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The discovery of the endogenous cannabinoid system led to the development of CB1 receptor antagonists. The first cannabinoid receptor antagonist, rimonabant, was described in 1994. Rimonabant blocks CB1 receptor selectively and it has been shown to decrease food intake and regulate body-weight gain. The prevalence of obesity worldwide is increasing dramatically and has a great impact on public health. The lack of efficient and well-tolerated drugs to cure obesity has led to an increased interest in research and development of cannabinoid antagonists.[1][2]
History
editFor centuries hashish and marijuana from the Indian hemp Cannabis sativa L. have been used for their medicinal and recreational purposes.[3]Cite error: The <ref>
tag has too many names (see the help page). In 1964 the main active constituent of C. sativa L., Δ9-tetrahydrocannabinol (THC), was isolated and synthesized by Mechoulam´s laboratory.[3][4] Two types of cannabinoid receptors, CB1 and CB2, responsible for the effects of the THC were discovered and cloned in the early 1990´s.[1][5] Once cannabinoid receptors had been discovered, it became important to establish whether their agonists occur naturally in the body. This search led to the discovery of the first endogenous cannabinoid (endocannabinoid), anandamide (arachidonoyl ethanolamide). Later on other endocannabinoids were found, for example 2-AG (2-arachidonoyl glycerol).[3] These findings raised further questions about the pharmacological and physiological role of the cannabinoid system. This revived the research on cannabinoid receptor antagonists which were expected to help answer these questions.[5] The use of the cannabinoid agonist, THC, in its many preparations to enhance appetite is a well known fact. This fact led to the logical extension that blocking of the cannabinoid receptors might be useful in decreasing appetite and food intake.[6] It was then discovered that the blockage of the CB1 receptor represented a new pharmacological target. The first specific CB1 receptor antagonist was rimonabant, discovered in 1994.[5][6]
Endocannabinoids and their signaling system
editThe endogenous cannabinoid system includes cannabinoid receptors, their endogenous ligands (endocannabinoids) and enzymes for their synthesis and degradation.[7]
There are two main receptor types associated with the endocannabinoid signaling system; cannabinoid receptor 1 (CB1) and 2 (CB2). Both receptors are 7-transmembrane G-protein coupled receptors (GPCRs) which inhibit the accumulation of cyclic adenosine monophosphate within cells.[8][9] CB1 receptors are present in highest concentration in the brain but can also be found in the periphery. CB2 receptors are mostly located in the immune and haematopoietic systems.[1][8]
Endocannabinoids are eicosanoids acting as agonists for cannabinoid receptors and they occur naturally in the body.[4] Cannabinoid receptor-related processes are for example involved in cognition, memory, anxiety, control of appetite, emesis, motor behavior, sensory, autonomic and neuroendocrine responses, immune responses and inflammatory effects.[7] There are two well-characterized endocannabinoids located in the brain and periphery. The first identified was anandamide (arachidonoyl ethanolamide) and the second was 2-AG (2-arachidonoyl glycerol). Additional endocannabinoids include virodhamine (O-arachidonoyl ethanolamine), noladin ether (2-arachidonoyl glyceryl ether) and NADA (N-arachidonoyl dopamine).[8]
Mechanism
editCB1 receptors are coupled through Gi/o proteins and inhibit adenylyl cyclase and activate mitogen-activated protein (MAP) kinase. In addition, CB1 receptors inhibit presynaptic N- and P/Q-type calcium channels and activate inwardly rectifying potassium channels. [3][6] CB1 antagonists produce inverse cannabimimetic effects that are opposite in direction from those produced by agonists for these receptors.[3][10]
CB1 receptors are highly expressed in hypothalamic areas which are involved in central food intake control and feeding behavior. This strongly indicates that the cannabinoid system is directly involved in feeding regulation. These regions are also interconnected with the mesolimbic dopamine pathway, the so-called „reward“ system. Therefore, CB1 antagonists might indirectly inhibit the dopamine-mediated rewarding properties of food.[8][10] Peripheral CB1 receptors are located in the gastrointestinal (GI) tract, liver and in adipose tissue. In the GI, CB1 receptors are located on nerve terminals in the intestines. Endocannabinoids act at the CB1 receptors to increase hunger and promote feeding and it is speculated that they decrease intestinal peristalsis and gastric emptying. Thus, antagonism at these receptors can inverse these effects.[8] Also, in peripheral tissues, antagonism of CB1 receptors increases insulin sensitivity and oxidation of fatty acids in muscles and the liver.[1] A hypothetical scheme for the metabolic effects of CB1 receptor antagonists is shown in Figure 1.
CB1 receptor antagonist drug design
editThe first approach to develop cannabinoid antagonists in the late 1980´s was to modify the structure of THC but the results were disappointing. In the early 1990´s new family of cannabinoid agonists was discovered from the NSAID (non-steroidal anti-inflammatory) drug pravadoline which led to the discovery of aminoalkyl indole antagonists with some but limited success. As the search based on the structure of agonists was disappointing it was no surprise that the first potent and selective cannabinoid antagonist belonged to an entirely new chemical family. In 1994 the first selective cannabinoid antagonist, SR141716 (rimonabant), was introduced by Sanofi belonging to a family of 1,5-diarylpyrazoles.[5][11]
Rimonabant
editRimonabant, also known by the systematic name [N-(piperidin-1-yl)-5-(4-chlorophenyl)-1-(2,4-dichlorophenyl)-4-methyl-1 H-pyrazole-3-carboxamidehydrochloride)], is a 1,5-diarylpyrazole CB1 receptor antagonist (Figure 2).[11] Rimonabant is not only a potent and highly selective ligand of the CB1 receptor, but it is also orally active and antagonizes most of the effects of cannabinoid agonists, such as THC, both in vitro and in vivo. Rimonabant has shown clear clinical efficacy for the treatment of obesity.[12]
Binding to receptor
editBinding of an agonist ligand to the CB1 receptor provokes a conformational change and leads to the active state of the receptor which is responsible for the signal transduction. However, there is an additional mechanism that can lead to the active state in the absense of ligand. As numerous other GPCRs, CB1 receptor displays a high level of constitutive activity and thus it can spontaneously adopt an active conformational state in the absence of agonist binding, keeping elevated basal levels of intracellular signaling.[13] This can be explained by the two state-model of receptor activation in which receptors are in equilibrium between two states, active and inactive (R* and R). An agonist will stabilize the active state leading to activation, a neutral antagonist binds equally to active and inactive states, whereas an inverse agonist will preferentially stabilize the inactive state (Figure 3).[13]
Rimonabant has been reported in many cases to behave as an inverse agonist rather than as a neutral antagonist and it is likely that it binds preferentially to the inactive state of the CB1, thereby decreasing the activation of the signaling pathway.[14][15] The key binding interaction is a hydrogen bond formed between the carbonyl group of rimonabant and the Lys192 residue of the CB1 receptor. This bond stabilizes the Lys192-Asp366 salt bridge of the intracellular end of transmembrane helices 3 and 6 (Figure 4). This specific salt bridge is present in the inactive state of the receptor but absent in the active state.[14][15]
In the inactive state of CB1 rimonabant binds within the transmembrane-3-4-5-6 aromatic microdomain. The binding of rimonabant involves direct aromatic stacking interactions between its 2,4-dichlorophenyl ring and the Trp279/Phe200/Trp356 residues on the one side and the para-chlorophenyl ring and the Tyr275/Trp255/Phe278 residues on the other side. The lipophilic piperidinyl moiety fits nicely in a cavity formed by the amino acid residues Val196/Phe170/Leu387 and Met384 (Figure 4).[12][13][14][16]
Pharmacophore
editMost CB1 antagonists reported so far are close analogs or isosteres of rimonabant.[17] A general CB1 inverse agonist pharmacophore model can be extracted from the common features of these analogs, diarylpyrazoles (Figure 4).[14] This pharmacophore contains a cyclic core, C, (e.g. pyrazole in rimonabant) substituted by two aromatic moieties, A and B. A hydrogen bond acceptor unit, D, connects C with a cyclic lipophilic part, E. In some cases unit E directly connects to C.[14][17] In Figure 4 rimonabant is used as an example. Unit A represents a 4-chlorophenyl group and unit B a 2,4-dichlorophenyl ring. Unit C is the central pyrazole ring and unit D represents the carbonyl group which serves as the hydrogen bond acceptor. Unit E represents a lipophilic aminopiperidinyl moiety.[14]
Structure-activity relationship (SAR)
editOptimal binding at the CB1 receptor requires a para-substituted phenyl ring at the pyrazole 5-position. The 5-substituent of the pyrazole is involved in receptor recognition and antagonism. The para-substituent of the phenyl ring could be chlorine, bromine or iodine, but it has been shown that an alkyl chain could also be tolerated.[14] Numbering of the central pyrazole ring is shown in Figure 2.
A 2,4-dichloro-substituted phenyl ring at the pyrazole 1-position is preferred for affinity as well as for the activity. It has been shown that additional halogens on this phenyl ring decrease affinity.[14]
It is also favorable to have a ring substitution at the 3-carboxamide group, such as the 1-piperidinyl group in rimonabant.[14] Replacement of the amino piperidinyl substituent by alkyl amides, ethers, ketones, alcohols or alkanes resulted mostly in decreased affinity. Replacement of the piperidinyl by pentyl or a heptyl chain gave the compounds agonistic properties. Based on these results it was concluded that the pyrazole 3-position seems to be involved in agonism, while the 1-,4-,5-positions appear to be involved in antagonism.[12]
Research has shown that the absence of the carboxamide oxygen results in decreased affinity. Furthermore, the presence of carboxamide oxygen contributes in conferring the inverse agonist properties, whereas analogs lacking this oxygen are found to be neutral antagonists. These results support the hypothesis that the carboxamide oxygen forms a hydrogen bond with Lys192 residue at the CB1 receptor.[18]
Diarylpyrazole derivatives of rimonabant
editSR141716 (rimonabant) analogs have recently been described by several groups, leading to a good understanding of the structure-activity relationship (SAR) within this chemical group. While most compounds described are less potent than SR141716, two of them are worth mentioning, SR147778 and AM251.[2]
SR147778 (surinabant), a second generation antagonist, has a longer duration of action than rimonabant and enhanced oral activity. This enhanced duration of action is probably due to the presence of the more metabolically stable ethyl group at the 4-position of its pyrazole ring. Another change is the replacement of the 5-phenyl chlorine substituent by bromine.[2][14][19]
The diarylpyrazole derivative, AM251, has been described where chlorine substituent has been replaced by iodine in the para position of the 5-phenyl ring. This derivative appeared to be more potent and selective than rimonabant.[6][12]
21 analogs possessing either an alkyl amide or an alkyl hydrazide of variant lengths in position 3 were synthesized. It was observed that affinity increases with increased carbon chain length up to five carbons. Also the amide analogs exhibited higher affinity than hydrazide analogs. However, none of these analogs possessed significantly greater affinity than rimonabant but nevertheless, they were slightly more selective than rimonabant for the CB1 receptor over the CB2 receptor.[12]
Several attempts have been made to increase the affinity of the diarylpyrazole derivatives by rigidifying the structure of rimonabant. In terms of the general pharmacophore model the units A, B and/or C are connected by additional bonds leading to rigid molecules. For example the condensed polycyclic pyrazole NESS0327 showed 5000 times more affinity for the CB1 receptor than rimonabant. However, this compound possesses a poor central bioavailability.[12][14]
Another compound, the indazole derivative O-1248, can be regarded as an analog of rimonabant wherein its 5-aryl group is fused to the pyrazole moiety. However, this structural modification resulted in a 67-fold decrease in CB1 receptor affinity.[14]
These diarylpyrazole derivatives of rimonabant are summarized in Table 1.
SR147778 | AM251 |
NESS0327 | O-1248 |
Other derivatives
editStructurally different from the 1,5-diarylpyrazoles are the chemical series of the 3,4-diarylpyrazolines. Within this series is SLV319, a potent CB1 antagonist which is about 1000-fold more selective for CB1 compared with CB2 and displays in vivo activity similar to rimonabant.[2][14]
Another approach used to develop analogs of rimonabant was to replace central pyrazole ring by another heterocycle. An example of this approach are 4,5-diarylimidazoles and 1,5-diarylpyrrole-3-carboxamides.[2]
A large number of fused bicyclic derivatives of diaryl-pyrazole and imidazoles have been reported. An example of these is a purine derivative where a pyrimidine ring is fused to an imidazole ring.[2] Otenabant (CP-945,598) is an example of a fused bicyclic derivative developed by Pfizer.[20]
Several research groups have studied six-membered ring pyrazole bioisosteres. For example one 2,3-diarylpyridine derivative was shown to be potent and selective CB1 inverse agonist. The structure of this compound demonstrates the possibility that the amide moiety of rimonabant could be split into a lipophilic (benzyloxy) and a polar (nitrile) functionality. Other six-membered ring analogs are for example pyrimidines and pyrazines.[2]
In addition to the five and six-membered ring analogs there are other cyclic derivatives such as the azetidines. One example is the methylsulfonamide azetidine derivative which has a 1,1-diaryl group that mimics the 1,5-diaryl moiety of the diarylpyrazoles. The sulfonyl group serves as a hydrogen bond acceptor. The 1,1-diaryl group is also present in derivatives such as the benzodioxoles and hydantoins.[2][14]
Acyclic analogs have also been reported. These analogs contain a 1,2-diaryl motif which corresponds to the 1,5-diaryl substituents of rimonabant.[2] An example of an acyclic analog is taranabant (MK-0364) developed by Merck.[20]
Representatives of these analogs are summarized in Table 2.
Current status
editRimonabant (Acomplia®) has been approved in the European Union (EU) since June 2006 for the treatment of obesity. On 23rd of October 2008 the European Medicines Agency (EMEA) has recommended the suspension of the marketing authorization across the EU for Acomplia® from Sanofi-Aventis based on the risk of serious psychiatric disorders.[21] On 5th of November 2008 Sanofi-Aventis announced discontinuation of rimonabant clinical development program.[22]
Sanofi-Aventis has also discontinued development of surinabant (SR147778), a CB1 receptor antagonist for smoking cessation (31st of October 2008).[23]
Merck has stated in its press release on 2nd of October 2008 that they will not seek regulatory approval for taranabant (MK-0364) to treat obesity and will discontinue its Phase III clinical development program. Data from Phase III clinical trial showed that greater efficacy and more adverse effects were associated with the higher doses of taranabant and it was determined that the overall profile of taranabant does not support further development for obesity.[24]
Another pharmaceutical company, Pfizer, terminated the Phase III development program for its obesity compound otenabant (CP-945,598), a selective antagonist of the CB1 receptor. According to Pfizer their decision was based on changing regulatory perspectives on the risk/benefit profile of the CB1 class and likely new regulatory requirements for approval.[25]
References
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- ^ a b c d Barth, F.; Rinaldi-Carmona, M. (1999), "The Development of Cannabinoid Antagonists", Current Medicinal Chemistry, 6: 745–755
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- ^ a b Svíženská, I.; Dubový, P.; Šulcová, A. (2008), "Cannabinoid receptor 1 and 2 ( CB1 and CB2), their distribution, ligands and functional involvement in nervous system structures – A short review" (PDF), Pharmacology, Biochemistry and Behavior, 90: 501–511
- ^ a b c d e Xie, S.; Furjanic, M.A.; Ferrara, J.J.; McAndrew, N.R.; Ardino, E.L.; Ngondara, A.; Bernstein, Y.; Thomas, K.J.; Kim, E.; Walker, J.M.; Nagar, S.; Ward, S.J.; Raffa, R.B. (2007), "The endocannabinoid system and rimonabant: a new drug with a novel mechanism of action involving cannabinoid CB1 receptor antagonism – or inverse agonism – as potential obesity treatment and other therapeutic use", Journal of Clinical Pharmacy and Therapeutics, 32: 209–231
- ^ Ashton, J.S.; Wrigth, J.L.; McPartland, J.M.; Tyndall, J.D.A. (2008), "Cannabinoid CB1 and CB2 Receptor Ligand Specificity and the Development of CB2-Selective Agonists", Current Medicinal Chemistry, 15: 1428–1443
- ^ a b Di Marzo, V. (2008), "CB1 receptor antagonism: biological basis for metabolic effects" (PDF), Drug Discovery Today: 1–16
- ^ a b Rinaldi – Carmona, M.; Barth, F.; Héaulme, M.; Shire, D.; Calandra, B.; Congy, C.; Martinez, S.; Maruani, J.; Néliat, G.; Caput, D.; Ferrara, P.; Soubrié, P.; Breliére, J.C.; Fur, G.L. (1994), "SR141716A, a potent and selective antagonist of the brain cannabinoid receptor" (PDF), FEBS Letters, 350: 240–244
- ^ a b c d e f Muccioli, G.G.; Lambert, D.M. (2005), "Current Knowledge on the Antagonists and Inverse Agonists of Cannabinoid Receptors" (PDF), Current Medicinal Chemistry, 12 (12): 1361–1394
- ^ a b c Ortega-Gutiérrez, S.; López-Rodriguez, M.L. (2005), "CB1 and CB2 Cannabinoid Receptor Binding Studies Based on Modeling and Mutagenesis Approaches", Mini-Reviews in Medicinal Chemistry, 5: 651–658
- ^ a b c d e f g h i j k l m n Lange, J.H.M.; Kruse, C.G. (2005), "Medicinal chemistry strategies to CB1 cannabinoid receptor antagonists" (PDF), Drug Discovery Today, 10 (10): 693–702
- ^ a b McAllister, S.D.; Rizvi, G.; Anavi-Goffer, S.; Hurst, D.P.; Barnett-Norris, J.; Lynch, D.L.; Reggio, P.H.; Abood, M.E. (2003), "An Aromatic Microdomain at the Cannabinoid CB1 Receptor Constitutes an Agonist/Inverse Agonist Binding Region", Journal of Medicinal Chemistry, 46: 5139–5152
- ^ Fan, H.; Kotsikorou, E.; Hoffman, A.F.; Ravert, H.T.; Holt, D.; Hurst, D.P.; Lupica, C.R.; Reggio, P.H.; Dannals, R.F.; Horti, A.G. (2008), "Analogs of JHU75528, a PET ligand for imaging of cerebral cannabinoid receptors (CB1): Development of ligands with optimized lipophilicity and binding affinity" (PDF), European Journal of Medicinal Chemistry: 1–16
- ^ a b Foloppe, N.; Allen, N.H.; Bentlev, C.H.; Brooks, T.D.; Kennett, G.; Knight, A.R.; Leonardi, S.; Misra, A.; Monck, N.J.T.; Sellwood, D.M. (2008), "Discovery of novel class of selective human CB1 inverse agonists" (PDF), Bioorganic & Medicinal Chemistry Letters, 18: 1199–1206
- ^ Jagerovic, N.; Fernandez – Fernandez, C.; Goya, P. (2008), "CB1 Cannabinoid Antagonists: Structure – Activity Relationships and Potential Therapeutic Applications", Current Topics in Medicinal Chemistry, 8: 205–230
- ^ Vemuri, V.K.; Janero, D.R.; Makriyannis, A. (2008), "Pharmacotherapeutic targeting of the endocannabinoid signaling system: Drugs for obesity and the metabolic syndrome" (PDF), Physiology & Behavior, 93: 671–686
- ^ a b Kim, M.; Yun, H.; Kwak, H.; Kim, J.; Lee, J. (2008), "Design, chemical synthesis, and biological evaluation of novel triazolyl analogues of taranabant (MK-0364), a cannabinoid-1 receptor inverse agonist" (PDF), Tetrahedron, 64: 10802–10809
- ^ http://www.emea.europa.eu
- ^ http://en.sanofi-aventis.com
- ^ http://www.sanofi-aventis.ca
- ^ http://www.merck.com
- ^ http://www.pfizer.com