Two types of cannabinoid receptor have been discovered so far, CB(1) (2.1: CBD:1:CB1:), cloned in 1990, and CB(2) (2.1:CBD:2:CB2:), cloned in 1993. Distinction between these receptors is based on differences in their predicted amino acid sequence, signaling mechanisms, tissue distribution, and sensitivity to certain potent agonists and antagonists that show marked selectivity for one or the other receptor type. Cannabinoid receptors CB(1) and CB(2) exhibit 48% amino acid sequence identity. Both receptor types are coupled through G proteins to adenylyl cyclase and mitogen-activated protein kinase. CB(1) receptors are also coupled through G proteins to several types of calcium and potassium channels. These receptors exist primarily on central and peripheral neurons, one of their functions being to inhibit neurotransmitter release. Indeed, endogenous CB(1) agonists probably serve as retrograde synaptic messengers. CB(2) receptors are present mainly on immune cells. Such cells also express CB(1) receptors, albeit to a lesser extent, with both receptor types exerting a broad spectrum of immune effects that includes modulation of cytokine release. Of several endogenous agonists for cannabinoid receptors identified thus far, the most notable are arachidonoylethanolamide, 2-arachidonoylglycerol, and 2-arachidonylglyceryl ether. It is unclear whether these eicosanoid molecules are the only, or primary, endogenous agonists. Hence, we consider it premature to rename cannabinoid receptors after an endogenous agonist as is recommended by the International Union of Pharmacology Committee on Receptor Nomenclature and Drug Classification. Although pharmacological evidence for the existence of additional types of cannabinoid receptor is emerging, other kinds of supporting evidence are still lacking.

https://pharmrev.aspetjournals.org/content/pharmrev/54/2/161.full.pdf

International Union of Pharmacology. XXVII. Classification of Cannabinoid Receptors

(−)-Cannabidiol (CBD) is a non-psychotropic component of Cannabis with possible therapeutic use as an anti-inflammatory drug. Little is known on the possible molecular targets of this compound. We investigated whether CBD and some of its derivatives interact with vanilloid receptor type 1 (VR1), the receptor for capsaicin, or with proteins that inactivate the endogenous cannabinoid, anandamide (AEA).


CBD and its enantiomer, (+)-CBD, together with seven analogues, obtained by exchanging the C-7 methyl group of CBD with a hydroxy-methyl or a carboxyl function and/or the C-5′ pentyl group with a di-methyl-heptyl (DMH) group, were tested on: (a) VR1-mediated increase in cytosolic Ca2+ concentrations in cells over-expressing human VR1; (b) [14C]-AEA uptake by RBL-2H3 cells, which is facilitated by a selective membrane transporter; and (c) [14C]-AEA hydrolysis by rat brain membranes, which is catalysed by the fatty acid amide hydrolase.


Both CBD and (+)-CBD, but not the other analogues, stimulated VR1 with EC50=3.2 – 3.5 μM, and with a maximal effect similar in efficacy to that of capsaicin, i.e. 67 – 70% of the effect obtained with ionomycin (4 μM). CBD (10 μM) desensitized VR1 to the action of capsaicin. The effects of maximal doses of the two compounds were not additive.


(+)-5′-DMH-CBD and (+)-7-hydroxy-5′-DMH-CBD inhibited [14C]-AEA uptake (IC50=10.0 and 7.0 μM); the (−)-enantiomers were slightly less active (IC50=14.0 and 12.5 μM). CBD and (+)-CBD were also active (IC50=22.0 and 17.0 μM).


CBD (IC50=27.5 μM), (+)-CBD (IC50=63.5 μM) and (−)-7-hydroxy-CBD (IC50=34 μM), but not the other analogues (IC50>100 μM), weakly inhibited [14C]-AEA hydrolysis.


Only the (+)-isomers exhibited high affinity for CB1 and/or CB2 cannabinoid receptors.


These findings suggest that VR1 receptors, or increased levels of endogenous AEA, might mediate some of the pharmacological effects of CBD and its analogues. In view of the facile high yield synthesis, and the weak affinity for CB1 and CB2 receptors, (−)-5′-DMH-CBD represents a valuable candidate for further investigation as inhibitor of AEA uptake and a possible new therapeutic agent.





Keywords: Cannabinoid, endocannabinoid, vanilloid, receptors, FAAH, anandamide transporter


Introduction
Among the bioactive constituents of Cannabis sativa, (−)-cannabidiol (CBD, Figure 1) is one of those with the highest potential for therapeutic use (Mechoulam, 1999). Although the pharmacological properties of the other major Cannabis component, (−)-Δ9-tetrahydrocannabinol (THC), have been more thoroughly investigated (Mechoulam, 1999; Pertwee, 1999, for reviews), THC, unlike CBD, exhibits potent psychotropic effects, which have complicated the full assessment of its therapeutic potential. Little is known of the molecular mechanism(s) of action of CBD, which, unlike THC, has very little affinity for either cannabinoid receptor subtypes identified so far, the CB1 and CB2 receptors (Pertwee, 1997, for review). Recent studies, together with the earlier finding of the anti anxiety (Guimaraes et al., 1994), neuro-protective and anti-convulsive activity of CBD and some of its analogues (Consroe et al., 1981; Martin et al., 1987), indicate that CBD may also exert cyto-protective effects by inhibiting the release of inflammatory cytokines from blood cells (Srivastava et al., 1998; Malfait et al., 2000), thus producing an anti-inflammatory action, for example against rheumatoid arthritis (Malfait et al., 2000). These effects of CBD may be due to its anti-oxidant properties (Hampson et al., 1998), to its direct interaction with cytochrome p450-enzymes (Bornheim & Correia, 1989) and other enzymes of the ‘arachidonate cascade' (Burstein et al., 1985), or to an action at a specific receptor. Recent studies have investigated whether CBD interacts with proteins of the ‘endocannabinoid signalling system' other than the CB1/CB2 receptors. These proteins are: (i) fatty acid amide hydrolase (FAAH) (Cravatt et al., 1996), the intracellular enzyme catalysing the hydrolysis of the endogenous cannabinoid ligand, anandamide (arachidonoylethanolamide, AEA) (Ueda et al., 2000, for review); and (ii) the ‘anandamide membrane transporter' (AMT) (Di Marzo et al., 1994), which facilitates the transport of AEA across the cell membrane and, subsequently, its intracellular degradation (Hillard & Jarrahian, 2000, for review). It was found that CBD inhibits both AEA hydrolysis by FAAH-containing membrane preparations (Watanabe et al., 1996), and AEA uptake by RBL – 2H3 cells via the AMT (Rakhshan et al., 2000). Although these effects were observed at high μM concentrations, these findings raised the possibility that some of the pharmacological actions of CBD might be due to inhibition of AEA degradation, with subsequent enhancement of the endogenous levels of this mediator, for which neuroprotective (Hansen et al., 1998) and anti-inflammatory (Di Marzo et al., 2000a) properties have been previously suggested.



Figure 1

Chemical structures of cannabidiol and capsaicin. The numbering for cannabidiol carbon atoms, and a possible cannabidiol-like conformation for capsaicin are shown.



Many pharmacological activities of CBD have been established only in vivo, hence some of them may be due to CBD metabolites. The metabolism of CBD is well established. The primary step is hydroxylation on C-7, leading to (−)-7-hydroxy-CBD, followed by further oxidation to (−)-7-carboxy-CBD (Agurell et al., 1986). Although the metabolism of the dimethyl-heptyl homologue of CBD and of the (+) enantiomer of CBD has not been investigated, it is reasonable to assume that it follows the same pathways. Hence we prepared these CBD metabolites, their DMH homologues and some of the respective metabolites in the unnatural (+) series. In particular, in the present study we have examined whether the stereochemistry and the presence of certain chemical groups on the C-5′ and C-1 of CBD affect its capability of influencing AEA inactivation via the AMT and FAAH. Furthermore, we have addressed the question of the possible molecular transducer of CBD by studying the possibility that this natural compound, its (+)-enantiomer and some of its synthetic analogues, interact with another proposed target for AEA, i.e. the vanilloid receptor type 1 (VR1) for capsaicin (Holzer, 1991, Figure 1). This protein is a ligand-, heat- and proton-activated non-specific cation channel acting as a molecular integrator of nociceptive stimuli (Tominaga et al., 1998). Recently, it was discovered that AEA is a full, albeit weak, VR1 agonist (Zygmunt et al., 1999; Smart et al., 2000) and that synthetic capsaicin analogues can interact with either CB1 receptors or the AMT, or both (Di Marzo et al., 1998). Thus, there appears to be some overlap between the ligand recognition properties of VR1 and CB1 receptors and, in particular, of VR1 and the AMT (de petrocellis et al., 2000; Szallasi & Di Marzo, 2000). Although VR1, via the release of inflammatory and algesic peptides, is involved in inflammatory hyperalgesia (Davis et al., 2000; Caterina et al., 2000), the stimulation of this receptor by capsaicin and some of its analogues leads to rapid desensitization, with subsequent paradoxical analgesic and anti-inflammatory effects (Holzer, 1991; Szallasi & Blumberg, 1999). As a consequence of this tachyphylactic effect, capsaicin, like CBD, has been used to treat arthritis (Lorton et al., 2000) and convulsions (Dib & Falchi, 1996).

We report data suggesting that VR1 is a possible molecular target for CBD, and that inhibitors of the AMT can be developed by chemical modification of this natural product.

/pdf/molecular-targets-for-cannabidiol-and-its-synthetic-1mdyidlwd6.pdf

Molecular targets for cannabidiol and its synthetic analogues: effect on vanilloid VR1 receptors and on the cellular uptake and enzymatic hydrolysis of anandamide.

Cannabinoid receptors and pain.

http://www.student.oulu.fi/~taneliha/15min_Vertailevan_Endokrinologian_opiskelijaesitelma_Endokannabinoidit/Suurin%20osa%20k%E4ytetyist%E4%20artikkeleista/Cannabinoid%20physiology%20and%20pharmacology%2030%20years%20of%20progress.pdf

Cannabinoid physiology and pharmacology: 30 years of progress

https://www.cell.com/trends/pharmacological-sciences/pdf/S0165-6147(15)00034-6.pdf

Endocannabinoid signaling at the periphery: 50 years after THC

Palmitoylethanolamide (PEA) and oleamide are two fatty acid amides which 1) share some cannabimimetic actions with delta9-tetrahydrocannabinol, anandamide and 2-arachidonoylglycerol, and 2) may interact with proteins involved in the biosynthesis, action and inactivation of endocannabinoids. Due to its pharmacological actions and its accumulation in damaged cells, PEA may have a physio-pathological role as an analgesic, anti-oxidant and anti-inflammatory mediator. However, its mechanism of action is puzzling. In fact, PEA does not bind to CB1 and CB2 receptors transfected into host cells, but might be a ligand for a putative CBn receptor present in the RBL-2H3 cell line. On the other hand, the analgesic effect of PEA is reversed by SR144528, a CB2 antagonist. PEA may act as an entourage compound for endocannabinoids, i.e. it may enhance their action for example by inhibiting their inactivation. Oleamide is a sleep inducing lipid whose mechanism of action is far from being understood. Although it does not bind with high affinity to CB1 or CB2 receptors, it exhibits some cannabimimetic actions which could be explained at least in part by entourage effects. It is likely that oleamide and anandamide have common as well as distinct pathways of action. The 5-HT2A receptor appears to be a target for oleamide but the possibility of the existence of specific receptors for this compound is open. The biosynthesis and tissue distribution of oleamide remain to be assessed in order to both substantiate its role as a sleep-inducing factor and investigate its participation in other physiopathological situations.

The palmitoylethanolamide and oleamide enigmas : are these two fatty acid amides cannabimimetic?

In the late 1990's, a series of experiments carried out independently in two laboratories led to establish an important connection between the function of the endocannabinoids, which, as exemplified in this special issue, is per se very complex and ubiquitous in animals, and that of the transient receptor potential (TRP) channels, a large family of plasma membrane cation channels involved in several mammalian and non-mammalian physiological and pathological conditions, overlapping only in part with those in which the cannabinoid receptors participate. These experiments were initially based on the observation that the endocannabinoid anandamide and the xenobiotic ligand of TRP channels of V1 type (TRPV1), capsaicin, are somehow chemically similar, both compounds being fatty acid amides, as are also synthetic activators of these channels and inhibitors of anandamide cellular re-uptake. As discussed in this article, the same type of "chemical thoughts" led to the discovery of N-arachidonoyl-dopamine, an endogenous ligand of TRPV1 channels that behaves also an endocannabinoid. The overlap between the ligand recognition properties of some TRP channels and proteins of the endocannabinoid system, namely the cannabinoid receptors and the proteins and enzymes catalyzing anandamide cellular re-uptake and hydrolysis, is being actively explored through the rational design and synthesis of new endocannabinoid-based drugs with multiple mechanisms of action. These aspects are discussed in this review article, together with the possible functional and pharmacological consequences of endocannabinoid-TRP channel interactions.

Endocannabinoids as regulators of transient receptor potential (TRP) channels: A further opportunity to develop new endocannabinoid-based therapeutic drugs.

In agreement with the highly lipophilic nature of (-)-Δ 9 -tetrahydrocannabinol, all the endogenous ligands of cannabinoid receptors identified so far are derivatives of long chain fatty acids. N- Arachidonoylethanolamine (anandamide) and some of its polyunsaturated congeners have been found in mammalian brain and shown to activate the CB1 and, with a lower efficacy, CB2 cannabinoid receptor subtypes. More recently, 2-arachidonoylglycerol (2-AG), a widespread intermediate in the metabolism of phosphoglycerides, diacylglycerols and triglycerides, was also found to activate the cannabinoid receptors. The capability of palmitoylethanolamide, an anti-inflammatory metabolite, to activate CB2-like receptors is still being debated. Here we review: 1) the metabolic pathways suggested so far to underlie the biosynthesis and inactivation of anandamide and 2-AG, and 2) the current knowledge of the chemical bases for the interactions of anandamide and 2-AG with proteins of the 'endogenous cannabinoid system' characterized so far, i.e. the CB1 and CB2 receptor subtypes, the membrane 'anandamide carrier', which facilitates anandamide diffusion into cells, and the enzyme 'fatty acid amide hydrolase', which catalyzes anandamide and, to a certain extent, 2-AG hydrolysis in vivo.

Cannabimimetic fatty acid derivatives: the anandamide family and other endocannabinoids.

Objective: Preparation and characterization of anandamide (N-arachidonoyl-ethanolamine, AEA) loaded polycaprolactone nanoparticles (PCL NP) as a research tool to clarify the presence of an AEA transporter in cell membranes and to avoid AEA plastic adsorption and instability.Materials and methods: High performance liquid chromatography and light scattering were used to determine encapsulation efficiency, particle size, drug release, permeability and stability.Results: A high encapsulation efficiency 96.05 ± 1.77% and a particle size of 83.52 ± 21.38 nm were obtained. Nearly 40% of AEA remained in the NP after a 99.9% dilution and only 50% was released after 24 h at 37°C with a 99% dilution. PCL NP prevented the adsorption of the drug to polypropylene or polystyrene, but not to acrylic multiwell plates. Drug permeability through artificial membranes was low (10−7 to 10−8 cm/s) and was affected by the presence of NP. NP increased AEA stability in suspension (drug half-life 431 h vs. 12 h) and freeze-dried wi...

Di Marzo

Papers

The palmitoylethanolamide and oleamide enigmas : are these two fatty acid amides cannabimimetic?

Endocannabinoids as regulators of transient receptor potential (TRP) channels: A further opportunity to develop new endocannabinoid-based therapeutic drugs.

Cannabimimetic fatty acid derivatives: the anandamide family and other endocannabinoids.

Anandamide-loaded nanoparticles: Preparation and characterization