∆⁹-Tetrahydrocannabinol, a major marijuana component, enhances the anesthetic effect of pentobarbital through the CB₁ receptor

While the current number of people arrested for marijuana (Cannabis sativa L)-related crimes under the Cannabis Control Law in Japan has decreased relatively over the past 10 years, there has been a gradually increase since 2014 [1]. A high proportion of people are arrested in their 20s, accounting for 42.4% of cannabis crimes, and a high ratio of first-time offenders is still observed. Despite prevention education of drug abuse being widespread, drug abuse-related crimes among young generations in Japan continue to exist. Moreover, cannabis continues to be the most widely cultivated, produced, trafficked and consumed drug worldwide, specifically in places such as North America, South America, Caribbean, and Africa, etc. Global number of users are estimated at 182.5 million [2]. Therefore, continuing scientific study of the interaction between drug toxicity and risk leads to the prevention of drug abuse.

Marijuana is positioned as a global gateway drug and its potential use with other abused drugs is a serious problem [3]. Furthermore, most cannabis components have oil-soluble properties [4], which upon entering the body, can become widely distributed due to these properties. In many cases, cannabis smokers continue to take other abused drugs, which may cause excess pharmacological interactions. Thus, it is important to understand the mechanism of drug-to-drug interactions when contributing to the prevention of drug abuse.

Marijuana contains a number of cannabinoids and the primary psychoactive component is ∆⁹-tetrahydrocannabinol (∆⁹-THC; Fig. 1). ∆⁹-THC is known to exhibit numerous pharmacological effects, such as catalepsy, hypothermia, analgesic effects, immobility, motor incoordination, and certain central nervous system (CNS) effects [5‐7]. As shown in Fig. 1, the other major constituents of marijuana are cannabidiol (CBD) and cannabinol. CBD also shows certain pharmacological effects, such as anticonvulsant effects and synergism with CNS drugs, including barbiturates [8‐10]. In terms of relative potencies of maximal electroshock test, CBD and ∆⁹-THC are similar, but both of them are more active than cannabinol [8]. CBD and ∆⁹-THC also prolonged pentobarbital-induced anesthesia [10].

Cannabinoid receptors are found in both the mammalian brain and peripheral organs, and are subdivided into central (CB₁) and peripheral (CB₂) receptors. Furthermore, the nucleotide sequences of both human receptors have been elucidated [11, 12]. The pharmacological effects of ∆⁹-THC on the CNS, such as hypoactivity, hypothermia, and antinociception, were reversed by the co-administration of the CB₁ receptor antagonists SR141716A [N-(piperidin-1-yl)-5-(4-chlorophenyl)-1-(2,4-dichlorophenyl)-4-methyl-1H-pyrazole-3-carboxamide] and AM251 [N-(piperidin-1-yl)-5-(4-iodophenyl)-1-(2,4-dichlorophenyl)-4-methyl-1H-pyrazole-3-carboxamide] [13‐15], indicating that these CNS effects were mediated by the CB₁ receptor. Further evidence of CNS effects of cannabinoids on the CB₁ receptor includes pharmacological effects and binding affinity of the brain CB₁ receptor [16, 17]. We revealed that certain cannabinoids, their metabolites, and synthetic cannabinoids caused a pentobarbital-induced sleep-prolonging effect, in addition to catalepsy, hypothermia, and reduced spontaneous activity in mice [18‐26]. Conversely, CBD is also known to prolong pentobarbital-induced sleep, but the potentiation mechanism was thought to differ to ∆⁹-THC. Namely, the CB₁ receptor affinity of CBD is quite low and pentobarbital-induced sleep-prolonging effects with CBD were due to inhibition of hepatic cytochrome P450 activity [27‐30]. Our previous data show that the pharmacological profile of each cannabinoid, including active metabolites such as 11-hydroxy-∆⁹-THC and 11-oxo-∆⁹-THC, based on the effects of hypothermia, catalepsy, and pentobarbital-induced sleep, differ widely in their site of action in the CNS [18‐26]. However, the action mechanism of cannabinoids concerning synergism with certain anesthetics has not yet been clearly elucidated. In the present study, we reveal the involvement of the CB₁ receptor for potentiating pentobarbital-induced sleep by ∆⁹-THC in mice using specific CB₁ receptor antagonists.

The effects of cannabinoid receptor antagonists on the synergistic effects of pentobarbital with ∆⁹-THC are shown in Fig. 2. ∆⁹-THC [vehicle (Veh) + ∆⁹-THC 10 mg/kg, i.v.] significantly prolonged pentobarbital-induced sleep by 3.3-folds compared with the vehicle-pretreated group (Veh + Veh). The result supports our previous finding that ∆⁹-THC prolonged pentobarbital-induced sleeping time in mice by various routes of administrations [22]. At this time, once an abused drug, such as pentobarbital, has entered the body, a drug interaction between ∆⁹-THC and pentobarbital may occur. Moreover, this should be treated as a serious problem, rather than simply a case of single administration of cannabis or barbiturates alone.

The cannabinoid receptor is subdivided into CB₁ and CB₂ receptors, with each specific ligand (agonist and antagonist) previously determined [37]. In the present study, SR141716A and AM251 were used as CB₁ receptor antagonists to investigate pharmacological effects and perform the receptor binding affinity experiment. Compton et al. [14] reported antagonistic response of SR141716A for pharmacological and behavioral experiments such as measurements of spontaneous locomotor activity, tail-flick responsiveness, or rectal temperature at the range of 1–10 mg/kg, i.v. to mice. We also used an equivalent dose of SR141716A for the effect of ∆⁹-THC-induced pentobarbital potentiation. When SR141716A or AM251 (2–10 mg/kg) was pre-administered by i.v. injection 10 min before ∆⁹-THC treatment, the potentiation of pentobarbital-induced sleep by ∆⁹-THC decreased dose-dependently. In particular, a low dose of the CB₁ receptor antagonists (2 mg/kg, i.v.) significantly suppressed the prolonging effect of ∆⁹-THC. Cannabinoid receptor antagonists themselves (AM251 + Veh or SR141716A + Veh) then caused no change in pentobarbital-induced sleeping time. The attenuated synergistic effect of ∆⁹-THC on pentobarbital-induced sleep was thought to be due to blockade of CB₁ receptor binding by specific CB₁ receptor antagonists.

Since a low dose of CB₁ receptor antagonists attenuated the synergistic effects of pentobarbital with Δ⁹-THC and CB₁ receptor affinity of SR141716A is much higher than the affinity of AM251, doses of 2 or 5 mg/kg, i.v. of SR141716A were used for the synergistic experiment of CBD and pentobarbital. CBD (Veh + CBD 10 mg/kg, i.v.) also significantly prolonged pentobarbital-induced sleep 1.8-fold compared with the control (Veh + Veh), while pretreatment with SR141716A (2 or 5 mg/kg, i.v.) failed to inhibit CBD-enhanced pentobarbital-induced sleep (Fig. 3). CBD is well known as a major constituent of marijuana, causing pharmacological effects, such as barbiturate synergism [8‐10, 24]. Watanabe et al. [30] previously reported the potentiation mechanism of CBD on pentobarbital-induced sleep, which is caused by inhibition of the hepatic drug-metabolizing enzymes by CBD. CBD inhibits the metabolism of pentobarbital, leading to increased levels of the drug in the body and enhances its action. Namely, the synergistic effect of CBD with pentobarbital is different from ∆⁹-THC, which reflects how the CB₁ receptor influences CNS pharmacological effects. Therefore, this failure of SR141716A to produce antagonistic effects on CBD-induced pentobarbital potentiation suggests that CBD does not bind to the CB₁ receptor in CNS at the supplied dosage of 10 mg/kg i.p. of CBD in mice.

As shown in Fig. 4, the affinities of antagonists for CB₁ receptor binding were evaluated using a radio receptor assay measuring specific [³H]CP55940 binding to the mouse brain synaptic membrane. All compounds concentration-dependently inhibited the specific [³H]CP55940 binding. ∆⁹-THC and CB₁ receptor antagonists, except for CBD, possessed the same potency for the CB₁ receptor binding. The Ki values of cannabinoid ligands are summarized in Table 1. The Ki values of ∆⁹-THC and CBD were 6.62 and 2010 nM, respectively, showing the high affinity of ∆⁹-THC and the low affinity of CBD for the CB₁ receptor. The Ki values of CB₁ receptor antagonists, SR141716A and AM251, were 9.54 and 2.58 nM, respectively, indicating the high affinities of these antagonists to the CB₁ receptor binding site, as well as ∆⁹-THC. Yamamoto et al. [38] also reported that active metabolites of ∆⁹-THC bound to the cannabinoid CB₁ receptor in the brain. The results confirm that the potentiation mechanism of pentobarbital-induced sleep by CBD is not mediated through the CB₁ receptor, but rather by other mechanisms, such as inhibition of barbiturate metabolism (Table 2).

The involvement of pentobarbital in CB₁ receptor function was also examined. We added 1 mM pentobarbital to the CB₁ receptor binding assay mixture. However, pentobarbital did not affect specific [³H]CP55940 binding to the mice brain synaptic membrane (Table 2). In other words, pentobarbital did not directly affect the CB₁ receptor binding site. The cannabinoid CB₁ receptor antagonists, SR141716A and AM251, are effective in antagonizing in vivo effects of ∆⁹-THC, such as hypothermia and antinociception, as well as decreasing locomotor activity [14, 37]. To date, several lines of evidence indicate that cannabinoids potentiate barbiturate potency as a pharmacological property of marijuana [5, 7]. We also revealed that marijuana constituents, their active metabolites, and synthetic analogues prolonged pentobarbital-induced sleep in mice [18, 23, 24]. In the structure–activity relationship of cannabinoids showing CNS pharmacological effects, the cannabinoid-induced barbiturate synergism was similar to other CNS indices, such as catalepsy and hypothermia [21], suggesting a close interaction between cannabinoid and barbiturate action sites.

Many reports explore the barbiturate active site, but a precise action mechanism of barbiturates is not fully elucidated. In general, barbiturates act on the GABA_A supramolecule receptor complex, which couples with the GABA and benzodiazepine binding sites, as well as the picrotoxinin and chloride ion channel [39]. We previously reported the effects of cannabinoids on the benzodiazepine receptor of the synaptic membrane in the bovine brain [40]. ∆⁹-THC and its metabolites competitively bound to the benzodiazepine receptor, indicating a slight co-modification of benzodiazepine receptor binding by these cannabinoids. Despite this, the receptor binding affinities of the cannabinoids to the benzodiazepine receptor were low. For the synergy of barbiturate with ∆⁹-THC, the direct interaction of pentobarbital with the CB₁ receptor was ruled out, since adding high concentrations of pentobarbital (1 mM) to the receptor binding mixture did not change the specific [³H]CP55940 binding to the membrane. In addition, treatment of CB₁ receptor antagonists without Δ⁹-THC resulted in no change in sleeping time compared with vehicle treatment, indicating pentobarbital did not compete with the CB₁ receptor binding site. Regarding the mechanism explaining the synergy between cannabinoids and barbiturate, the barbiturate action site differed from the CB₁ receptor, suggesting the CB₁ receptor signal may activate the barbiturate site downstream to the CB₁ receptor site. CB₁ receptors are known to be coupled through G protein-dependent and G protein-independent (Gi/o) receptors to certain ion channels [41]. The present results suggest that positive cross-talk is present between CB₁ receptor signaling and pentobarbital-induced chloride channels. However, concerning the action mechanism downstream of the CB₁ receptor binding site is still unknown. It may be related to a certain signal transduction between the cannabinoid receptor and barbiturate active sites, including the GABA_A receptor and G protein. Since the CB₁ receptor is known to couple Gi/o protein, measurement of adenylate cyclase activity of CB₁ receptor in the presence of pentobarbital may be evidence of this interaction. Moreover, barbiturates are known to affect to GABA_A receptor. Study of involvement of GABA_A receptor to CB₁ receptor is future work.

Our study suggested that the enhanced anesthetic effect of pentobarbital with ∆⁹-THC results in an interaction between the CB₁ receptor and barbiturate action site.

∆⁹-THC induced pentobarbital potentiation in mice and this potentiation was blocked by specific CB₁ receptor antagonists, SR141716A and AM251. The affinities of CB₁ receptor antagonists to the mouse brain synaptic membrane were similar to blockage effects on pentobarbital-induced sleep potentiation by ∆⁹-THC. Pentobarbital did not directly affect specific CB₁ receptor binding, suggesting that ∆⁹-THC and barbiturate did not share the same active site. Since CB₁ receptor antagonists blocked ∆⁹-THC potentiating pentobarbital-induced sleep, the interaction site of pentobarbital may be located downstream of the CB₁ receptor. The pharmacological results indicate the effect of ∆⁹-THC co-administered with pentobarbital was a synergistic, but not additive, action in mice. Further evidence suggests the CB₁ receptor plays an important role as a trigger in potentiating pentobarbital-induced sleep by ∆⁹-THC.