Peter J. McLaughlin

The Novel Cannabinoid CB1 Receptor Neutral Antagonist AM4113 Suppresses Food Intake and Food-Reinforced Behavior but Does not Induce Signs of Nausea in Rats

Drugs that interfere with cannabinoid CB1 transmission suppress various food-motivated behaviors, and it has been suggested that such drugs could be useful as appetite suppressants. Biochemical studies indicate that most of these drugs assessed thus far have been CB1 inverse agonists, and although they have been shown to suppress food intake, they also appear to induce nausea and malaise. The present studies were undertaken to characterize the behavioral effects of AM4113, which is a CB1 neutral antagonist, and to examine whether this drug can reduce food-reinforced behaviors and feeding on diets with varying macronutrient compositions. Biochemical data demonstrated that AM4113 binds to CB1 receptors, but does not show inverse agonist properties (ie no effects on cyclic-AMP production). In tests of spontaneous locomotion and analgesia, AM4113 reversed the effects of the CB1 agonist AM411. AM4113 suppressed food-reinforced operant responding with rats responding on fixed ratio (FR) 1 and 5 schedules of reinforcement in a dose-dependent manner, and also suppressed feeding on high-fat, high-carbohydrate, and lab chow diets. However, in the same dose range that suppressed feeding, AM4113 did not induce conditioned gaping, which is a sign of nausea and food-related malaise in rats. These results suggest that AM4113 may decrease appetite by blocking endogenous cannabinoid tone, and that this drug may be less associated with nausea than CB1 inverse agonists.

Cannabinoid CB1 receptor inverse agonists and neutral antagonists: Effects on food intake, food-reinforced behavior and food aversions

Drugs that interfere with cannabinoid CB1 receptor transmission suppress a number of food-related behaviors, and these compounds are currently being assessed for their potential utility as appetite suppressants. In addition to rimonabant (SR141716A), several other compounds have been evaluated, including AM251 and AM1387. Biochemical studies indicate that most of the drugs assessed thus far have been CB1 inverse agonists, and these drugs all act to suppress food intake and disrupt food-reinforced behavior. Behavioral tests involving intake of different diets (i.e., high fat, high carbohydrate, laboratory chow) indicate that consumption of all three food types is disrupted by CB1 inverse agonists, and that, expressed as a percent of baseline intake, the effect is roughly comparable across different diets. Although CB1 inverse agonists do not appear to produce severe motor impairments that disrupt feeding behavior, there is evidence that they can induce nausea and malaise. Recent studies have been undertaken to characterize the behavioral effects of CB1 receptor neutral antagonists such as AM4113 to determine if these drugs can reduce feeding and food-reinforced behaviors. Across a variety of different tests, AM4113 produces effects on food-motivated behavior that are very similar to those produced by CB1 inverse agonists. Moreover, this drug did not induce conditioned gaping in rats or vomiting in ferrets. These results suggest that CB1 receptor neutral antagonists may decrease appetite by blocking endogenous cannabinoid tone, and that these drugs may be less associated with nausea than is the case for CB1 inverse agonists.

The muscarinic receptor antagonist tropicamide suppresses tremulous jaw movements in a rodent model of parkinsonian tremor: possible role of M4 receptors

RationaleNonselective muscarinic acetylcholine antagonists have been used for several years as antiparkinsonian drugs. However, there are at least five subtypes of muscarinic receptor (M1–5). Neostriatal M4 receptors have been implicated in aspects of motor function, and it has been suggested that M4 antagonists could be used as treatments for parkinsonism.ObjectiveCurrently, there is a lack of highly selective M4 antagonists that readily penetrate the blood brain barrier. Thus, the present studies focused upon the effects of tropicamide, a muscarinic acetylcholine receptor antagonist with moderate binding selectivity for the M4 receptor subtype.Materials and methodsTremulous jaw movements were used as a model of parkinsonian tremor in these studies, and the effects of tropicamide were compared with those of the nonselective muscarinic antagonist atropine.ResultsTropicamide suppressed the tremulous jaw movements induced by the muscarinic agonist pilocarpine and the dopamine antagonist pimozide. Analysis of the dose–response curves indicated that tropicamide showed approximately the same potency as atropine for suppression of pilocarpine-induced jaw movements but was more potent than atropine on the suppression of pimozide-induced jaw movements. In contrast, atropine was more potent than tropicamide in terms of impairing performance on visual stimulus detection and delayed nonmatch-to-position tasks.ConclusionsThese studies demonstrate that tropicamide, which currently is used clinically for ophthalmic purposes, can exert actions that are consistent with antiparkinsonian effects. Moreover, the different pattern of effects shown by tropicamide compared to those of atropine on motor vs cognitive tasks could be due to the modest M4 selectivity shown by tropicamide.

Suppression of food intake and food-reinforced behavior produced by the novel CB1 receptor antagonist/inverse agonist AM 1387

Cannabinoid CB1 receptor antagonist/inverse agonists are becoming increasingly recognized for their potential therapeutic utility as appetite suppressants. In the current paper we characterize the biochemical and behavioral effects of AM 1387, which is a novel CB1 antagonist. AM 1387 exhibited binding affinity and selectivity for the CB1 over the CB2 receptor. Moreover, AM 1387 decreased GTPgammaS (EC50: 22.82 nM) and increased forskolin-stimulated cAMP (EC50: 274.6 nM), as did the CB1 inverse agonist AM 251 (GTPgammaS EC50: 25.82 nM; cAMP EC50: 363.8 nM), indicating that AM1387 also has inverse agonist properties in vitro. In the behavioral characterization in rats, AM 1387 suppressed lever pressing for food on two operant schedules (fixed-ratio 1 and 5). Timecourse of the effect on fixed-ratio 5 responding was then determined, and the half-life (t1/2=4.87 h) was found to be threefold shorter than what has been shown for SR 141716A, and fourfold shorter than AM 251. Finally, AM 1387 was found to suppress food intake using three diets of differing macronutrient composition and palatability. It was concluded that AM 1387 may be a useful tool for examining the effects of CB1 receptor antagonism or inverse agonism on food intake.

Behavioral effects of the novel cannabinoid full agonist AM 411

AM 411 ((-)-1-adamantyl-Delta8-tetrahydrocannabinol) is a novel full agonist at cannabinoid CB1 receptors. The present studies were conducted to provide behavioral characterization of this compound in rats. It was hypothesized that AM 411 should produce behavioral effects similar to known cannabinoid agonists, and that these effects should be inhibited by co-treatment with a CB1 antagonist. In Experiments 1 and 2, AM 411 dose-dependently produced behaviors consistent with CB1 agonism, including analgesia, hypothermia, catalepsy and reductions in locomotion, which were blocked by a CB1-selective antagonist. In Experiment 3, AM 411 produced a dose-dependent suppression of lever-pressing on a fixed-ratio 5 (FR5) schedule, a task known to be sensitive to administration of CB1 agonists. Detailed analysis of the temporal patterns of operant responding showed that AM 411 altered the distribution of interresponse times. Experiment 4 showed that AM 411 decreased relative interior activity in the open field, which is suggestive of an anxiogenic effect. It is concluded that AM 411 produces CB1 agonist-like behavior with potency between that of WIN 55,212-2 and AM 356. AM 411 could be a useful tool for understanding the behavioral and neural effects of CB1 receptor stimulation.

Systemic administration of the adenosine A2A agonist CGS 21680 induces sedation at doses that suppress lever pressing and food intake

Adenosine A(2A) receptors are involved in the regulation of several behavioral functions. Adenosine A(2A) antagonists exert antiparkinsonian effects in animal models, and adenosine A(2A) agonists suppress locomotion and impair various aspects of motor control. The present experiments were conducted to study the effects of low doses of the adenosine A(2A) agonist CGS 21680 on lever pressing, specific parameters of food intake, and sedation. In the first experiment, the effects of CGS 21680 on fixed ratio 5 lever pressing were assessed. In the second experiment, rats were tested in 30 min feeding sessions, and also were observed for drug-induced sedation using a sedation rating scale. CGS 21680 (0.025, 0.05, 0.1 mg/kg IP) produced a dose related suppression of lever pressing, and also reduced the amount of food consumed. The feeding effect was largely dependent upon a slowing of the rate of feeding, and there was only a modest suppression of time spent feeding. Doses of CGS 21680 that suppressed lever pressing and feeding also were associated with sedation/drowsiness. In conjunction with other studies, the present results suggest that sedative effects may play an important role in some of the behavioral effects produced by systemic administration of adenosine A(2A) agonists.

Central vs. peripheral administration of ethanol, acetaldehyde and acetate in rats: effects on lever pressing and response initiation.

The metabolites of ethanol, acetaldehyde and acetate, are biologically active, and different effects may be produced depending upon the particular metabolite and the route of administration. These studies characterized the effects of intraperitoneal (IP) vs. intraventricular (ICV) administration of ethanol, acetaldehyde, and acetate administered to male Sprague-Dawley rats. Operant behavior was assessed by conducting a detailed temporal analysis of lever pressing with rats responding on a fixed ratio 5 schedule of food reinforcement. IP administration of all three drugs produced a rate-decreasing effect on the total number of responses. Acetaldehyde and acetate were much more potent than ethanol at reducing lever pressing. The interresponse time (IRT) distribution also was more potently altered by IP administration of ethanol metabolites than by ethanol itself. The total lever pressing and IRT distributions of ethanol- and acetaldehyde- treated rats were not significantly affected when these drugs were administered ICV, while acetate produced a marked suppression of fast responses and an increase in pausing. The metabolites of ethanol are more potent than ethanol itself in terms of altering patterns of lever pressing. Thus, the effects of ethanol administration could in part be due to the actions of its biologically active metabolites.

Behavioral effects of the novel potent cannabinoid CB1 agonist AM 4054

Due to the ubiquity of the CB1 cannabinoid receptor throughout the nervous system, as well as the many potential therapeutic uses of CB1 agonist-based interventions, it is desirable to synthesize novel probes of the CB1 receptor. Here, the acute behavioral effects of systemic (i.p.) administration of the putative novel CB1 full agonist AM 4054 were tested in rats. In Experiment 1, a dose range (0.15625-1.25 mg/kg) of AM 4054 produced effects consistent with CB1 agonism in the cannabinoid tetrad of tasks in rats, including induction of analgesia, catalepsy, hypothermia, and locomotor suppression. These effects were reversed with the CB1-selective inverse agonist AM 251 in Experiment 2, indicating that AM 4054 produced CB1 receptor-mediated effects. Analysis of open-field activity indicated that the reduction in locomotion is more consistent with general motor slowing than anxiogenesis. AM 4054 (0.0625-0.5 mg/kg) also dose-dependently reduced fixed-ratio 5 (FR5) operant responding for food in Experiment 3, and microanalysis of the timing and rate of lever pressing indicated a pattern of suppression similar to other CB1 agonists. Minimum doses of AM 4054 (0.125-0.3125 mg/kg) required to produce significant effects in these behavioral assays were lower than those of many CB1 agonists. It is likely that AM 4054 is a potent pharmacological tool for assessment of cannabinoid receptor function.

The novel cannabinoid agonist AM 411 produces a biphasic effect on accuracy in a visual target detection task in rats.

Cannabinoid agonists have been shown to produce dose-related impairments in several measures of cognitive performance. However, it is unclear if low doses of cannabinoid CB1 agonists, or CB1 antagonists, can facilitate aspects of stimulus detection. The present study employed an operant procedure involving visual stimulus detection in rats. The task was found to be sensitive to the muscarinic acetylcholine antagonist scopolamine. The CB1 antagonist AM 251 did not affect stimulus detection processes across a broad range of doses. However, the novel CB1 agonist AM 411 produced a biphasic effect, with the two lowest doses (0.25 and 0.5 mg/kg) enhancing accuracy. AM 411 changed patterns of responding toward runs of consecutive errors on only one of the two levers. It produced a biphasic effect on consecutive errors on the lever associated with a higher level of errors, with decreases in errors following the lower doses (0.25 and 0.5 mg/kg) and increases following the highest dose (2.0 mg/kg). These effects were not accompanied by changes in measures of bias commonly used to uncover such patterns in rodent operant models of cognitive performance. In contrast to the cognitive impairment seen after administration of moderate to high doses of CB1 agonists, it appears that low doses of some CB1 agonists may be capable of enhancing stimulus detection processes.

Detailed analysis of food-reinforced operant lever pressing distinguishes effects of a cannabinoid CB1 inverse agonist and dopamine D1 and D2 antagonists

Overt similarities exist between the effects of systemic cannabinoid CB1 inverse agonists and dopamine (DA) antagonists on appetitive behavior. The present set of studies was undertaken to apply a fine-grained analysis of food-reinforced operant lever pressing in rats in order to compare the pattern of effects produced by administration of the CB1 inverse agonist AM 251 and those induced by the DA D1 antagonist SKF 83566, and the D2 antagonist raclopride. Three groups of rats were trained on a fixed-ratio 5 (FR5) schedule and administered these compounds over a range of doses expected to suppress responding. All three drugs produced a dose-related suppression of total lever pressing. In addition to main effects of dose, regression analyses were performed to determine which of several response timing- and rate-related variables correlated most strongly with overall responding in each group. It was found that total session time spent pausing from responding was significantly better at predicting responding in the AM 251 group, while both DA antagonists produced significantly stronger regression coefficients (versus AM 251) from fast responding measures. These results suggest that, while several similarities exist, CB1, D1, and D2 antagonists are not identical in their pattern of suppression of food-maintained lever pressing.