Cannabinoid type 2 receptors in dopamine neurons inhibits psychomotor behaviors, alters anxiety, depression and alcohol preference.

Cannabinoid CB2 receptors (CB2Rs) are expressed in mouse brain dopamine (DA) neurons and are involved in several DA-related disorders. However, the cell type-specific mechanisms are unclear since the CB2R gene knockout mice are constitutive gene knockout. Therefore, we generated Cnr2-floxed mice that were crossed with DAT-Cre mice, in which Cre- recombinase expression is under dopamine transporter gene (DAT) promoter control to ablate Cnr2 gene in midbrain DA neurons of DAT-Cnr2 conditional knockout (cKO) mice. Using a novel sensitive RNAscope in situ hybridization, we detected CB2R mRNA expression in VTA DA neurons in wildtype and DAT-Cnr2 cKO heterozygous but not in the homozygous DAT-Cnr2 cKO mice. Here we report that the deletion of CB2Rs in dopamine neurons enhances motor activities, modulates anxiety and depression-like behaviors and reduces the rewarding properties of alcohol. Our data reveals that CB2Rs are involved in the tetrad assay induced by cannabinoids which had been associated with CB1R agonism. GWAS studies indicates that the CNR2 gene is associated with Parkinson's disease and substance use disorders. These results suggest that CB2Rs in dopaminergic neurons may play important roles in the modulation of psychomotor behaviors, anxiety, depression, and pain sensation and in the rewarding effects of alcohol and cocaine.

Molecular neurobiological methods in marijuana-cannabinoid research.

Recent aggregation of evidence for the roles of endogenous agonist and receptor systems that are mimicked or activated by cannabanoid ligands has provided a focus for work that has elucidated details of some of the multiple physiological roles and pharmacological functions that these systems play in brain and peripheral tissues. This chapter reviews some of the approaches to improved elucidation of these systems, with special focus on the human genes that encode cannabanoid receptors and the variants in these receptors that appear likely to contribute to human addiction vulnerabilities.

Methods to study the behavioral effects and expression of CB2 cannabinoid receptor and its gene transcripts in the chronic mild stress model of depression.

Behavioral and molecular methods were used to study and determine whether there is a link between depression that may be a factor in drug/alcohol addiction, and the endocannabinoid hypothesis of substance abuse. Depression is a lack of interest in the pleasurable things of life (termed anhedonia) and depressed mood. It is unknown whether CB2 cannabinoid receptors are expressed in the brain and whether they are involved in depression and substance abuse. Therefore, mice were subjected daily for 4 wk to chronic mild stress (CMS), and anhedonia was measured by the consumption of 2% sucrose solution. Behavioral and rewarding effects of abused substances were determined in the CMS and control animals. The expression of CB2 receptors and their gene transcripts was compared in the brains of CMS and control animals by Western blotting using CB2 receptor antibody and reverse transcriptase-polymerase chain reaction (RT-PCR). Furthermore, the expression and immunocytochemical identification of CB2 cannabinoid receptor in the rat brain were determined. CMS induced gender-specific aversions, which were blocked by WIN55,212-2, a nonspecific CB1 and CB2 cannabinoid receptor agonist. Direct CB2 antisense oligonucleotide microinjection into the mouse brain induced anxiolysis, indicating that CB2 or CB2-like receptors are present in the brain and may influence behavior. The major finding from these studies was the expression of CB2 receptor and its gene transcript in the mouse brain, which was enhanced by CMS. These preliminary results, if confirmed, suggest that the CB2 receptors are expressed in the mammalian brain and may be involved in depression and substance abuse.

Endocannabinoids and cannabinoid receptor genetics.

This review presents the remarkable advances that have been achieved in marijuana (cannabinoid) research, with the discovery of specific receptors and the existence of naturally occurring cannabis-like substances in the human body and brain. The last decade has seen more rapid progress in marijuana research than any time in the thousands of years that marijuana has been used by humans, particularly in cannabinoid genomics. The cDNA and genomic sequences encoding G protein-coupled cannabinoid receptors (Cnrs) from several species have now been cloned. Endogenous cannabinoids (endocannabinoids), synthetic and hydrolyzing enzymes and transporters that define neurochemically-specific cannabinoid brain pathways have been identified. Endocannabinoid lipid signaling molecules alter activity at G protein-coupled receptors (GPCR) and possibly at anandamide-gated ion channels, such as vanilloid receptors. Availability of increasingly-specific CB1 and CB2 Cnr antagonists and of CB1 and CB2 Cnr knockout mice have increased our understanding of these cannabinoid systems and provides tantalizing evidence for even more G protein-coupled Cnrs. Initial studies of the Cnr gene structure, regulation and polymorphisms whet our appetite for more information about these interesting genes, their variants and roles in vulnerabilities to addictions and other neuropsychiatric disorders. Behavioral studies of cannabinoids document the complex interactions between rewarding and aversive effects of these drugs. Pursuing cannabinoid-related molecular, pharmacological and behavioral leads will add greatly to our understanding of endogenous brain neuromodulator systems, abused substances and potential therapeutics. This review of CB1 and CB2 Cnr genes in human and animal brain and their neurobiological effects provide a basis for many of these studies. Therefore, understanding the physiological cannabinoid control system in the human body and brain will contribute to elucidating this natural regulatory mechanism in health and disease.