Evidence for a new G protein-coupled cannabinoid receptor in mouse brain.

The purpose of these studies was to support the hypothesis that an undiscovered cannabinoid receptor exists in brain. [(35)S]GTP gamma S binding was stimulated by anandamide and WIN55212-2 in brain membranes from both CB(1)(+/+) and CB(1)(-/-) mice. In contrast, a wide variety of other compounds that are known to activate CB(1) receptors, including CP55940, HU-210, and Delta(9)-tetrahydrocannabinol, failed to stimulate [(35)S]GTP gamma S binding in CB(1)(-/-) membranes. In CB(1)(-/-) membranes, SR141716A affected both basal and anandamide- or WIN55212-2-induced stimulation of [(35)S]GTP gamma S binding only at concentrations greater than 1 microM. In CB(1)(+/+) membranes, SR141716A inhibited only 84% of anandamide and 67% of WIN55212-2 stimulated [(35)S]GTP gamma S binding with an affinity appropriate for mediation by CB(1) receptors (K(B) approximately 0.5 nM). The remaining stimulation seemed to be inhibited with lower potency (IC(50) approximately 5 microM) similar to that seen in CB(1)(-/-) membranes or in the absence of agonist. Further experiments determined that the effects of anandamide and WIN55212-2 were not additive, but that the effect of mu opioid, adenosine A1, and cannabinoid ligands were additive. Finally, assays of different central nervous system (CNS) regions demonstrated significant activity of cannabinoids in CB(1)(-/-) membranes from brain stem, cortex, hippocampus, diencephalon, midbrain, and spinal cord, but not basal ganglia or cerebellum. Moreover, some of these same CNS regions also showed significant binding of [(3)H]WIN55212-2, but not [(3)H]CP55940. Thus anandamide and WIN55212-2 seemed to be active in CB(1)(-/-) mouse brain membranes via a common G protein-coupled receptor with a distinct CNS distribution, implying the existence of an unknown cannabinoid receptor subtype in brain.

Agonist efficacy and receptor efficiency in heterozygous CB1 knockout mice: relationship of reduced CB1 receptor density to G-protein activation.

Heterozygous CB1 receptor knockout mice were used to examine the effect of reduced CB1 receptor density on G-protein activation in membranes prepared from four brain regions: cerebellum, hippocampus, striatum/globus pallidus (striatum/GP) and cingulate cortex. Results showed that CB1 receptor levels were approximately 50% lower in heterozygous mice in all regions examined. However, maximal stimulation of [(35)S]guanosine-5'-(gamma-O-thio) triphosphate ([(35)S]GTPgammaS) binding by the high efficacy agonist WIN 55,212-2 was reduced by only 20-25% in most brain regions, with the exception of striatum/GP where the decrease in stimulation was as predicted (approximately 50%). Furthermore, although the efficacies of the cannabinoid partial agonists, methanandamide and (9)-tetrahydrocannabinol, were similarly lower in heterozygous mice, their relative efficacies compared with WIN 55,212-2 were generally unchanged. Saturation analysis of net WIN 55,212-2-stimulated [(35)S]GTPgammaS binding showed that decreased stimulation by WIN 55,212-2 in striatum/GP of heterozygous mice was caused by a decrease in the apparent affinity of net-stimulated [(35)S]GTPgammaS binding. The apparent maximal number of binding sites (B(max)) values of net WIN 55,212-2-stimulated [(35)S]GTPgammaS binding were unchanged in cerebellum and striatum/GP of heterozygous mice, but decreased in cingulate cortex, with a similar trend in hippocampus. Moreover, in every region except cingulate cortex, the maximal number of net-stimulated [(35)S]GTPgammaS binding sites per receptor was significantly increased in heterozygous mice. These results indicate region-dependent increases in the apparent efficiency of CB1 receptor-mediated G-protein activation in heterozygous CB1 knockout mice.

Levels, metabolism, and pharmacological activity of anandamide in CB(1) cannabinoid receptor knockout mice: evidence for non-CB(1), non-CB(2) receptor-mediated actions of anandamide in mouse brain.

Anandamide [arachidonylethanolamide (AEA)] appears to be an endogenous agonist of brain cannabinoid receptors (CB(1)), yet some of the neurobehavioral effects of this compound in mice are unaffected by a selective CB(1) antagonist. We studied the levels, pharmacological actions, and degradation of AEA in transgenic mice lacking the CB(1) gene. We quantified AEA and the other endocannabinoid, 2-arachidonoyl glycerol, in six brain regions and the spinal cord by isotope-dilution liquid chromatography-mass spectrometry. The distribution of endocannabinoids and their inactivating enzyme, fatty acid amide hydrolase, were found to overlap with CB(1) distribution only in part. In CB(1) knockout homozygotes (CB(1)-/-), the hippocampus and, to a lesser extent, the striatum exhibited lower AEA levels as compared with wild-type (CB(1)+/+) controls. These data suggest a ligand/receptor relationship between AEA and CB(1) in these two brain regions, where tonic activation of the receptor may tightly regulate the biosynthesis of its endogenous ligand. 2-Arachidonoyl glycerol levels and fatty acid amide hydrolase activity were unchanged in CB(1)-/- with respect to CB(1)+/+ mice in all regions. AEA and Delta(9)-tetrahydrocannabinol (THC) were tested in CB(1)-/- mice for their capability of inducing analgesia and catalepsy and decreasing spontaneous activity. The effects of AEA, unlike THC, were not decreased in CB(1)-/- mice. AEA, but not THC, stimulated GTPgammaS binding in brain membranes from CB(1)-/- mice, and this stimulation was insensitive to CB(1) and CB(2) antagonists. We suggest that non-CB(1), non-CB(2) G protein-coupled receptors might mediate in mice some of the neuro-behavioral actions of AEA.

Neurobehavioral activity in mice of N-vanillyl-arachidonyl-amide.

We studied the cannabimimetic properties of N-vanillyl-arachidonoyl-amide (arvanil), a potential agonist of cannabinoid CB(1) and capsaicin VR(1) receptors, and an inhibitor of the facilitated transport of the endocannabinoid anandamide. Arvanil and anandamide exhibited similar affinities for the cannabinoid CB(1) receptor, but arvanil was less efficacious in inducing cannabinoid CB(1) receptor-mediated GTPgammaS binding. The K(i) of arvanil for the vanilloid VR(1) receptor was 0.28 microM. Administered i.v. to mice, arvanil was 100 times more potent than anandamide in producing hypothermia, analgesia, catalepsy and inhibiting spontaneous activity. These effects were not attenuated by the cannabinoid CB(1) receptor antagonist N-(piperidin-1-yl)-5-(4-chloro-phenyl)-1-(2, 4-dichlorophenyl)-4-methyl-1H-pyrazole-3-carboxamide.HCl (SR141716A). Arvanil (i.t. administration) induced analgesia in the tail-flick test that was not blocked by either SR141716A or the vanilloid VR(1) antagonist capsazepine. Conversely, capsaicin was less potent as an analgesic (ED(50) 180 ng/mouse, i.t.) and its effects attenuated by capsazepine. The analgesic effect of anandamide (i.t.) was also unaffected by SR141716A but was 750-fold less potent (ED(50) 20.5 microg/mouse) than capsaicin. These data indicate that the neurobehavioral effects exerted by arvanil are not due to activation of cannabinoid CB(1) or vanilloid VR(1) receptors.

Cannabinoid agonist signal transduction in rat brain: comparison of cannabinoid agonists in receptor binding, G-protein activation, and adenylyl cyclase inhibition.

To investigate differences in agonist affinity, potency, and efficacy across rat brain regions, five representative cannabinoid compounds were investigated in membranes from three different rat brain regions for their ability to maximally stimulate [(35)S]guanosine-5'-O-(3-thio)triphosphate (GTPgammaS) binding and bind to cannabinoid receptors (measured by inhibition of [(3)H]antagonist binding) under identical assay conditions. In all three brain regions, the rank order of potency for the stimulation of [(35)S]GTPgammaS binding and the inhibition of [(3)H]SR141716A binding for these compounds were identical, with CP55940 approximately levonantradol > WIN55212-2 >/= Delta(9)-tetrahydrocannabinol (Delta(9)-THC) > methanandamide. The rank order of efficacy was not related to potency, and relative maximal agonist effects varied across regions. Receptor binding fit to a three-site model for most agonists, stimulation of [(35)S]GTPgammaS binding fit to a two-site model for all agonists, and high-affinity receptor binding did not appear to produce any stimulation of [(35)S]GTPgammaS binding. WIN55212-2, methanandamide, and Delta(9)-THC also were assayed for the inhibition of adenylyl cyclase in cerebellar membranes. The rank orders of potency and efficacy were similar to those for [(35)S]GTPgammaS binding, but the efficacies and potencies of methanandamide and Delta(9)-THC compared with WIN55212-2 were higher for adenylyl cyclase inhibition, implying receptor/G-protein reserve.

Activation of cannabinoid receptors in rat brain by WIN 55212-2 produces coupling to multiple G protein alpha-subunits with different potencies.

Previous studies had shown that the amplification factors for cannabinoid receptors, defined as the number of total G proteins activated per occupied receptor, differs between several rat brain regions. In this study, we sought to determine which specific Gi/Go(alpha) subunits were activated by CB1 receptors in several rat brain regions and if this coupling might explain the regional differences in receptor/G protein amplification factors. Furthermore, we examined whether cannabinoid agonists might activate different subtypes of G(alpha) subunits with varying degrees of efficacy and/or potency. Activation of specific G proteins by cannabinoid receptors was evaluated by the ability of the agonist WIN 55212-2 to stimulate incorporation of [alpha-(32)P]azidoanilido-GTP into G(alpha) subunits in membranes. Photolabeled G proteins were either directly resolved using urea/SDS-polyacrylamide gel electrophoresis or first immunoprecipitated with specific antisera for different G(alpha) subunits before electrophoresis. Individual G(alpha) subunits were separated into distinct bands on a single gel and the amount of agonist-induced increase in radioactivity was quantified by densitometry. Stimulation of CB1 receptors by WIN 55212-2 resulted in the activation of a distinct pattern of at least five different G(ialpha)/G(oalpha) subunits in several brain regions. Furthermore, although the pattern of G proteins activated by WIN 55212-2 appeared to be similar across brain regions, slight differences were observed in both the percentage of increase and the amount of the individual G(alpha) subunits activated. Most importantly, the amount of WIN 55212-2 required to half-maximally activate individual G proteins in the cerebellum varied over a 30-fold range for different G(alpha) subunits. These results suggest that cannabinoid receptors activate multiple G proteins simultaneously in several brain regions and both the efficacy and potency of cannabinoid agonists to activate individual G(alpha) subunits may vary considerably.

Chronic delta9-tetrahydrocannabinol treatment produces a time-dependent loss of cannabinoid receptors and cannabinoid receptor-activated G proteins in rat brain.

Chronic treatment of rats with delta9-tetrahydrocannabinol (delta9-THC) results in tolerance to its acute behavioral effects. In a previous study, 21-day delta9-THC treatment in rats decreased cannabinoid activation of G proteins in brain, as measured by in vitro autoradiography of guanosine-5'-O-(3-[35S]thiotriphosphate) ([35S]GTPgammaS) binding. The present study investigated the time course of changes in cannabinoid-stimulated [35S]GTPgammaS binding and cannabinoid receptor binding in both brain sections and membranes, following daily delta9-THC treatments for 3, 7, 14, and 21 days. Autoradiographic results showed time-dependent decreases in WIN 55212-2-stimulated [35S]GTPgammaS and [3H]WIN 55212-2 binding in cerebellum, hippocampus, caudate-putamen, and globus pallidus, with regional differences in the rate and magnitude of down-regulation and desensitization. Membrane binding assays in these regions showed qualitatively similar decreases in WIN 55212-2-stimulated [35S]GTPgammaS binding and cannabinoid receptor binding (using [3H]SR141716A), and demonstrated that decreases in ligand binding were due to decreases in maximal binding values, and not ligand affinities. These results demonstrated that chronic exposure to delta9-THC produced time-dependent and region-specific down-regulation and desensitization of brain cannabinoid receptors, which may represent underlying biochemical mechanisms of tolerance to cannabinoids.

Cannabinoid receptor agonist efficacy for stimulating [35S]GTPgammaS binding to rat cerebellar membranes correlates with agonist-induced decreases in GDP affinity.

The relationship between GDP and cannabinoid-stimulated [35S]guanosine-5'-O-(3-thiotriphosphate) ([35S]GTPgammaS) binding was investigated in rat cerebellar membranes. Kinetic analyses showed that [35S]GTPgammaS binding reached steady-state levels and that the association rate was increased by the agonist WIN 55212-2 proportional to the concentration of GDP. Dissociation of [35S]GTPgammaS occurred with two rates (t1/2 = 7 and 170 min), and WIN 55212-2 increased the proportion of sites exhibiting the faster rate. Without GDP, [35S]GTPgammaS bound to membranes with high and low affinity, and WIN 55212-2 had no effect. With 30 microM GDP, [35S]GTPgammaS bound to low and intermediate affinity sites, and WIN 55212-2 induced high affinity [35S]GTPgammaS binding without affecting low affinity sites. GDP competed for high affinity [35S]GTPgammaS binding with high and intermediate affinity in the absence of WIN 55212-2 and with high and low affinity in the presence of WIN 55212-2. Cannabinoid ligands displayed differential abilities to maximally stimulate [35S]GTPgammaS binding in the presence of GDP. Efficacy differences among ligands increased with increasing GDP concentrations. GDP competition curves revealed that agonists induced low affinity GDP Ki values that were proportional to agonist Emax values, indicating that agonist efficacy is determined by displacement of GDP from G-proteins.

Opioid inhibition of adenylyl cyclase in membranes from pertussis toxin-treated NG108-15 cells.

Gi/Go proteins are uncoupled from receptors by ADP-ribosylation with pertussis toxin (PTX). However, PTX treatment of delta opioid receptor-containing NG108-15 cells reduces, but does not eliminate, opioid inhibition of adenylyl cyclase. The present study explored potential mechanisms of this residual inhibition. Overnight treatment of NG108-15 cells with 100 ng/ml PTX eliminated both PTX-catalyzed [adenylyl-32P]NAD+-labeling of G proteins and agonist stimulation of low Km GTPase in membranes. Although PTX-treatment decreased the maximal opioid inhibition of adenylyl cyclase by 50-65%, the inhibition that remained was concentration-dependent and antagonist-reversible. This inhibition persisted in the absence of GTP (even though opioid inhibition of adenylyl cyclase in untreated membranes was GTP-dependent), but was eliminated by hydrolysis-resistant guanine nucleotide analogs, indicating that G-proteins were still involved in the coupling mechanism. However, assays of agonist-stimulated [35S]GTPgammaS binding in the presence of excess GDP indicated that PTX pretreatment eliminated stimulation of guanine nucleotide exchange by opioid agonists. These results suggest that in membranes from PTX-treated NG108-15 cells, a subpopulation of G proteins may transduce an inhibitory signal from agonist-bound opioid receptors without involvement of guanine nucleotide exchange.

The functional neuroanatomy of brain cannabinoid receptors.

The effects of the primary psychoactive constituent of marijuana, delta 9-tetrahydrocannabinol, are mediated by cannabinoid receptors, CB1 and CB2. The CB1 receptors display a unique central nervous system (CNS) distribution and are present in mammalian brain at higher levels than most other known G-protein-coupled receptors. The highest levels occur in several areas involved in motor control and hippocampus. Cannabinoid effects on CNS activities, including movement, memory, nociception, endocrine regulation, thermoregulation, sensory perception, cognitive functions, and mood, correlate with the regional distribution of cannabinoid receptors and their activation of specific G-protein-mediated signal transduction systems in various brain regions.

Regional differences in cannabinoid receptor/G-protein coupling in rat brain.

Cannabinoid receptor activation of G-proteins can be measured by WIN 55212-2-stimulated [35S]GTPgammaS binding. Receptor/transducer amplification factors, interpreted as the number of G-proteins activated per occupied receptor, are the ratio of the apparent B(max) of net agonist-stimulated [35S]GTPgammaS binding to the B(max) of receptor binding. The present study examined whether amplification factors for cannabinoid receptors differ among various rat brain regions. In autoradiographic studies with [3H]WIN 55212-2 and WIN 55212-2-stimulated [35S]GTPgammaS binding, some regions displayed different relative levels of agonist-stimulated [35S]GTPgammaS binding than receptor binding. To quantify amplification factors, membranes from different brain regions were assayed by saturation binding analysis of net WIN 55212-2-stimulated [35S]GTPgammaS, [3H]SR141716A (antagonist) and [3H]WIN 55212-2 (agonist) binding. For [3H]SR141716A binding, amplification factors varied significantly from 2.0 (frontal cortex) to 7.5 (hypothalamus). For [3H]WIN 55212-2 binding, amplification factors ranged from 2.4 (hippocampus) to 5.5 (thalamus). Comparison of receptor binding and G-protein activation at subsaturating concentrations of WIN 55212-2 indicated that amplification factors may vary with receptor occupancy in some regions like cerebellum. Ratios between high-affinity [3H]WIN 55212-2 B(max) and [3H]SR141716A B(max) also differed significantly among brain regions. These results demonstrate that G-protein coupling by cannabinoid receptors differs among brain regions, and therefore depends on the cellular environment.

Acute and chronic effects of opioids on delta and mu receptor activation of G proteins in NG108-15 and SK-N-SH cell membranes.

To compare activation of G proteins by opioid receptors, opioid agonist-stimulated guanosine 5'-O-(3-[35S]thiotriphosphate) ([35S]GTP gamma S) binding in the presence of excess GDP was assayed in membranes from NG108-15 (delta) and SK-N-SH (primarily mu) cells. Basal [35S]GTP gamma S binding consisted of a single class of low-affinity sites (KD 400-500 nM). Addition of agonists produced a high-affinity site 100-300-fold higher in affinity than the basal site. The receptor/transducer amplification factor (ratio of activated G protein Bmax to opioid receptor Bmax) was 10-fold higher for SK-N-SH mu receptors than for NG108-15 delta receptors. Chronic delta agonist ([D-Ser2]-Leu-enkephalin-Thr; DSLET) treatment of NG108-15 cells resulted in an 80% loss of DSLET-stimulated [35S]-GTP gamma S binding within 1 h. Morphine treatment of SK-N-SH cells decreased mu agonist ([D-Ala2, N-Me-Phe4,Gly5-ol]-enkephalin; DAMGO)-stimulated [35S]GTP gamma S binding by 45% after 16 h, with no effect after 1 h. Loss of agonist response was due to a decrease in the Bmax of activated G proteins with no change in the KD. These results provide a quantitative description of G protein activation occurring on acute and chronic exposure to opioid agonists.

Time-dependent effects of in vivo pertussis toxin on morphine analgesia and G-proteins in mice.

Previous studies have indicated a long-duration of effect of in vivo pertussis toxin (PTX) on morphine analgesia in the mouse. However, the time-course of potency changes in morphine analgesia as determined in dose-response studies and biochemical correlates of PTX treatment have not been reported to date. Therefore, in the present studies the effects of in vivo PTX on morphine analgesia ED50 and PTX-catalyzed incorporation of [32P]-ADP-ribose and synapsin content in mouse spinal cord were examined. Mice were injected IT & ICV with saline or PTX (total dose = 0.2 microg) and tested for systemic morphine analgesia (tail-flick) 1, 10, 16 & 40 days later. There was no significant decrease in morphine potency 1 day following PTX treatment, whereas PTX produced a significant decrease in morphine potency at 10, 16 & 40 days. Concurrent decreases in the incorporation of [32P]-ADP-ribose in spinal cord by PTX were observed on days 10, 16 & 40. No changes were observed in synapsin content which suggests that the effect was not nonspecific. This study indicates that in vivo PTX produces co-ordinate long-lasting effects in both functional (analgesia) and biochemical (Gi/o-proteins) assays.

Opioid receptor-coupled G-proteins in rat locus coeruleus membranes: decrease in activity after chronic morphine treatment.

The nucleus locus coeruleus is involved in the expression of opiate physical dependence and withdrawal, and has been characterized extensively with regard to chronic morphine-induced alterations in biochemical and electrophysiological responses. In the present study the effects of chronic morphine treatment on opioid receptor-coupled G-protein activity was investigated in membranes from rat locus coeruleus. Opioid agonists stimulated low Km GTPase activity with pharmacology consistent with mu receptors. Chronic morphine treatment resulted in decreases in both basal and opioid-stimulated low Km GTPase activity, with no change in the percent stimulation by agonist. The decrease in low Km GTPase activity appeared to be due to a decrease in the Vmax of the enzyme, with no change in the Km for GTP hydrolysis. These results were confirmed by assays of basal and opioid receptor-stimulated [35S]GTP gamma S binding in the presence of excess GDP. Thus, chronic morphine treatment apparently decreased inhibitory G-protein activity in the locus coeruleus without producing any detectable desensitization. These results suggest a potential adaptation at the receptor/transducer level which may contribute to other biochemical changes produced in the locus coeruleus by chronic morphine treatment.

Modification of G protein-coupled functions by low-pH pretreatment of membranes from NG108-15 cells: increase in opioid agonist efficacy by decreased inactivation of G proteins.

Low-pH pretreatment increases opioid agonist efficacy in inhibiting adenylyl cyclase in brain membranes. The mechanism of this effect was examined in membranes from cultured NG108-15 cells. Pretreatment of NG108-15 membranes at pH 4.5 before assay at pH 7.4 produced the following modifications in G protein-mediated signal transduction: 1) decreased activation of adenylyl cyclase by Gs, 2) increased maximal inhibition of opioid agonist binding by sodium and by guanine nucleotides in the presence of sodium, and 3) increased maximal inhibition of adenylyl cyclase by agonists for G(i)-coupled receptors. These results are similar to those previously observed in rat brain membranes. The mechanism by which low-pH pretreatment increased receptor-mediated inhibition of adenylyl cyclase was investigated further by examining low-Km GTPase activity in low-pH-pretreated NG108-15 cell membranes. Low-pH pretreatment decreased basal and agonist-stimulated low-Km GTPase activity maximally in the absence of sodium and minimally in the presence of 120 mM NaCl. This change was due to a decrease in the Vmax of the enzyme, with no change in the Km for GTP, indicating that GTP hydrolysis was decreased without any decrease in the affinity of the G protein for GTP. Scatchard analysis revealed no decrease in the Bmax for high affinity opioid agonist binding, and Western blot analysis with a G(i)-specific antibody revealed no loss of G(i) protein, in low-pH-pretreated membranes. Moreover, concentration-effect curves for GTP in supporting opioid inhibition of adenylyl cyclase showed that low-pH pretreatment increased inhibition by the agonist only at GTP concentrations equal to or greater than the Km for GTP hydrolysis by the low-Km GTPase. Taken together, these results indicate that the efficacy of receptor-mediated inhibition of adenylyl cyclase can be increased by decreasing the maximal inactivation rate of G(i) subsequent to its activation by the receptor.