of 24-hour estradiol treatment on hippocampal neurons were investigated using fluorescence imaging and electrophysiological techniques. Further, the ability of gabapentin, an antiepileptic drug sometimes used to treat hormone sensitive seizures, to counteract the effects of estradiol was studied. Synaptic vesicles were labeled by uptake of FM 1-43, and high K+- triggered exocytotic release was monitored by fluorescence imaging. The reduction in intensity of FM 1-43 fluorescence, which is a measure of vesicular release, was enhanced by estradiol, suggesting that estradiol upregulates the exocytotic machinery. The high K+-evoked intracellular Ca2+ rise in neurons, studied by loading the neurons with the Ca2+ indicator dye fluo-3 AM, was potentiated following estradiol treatment. Electrophysiological recordings from neurons following estradiol treatment showed an increase in the frequency of miniature excitatory postsynaptic currents (mEPSCs) and a larger number of mEPSC events with a predominant NMDA component. Many of the estradiol-induced excitatory effects on the neuronal network were abolished by incubating the cultures with a combination of estradiol and gabapentin suggesting a mechanism of action for the drug in the treatment of hormone sensitive seizures. Glial cells were once regarded as passive, supportive elements in the nervous system. This view of glial cells has drastically changed over the past decade and it is now known that glial cells are dynamic signaling elements in the brain. In view of the emerging importance of glia in the physiology of the nervous system and accumulating evidence of direct effects of steroid hormones on these cells, the subsequent part of the work delves into the consequences of 24-hour estradiol treatment on astrocytes and neuron-to-astrocyte signaling. Estrogen receptors have been described on both neurons and astrocytes in the hippocampus suggesting a complex interplay between the two cell types in mediating the effects of the hormone. Astrocytes sense and respond to neuronal activity with a rise in intracellular calcium concentration, ([Ca2+]i). Astrocyte ([Ca2+]i) transients can modulate neuronal activity, indicating a bi-directional form of communication between neurons and astrocytes. Using simultaneous electrophysiology and calcium imaging techniques, neuronal activity-evoked ([Ca2+]i) changes in fluo-3 AM loaded astrocytes were monitored. Action potential firing in neurons, elicited by injecting depolarizing current pulses, was associated with ([Ca2+]i) elevations in adjacent astrocytes which could be blocked by 200 µM MCPG and also 1 µM TTX. Comparison of astrocytic ([Ca2+]i) transients in control and estradiol treated cultures revealed that the amplitude of the ([Ca2+]i) transient, the number of responsive astrocytes and the ([Ca2+]i) wave velocity were all significantly reduced in estradiol treated cultures. ([Ca2+]i) rise in astrocytes in response to local application of the metabotropic glutamate receptor agonist t-ACPD was attenuated in estradiol treated cultures suggesting functional changes in the astrocyte metabotropic glutamate receptor following 24-hour treatment with estradiol. Since astrocytes can modulate synaptic transmission by release of glutamate, the attenuated ([Ca2+]i) response seen following estradiol treatment could have functional consequences on astrocyte-neuron signaling. The acute effects of estradiol on astrocyte-to-astrocyte and astrocyte-to-neuron signaling have been addressed in the next part of the study. Bidirectional communication between neurons and astrocytes involves integration of neuronal inputs by astrocytes, and release of gliotransmitters that modulate neuronal excitability and synaptic transmission. In addition to its rapid actions on neuronal electrical activity, estradiol can rapidly alter astrocyte ([Ca2+]i) levels through a plasma membrane-associated estrogen receptor. The functional consequences of acute estradiol treatment (5 min) on astrocyte-astrocyte and astrocyte-neuron communication were investigated using calcium imaging and electrophysiological techniques. Mechanical stimulation of an astrocyte evoked a ([Ca2+]i) rise in the stimulated astrocyte, which propagated to the surrounding astrocytes as a ([Ca2+]i) wave. Following acute treatment with estradiol, the amplitude of the ([Ca2+]i) elevation in astrocytes around the stimulated astrocyte was attenuated. Further, estradiol inhibited the ([Ca2+]i) rise in individual astrocytes in response to the metabotropic glutamate receptor agonist, t-ACPD. Mechanical stimulation of astrocytes induced ([Ca2+]i) elevations and electrophysiological responses in adjacent neurons. Estradiol rapidly attenuated the astrocyte-evoked glutamate-mediated ([Ca2+]i) rise and slow inward current in neurons. Also, the incidence of astrocyte-induced increase in spontaneous postsynaptic current frequency was reduced in presence of estradiol. The effects of estradiol were stereo-specific and reversible following washout. These findings indicate that the regulation of neuronal excitability and synaptic transmission by astrocytes is sensitive to rapid estradiol mediated hormonal control. Brain Reception Neural Network (Brain) Signal Transduction Hippocampal Neurons - Estradiol Effects Neuronal Networks - Estradiol Effects Estradiol Astrocyte-Astrocyte - Estradiol Effects Hippocampal Cultures 17ß-estradiol Neurobiology
62	Investigation of spatiotemporal calcium transients in astrocytic soma and processes upon purinergic receptor activation using genetically encoded calcium sensors / Etude en microscopie biphotonique de l’activité calcique astrocytaire mesurée par des indicateurs protéiques et induite par des agonistes purinergiques Schmidt, Elke 27 February 2015 (has links) Les astrocytes protoplasmiques de la matière grise corticale sont des cellules gliales dont les prolongements très fins et ramifiés sont en contact avec les éléments neuronaux pré- et post-synaptiques d’une part, et les vaisseaux sanguins d’autre part. Ils expriment plusieurs récepteurs des neurotransmetteurs, entre autres des récepteurs purinergiques dont l'activation facilite l’activité calcique astrocytaire et la libération de gliotransmitters (par exemple, le glutamate, le GABA, l'ATP, et la D sérine) qui régulent l’activité des neurones et des cellules gliales situées au voisinage. L’objectif de ma thèse était d’étudier in situ l’activité calcique des astrocytes et de leurs prolongements en réponse à l’application des agonistes purinergiques. Lors de ma thèse, j’ai tout d'abord testé la possibilité d’induire l’expression spécifique de gènes d’intérêt par les astrocytes corticaux de souris adultes par la technique de recombinaison Cre-LoxP. J’ai comparé les performances d’un virus adeno-associé de type 5 (AAV5) flexé (AAV5.FLEX.EGFP) et d’une souris qui exprime un indicateur calcique (GCaMP3) sous contrôle de la recombinase (souris Rosa-CAG-LSL-GCaMP3). L’injection d’AAV5.FLEX.EGFP dans le cortex d’une souris hGFAPcre n’a pas permis l’expression spécifique d’EGFP. La combinaison des souris exprimant le cre recombinase sous contrôle d’un promoteur sélectif des astrocytes (GLAST-CreERT2 et Cx30-CreERT2) avec le AAV5.FLEX.EGFP ou avec une lignée des souris Rosa-CAG-LSL-GCaMP3 permet l’expression spécifique des gènes d’intérêt (EGFP et GCaMP3) par les astrocytes corticaux. J’ai ensuite analysé l’activité calcique des astrocytes qui expriment GCaMP3. J’ai utilisé la microscopie biphotonique et enregistré l’activité calcique spontanée et évoquée par application d’agonistes purinergiques sur des tranches de cortex somatosensoriel primaire de souris adultes GLAST-CreERT2. L’activité calcique spontanée est complexe, généralement locale et désynchronisée, répartie dans les prolongements et la région somatique. Les régions actives ont été identifiées à partir d’une carte de corrélation temporale calculée en MATLAB, et leurs caractéristiques (amplitude, durée, position, fréquence) mesurées grâce à des routines établies sous IGOR. La fréquence et l’amplitude de l’activité calcique paraissent augmenter lors de l’enregistrement, ce qui suggère une sensibilité significative et une photoactivation des astrocytes, en imagerie biphotonique. La durée des impulsions laser modulerait ce phénomène. En présence d'adénosine (1-100 µM) et d’ATP (100 µM), et de façon marginale en présence d’un agoniste P2X7 non sélectif (BzATP 50-100 µM), une activité calcique synchronisée accrue est visible dans le soma et les prolongements astrocytaires en présence de tétrodotoxine qui bloque les potentiels d'action et minimise l’activité synaptique. Le mécanisme de ces réponses synchronisées reste à étudier. Aucun effet significatif n’a été observé en présence d’un agoniste spécifique P2Y1 (MRS2365 50 uM). Mon travail a permis le développement : i) de modèles murins pour l’adressage sélectif de protéines d’intérêt au niveau des astrocytes protoplasmiques ; ii) d’outils d’analyse des signaux calciques astrocytaires au niveau sub-cellulaire. Il a mis en évidence des limites possibles des protocoles standards d'enregistrement de l’activité calcique des astrocytes en imagerie biphotonique. Il confirme l’importance de l’ATP et de l’adénosine pour la signalisation astrocytaire. / Grey matter protoplasmic astrocytes are compact glial cells with highly branched processes, enwrapping synapses, and one or two endfeet contacting the blood vessels. Several neurotransmitter receptors are expressed by astrocytes, among them purinergic receptors. Upon activation of these receptors, intracellular calcium (Ca2+) transients can be induced, that, in turn, trigger gliotransmitter release (e.g. glutamate, GABA, ATP, D-serine) and participate in astrocyte-to-astrocyte signaling as well as in the communication between astrocytes and neurons or other glia. During my PhD work, I first implemented and validated several approaches for targeting transgene expression specifically to cortical astrocytes and employed them to study purinergic signaling in astrocytes. To achieve astrocyte-specific transgene expression, I used either floxed adeno-associated viral (AAV) vectors or a Cre-dependent mouse line and several mouse lines expressing the Cre recombinase under astrocyte-specific promoters. Intracerebral injections of a Cre-dependent AAV serotype 5 containing the ubiquitous CAG promoter and an enhanced green fluorescent protein (AAV5.CAG.flex.EGFP) in adult mice expressing Cre recombinase under the human glial fibrillary protein (hGFAP) promoter resulted in a non-astrocyte specific expression in the cortex. Combining inducible mouse lines expressing Cre recombinase under the glutamate aspartate transporter (GLAST) promoter with the same AAV vector resulted in a virtually astrocyte-specific expression of the reporter gene. As an alternative approach for astrocyte-specific transgene expression, we used a Cre-dependent mouse line expressing the genetically encoded Ca2+ indicator GCaMP3. Crossing this mouse line with the above described GLAST-CreERT2 mouse line or a Connexin30 (Cx30)-CreERT2 line led to selective GCaMP3 expression in cortical astrocytes. Second, I investigated both spontaneous and agonist-evoked Ca2+ transients in astrocytic processes, the investigation of which has presented a major challenge in earlier studies, due to the unspecific and weak labeling by membrane-permeable chemical Ca2+ indicators. Using the strategy developed in the first part of my work allowing an astrocyte-specific expression of the genetically encoded Ca2+ indicator GCaMP3. Using two-photon excitation fluorescence (2PEF) imaging in acute slices of the primary somatosensory cortex, I recorded Ca2+ transients in the astrocytic soma and processes. By aid of a custom-made MATLAB routine based on a temporal Pearson correlation coefficient, active regions could be identified in an unbiased manner. Evoked Ca2+ transients were quantified using custom IGOR routines. Spontaneous desynchronized Ca2+ transients occurred in the processes and rarely in the soma. Ca2+ signals appeared localized in distinct microdomains. Their frequency appeared to increase during long recordings of several hundred images, suggesting that fine astrocytes are vulnerable to photodamage under imaging conditions routine in 2PEF microscopy. The possibility to minimize photodamage, by varying the length of the femtosecond laser pulses is under investigation. Bath application of adenosine (1-100 µM) and adenosine-triphosphate (ATP, 100 µM), as well as the application of the non-selective P2X7 receptor agonist (2'(3')-O-(4-Benzoylbenzoyl)adenosine-5'-triphosphate, BzATP, 50-100 µM), in the presence of tetrodotoxin to block neuronal action potentials, evoked synchronized Ca2+ rises in the soma and the processes of astrocytes. The effect of adenosine was dose-dependent. No significant effect of the specific P2Y1 agonist (MRS2365, 50 µM) was seen. Altogether, my work sets up a powerful and versatile toolbox for studying astrocytic Ca2+ signaling at the sub-cellular level. It also pinpoints possible limits of standard two-photon recording protocols to investigate the local Ca2+ signals in fine astrocytic processes. Astrocyte Cre recombinase Expression sélective des transgènes ATP Adénosine Microscopie biphotonique GCaMP3 GLAST Cx30 Astrocyte Cre recombinase Astrocyte-specific transgene expression ATP Adenosine Two-photon microscopy GCaMP3 GLAST Cx30 612.8
63	Rôle de la D-sérine dans les interactions entre systèmes dopaminergique et glutamatergique dans le cortex préfrontal du rat adulte / Role of D-serine in the interaction between dopaminergic and glutamatergic systems in the prefrontal cortex of adult rat Turpin, Fabrice 21 December 2010 (has links) Le cortex préfrontal (PFC) est le principal locus des perturbations dans l’activité des réseaux de neurones chez les schizophrènes. Ces perturbations résultent d’une dérégulation des interactions entre le système dopaminergique et le système glutamatergique dont l’origine demeure inconnue. Il est acquis que les cellules gliales détectent et intègrent les signaux synaptiques, et libèrent différentes substances neuroactives comme la D-sérine. Cet acide aminé est aujourd’hui reconnu comme le coagoniste endogène des récepteurs au glutamate de type NMDA dans de nombreuses aires cérébrales. Mon travail de thèse est centré sur le rôle de la d-sérine dans la transmission synaptique excitatrice glutamatergique dans le PFC du rongeur adulte et dans la gouvernance des interactions entre systèmes glutamatergique et dopaminergiques J’ai tout d’abord montré en utilisant des enregistrements électrophysiologiques sur tranches que la d-sérine est le coagoniste des récepteurs NMDA synaptiques dans les couches V/VI du PFC. Cet acide aminé est synthétisé par les astrocytes et contrôle l’induction de la potentialisation à long terme. D’autre part, j’ai montré que la dopamine exerce un effet biphasique sur l’activité des récepteurs NMDA synaptiques et sur l’excitabilité des neurones pyramidaux des couches V/VI du PFC et ce en contrôlant la libération de d-sérine. Une approche pharmacologique sélective a permis de mettre en évidence le rôle des récepteurs D1 dans les effets potentialisateurs et le rôle des récepteurs D2/D3 dans les effets inhibiteurs de la dopamine. Mon travail démontre que les astrocytes arborent des récepteurs à la dopamine qui contrôlent la libération de la d-sérine. / The prefontal cortex (PFC) is the main locus where dysfunctions of neuronal networks are evident in schizophrenia. These dysfunctions are caused by an impairment of cross-talk between dopaminergic and glutamatergic systems whose origin is unknown. It is now accepted that glia detect and integrate synaptic signals and then release many neuroactive substances such as D-serine. This amino acid is now considered to be the endogenous coagonist of the NMDA subtype receptors for glutamate in many brain areas. My PhD work focuses on the functions of d-serine in glutamatergic excitatory synaptic transmission in the PFC of adult rodent and in governing the interactions between dopaminergic and glutamatergic systems. First, using electrophysiological recordings on brain slices, I have shown that d-serine is the coagonist of synaptic NMDA receptors in layers V/VI of PFC. This amino acid is synthesized by glia and is crucial for the induction of long term potentiation. In addition, I have shown that dopamine has a bell-shape effect on the activity of synaptic NMDA receptors and on the excitability of excitatory pyramidal neurons by controlling the release of d-serine. The use of specific pharmacological tools allowed me to show the potentiating effects of dopamine are mediated by D1 receptors whereas the inhibitory effects are due to the activation of D2/D3 receptors. Finally, my work highlights the presence of functional dopaminergic receptors on astrocytes that modulate the release of d-serine in the PFC, thus impacting NMDA receptor activity. Astrocyte Cortex préfrontal Dopamine D-sérine Glutamate Récepteur NMDA Schizophrénie Synapse Astrocyte Prefrontal cortex Dopamine D-serine Glutamate Nmda receptors Schizophrenia Synapse
64	Relations astrocytes-neurones et mécanismes d'action des inhibiteurs sélectifs de recapture de la sérotonine : rôle du BDNF et des récepteurs 5-HT2A / Astrocyte-neuron relationships in the mechanism of action of selective serotonin reuptake inhibitors : the role of BDNF and 5-HT2A receptor Quesseveur, Gaël 27 September 2013 (has links) Les astrocytes joueraient un rôle central dans la physiopathologie des troubles anxio-dépressifs et dans l’activité thérapeutique des antidépresseurs. En effet, différentes études in vitro suggèrent que les inhibiteurs sélectifs de recapture de la sérotonine (ISRS) stimulent la synthèse de substances neuroactives par ces cellules gliales nécessaires à la prolifération, la maturation et la survie neuronale mais également au maintien de la plasticité synaptique. Le Brain-derived neurotrophic factor (BDNF) fait partie de ces substances mais son origine, notamment astrocytaire, doit encore être démontrée dans les systèmes intégrés tel que l’animal vivant. A partir de ce constat, dans une première partie de ce travail de thèse, nous avons donc voulu préciser si les astrocytes constituent une source cellulaire participant à la synthèse et/ou à la libération de BDNF en réponse à l’administration prolongée d’un ISRS, la fluoxétine d’une part chez des souris naïves et d’autre part chez des souris exposées à la corticostérone pendant plusieurs semaines (modèle « CORT »). Pour cela, nous avons utilisé une stratégie de transfection virale induisant la surexpression de BDNF spécifiquement dans les astrocytes de l'hippocampe. Nos résultats mettent en lumière que cette surexpression provoque des effets de types anxiolytiques-antidépresseurs dépendant de la neurogenèse hippocampique chez des souris naïves soumises au test d’hypophagie induite par la nouveauté mais pas dans le modèle CORT. Nous avons également mis en évidence que le BDNF pouvait agir en retour sur les cellules qui l’ont libéré pour renforcer le réseau astrocytaire (mécanisme autocrine) mais également sur les neurones sérotoninergiques pré-synaptiques (mécanisme paracrine) pour exercer un frein sur la libération de sérotonine dans l’hippocampe. Différents arguments de la littérature suggèrent d’ailleurs que ce dernier mécanisme pourrait être favorable à l’activité anxiolytique de la fluoxétine tel que nous l’avons observé dans ce travail. Sachant que les astrocytes expriment à leur surface, une grande variété de récepteurs sérotoninergiques, nous nous sommes ensuite intéressé à la possibilité que le sous-type de récepteur 5-HT2A pourrait être un élément clé dans la synthèse et/ou la libération de BDNF et de ce fait moduler la réponse au stress et celle à la fluoxétine. Lors de cette seconde étude nous avons appliqué une approche génétique utilisant des souris mutées, privées de manière constitutive du récepteur 5-HT2A (5-HT2A-/-). A l’opposé de la surexpression de BDNF dans les astrocytes, nous avons montré que les souris 5-HT2A-/- sont plus sensibles au stress, modélisé par l’exposition chronique à la corticostérone, et semblent résistantes à la fluoxétine comparées aux souris 5-HT2A+/+. Afin de préciser le mécanisme pouvant rendre compte de ces observations, nous avons mis en évidence que l’inactivation du récepteur 5-HT2A s’accompagne d’une hypersensibilité du frein inhibiteur exercé par les autorécepteurs 5-HT1A somatodendritiques sur le tonus sérotoninergique. / Growing evidence demonstrates that astrocytes could play a crucial role in the pathophysiologies of anxiety and depression as well as in the therapeutic activity of antidepressant drugs. Indeed, in vitro studies suggest that the selective serotonin reuptake inhibitors (SSRIs) stimulate the synthesis of neuroactive substances by these glial cells which are necessary for the proliferation and maturation of neuronal progenitors but also for the maintenance of the neuronal survival. Brain-derived neurotrophic factor (BDNF) is one of these substances, but its cellular origin has yet to be demonstrated in embedded systems such as living animals. In this context, the first part of this thesis was aimed at clarifying whether astrocytes constitute a source of BDNF in response to the chronic administration of the SSRI, fluoxetine, in both naive and anxio-depressive mice exposed to corticosterone (" CORT" model). In this prospect, we used a novel and efficient gene transfer strategy inducing BDNF overexpression specifically in the astrocytes of the hippocampus. Our results indicated that BDNF overexpression produced anxiolytic-/antidepressant-like activity in the novelty suppressed feeding paradigm in relation with the stimulation of hippocampal neurogenesis in naive mice but not in the CORT model. We also showed that BDNF could act on astrocytes themselves (autocrine mechanism) to improve the hippocampal astrocytic network but also on the pre-synaptic serotonergic nerve terminals (paracrine mechanism) to limit the local serotonin release. Different arguments from the literature suggest that the latter mechanism may be favorable to an anxiolytic-like activity of fluoxetine. Given that astrocytes express at the surface a variety of serotonin receptors, we then raised the possibility that the 5-HT2A receptor subtype may be a key element in the synthesis and/or release of BDNF and thereby modulating the vulnerability to depression and/or the response of fluoxetine. In the second part of this thesis, a genetic approach with mutant mice constitutively lacking the 5-HT2A receptor (5-HT2A-/-) was applied. In contrast to Lenti-BDNF mice, we showed that 5-HT2A-/- mice were more prone to develop anxio-depressive-like symptoms in response to the chronic exposure to corticosterone. Moreover, these mutants were resistant to the chronic administration of fluoxetine compared to 5-HT2A+/+ wild type mice. In order to clarify the mechanism underpinning these observations, we demonstrated that the inactivation of the 5-HT2A receptor was associated with a hypersensitivity of a negative feedback exerted by the somatodendritic 5-HT1A autoreceptors on serotonergic tone.Together these data suggest that astrocytes act in concert with neurons to regulate mood and antidepressant drug response, notably through the synthesis and/or release of BDNF following the activation of the 5-HT2A receptor. More generally, our results illustrate the concept of the tripartite synapse in which the bidirectional communication between astrocytes and monoaminergic neurons would be essential in the regulation of higher brain functions. 5-HT2A Antidépresseur Anxiété Astrocyte BDNF Corticostérone Dépression Neurogenèse et stress 5-HT2A receptor Antidepressant Anxiety Astrocyte BDNF Corticosterone Depression Neurogenesis and stress
65	Etude des mécanismes d’action de l’ocytocine sur la modulation des circuits astro-neuronaux de régulation de la douleur / Study of the mechanisms of action of oxytocin in the modulation of astro-neuronal circuits of pain modulation Wahis, Jérôme 10 April 2017 (has links) La douleur est un phénomène complexe régi par le système nerveux. De nombreuses molécules modulent la douleur par des mécanismes complexes et variés. L’une d’elle, l’ocytocine, est plus connue pour ses rôles dans la reproduction et les interactions sociales, mais est pourtant un puissant agent analgésique endogène. Au cours de cette thèse, j’ai cherché à comprendre comment l’ocytocine régulait la douleur dans deux différentes régions du cerveau, l’hypothalamus et l’amygdale. Ces travaux ont permis de mettre à jour un petit groupe de neurones ocytocinergiques de l’hypothalamus, qui contrôle la douleur par une action double, à la fois en inhibant la transmission du message douloureux dans la moelle épinière et en contrôlant en même temps l’activité d’autres neurones ocytocinergiques qui sécrètent alors de l’ocytocine dans la circulation sanguine. Dans l’amygdale, nous avons pu montrer que l’effet analgésique de l’ocytocine nécessitait le bon fonctionnement d’un type de cellule non neuronal, l’astrocyte, qui répond à la présence d’ocytocine et, ce faisant, permet l’activation de circuits de neurones contrôlant la douleur. / Pain is a complex phenomenon arising from the nervous system. Numerous molecules modulate pain through complex and various mechanisms. One of those, oxytocin, is more famous for its roles in reproduction and social interactions, but is also a potent endogenous analgesic. During this thesis, I tried to understand how oxytocin modulates pain in two brain regions, the hypothalamus and the amygdala. This work unveiled a small group of oxytocinergic neurons in the hypothalamus which control pain through a dual action, firstly by inhibiting the pain signals in the spinal cord and secondly by activating at the same time another population of oxytocinergic neurons, which then secrete oxytocin in the bloodstream. In the amygdala, we showed that the analgesic effect of oxytocin required the proper functioning of a non-neuronal cell type, the astrocyte, which responds to oxytocin and, doing so, allows the activation of neural circuits which modulate pain. Douleur Ocytocine Hypothalamus Amygdale Moelle epinière Analgésie Electrophysiologie Imagerie calcique Astrocyte Pain Oxytocin Astrocyte Hypothalamus Amygdala Spinal cord Analgesia Electrophysiology Calcium imaging 571.7 616.047 616.8
66	Altered gene expression profile in a mouse model of SCN8A encephalopathy Sprissler, Ryan S., Wagnon, Jacy L., Bunton-Stasyshyn, Rosie K., Meisler, Miriam H., Hammer, Michael F. 02 1900 (has links) 12 month embargo; Available online 9 November 2016 / SCN8A encephalopathy is a severe, early-onset epilepsy disorder resulting from de novo gain-of-function mutations in the voltage-gated sodium channel Na(v)1.6. To identify the effects of this disorder on mRNA expression, RNA-seq was performed on brain tissue from a knock-in mouse expressing the patient mutation p.Asn1768Asp (N1768D). RNA was isolated from forebrain, cerebellum, and brainstem both before and after seizure onset, and from age-matched wildtype littermates. Altered transcript profiles were observed only in forebrain and only after seizures. The abundance of 50 transcripts increased more than 3-fold and 15 transcripts decreased more than 3 fold after seizures. The elevated transcripts included two anti-convulsant neuropeptides and more than a dozen genes involved in reactive astrocytosis and response to neuronal damage. There was no change in the level of transcripts encoding other voltage-gated sodium, potassium or calcium channels. Reactive astrocytosis was observed in the hippocampus of mutant mice after seizures. There is considerable overlap between the genes affected in this genetic model of epilepsy and those altered by chemically induced seizures, traumatic brain injury, ischemia, and inflammation. The data support the view that gain-of-function mutations of SCN8A lead to pathogenic alterations in brain function contributing to encephalopathy. RNA-seq Transcriptome Seizure Epileptic encephalopathy Astrocyte Gene expression Sodium channel
67	AEG-1 KNOCKOUT SENSITIZES HEPATOCELLULAR CARCINOMA (HCC) CELLS TO IONIZING RADIATION Khan, Maheen 01 January 2019 (has links) Liver cancer is the fourth leading cause of cancer-associated deaths globally, and among primary liver cancers, hepatocellular carcinoma (HCC) encompasses 75-85% of all cases. HCC is a highly lethal disease due to limited treatment options – only a small subset of patients qualify for surgical resection or transplantation; the remaining patients often display resistance to radiation therapy or chemotherapy. Overexpression of the oncogene astrocyte elevated gene-1 (AEG-1) is associated with poorer survival and increased tumor recurrence in HCC, and numerous studies show its role in initiation of hepatocarcinogenesis. A prior study also demonstrated AEG-1 expression inhibits senescence by diminishing the ATM/Chk1/Chk2/p53/p21 DNA damage response (DDR) pathway. The aim of this study is to understand if AEG-1 expression promotes radioresistance in HCC. A CRISPR/Cas9 plasmid system was used to delete AEG-1 in the QGY-7703, HuH7 and DihXY cell lines, which model HCC. The cell lines were then treated with ionizing radiation (IR). We find that knockout of AEG-1 in these cell lines induces sensitivity to IR at 2.5 Gy. In response to radiation, AEG-1 wildtype cells more profoundly upregulate ATR, Chk1, and Chk2 signaling; and also more rapidly induce γH2AX, ATM, and BRCA1 signaling, which sense dsDNA breaks to initiate homologous recombination repair. We conclude that AEG-1 expression protects HCC cells from IR through two mechanisms: 1) rapidly initiating the DNA damage response; and 2) increasing replication fork stabilization. These findings indicate AEG-1 can be a therapeutic target in combination with radiation treatment to improve outcomes for HCC patients who demonstrate radioresistance. Hepatocellular carcinoma ionizing radiation astrocyte elevated gene-1 DNA damage response Molecular Genetics
68	Modelling Chemical Communication in Neuroglia Edwards, James Roy January 2007 (has links) Master of Science / In vivo many forms of glia utilise both intercellular and extracellular pathways in the form of IP3 permeable gap junctions and cytoplasmic ATP diffusion to produce calcium waves. We introduce a model of ATP and Ca2+ waves in clusters of glial cells in which both pathways are included. Through demonstrations of its capacity to replicate the results of existing theoretical models of individual pathways and to simulate experimental observations of retinal glia the validity of the model is confirmed. Characteristics of the waves resulting from the inclusion of both pathways are identified and described. Mathematical Model Astrocyte Neuroglia Calcium Wave ATP Wave Retina Numerical Diffusion
69	Identification et exocytose d´organelles dans les astrocytes en culture: couplage de la microscopie à onde évanescente et de la décomposition spectrale Nadrigny, Fabien 26 September 2006 (has links) (PDF) Les astrocytes sont capables de sécréter des gliotransmetteurs en réponse à une stimulation qui engendre l'augmentation de la concentration calcique intra-cellulaire. Différents mécanismes de sécrétion ont été proposés, parmi lesquels l'exocytose régulée. Mais les expériences menées dans le but d'observer la fusion d'organelles individuels dans des astrocytes en culture ont conduit à des résultats contradictoires, notamment en terme d'identité des vésicules libérables. Nos expériences préliminaires nous ont convaincus que les conflits sur l'identité des organelles libérables sont dus à de fausses colocalisations à cause du recouvrement spectral des marqueurs fluorescents utilisés et de la présence d'autofluorescence dans les astrocytes en culture. Nous avons donc adapté la décomposition spectrale à l'identification rigoureuse d'organelles individuels et au suivi de leur exocytose. La décomposition spectrale permet la séparation de sources de fluorescence mal séparées et ainsi l'étude de l'expression et de la colocalisation de protéines fluorescentes, même en présence d'autofluorescence. Nous avons à cette occasion introduit un intervalle de confiance du résultat de l'estimation des quantités de colorants. Appliquée au marquage des organelles astrocytaires avec la EGFP et l'acridine orange, cette méthode a montré que l'apparente colocalisation entre ces marqueurs reflète en fait la présence d'acridine orange plus intense que la EGFP et coexistant dans les mêmes organelles sous deux formes verte et rouge. A l'aide de la décomposition spectrale et de la microscopie à onde évanescente, nous avons ensuite montré que les organelles autofluorescents dans les astrocytes sont en majorité des lysosomes capables de fusionner lors d'une stimu\-lation qui engendre l'augmentation du calcium intra-cellulaire. Ces lysosomes sont peut-être les organelles majoritairement responsables de l'exocytose dans les astrocytes en culture. [SDV] Life Sciences [PHYS] Physics Unmixing Tirfm Astrocyte Exocytose Onde évanescente Décomposition spectrale Vésicule Lysosome
70	A Comparative Study of the Impact of Sustained and Intermittent Docetaxel Chemotherapy in Brain in a Mouse Model Zhang, Ji 04 December 2012 (has links) Title: “A comparative study of the impact of sustained and intermittent docetaxel chemotherapy in brain in a mouse model” Ji Zhang Master of Science Graduate Department of Pharmaceutical Sciences, University of Toronto November, 2011 Abstract A subset of patients suffers cognitive impairment during or long after chemotherapy. This may result from chemotherapeutic agents crossing the blood brain barrier (BBB). This thesis examined the effects of docetaxel (DTX) on brain toxicity, and the effects of different dosing schedules on brain DTX concentrations and neurotoxicity. Examination of DTX treated mice (total dose of 32mg/kg) revealed appreciable amounts of DTX crossed the BBB after either intermittent (four weekly doses) or sustained (one injection of DTX-PoLigel) administration despite differences in peak drug concentrations and overall exposure profiles. Measurements of autophagy and astrocytes activation not only provided evidence of DTX caused neurotoxicity in the central nervous system, but also revealed a link between dosing schedule and neurotoxicity. Furthermore, the discovery suggested connections between DTX brain exposure, diverse biological events (such as BBB permeability and reactive oxygen species activity), and the microenvironment at synapse-neuron junctions, which should be further explored. Docetaxel Chemotherapy Cognitive impairment Neurotoxicity Autophagy Astrocyte Apoptosis Neuronal Calcium Sensor-1 0491

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