Structure-Activity Relationships of Indole- and Pyrrole-Derived Cannabinoids

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Vol. 285, Issue 3, 995-1004, June 1998

Structure-Activity Relationships of Indole- and Pyrrole-Derived Cannabinoids¹

Jenny L. Wiley, David R. Compton, Dong Dai, Julia A. H. Lainton, Michelle Phillips, John W. Huffman and Billy R. Martin

Department of Pharmacology and Toxicology, Virginia Commonwealth University, Medical College of Virginia Campus, Richmond, Virginia (J.L.W., D.R.C., B.R.M.) and Department of Chemistry, Clemson University, Clemson, South Carolina (D.D., J.A.H.L., M.P., J.W.H.)

Early molecular modeling studies with $Delta$ ⁹-tetrahydrocannabinol ( $Delta$ ⁹-THC) reported that three discrete regions which interact withbrain cannabinoid (CB1) receptors corresponded to the C-9 positionof the cyclohexene ring, the phenolic hydroxyl and the carbonside chain at the C3 position. Although the location of theseattachment points for aminoalkylindoles is less clear, the naphthalenering, the carbonyl group and the morpholinoethyl group have beensuggested as probable sites. In this study, a series of indole-and pyrrole-derived cannabinoids was developed, in which the morpholinoethylgroup was replaced with another cyclic structure or with a carbonchain that more directly corresponded to the side chain of $Delta$ ⁹-THC and were tested for CB1 binding affinity and in a batteryof in vivo tests, including hypomobility, antinociception, hypothermiaand catalepsy in mice and discriminative stimulus effects in rats.Receptor affinity and potency of these novel cannabinoids wererelated to the length of the carbon chain. Short side chains resultedin inactive compounds, whereas chains with 4 to 6 carbons producedoptimal in vitro and in vivo activity. Pyrrole-derived cannabinoidswere consistently less potent than were the corresponding indolederivatives and showed pronounced separation of activity, in thatpotencies for hypomobility and antinociception were severalfoldhigher than potencies for hypothermia and ring immobility. Theseresults suggest that, whereas the site of the morpholinoethylgroup in these cannabinoids seems crucial for attachment to CB1receptors, the exact structural constraints on this part of themolecule are not as strict as previously thought.

0022-3565/98/2853-0995$03.00/0
THE JOURNAL OF PHARMACOLOGY AND EXPERIMENTAL THERAPEUTICS
Copyright © 1998 by The American Society for Pharmacology and Experimental Therapeutics

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Structure-Activity Relationships of Indole- and Pyrrole-Derived Cannabinoids1

Structure-Activity Relationships of Indole- and Pyrrole-Derived Cannabinoids¹