Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UNIPROT:P21554 (cannabinoid receptor)
3,582 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Cloning of the cannabinoid receptor affords the opportunity to examine its developmental expression. Other G-protein-coupled receptor systems, those for the opioids for example, exhibit distinct ontogenies. For the initial study, therefore, cannabinoid receptor mRNA expression was assessed in rat pups postnatal days 3, 5, 8, 10, 12, 15, 18 and 21. The brains were grossly dissected into cerebellum/brainstem and forebrain, and total RNA was extracted by a modified acid-extraction method. Expression of the cannabinoid receptor was analyzed by two methods: polymerase chain reaction (PCR) and Northern blot analysis. Oligonucleotide primers based on bp 1-21 and bp 824-843 on the opposite strand were chosen for use in the PCR. The probe used in the Northern blot analysis was a full length cDNA corresponding to the rat cannabinoid receptor and was cloned in our lab based on published sequence information. Our results indicate that by postnatal day 3, cannabinoid receptor mRNA can be detected in the brain. Our results further indicate that cannabinoid mRNA expression steadily increases in the cerebellum/brainstem until postnatal days 18-21, while expression in the forebrain does not change. The findings from the present study indicate that cannabinoid receptor mRNA is present in very young rats. Our data also suggest, however, regional differences in the relative expression of message which may parallel cerebellar proliferation and organization.
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PMID:Developmental expression of cannabinoid receptor mRNA. 830 33

Marijuana is currently the most widely abused street drug. However, the functional significance of the cannabinoid receptor system in health and disease includes the use of cannabinoids as analgesics, antiemetics in cancer patients, anticonvulsants for epilepsy, and as antiglaucoma agents as well as immunomodulatory agents. Our knowledge of the mechanisms of action of cannabinoids has increased greatly in the past several years. Two cannabinoid receptors have been identified to date: one is located predominantly in the central nervous system (CBI), whereas the other is expressed in peripheral tissues (CB2). Both are members of the G-protein-coupled receptor family and couple to inhibition of adenylyl cyclase (as well as additional second messenger systems), in transfected cells expressing these receptors, and in the nervous system. An endogenous ligand has been isolated for the CBI receptor; it is arachidonic acid ethanolamide, or anandamide. Candidate endogenous ligands for the CB2 receptor have also been described. Another development is the discovery of a selective antagonist for the CBI receptor. The distribution of the cannabinoid receptor subtypes has been mapped by receptor autoradiography, RT-PCR and in situ hybridization. These new research tools will aid in the elucidation of the physiological role of the endogenous cannabinoid system.
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PMID:Molecular neurobiology of the cannabinoid receptor. 889 48

A new common region of virus integration, Evi11, has been identified in two retrovirally induced murine myeloid leukemia cell lines, NFS107 and NFS78. By interspecific backcross analysis, it was shown that Evi11 is located at the distal end of mouse chromosome 4, in a region that shows homology with human 1p36. The genes encoding the peripheral cannabinoid receptor (Cnr2) and alpha-L-fucosidase (Fuca1) were identified near the integration site by using a novel exon trapping system. Cnr2 is suggested to be the target gene for viral interference in Evi11, since proviruses are integrated in the first intron of Cnr2 and retroviral integrations alter mRNA expression of Cnr2 in NFS107 and NFS78. In addition, proviral integrations were demonstrated within the 3' untranslated region of Cnr2 in five independent newly derived CasBrM-MuLV (mouse murine leukemia virus) tumors, CSL13, CSL14, CSL16, CSL27, and CSL97. The Cnr2 gene encodes a seven-transmembrane G-protein-coupled receptor which is normally expressed in hematopoietic tissues. Our data suggest that the peripheral cannabinoid receptor gene might be involved in leukemogenesis as a result of aberrant expression of Cnr2 due to retroviral integration in Evi11.
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PMID:The genes encoding the peripheral cannabinoid receptor and alpha-L-fucosidase are located near a newly identified common virus integration site, Evi11. 926 4

We have found that phosphorylation of a G-protein-coupled receptor by protein kinase C (PKC) disrupts modulation of ion channels by the receptor. In AtT-20 cells transfected with rat cannabinoid receptor (CB1), the activation of an inwardly rectifying potassium current (Kir current) and depression of P/Q-type calcium channels by cannabinoids were prevented by stimulation of protein kinase C by 100 nM phorbol 12-myristate 13-acetate (PMA). In contrast, activation of Kir current by somatostatin was unaffected, and inhibition of calcium channels was only modestly attenuated. The possibility that PKC acted by phosphorylating CB1 receptors was confirmed by demonstrating that PKC phosphorylated a single serine (S317) of a fusion protein incorporating the third intracellular loop of CB1. Mutating this serine to alanine did not affect the ability of CB1 to modulate currents, but it eliminated disruption by PMA, demonstrating that PKC can disrupt ion channel modulation by receptor phosphorylation.
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PMID:Protein kinase C disrupts cannabinoid actions by phosphorylation of the CB1 cannabinoid receptor. 952

The CB1 cannabinoid receptor in brain is a G-protein-coupled receptor that exists as a protein possessing seven transmembrane helices that span the membrane. The intracellular surface is able to interact with f1p4oteins of the Gi/o family to regulate effector proteins, including adenylate cyclase, Ca2+ channels, and K+ channels, and to stimulate the mitogen-activated protein kinase pathway. The CB1 cannabinoid receptor recognizes three classes of agonist ligands: cannabinoid, eicosanoid, and aminoalkylindole. These agonist subtypes may interact with the CB1 cannabinoid receptor by some common points of association, yet may have subtle differences in the way that they interact with the receptor protein. This may be evident in the allosteric regulation by monovalent cations and individual agonists. The juxtamembrane region of the C-terminal is able to activate G-proteins. It is proposed that conformational changes in the receptor induced by agonist ligands may alter the conformation or exposure of the juxtamembrane C-terminal region extending from helix VII.
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PMID:The CB1 cannabinoid receptor in the brain. 997 74

We tested the hypothesis that human CB1 cannabinoid receptors (hCB1) can sequester G(i/o)-proteins from a common pool and prevent other receptors from signaling. Human CB1 cannabinoid receptors were expressed in superior cervical ganglion (SCG) neurons by microinjection of hCB1 cDNA. Expression of hCB1 cannabinoid receptors abolished the Ca(2+) current inhibition by endogenous pertussis toxin-sensitive G(i/o)-coupled receptors for norepinephrine (NE) and somatostatin (SOM) but not by endogenous pertussis toxin-insensitive G(s)-coupled receptors for vasoactive intestinal polypeptide. Signaling by NE was rescued by expression of Galpha(oB), Gbeta(1), and Ggamma(3). Expression of mGluR2 metabotropic glutamate receptors, another pertussis toxin-sensitive G-protein-coupled receptor, had no effect on the signaling by NE or SOM. Some hCB1 receptors were constitutively active because the cannabinoid receptor inverse agonist SR 141617A enhanced the Ca(2+) current. Some hCB1 receptors also appear to be precoupled to G(i/o)-proteins because the cannabinoid agonist WIN 55,212-2 decreased the Ca(2+) current at a time when no G-proteins were available to couple to alpha(2)-adrenergic and somatostatin receptors. In SCG neurons microinjected with a lower concentration of hCB1 cDNA, the effect of SR 141716A was reduced, and the response to NE and SOM was partially restored. Subsequent to the application of SR 141716A, the Ca(2+) current inhibition by NE and SOM was abolished. These results suggest that both the active and inactive states of the hCB1 receptor can sequester G(i/o)-proteins from a common pool. Cannabinoid receptors thus have the potential to prevent other G(i/o)-coupled receptors from transducing their biological signals.
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PMID:The CB1 cannabinoid receptor can sequester G-proteins, making them unavailable to couple to other receptors. 1053 31

Cannabinoids exert most of their effects in the central nervous system through the CB(1) cannabinoid receptor. This G-protein-coupled receptor has been shown to be functionally coupled to inhibition of adenylate cyclase, modulation of ion channels and activation of extracellular-signal-regulated kinase. Using Chinese hamster ovary cells stably transfected with the CB(1) receptor cDNA we show here that Delta(9)-tetrahydrocannabinol (THC), the major active component of marijuana, induces the activation of protein kinase B/Akt (PKB). This effect of THC was also exerted by the endogenous cannabinoid anandamide and the synthetic cannabinoids CP-55940 and HU-210, and was prevented by the selective CB(1) antagonist SR141716. Pertussis toxin and wortmannin blocked the CB(1) receptor-evoked activation of PKB, pointing to the sequential involvement of a G(i)/G(o) protein and phosphoinositide 3'-kinase. The functionality of the cannabinoid-induced stimulation of PKB was proved by the increased phosphorylation of glycogen synthase kinase-3 serine 21 observed in cannabinoid-treated cells and its prevention by SR141716 and wortmannin. Cannabinoids activated PKB in the human astrocytoma cell line U373 MG, which expresses the CB(1) receptor, but not in the human promyelocytic cell line HL-60, which expresses the CB(2) receptor. Data indicate that activation of PKB may be responsible for some of the effects of cannabinoids in cells expressing the CB(1) receptor.
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PMID:The CB1 cannabinoid receptor is coupled to the activation of protein kinase B/Akt. 1074 65

Cannabinoids exert most of their effects through the CB(1) receptor. This G-protein-coupled receptor has been shown to be functionally coupled to inhibition of adenylyl cyclase, modulation of ion channels, and activation of extracellular signal-regulated kinase. Using Chinese hamster ovary cells stably transfected with the CB(1) receptor cDNA, we show here that Delta(9)-tetrahydrocannabinol (THC), the major active component of marijuana, induces the activation of c-Jun N-terminal kinase (JNK). Western blot analysis showed that both JNK-1 and JNK-2 were stimulated by THC. The effect of THC was also exerted by endogenous cannabinoids (anandamide and 2-arachidonoylglycerol) and synthetic cannabinoids (CP-55,940, HU-210, and methanandamide), and was prevented by the selective CB(1) antagonist SR141716. Pertussis toxin, wortmannin, and a Ras farnesyltransferase inhibitor peptide blocked, whereas mastoparan mimicked, the CB(1) receptor-evoked activation of JNK, supporting the involvement of a G(i)/G(o)-protein, phosphoinositide 3'-kinase and Ras. THC-induced JNK stimulation was prevented by tyrphostin AG1296, pointing to the implication of platelet-derived growth factor receptor transactivation, and was independent of ceramide generation. Experiments performed with several types of neural cells that endogenously express the CB(1) receptor suggested that long-term JNK activation may be involved in THC-induced cell death. The CB(1) cannabinoid receptor was also shown to be coupled to the activation of p38 mitogen-activated protein kinase. Data indicate that activation of JNK and p38 mitogen-activated protein kinase may be responsible for some of the cellular responses elicited by the CB(1) cannabinoid receptor.
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PMID:The CB(1) cannabinoid receptor is coupled to the activation of c-Jun N-terminal kinase. 1099 52

Cannabinoids exert most of their effects through the CB(1) receptor. This G protein-coupled receptor signals inhibition of adenylyl cyclase, modulation of ion channels, and stimulation of mitogen- and stress-activated protein kinases. In this article, we report that Delta(9)-tetrahydrocannabinol (THC), the major active component of marijuana, induces sphingomyelin hydrolysis in primary astrocytes but not in other cells expressing the CB(1) receptor, such as primary neurons, U373 MG astrocytoma cells, and Chinese hamster ovary cells transfected with the CB(1) receptor cDNA. THC-evoked sphingomyelin breakdown in astrocytes was also exerted by the endogenous cannabinoid anandamide and the synthetic cannabinoid HU-210 and was prevented by the selective CB(1) antagonist SR141716. By contrast, the effect of THC was not blocked by pertussis toxin, pointing to a lack of involvement of G(i/o) proteins. A role for the adaptor protein FAN in CB(1) receptor-coupled sphingomyelin breakdown is supported by two observations: 1) coimmunoprecipitation experiments show that the binding of FAN to the CB(1) receptor is enhanced by THC and prevented by SR141716; 2) cells expressing a dominant-negative form of FAN are refractory to THC-induced sphingomyelin breakdown. This is the first report showing that a G-protein-coupled receptor induces sphingomyelin hydrolysis through FAN and that the CB(1) cannabinoid receptor may signal independently of G(i/o) proteins.
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PMID:The CB(1) cannabinoid receptor of astrocytes is coupled to sphingomyelin hydrolysis through the adaptor protein fan. 1130 75

The plant Cannabis sativa has been used by humans for thousands of years because of its psychoactivity. The major psychoactive ingredient of cannabis is Delta(9)-tetrahydrocannabinol, which exerts effects in the brain by binding to a G-protein-coupled receptor known as the CB1 cannabinoid receptor. The discovery of this receptor indicated that endogenous cannabinoids may occur in the brain, which act as physiological ligands for CB1. Two putative endocannabinoid ligands, arachidonylethanolamide ('anandamide') and 2-arachidonylglycerol, have been identified, giving rise to the concept of a cannabinoid signalling system. Little is known about how or where these compounds are synthesized in the brain and how this relates to CB1 expression. However, detailed neuroanatomical and electrophysiological analysis of mammalian nervous systems has revealed that the CB1 receptor is targeted to the presynaptic terminals of neurons where it acts to inhibit release of 'classical' neurotransmitters. Moreover, an enzyme that inactivates endocannabinoids, fatty acid amide hydrolase, appears to be preferentially targeted to the somatodendritic compartment of neurons that are postsynaptic to CB1-expressing axon terminals. Based on these findings, we present here a model of cannabinoid signalling in which anandamide is synthesized by postsynaptic cells and acts as a retrograde messenger molecule to modulate neurotransmitter release from presynaptic terminals. Using this model as a framework, we discuss the role of cannabinoid signalling in different regions of the nervous system in relation to the characteristic physiological actions of cannabinoids in mammals, which include effects on movement, memory, pain and smooth muscle contractility. The discovery of the cannabinoid signalling system in mammals has prompted investigation of the occurrence of this pathway in non-mammalian animals. Here we review the evidence for the existence of cannabinoid receptors in non-mammalian vertebrates and invertebrates and discuss the evolution of the cannabinoid signalling system. Genes encoding orthologues of the mammalian CB1 receptor have been identified in a fish, an amphibian and a bird, indicating that CB1 receptors may occur throughout the vertebrates. Pharmacological actions of cannabinoids and specific binding sites for cannabinoids have been reported in several invertebrate species, but the molecular basis for these effects is not known. Importantly, however, the genomes of the protostomian invertebrates Drosophila melanogaster and Caenorhabditis elegans do not contain CB1 orthologues, indicating that CB1-like cannabinoid receptors may have evolved after the divergence of deuterostomes (e.g. vertebrates and echinoderms) and protostomes. Phylogenetic analysis of the relationship of vertebrate CB1 receptors with other G-protein-coupled receptors reveals that the paralogues that appear to share the most recent common evolutionary origin with CB1 are lysophospholipid receptors, melanocortin receptors and adenosine receptors. Interestingly, as with CB1, each of these receptor types does not appear to have Drosophila orthologues, indicating that this group of receptors may not occur in protostomian invertebrates. We conclude that the cannabinoid signalling system may be quite restricted in its phylogenetic distribution, probably occurring only in the deuterostomian clade of the animal kingdom and possibly only in vertebrates.
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PMID:The neurobiology and evolution of cannabinoid signalling. 1131 86


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