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Query: UNIPROT:P21554 (
cannabinoid receptor
)
3,582
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Aminoalkylindoles (AAIs) are structurally dissimilar from the classical cannabinoids (CCs), however, both AAIs and CCs appear to bind at the same site on the
cannabinoid receptor
. To obtain better insights on the structural correlation between AAIs and CCs, we have studied the conformational properties of the potent cannabimimetic AAI WIN 55212-2 and its inactive analogs using high resolution 2D NMR spectroscopy in combination with computer-assisted molecular modeling. The pharmacophoric similarities between the AAIs and the CCs were then investigated using superimposition techniques. The absolute stereochemistries of the biologically active enantiomer (-)
HHC
were used as superimposition points and considered as internal controls in order to test the molecular principles guiding this experiment. Our results show that the model is congruent with a superimposition in which the naphthoyl, morpholino and 3-keto groups in the AAI, respectively correspond to the side chain, cyclohexanol OH and phenolic OH of
HHC
. A good fit is obtained when the two biologically active antipodes are superimposed. Conversely, the fit is poor if the inactive AAI enantiomer is superimposed on the active
HHC
enantiomer. It can also be seen that in such an orientation a certain deviation of the C-ring from the plane of the phenol ring of the tricyclic
HHC
component and of the morpholinyl portion from the plane of the indole ring of WIN 55212-2 is essential for cannabimimetic activity. The inactive enantiomer WIN 55212-3 has its respective components aligned in the opposite quadrant. By comparing the stereoelectronic features of representative AAIs and CCs, we have developed a model which may help to uncover the pharmacophoric requirements of the AAIs and serve as a basis for future SAR and drug design.
...
PMID:Common cannabimimetic pharmacophoric requirements between aminoalkyl indoles and classical cannabinoids. 777 20
The separation of the mood-altering effects of cannabinoids from their therapeutic effects has been long sought. Results reported here for a series of C-9 analogs of the cyclic ether O,2-propano-delta 8-tetrahydrocannabinol (O,2-propano-delta 8-THC) point to the C-1 position in classical cannabinoids as a position for which CB2 subtype selectivity occurs within the cannabinoid receptors. O,2-Propano-11-delta 8-THC, O,2-propano delta 9,11-THC, O,2-propano-9-oxo-11-nor-hexahydrocannabinol (O,2-propano-9-oxo-11-nor-
HHC
), and O,2-propano-9 alpha- and O,2-propano-9 beta-OH-11-nor-
HHC
were synthesized and evaluated in radioligand displacement assays for affinity at the CB1 and CB2 receptors and in the mouse vas deferens in vitro assay and the mouse tetrad in vivo assay for cannabinoid activity. Evaluation of binding affinity at the CB1 and CB2 receptors revealed that each compound possesses a modest increased affinity for the CB2 receptor. Analogs which contained an oxygen attached to C-9 (i.e., oxo and hydroxy derivatives) showed the highest affinity and selectivity for CB2 (for O,2-propano-9-oxo-11-nor-
HHC
, Ki(CB1) = 90 nM, Ki(CB2) = 23 nM, selectivity ratio 3.9; for O,2-propano-9 beta-OH-11-nor-
HHC
, Ki(CB1) = 26 nM, Ki(CB2) = 5.8 nM, selectivity ratio 4.5). Each compound was found to produce a dose-dependent inhibition of electrically-evoked contractions of the mouse isolated vas deferens when administered at submicromolar concentrations. This inhibition could readily be prevented by the selective
CB1 cannabinoid receptor
antagonist SR-141716A. The analogs exhibited unique in vivo profiles with O,2-propano-delta 9,11-THC exhibiting antinociception with reduced activity in three other in vivo measures and O,2-propano-9 beta-OH-
HHC
exhibiting lack of dose responsiveness in all measures. The CB2 selectivities in the O,2-propano analogs may be due to differences in solvation/desolvation that occur when the ligands enter the CB1 vs CB2 binding site. Alternatively, the CB2 selectivities may be a results of an amino acid change from a hydrogen bond-accepting residue in CB1 to a hydrogen bond-donating residue in CB2.
...
PMID:Importance of the C-1 substituent in classical cannabinoids to CB2 receptor selectivity: synthesis and characterization of a series of O,2-propano-delta 8-tetrahydrocannabinol analogs. 937 52
Constrained molecular dynamics simulations on anandamide, together with a systematic distance comparison search, have revealed a specific low-energy conformer whose spatial disposition of the pharmacophoric elements closely matches that of
HHC
. This conformer enables near superposition of the following: (1) the oxygen of the carboxyamide and the phenolic hydroxyl group of
HHC
, (2) the hydroxyl group of the ethanol and the cyclohexyl hydroxyl group of
HHC
, (3) the alkyl tail and the lipophilic side chain of
HHC
, and (4) the polyolefin loop and the tricyclic ring structure of
HHC
. The close matching of common pharmacophoric elements of anandamide with
HHC
offers persuasive evidence of the biological relevance of this conformer. The proposed pharmacophore model was capable of discriminating between structurally related compounds exhibiting different pharmacological potency for the
CB1 cannabinoid receptor
, i.e., anandamide and N-(2-hydroxyethyl)prostaglandinamide. Furthermore, a 3D-QSAR model was derived using CoMFA for a training set of 29 classical and nonclassical analogues which rationalized the binding affinity in terms of steric and electrostatic properties and, more importantly, which predicted the potency of anandamide in excellent agreement with experimental data. The ABC tricyclic HU-210/HU-211 and ACD tricyclic CP55,243/CP55,244 enantiomeric pairs were employed as test compounds to validate the present CoMFA model. For each enantiomeric pair, the CoMFA-predicted log Ki values correctly identified that enantiomer exhibiting the higher affinity for the receptor.
...
PMID:Derivation of a pharmacophore model for anandamide using constrained conformational searching and comparative molecular field analysis. 978 95
