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RESEARCH PRODUCT
Understanding Cannabinoid Psychoactivity with Mouse Genetic Models
Thomas LembergerNadine KaiserCarsten T. WotjakBeat LutzBeat LutzFederico MassaFederico MassaKrisztina MonoryHeike BlaudzunGiovanni MarsicanoGiovanni MarsicanoGünther Schützsubject
MaleMESH: Body TemperatureCannabinoid receptormedicine.medical_treatmentGene ExpressionMESH: Receptor Cannabinoid CB1NeocortexMESH: gamma-Aminobutyric AcidMESH: CatalepsyPharmacologyHippocampusMESH: Mice KnockoutMESH: Corpus StriatumBody TemperatureMESH: Autonomic Nervous SystemMESH: NeocortexMice0302 clinical medicineReceptor Cannabinoid CB1MESH: Behavior AnimalCannabinoid receptor type 1MESH: AnimalsMESH: Gene SilencingDronabinolMESH: NociceptorsBiology (General)gamma-Aminobutyric AcidMice Knockout0303 health sciencesBehavior Animalmusculoskeletal neural and ocular physiologyGeneral NeuroscienceMESH: Pain ThresholdNociceptorsMESH: Glutamic AcidMESH: InterneuronsMESH: Motor Activity3. Good healthGABAergicMESH: TetrahydrocannabinolGeneral Agricultural and Biological SciencesResearch Articlemedicine.drugPain ThresholdMESH: Gene ExpressionMESH: Psychotropic DrugsQH301-705.5Glutamic AcidMotor ActivityBiologyAutonomic Nervous SystemGeneral Biochemistry Genetics and Molecular Biologygamma-Aminobutyric acid03 medical and health sciencesGlutamatergicDopamine receptor D1InterneuronsCannabinoid Receptor Modulatorsmental disorders[SDV.BBM] Life Sciences [q-bio]/Biochemistry Molecular BiologymedicineAnimalsGenetic Predisposition to Disease[SDV.BBM]Life Sciences [q-bio]/Biochemistry Molecular BiologyGene SilencingTetrahydrocannabinolMESH: MiceAnesthesiology and Pain Management030304 developmental biologyPharmacologyCatalepsyPsychotropic DrugsModels GeneticGeneral Immunology and MicrobiologyCannabinoidsIllicit Drugsorganic chemicalsMESH: MaleCorpus StriatumPrimerDisease Models Animalnervous systemCannabinoidNervous System Diseases030217 neurology & neurosurgeryNeurosciencedescription
Marijuana and its main psychotropic ingredient Δ9-tetrahydrocannabinol (THC) exert a plethora of psychoactive effects through the activation of the neuronal cannabinoid receptor type 1 (CB1), which is expressed by different neuronal subpopulations in the central nervous system. The exact neuroanatomical substrates underlying each effect of THC are, however, not known. We tested locomotor, hypothermic, analgesic, and cataleptic effects of THC in conditional knockout mouse lines, which lack the expression of CB1 in different neuronal subpopulations, including principal brain neurons, GABAergic neurons (those that release γ aminobutyric acid), cortical glutamatergic neurons, and neurons expressing the dopamine receptor D1, respectively. Surprisingly, mice lacking CB1 in GABAergic neurons responded to THC similarly as wild-type littermates did, whereas deletion of the receptor in all principal neurons abolished or strongly reduced the behavioural and autonomic responses to the drug. Moreover, locomotor and hypothermic effects of THC depend on cortical glutamatergic neurons, whereas the deletion of CB1 from the majority of striatal neurons and a subpopulation of cortical glutamatergic neurons blocked the cataleptic effect of the drug. These data show that several important pharmacological actions of THC do not depend on functional expression of CB1 on GABAergic interneurons, but on other neuronal populations, and pave the way to a refined interpretation of the pharmacological effects of cannabinoids on neuronal functions.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2007-10-01 | PLoS Biology |