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Rôles des récepteurs cannabinoïdes de type 1 dans le cortex piriforme antérieur / Roles of cannabinoid type-1 receptors in the anterior piriform cortexTerral, Geoffrey 14 December 2018 (has links)
Impliquée dans de nombreuses fonctions comportementales, l'olfaction joue un rôle majeur quant à l'orientation de nos actions. Les odeurs communiquent avec le système nerveux central par l'intermédiaire de récepteurs situés dans l'épithélium olfactif du nez qui génèrent des signaux neuronaux, transmis et traités dans de nombreuses régions du cerveau. En particulier, le cortex piriforme antérieur (CPa) est une région olfactive importante impliquée dans la perception et l'intégration des odeurs. Étant donné le rôle du principal récepteur aux cannabinoïdes de type 1 (CB1) dans les fonctions sensorielles et les processus de mémoire, nous avons émis l'hypothèse que ces récepteurs pourraient moduler le traitement des odeurs dans le CPa. Pour ce faire, en combinant des approches anatomiques, électrophysiologiques et pharmacologiques, nous avons d'abord caractérisé la répartition des récepteurs CB1 et évalué leur capacité à réguler les circuits du CPa. Nous avons observé que ces récepteurs sont principalement exprimés dans les interneurones GABAergiques et que leur activation régule la transmission et la plasticité inhibitrice. Puis, nous avons cherché à déterminer le rôle et l'impact des récepteurs CB1 dans le traitement des odeurs dans le CPa. Grâce à une technique d'imagerie calcique in vivo, nous avons montré que l'altération de la signalisation des récepteurs CB1 affecte l'activité des neurones du CPa en réponse aux odeurs. En agissant très semblablement sur les circuits inhibiteurs locaux, nous avons mis en évidence que le fonctionnement physiologique des récepteurs CB1 dans le CPa est nécessaire pour le rappel d’une information olfactive apprise dans un contexte appétitif mais pas aversif. De façon générale, ces travaux permettent de mieux comprendre comment les récepteurs CB1 modulent les processus olfactifs dans le CPa. / Being involved in many behavioral functions, olfaction has powerful influence in guiding our actions. Odors communicate with the central nervous system via specialized receptors in the nose olfactory epithelium that generate neuronal signals, which in turn are eventually distributed and processed in many brain regions. In particular, the anterior piriform cortex (aPC) is an important olfactory area involved in perception and integration of odors. Given the extended role of the main cannabinoid type-1 (CB1) receptor in sensory and memory brain functions, we hypothesized that CB1 receptors could modulate odor processing in the aPC. To this aim, using a combination of anatomical, electrophysiological, and pharmacological approaches, we first characterized the distribution of CB1 receptors and their ability to regulate aPC circuits. We found that CB1 receptors are mainly expressed in GABAergic interneurons where their activation regulates inhibitory transmission and plasticity. Then, we evaluated the role and the impact of CB1 receptor modulation on odor-related aPC processing. In vivo calcium imaging revealed that odor-evoked aPC activity is affected by alteration of CB1 receptor signaling. Additionally, we demonstrated that physiological aPC-CB1 receptors functioning is necessary for retrieve appetitive but not aversive olfactory memory, likely through modulation of local inhibitory circuits. Overall, this work contribute to a better understanding of how CB1 receptors modulate olfactory processes in the aPC.
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Synthetic cannabinoids versus delta-9-tetrahydrocannabinol: abuse-related consequences of enhanced efficacy at the cannabinoid 1 receptorGrim, Travis 01 January 2015 (has links)
In the past ten years, synthetic cannabinoids (SC) have emerged as drugs of abuse. Unlike D9-tetrahydrocannabinol (THC), many SCs are associated with serious health complications and death. One way in which THC and SCs differ lies with their enhanced potency and efficacy at the CB1 receptor. No current methods exist to measure efficacy at the CB1 receptor in vivo, and the abuse-related properties of SC cannabinoids are not well explored. Here, we utilized CB1 wild type (WT), heterozygous (HET), and knockout (KO) mice. By employing CB1 ligands which differ in efficacy we have developed a method to explore the relationship between efficacy and the ability to produce cannabimimetic (catalepsy, hypothermia, and antinociception) effects when CB1 expression was reduced by half. Additionally, the intracranial self-stimulation procedure (ICSS) was utilized to investigate the effects of enhanced efficacy at CB1 upon reward processes using representative SC CP55,940. As predicted, the potency shift between WT and HET mice inversely correlated with the efficacy of the test drug for both hypothermia and antinociception, but not catalepsy. This efficacy stratification was correlated with the agonist-stimulated [35S]GTPgS binding assay, demonstrating this model as an effective tool to ascertain in vivo efficacy differences at CB1. In ICSS, CP55,940 elicited only rate-decreasing effects acutely, although tolerance developed following repeated dosing, with no evidence for spontaneous or rimonabant-precipitated withdrawal. Together, these data indicate that highly efficacious cannabinoid ligands require few receptors to produce cannabimimetic effects, and that the model provides an effective means to quickly ascertain differences in efficacy.
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Functional redistribution of hippocampal cannabinoid CB₁ receptors in the rat pilocarpine model of acquired epilepsy /Falenski, Katherine Winslow, January 2006 (has links)
Thesis (Ph. D.)--Virginia Commonwealth University, 2006. / Prepared for: Dept. of Neurology. Bibliography: leaves 180-205. Also available online.
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Rôle du récepteur aux cannabinoïdes de type 1 (CB1) hypothalamique dans la régulation de la balance énergétique et de l’homéostasie du glucose / Role of hypothalamic cannabinoid type 1 receptors (CB1) in energy balance regulation and glucose homeostasisCardinal, Pierre 04 March 2013 (has links)
Le système endocannabinoïde est un acteur majeur de la régulation de la balance énergétique. Cependant, son rôle au niveau de l’hypothalamus, une région critique dans la régulation de la balance énergétique, reste méconnu. L’objectif général de ce travail de thèse a été de disséquer le rôle du récepteur aux cannabinoïdes de type 1 (CB1) exprimé par des populations neuronales hypothalamiques spécifiques dans la régulation de la balance énergétique et l’homéostasie du glucose en caractérisant trois nouvelles lignées de souris possédant une mutation conditionnelle de CB1. En régime standard, la délétion de CB1 dans l’hypothalamus induit une augmentation de la dépense énergétique et une baisse de prise de poids corporel sans modifier la prise alimentaire alors que la délétion de CB1 dans le noyau ventromédian de l’hypothalamus (VMN-CB1-KO) entraîne une baisse significative de masse grasse, une augmentation de l’oxydation des acides gras in vivo, une augmentation de l’activité du système nerveux sympathique (SNS) et un métabolisme du glucose périphérique amélioré. Enfin, la délétion de CB1 dans le noyau paraventriculaire de l’hypothalamus (PVN-CB1-KO) induit une baisse de poids sans modifier la prise alimentaire ni la composition corporelle. Lors de l’exposition à un régime riche en graisses, les souris VMN-CB1-KO prennent plus de poids et de masse grasse que les WT, tandis que les souris PVN-CB1-KO sont partiellement protégées de l’obésité alimentaire grâce à une dépense énergétique accrue.Ces résultats suggèrent que CB1 exprimé par différentes populations hypothalamiques joue un rôle différent dans la régulation de la balance énergétique, qui dépend aussi du régime alimentaire. / The endocannabinoid system is a major player in energy balance regulation. However, a complete understanding of its role within the hypothalamus, a region critically involved in energy balance regulation, is still missing. The general aim of this PhD work was to dissect the specific role of the cannabinoid type 1 receptor (CB1) expressed on different hypothalamic neuronal populations in energy balance regulation and glucose homeostasis by characterizing three new mouse mutant lines with a conditional deletion of CB1. On standard diet, CB1 deletion within the hypothalamus induced an increase in energy expenditure and a decrease in body weight gain without modifying food intake, while CB1 deletion within the ventromedial nucleus of the hypothalamus (VMN-CB1-KO) decreased fat mass, increased fatty acid oxidation in vivo and sympathetic nervous system (SNS) activity, and improved peripheral glucose metabolism. CB1 deletion within the paraventricular nucleus of the hypothalamus (PVN-CB1-KO) decreased body weight gain without affecting food intake or body composition. When exposed to a high-fat diet, VMN-CB1-KO mice gained significantly more weight and fat mass than their WT, while PVN-CB1-KO mice were partly protected from diet-induced obesity thanks to increased energy expenditure. These results overall suggest that CB1 expressed on different hypothalamic neuronal populations have distinct roles in energy balance regulation, which in turn also depend on the diet consumed.
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Efeito do agonista seletivo do receptor canabinoide 1 (CB1) em modelos de neurodegeneração induzida pela estreptozotocina. / The effect of cannabinoid receptor 1 (CB1) selective agonist on models of streptozotocin-induced neurodegeneration.Crunfli, Fernanda 13 December 2017 (has links)
A doença de Alzheimer (DA) é caracterizada por déficit cognitivo, associada com prejuízos no metabolismo energético e na via de sinalização da insulina encefálicos. A injeção intracerebroventricular de baixas doses de estreptozotocina (STZ) tem sido utilizada como um modelo experimental da DA em ratos. Nesse sentido, tem sido demonstrada a participação do sistema canabinoide em processos neurodegenerativos e seus efeitos neuroprotetores e anti-inflamatórios. O objetivo deste trabalho foi caracterizar as alterações comportamentais e moleculares em modelos experimentais (in vivo e in vitro) expostos à STZ e avaliar a participação do sistema canabinoide. A STZ produziu prejuízo cognitivo, morte celular por apoptose, deficiência na resposta à insulina e alterações na via IR/PI3K, semelhantes às encontradas na DA. O agonista canabinoide ACEA foi capaz de reverter o prejuízo cognitivo, modificar as alterações proteicas da via IR/PI3K, e regular positivamente a via anti-apoptótica, gerando uma neuroproteção. / Alzheimer\'s disease (AD) is characterized by cognitive deficit associated with energy metabolism impairment and changes in insulin signaling. In this context, low doses of intracerebroventricular streptozotocin (STZ) injection has been used as an experimental model of AD in rats. Several studies have demonstrated the participation of the cannabinoid system in neurodegenerative processes and its neuroprotective and anti-inflammatory properties. Thus, the aim of this work was to characterize the molecular and behavior alterations in experimental models (in vitro and in vivo) produced by STZ exposure and evaluate the cannabinoid system participation in these models. STZ was able to induce cognitive impairment, apoptosis cell death, impaired insulin response and alterations in the IR/PI3K signaling pathway, similar to those found in AD. CB1 agonist, ACEA reversed cognitive impairment and modified some protein changes in IR/PI3K pathway caused by STZ, and positively regulate the anti-apoptotic pathway, generating neuroprotection.
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Caracterização da hemopressina (agonista inverso de receptores canabinóides do tipo 1) na neuropatia diabética experimental. / Characterization of hemopressin (inverse agonist of the cannabinoid receptor type 1) in experimental diabetic neuropathy.Toniolo, Elaine Flamia 26 August 2015 (has links)
A neuropatia periférica diabética é caracterizada por hiperalgesia e alodínia. O receptor CB1 é o principal responsável pelo efeito dos canabinóides na via nociceptiva. A Hemopressina (Hp), é um agonista inverso do CB1, que induz antinocicepção. Neste trabalho investigamos o efeito do tratamento com Hp (2,5 mg/Kg, por 28 dias) sobre a neuropatia diabética de camundongos, induzido por estreptozotocina (200mg/kg). A Hp reverte a hipersensibilidade mecânica em camundongos com neuropatia diabética, sendo que este efeito é específico para o tratamento da nocicepção e envolve a participação de receptores CB1, astrócitos e microglia em nível espinal. A Hp também previne a desmielinização do nervo isquiático dos animais diabéticos, e auxilia na manutenção dos níveis do NGF. Ainda, a Hp participa no controle da sensibilidade ao estímulo térmico quente em animais KO MOR e participa do controle da sensibilidade mecânica de animais KO MOR diabéticos pelo aumento da dimerização de CB1-DOR na medula espinal. Revelando a Hp um candidato para fins terapêuticos. / Diabetic peripheral neuropathy is characterized by hyperalgesia and allodynia. CB1 receptors are primarily responsible for the effect of cannabinoids in nociceptive pathways. Hemopressin (Hp) is an inverse agonist of CB1, which induces antinociception. In this study we investigated the effects of treatment with Hp (2.5 mg / kg for 28 days) on mice subjected to diabetic neuropathy by streptozotocin (STZ - 200 mg/kg). Hp treatement reversed the mechanical hypersensitivity in mice with neuropathy diabetic, and this effect is specific for the treatment of nociception and involves the participation of CB1 receptors, astrocytes and microglia at the spinal level. Hp prevented demyelination of the sciatic nerve in diabetic animals, and assisted in mantaining the levels of NGF. Also, Hp participates in the control of heat sensitivity to thermal stimulus in KO MOR animals and participates in the control of mechanical sensitivity in KO MOR diabetics animals by the increase in CB1-DOR dimerization in the spinal cord. Revealing Hp as a candidate for therapeutic purposes.
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Participação do sistema canabinoide em processos oxidativo e inflamatório relacionados à neurodegeneração in vitro. / Participation of the cannabinoid system in oxidative and inflammatory processes related to neurodegeneration in vitro.Silva, Hadassa Batinga da 08 December 2014 (has links)
A ativação do receptor CB1, leva a modulação de processos intracelulares que muda a resposta celular de acordo com o estímulo, além de estar envolvida em mecanismos de proliferação, diferenciação, movimentação e morte celular. O objetivo desse trabalho foi avaliar a participação desse sistema em processos oxidativo e inflamatório relacionados à neurodegeneração in vitro. Foi utilizado a linhagem de neuroblastoma Neuro2a diferenciada em células dopaminérgicas que foram expostas a três condições: com 6OHDA, H2O2 e LPS e co-tratadas com o agonista do receptor CB1 ACEA e o antagonista/agonista inverso AM251 por 24 horas. Utilizamos parâmetros funcionais de viabilidade celular, produção de espécies reativas de oxigênio e técnica de western blot. O tratamento com ACEA ou ACEA/AM251 produziram um aumento da viabilidade celular nos três modelos de exposição propostos; redução da produção de espécies reativas de oxigênio e ativação da via da proteína ERK1/2, além da inibição da morte celular pela diminuição da expressão da caspase 3. Concluímos que os canabinoides escolhidos foram capazes de proteger as células dopaminérgicas do dano oxidativo e inflamatório através do aumento da sobrevida celular por diminuição da produção de ROS. / The CB1 receptor activation leads to modulation of intracellular processes that change the cellular response according to the stimulus, as well as being involved in mechanisms of proliferation, differentiation, cell movement and death. The present study evaluated the participation of this system in oxidative and inflammatory processes related to neurodegeneration in vitro. We have used the Neuro2A neuroblastoma lineage, which those were differentiated into dopaminergic cells, and exposed to 6OHDA, H2O2 and LPS. They were co-treated with ACEA, CB1 receptor agonist, and AM251, the CB1 receptor antagonist/inverse agonist, for 24 hours. We used functional parameters of cell viability, production of reactive oxygen species and protein analyses by western blot. Treatment with ACEA or ACEA/AM251 produced an increase in cell viability; reduced production of reactive oxygen species and activation of the ERK1/2 protein, in addition to inhibition of cell death by decreasing the expression of caspase 3 in all three models proposed. We concluded that chosen cannabinoids were able to protect dopaminergic cells from oxidative damage and inflammation through the increased cell survival by decreasing the production of ROS.
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O potencial terapêutico de compostos canabinoides em um modelo in vitro de morte neuronal. / The therapeutic potential of cannabinoid compounds in an in vitro model of neuronal death.Vrechi, Talita Aparecida de Moraes 08 April 2016 (has links)
A neurodegeneração é o resultado da destruição progressiva e irreversível dos neurônios no sistema nervoso central, apresentando causas desconhecidas e mecanismos patológicos não totalmente elucidados. Fatores como a idade, o aumento da formação de radicais livres e/ou estresse oxidativo, defeito no metabolismo energético, a inflamação e acúmulo de elementos neurotóxicos e de proteínas malformadas no lúmen do retículo endoplasmático (RE) contribuem para o desenvolvimento dos processos neurodegenerativos. O sistema canabinoide tem sido proposto como neuroprotetor em diversos modelos de neurodegeneração como hipóxia aguda e epilepsia, isquemia cerebral, lesão cerebral e modelos de estresse oxidativo. Assim, este trabalho teve como objetivo investigar o papel do sistema canabinoide em uma linhagem de neuroblastoma (Neuro 2a) submetida a condições de estresse oxidativo (H2O2), inflamação (LPS) e estresse do RE (tunicamicina), avaliando parâmetros de viabilidade celular e vias de sinalização envolvidas. Nossos resultados mostram que o agonista canabinoide ACEA foi capaz de proteger as células da morte celular causada pela inflamação e pelo estresse de retículo endoplasmático, mas não pelo estresse oxidativo. Esse efeito neuroprotetor exercido pelo ACEA parece pelo menos em parte ocorrer via receptor CB1 no modelo de inflamação e ser independente deste receptor no modelo de estresse de RE. Os efeitos neuroprotetores observados envolveram a modulação dos níveis de proteínas pré-apoptóticas, CHOP e Caspase 12, e da proteína relacionada à sobrevivência celular ERK 1/2. Nossos dados sugerem um papel neuroprotetor do sistema canabinoide em mecanismos relacionados aos processos neurodegenerativos e propõem a manipulação desse sistema como possível alvo terapêutico. / Neurodegeneration is the result of progressive and irreversible destruction of neurons in the central nervous system, with unknown causes and pathological mechanisms not fully elucidated. Factors such as age, increased formation of free radicals and/or oxidative stress, defects in energetic metabolism, inflammation and accumulation of neurotoxic factors and misfolded proteins in the lumen of the endoplasmic reticulum (ER) contribute to the development of neurodegenerative processes. The cannabinoid system has been proposed as neuroprotector in several models of neurodegeneration such as acute hypoxia and epilepsy, cerebral ischaemia, brain injury and oxidative stress models. This work aimed to investigate the role of the cannabinoid system in a neuroblastoma line (Neuro 2a) submitted to oxidative stress (H2O2), inflammation (LPS) and ER stress (tunicamycin) conditions, assessing cell viability parameters and signaling pathways involved. Our results show that the ACEA cannabinoid agonist was able to protect cells from cell death caused by inflammation and ER stress, but not from oxidative stress. This neuroprotective effect exerted by ACEA appears to occur at least in part via the CB1 receptor in inflammation model and it seems to be independent of this receptor in the ER stress model. The neuroprotective effects observed involved the modulation of the levels of pre-apoptotic proteins CHOP and Caspase 12 and the cell survival related protein ERK 1/2. Our data suggest a neuroprotective role of the cannabinoid system in mechanisms related to neurodegenerative processes and propose it as possible therapeutic target.
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Endocannabinoids in TNF-α and Ethanol ActionsRettori, Valeria, Fernandez-Solari, Javier, Prestifilippo, Juan P., Mohn, Claudia, De Laurentiis, Andrea, Bornstein, Stefan R., Ehrhart-Bornstein, Monika, Elverdin, Juan C., McCann, Samuel M. 03 March 2014 (has links) (PDF)
During marijuana and alcohol consumption as well as during inflammation the reproductive axis is inhibited, mainly through the inhibition of luteinizing hormone-releasing hormone release. In male rats, this inhibitory effect is mediated, at least in part, by the activation of hypothalamic cannabinoid type 1 receptors (CB1). During inflammation, this activation of the endocannabinoid system seems to be mediated by an increase in TNF-α production followed by anandamide augmentations, similarly the effect of intragastric administration of ethanol (3 g/kg) seems to be due to an increase in anandamide. On the other hand, a number of different actions mediated by the endocannabinoid system in various organs and tissues have been described. Both cannabinoid receptors, CB1 and CB2, are localized in the submandibular gland where they mediate the inhibitory effect of intrasubmandibular injections of the endocannabinoid anandamide (6 × 10–5M) on salivary secretion. Lipopolysaccharide (5 mg/kg/3 h) injected intraperitoneally and ethanol (3 g/kg/1 h) injected intragastrically inhibited the salivary secretion induced by the sialogogue metacholine; this inhibitory effect was blocked by CB1 and/or CB2 receptor antagonists. Similar to the hypothalamus, these effects seem to be mediated by increased anandamide. In summary, similar mechanisms mediate the inhibitory actions of endocannabinoids and cannabinoids in both hypothalamus and submandibular gland during drug consumption and inflammation. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.
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Caracterização da hemopressina (agonista inverso de receptores canabinóides do tipo 1) na neuropatia diabética experimental. / Characterization of hemopressin (inverse agonist of the cannabinoid receptor type 1) in experimental diabetic neuropathy.Elaine Flamia Toniolo 26 August 2015 (has links)
A neuropatia periférica diabética é caracterizada por hiperalgesia e alodínia. O receptor CB1 é o principal responsável pelo efeito dos canabinóides na via nociceptiva. A Hemopressina (Hp), é um agonista inverso do CB1, que induz antinocicepção. Neste trabalho investigamos o efeito do tratamento com Hp (2,5 mg/Kg, por 28 dias) sobre a neuropatia diabética de camundongos, induzido por estreptozotocina (200mg/kg). A Hp reverte a hipersensibilidade mecânica em camundongos com neuropatia diabética, sendo que este efeito é específico para o tratamento da nocicepção e envolve a participação de receptores CB1, astrócitos e microglia em nível espinal. A Hp também previne a desmielinização do nervo isquiático dos animais diabéticos, e auxilia na manutenção dos níveis do NGF. Ainda, a Hp participa no controle da sensibilidade ao estímulo térmico quente em animais KO MOR e participa do controle da sensibilidade mecânica de animais KO MOR diabéticos pelo aumento da dimerização de CB1-DOR na medula espinal. Revelando a Hp um candidato para fins terapêuticos. / Diabetic peripheral neuropathy is characterized by hyperalgesia and allodynia. CB1 receptors are primarily responsible for the effect of cannabinoids in nociceptive pathways. Hemopressin (Hp) is an inverse agonist of CB1, which induces antinociception. In this study we investigated the effects of treatment with Hp (2.5 mg / kg for 28 days) on mice subjected to diabetic neuropathy by streptozotocin (STZ - 200 mg/kg). Hp treatement reversed the mechanical hypersensitivity in mice with neuropathy diabetic, and this effect is specific for the treatment of nociception and involves the participation of CB1 receptors, astrocytes and microglia at the spinal level. Hp prevented demyelination of the sciatic nerve in diabetic animals, and assisted in mantaining the levels of NGF. Also, Hp participates in the control of heat sensitivity to thermal stimulus in KO MOR animals and participates in the control of mechanical sensitivity in KO MOR diabetics animals by the increase in CB1-DOR dimerization in the spinal cord. Revealing Hp as a candidate for therapeutic purposes.
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