Charakterisierung von einer retrograden Modulation inhibitorischer synaptischer Transmission im Kleinhirn der Ratte / Characterisation of a retrograde form of modulation of the synaptic inhibitory transmission in the rat cerebellum

Diana, Marco Alberto

31 January 2003

No description available.

Mathematics and Computer Science

Cannabinoide

GABAerge synaptische Transmission

Kleinhirn

DSI

synaptische Plastizitaet

000 Allgemeines

Wissenschaft

Cannabinoids

GABAergic synaptic transmission

Cerebellum

DSI

synaptic plasticity

The endocannabinoid system and autistic behavior in the Fmr1- KO mouse

Lenz, Frederike

11 July 2017

Background: Background of this work was the investigation of the endocannabinoid system (ECS) in the Fmr1 knock- out (KO) mouse. The Fmr1- KO mouse is a mouse model for fragile X syndrome (FXS). FXS is the leading monogenic cause for autism spectrum disorders (ASD) in humans. The Fmr1- KO mouse displays autistic behavior such as an impaired social interaction, repetitive behavior, cognitive deficits, increased anxiety and aggressiveness. Alterations of the ECS have been suggested to play a key role in the etiopathology of a variety of neuropsychiatric disorders. Until today, little has been described about the involvement of the ECS in ASD. Interrogation: 1. Evaluating the manifestation of typical cannabinoid- induced effects in the Fmr1- KO mouse 2. Investigating the influenceability of autistic symptoms with THC treatment in the Fmr1- KO mouse 3. Analyzing the signaling cascade of the stimulated and unstimulated ECS in different brain regions of the Fmr1- KO mouse Material and Methods: Experiments were carried out on adult (12±1 weeks old) male Fmr1- KO and Fmr1- wild- type (WT) mice from the C57BL/6J- (B6)- background. N= 15 mice received THC (10mg/kg bodyweight) and N= 16 received WIN55,212 (3mg/kg bodyweight). 30min after injection, the body temperature was measured and the distance animals moved in an open field during 15min was recorded (locomotion). Then, animals were placed with their forepaws onto a horizontally fixed bar and the time remaining in this position (catalepsy) was measured. Finally animals were placed on a preheated plate and the temperature at which a pain stimulus occurred was determined (testing analgesia). All 4 experiments are called tetrad experiment. Afterwards changes in body temperature, locomotion, catalepsy and analgesia of the animals was evaluated. To explore long-term effects of THC after the tetrad, N= 15 animals were tested in a social interaction test with a female contact mouse, 10 and 20 days after THC treatment. Therefore, the tested mouse and the contact mouse were placed together into a cage and the time mice spent in social interaction (nose, body and anogential sniffing, allogrooming and body contact) was manually quantified during 6min of recorded testing time. Another group of N= 19 received a premedication of rimonabant (Cannabinoid- receptor 1 (CB1) antagonist, 3mg/kg bodyweight) 30min prior to THC treatment. Rimonabant prevents THC from binding to CB1 and therefore allows the assessment of the involvement of CB1 in mediating social behavior. Furthermore the suggestibility of context-dependent fear conditioning with THC treatment has been tested on N= 13 mice. Animals were placed into a conditioning chamber that delivered 6 short electric shocks with a 30sec pause to their paws (conditioning phase). Immediately afterwards mice received THC or placebo. 24h later contextdependent fear was evaluated by quantification of the time mice spent freezing in the conditioning-chamber (fear) without receiving foot shocks. Intraneuronal signaling of the ECS was analyzed with N= 29 animals using western blots. Quantities of phosphorylated (“activated”) protein kinases (ERK, AKT and S6) from different brain homogenates (hippocampus, striatum, cortex and cerebellum) were therefore measured after THC or placebo injection (30 minutes prior to sacrificing). Results: Cannabinoids induced hypothermia, hypolocomotion, analgesia and catalepsy in WTmice. These effects were significantly less detectable in Fmr1- KO mice. Effects of both cannabinoids, THC and WIN55,212, were comparable with a slightly greater but not significant efficiency of THC. THC treated WT- mice exhibited further reduced social interaction 10 days after treatment, an effect that was partially prevented by premedication with rimonabant. THC increased social interaction in Fmr1- KO mice comparable to the level of untreated WT- mice. THC had no effect on behavior of WT- mice in context-dependent fear conditioning. Fmr1- KO mice showed significant less contextdependent fear conditioning compared to WT- mice. THC facilitated the recognition of an anxiety-correlated context in Fmr1- KO mice comparable to untreated WT- mice. In western blots significant changes in the THC- induced signaling cascade were detectable and depending on genotype, brain-region and analyzed protein-kinase. In the hippocampus there were no changes in untreated Fmr1- KO mice compared to WT- mice. THC had no effect on activation of protein-kinases in WT- and Fmr1- KO mice. In the striatum there were no changes in untreated Fmr1- KO mice compared to WTmice. THC significantly increased activity of ERK, AKT and S6 in WT-mice and not in Fmr1- KO mice. In the cortex of untreated Fmr1- KO mice AKT showed a significantly increased activity compared to WT- mice. THC significantly increased AKT activity in WT- mice without having an effect on KO- mice. In the cerebellum there were no changes in untreated Fmr1- KO mice compared to WT- mice. THC significantly increased ERK- activity in Fmr1- KO mice but had no effect on protein kinase activity in WT- mice. Conclusion: We observed physiological cannabinoid effects in WT- mice after treatment with THC and WIN55,212. These effects are significantly attenuated in Fmr1- KO mice. This may be interpreted as a desensitization of the ECS in the Fmr1- KO mouse. At the same time it was demonstrated that THC has the potential to improve context dependent memory consolidation and to increase social interaction in the Fmr1- KO mouse. In particular the influence of THC on impaired social interaction should be a target of further investigations to find possible therapeutic options for this typical symptom of Autism. Underlying molecular mechanisms remain unclear and the analysis of THC stimulated intraneuronal signaling gave no clear indication of possible molecular alterations in the Fmr1- KO mouse.

info:eu-repo/classification/ddc/610

ddc:610

Sistemas cannabinoide y purinérgico: posibles sustratos neurobiológicos de la drogadicción

Soria Rodríguez, Guadalupe

21 June 2006

La adicción es un trastorno crónico de la conducta caracterizado por la búsqueda y el consumo compulsivos de la droga, la pérdida de control para limitar dicho consumo, a aparición de un estado emocional negativo cuando el acceso a la droga está impedido y la recaída en el proceso incluso tras largos períodos de abstinencia. El sistema dopaminérgico mesolímbico cortical ha sido propuesto como la principal base neurobiológica de la adicción, sin embargo existen otros sistemas de neurotransmision que participan en la consolidación del proceso adictivo.El sistema endocannabinoide, a traves del receptor CB1, participa en las propiedades adictivas de diferentes drogas de abuso como el delta9-tetrahidrocannabinol, la nicotina y la morfina. Sin embargo, hasta el momento de iniciar este trabajo, pocos estudios han demostrado una clara implicación del sistema endocannabinoide en las propiedades reforzantes de los psicoestimulantes. Mediante el uso de ratones CB1 knockout, hemos demostrado que el receptor CB1 participa en la eficacia reforzante de la cocaína. Además, la presencia de dicho receptor es necesaria para los procesos de consolidación de una conducta operante mantenida por la autoadministración de cocaína. Este estudio demuestra la importancia de dicho receptor CB1 en las propiedades adictivas de la cocaína, confirmando que el sistema endocannabinoide es un sustrato común para la adicción de drogas de abuso. Por otra parte, el sistema purinérgico modula numerosos sistemas de neurotransmisión en el SNC. La estrecha relación a nivel celular y funcional entre los receptores de adenosina y los receptores dopaminérgicos proporciona evidencias de que el sistema purinérgico podría modular los sistemas de recompensa. Utilizando diferentes modelos animales, hemos demostrado que los receptores de adenosina A2A son necesarios para que las propiedades adictivas de las drogas de abuso como los cannabinoides, los opioides, la nicotina y los psicoestimulantes se produzcan de un modo completo.Nuestros estudios nos permiten afirmar que ambos sistemas, el cannabinoide y el purinérgico podría suponer la existencia de nuevos sistemas de modulación común de los procesos adictivos. Asi, sería de gran interés desarrollar nuevas estrategias de bloqueo de los receptores A2A y CB1 para atenuar e incluso prevenir el desarrollo de la adicción. / Drug addiction is a chronically relapsing disorder that is defined by a compulsion to take the drug intake, a loss of control in limiting intake and a withdrawal-negative affect state when the access to the drug is interrupted. Mesolimbic dopaminergic system has been proposed as a fundamental neurobiological substrate for drug addiction. However, there is evidence for other neurotransmitter systems involved in the consolidation of the addictive process. The endocannabinoid system, through the activation of CB1 receptor, participates in the addictive properties of different drugs of abuse such as delta9-tetrahydrocannabinol, morphine and nicotine. Nevertheless, few studies have revealed an important implication of CB1 receptor in the reinforcing properties of psychostimulants. By using CB1 knockout mice, we have demonstrated that CB1 receptor participates in the reinforcing efficacy of cocaine. Moreover, this receptor is necessary for the consolidation processes involved in cocaine maintained intravenous self-administration. Therefore, this study reveals an essential role of CB1 receptor in cocaine addictive properties, confirming that the endocannabinoid system is a common substrate of addiction to drugs of abuse.On the other hand, the purinergic system modulates different neurotransmitter systems in the CNS. Adenosine receptors are closely related to dopaminergic receptors at both cellular and functional levels, suggesting that purinergic system could modulate the reward systems. By using different animal models, we have demonstrated that A2A adenosine receptors are necessary for the development of the addictive properties of drugs of abuse such as opioids, cannabinoids, nicotine and cocaine. Our studies suggest that both cannabinoid and purinergic systems could represent new and common modulatory systems of addictive processes. Thus, it would be of interest to develop new therapeutic targets blocking CB1 and A2A receptors to attenuate the development of addiction.

withdrawal syndrome

dependence

reinforcement

interaction

reward

mice

knockout

adenosine

A2A receptor

purinergic system

CB1 receptor

dopamina

cannabinoid system

adicción

comportamiento

abstinencia

refuerzo

dependencia

knockout

interacción

ratón

adenosina

receptor A2A

sistema purinérgico

receptor CB1

sistema cannabinoide

behaviour

addiction

dopamine

575

616.8

Participación del sistema cannabinoide endógeno en el control de las respuestas relacionadas con trastornos afectivos

Aso Pérez, Ester

19 December 2008

Los trastornos emocionales de tipo depresivo y la ansiedad son las formas más prevalentes de enfermedad mental y suponen un serio problema de salud en la sociedad occidental. Recientemente, se ha postulado que el sistema endocannabinoide pueda ser un importante sustrato en el desarrollo de estos trastornos dada su participación en el control de las emociones. Nuestros resultados demuestran que los animales carentes del receptor cannabinoide CB1 manifiestan un fenotipo de tipo depresivo asociado a una deficiencia del factor neurotrófico BDNF en el hipocampo, que podría estar causada por los elevados niveles de glucocorticoides liberados en respuesta al estrés en estos mutantes. Por otra parte, el sistema endocannabinoide participa en los efectos inducidos por la nicotina sobre la ansiedad y en la expresión del síndrome de abstinencia de esta droga. Así, la actividad del receptor CB1 alivia los efectos ansiogénicos de dosis elevadas de nicotina y facilita los efectos ansiolíticos de dosis bajas. Además, la administración del agonista cannabinoide 9-THC atenúa las manifestaciones somáticas y emocionales negativas de la abstinencia de nicotina. En general, considerando los resultados presentados en esta Tesis Doctoral, podemos afirmar que el receptor CB1 participa de forma determinante en la recuperación del balance homeostático del organismo tras la exposición a un estímulo emocional negativo, bien sea una situación estresante aguda o sostenida, o bien una droga que incrementa los niveles de ansiedad o cuya retirada produce abstinencia. / Mood disorders such as depression and anxiety are the most common mental diseases and they suppose a serious health problem in our society. Recently, endocannabinoid system has been postulated to be an important substrate in the development of such disorders taking into account the role exerted by this neuromodulatory system in mood and emotions. Our results demonstrate that CB1 knockout mice exhibit a depressive-like phenotype associated to a deficiency in the neurotrophic factor BDNF in the hippocampus, which could be a consequence of the increased glucocorticoid release in response to stress exposure. On the other hand, the endocannabinoid system participates in nicotine induced effects on anxiety and in the expression of nicotine withdrawal. Thus, CB1 receptor activity attenuates anxiogenic-like effects and facilitates anxiolytic-like responses induced by high or low doses of nicotine, respectively. Moreover, 9-THC administration ameliorates somatic and negative motivational signs of nicotine withdrawal. In summary, the results presented in this Doctoral Thesis indicate that CB1 receptor participates in the recovery of the homeostatic balance after the exposure to negative emotional stimuli, either acute or sustained stress or a drug which induced anxiety-like effects or withdrawal signs after the end of the exposure.

glucocorticoid

stress

behaviour

serotonin

nicotine

withdrawal

anxiety

depression

CB1 receptor

serotonergic system

cannabinoid system

brain

knockout

ratón

antidepresivo

5-HTT

5-HT2C

5-HT2A

5-HT1A

BDNF

hipocampo

glucocorticoide

estrés

comportamiento

serotonina

nicotina

abstinencia

ansiedad

depresión

receptor CB1

sistema serotonérgico

sistema cannabinoide

cerebro

hippocampus

BDNF

5-HT1A

5-HT2A

5-HT2C

5-HTT

antidepressant

mouse

knockout

57

Study of the interaction between 3,4 methylenedioximethamphetamine and the endocannabinoid system

Touriño Raposo, Clara

17 February 2009

La 3,4-metilendioximetamfetamina (MDMA, èxtasi) i el cannabis són dues drogues les quals es consumeixen conjuntament de manera habitual. Malgrat que tots dos compostos presenten propietats reforçant i potencial addictiu, també tenen propietats farmacològiques oposades. La MDMA es una droga psicoestimulant, la qual causa hiperlocomoció, hipertèrmia, resposted de tipus asiogènic i neurotoxicitat. Per altra banda el Δ9-tetrahydrocannabinol (THC), principal compost psicoactiu del cannabis, posseeix efectes relaxants, hipolocomotors, hipotèrmics i neuroprotectors. Els efectes de la MDMA i el THC al sistema nerviós central es troben mediats per dos mecanismes notablement diferents. La MDMA augmenta els nivells extracel·lulars de dopamina i serotonina, mentre que el THC produeix l'activació del receptor cannabinoide CB1. Cal destacar a més que les interaccions entre els sistemes monoaminèrgic i endocannabinoide s'observa de manera freqüent en l'organisme.En el present estudi hem explorat la implicació del sistema endocannabinoide i la MDMA en diversos aspectes. Per una banda el receptor cannabinoide CB1 juga un important paper en els efectes hiperlocomotors i hipertèrmics, i en les respostes de tipus ansiogènic produïdes per la MDMA. Curiosament, encara que el receptor CB1 no participa en els efectes recompensants primaris de la MDMA, és imprescindible per que tinguin lloc els seus efectes reforçants. Així mateix, l'alliberació de serotonina per part de la MDMA redueix de manera dosi-depenent la simptomatologia física causada pel síndrome d'abstinència a cannabinoides precipitada per un antagonista del receptor CB1. Finalment, el tractament amb THC era capaç de prevenir la hipertèrmia, activació glial, estrès oxidatiu i pèrdua de terminals causada per la MDMA. Com a conseqüència el THC exerceix un efecte neuroprotector contra la neurotoxicitat induïda per la MDMA. / 3,4-methylenedioximethamphetamine (MDMA, ecstasy) and cannabis are two drugs frequently consumed in combination. Despite both compounds have rewarding properties and abuse liability, they show opposite pharmacological properties. On the one hand, MDMA is a psychostimulant drug with hyperlocomotor, hyperthermic, anxiogenic-like and neurotoxic effects. On the other hand, Δ9-tetrahydrocannabinol (THC), the main psychoactive compound of cannabis, has relaxant, hypolocomotor, hypothermic and neuroprotective properties. The effects of MDMA and THC in the central nervous system are mediated by two different mechanisms. MDMA enhances the extracellular levels of dopamine and serotonin, whereas THC activates the CB1 cannabinoid receptor. Likewise, interactions between the monoaminergic and the endogenous cannabinoid system have been frequently observed.In the current study, we explored the involvement of CB1 cannabinoid receptor on the hyperlocomotor, hyperthermic, anxiogenic-like, rewarding and reinforcing effects of MDMA. We also studied the effect of acute and chronic administration of MDMA on rimonabant-precipitated THC withdrawal syndrome. Furthermore, we explored the neuroprotective effects of THC on MDMA-induced neurotoxicity.As a result of this study we may conclude that endocannabinoid system and MDMA interact in a wide variety of aspects. CB1 receptor plays an important role on the hyperlocomotor, hyperthermic, and anxiogenic-like effects of MDMA. Interestingly, CB1 receptor is essential for the reinforcing but not the primary rewarding properties of MDMA. In addition, the release of serotonin by MDMA dose-dependently reduced the severity of THC withdrawal syndrome triggered by a CB1 antagonist. Finally, pretreatment with THC prevented the hyperthermia, glial activation, oxidative stress and terminal loss caused by MDMA. Consequently, THC exerts a neuroprotective effect against MDMA-induced neurotoxicity.

tremolor

transportador de dopamina

tirosina hidroxilasa

THC

temperatura corporal

sintasa d'òxid nítric

síndrome d'abstinència

serotonina

rotarod

rimonabant

reforç

recompensa

receptor cannabinoide

Ptosis

proteïna glial fibrilar acídica

preferència de plaça condicionada

piloerecció

pèrdua de terminals

nucli accumbens

neuroprotecció

neurotoxicitat

microglia

microdialisis

MDMA

masticació

laberint en creu elevat

infusió

inflamació

immunohistoquímica

hipotèrmia

hipolocomoció

hipertèrmia

hiperlocomoció

glutamat

èxtasi

estriat

dopamina

diarrea

dependència

DAT

dany neuronal

coordinació motora

CD11b

CB2

CB1

autoadministració

atàxia

astròcits

anxiolític

anxiogènic

ansietat

activitat locomotora

abstinència

4-metilendioximetamfetamina

3

Δ9-tetrahydrocannabinol

western blot

Δ9-tetrahydrocannabinol

3

4-methylenedioximethamphetamine

abstinence

anxiety

anxiogenic

anxiolytic

astrocytes

ataxia

body temperature

615

616.8