RATIONALE: Nicotine produces behavioural effects that are potentially related to its interaction with diverse nicotinic acetylcholine receptor populations. Evidence from gene deletion studies suggests that the interoceptive stimulus properties of nicotine are mediated by heteromeric high-affinity receptors containing alpha4beta2 subunits. Mice lacking beta2 subunits do not discriminate nicotine (Shoaib et al., Neuropharmacology, 42:530-539, 2002), and nicotine does not elicit dopamine release in these animals (Grady et al., J Neurochem, 76:258-268, 2001). The stimulus properties of nicotine can be detected in rats using a two-lever operant drug discrimination paradigm, allowing them to be classified pharmacologically using ligands with selectivity for receptors containing alpha4beta2, alpha3beta4 or alpha7 subunits. MATERIALS AND METHODS: Rats trained to discriminate 0.4 mg/kg nicotine from vehicle were given the nicotinic receptor agonists, cytisine, varenicline, TC2559, ABT-594, A-85380 (all having high affinity but varying selectivity for alpha4beta2-containing receptors), and WO 03/062224 and WO 01/60821A1 (selective for beta4- and alpha7-containing receptors, respectively). In separate studies, WO 03/062224 was used as the training stimulus. RESULTS: Nicotine, TC-2559, A-85380 and ABT-594 showed dose-dependent and complete stimulus substitution, whilst WO 03/062224 and WO 01/60821A1 were completely without effect. Cytisine and varenicline showed partial generalisation, consistent with their partial agonist activity at nicotinic receptors eliciting dopamine release in rat striatal slices. After almost 50 training sessions with WO 03/062224, there was no clear evidence that an alpha3beta4 receptor agonist could sustain a discriminable stimulus. CONCLUSION: Substitution to the nicotine discriminative stimulus required high-affinity and high intrinsic activity at beta2 but not at beta4- or at alpha7-containing nicotinic receptors.
RATIONALE: Nicotine produces behavioural effects that are potentially related to its interaction with diverse nicotinic acetylcholine receptor populations. Evidence from gene deletion studies suggests that the interoceptive stimulus properties of nicotine are mediated by heteromeric high-affinity receptors containing alpha4beta2 subunits. Mice lacking beta2 subunits do not discriminate nicotine (Shoaib et al., Neuropharmacology, 42:530-539, 2002), and nicotine does not elicit dopamine release in these animals (Grady et al., J Neurochem, 76:258-268, 2001). The stimulus properties of nicotine can be detected in rats using a two-lever operant drug discrimination paradigm, allowing them to be classified pharmacologically using ligands with selectivity for receptors containing alpha4beta2, alpha3beta4 or alpha7 subunits. MATERIALS AND METHODS:Rats trained to discriminate 0.4 mg/kg nicotine from vehicle were given the nicotinic receptor agonists, cytisine, varenicline, TC2559, ABT-594, A-85380 (all having high affinity but varying selectivity for alpha4beta2-containing receptors), and WO 03/062224 and WO 01/60821A1 (selective for beta4- and alpha7-containing receptors, respectively). In separate studies, WO 03/062224 was used as the training stimulus. RESULTS:Nicotine, TC-2559, A-85380 and ABT-594 showed dose-dependent and complete stimulus substitution, whilst WO 03/062224 and WO 01/60821A1 were completely without effect. Cytisine and varenicline showed partial generalisation, consistent with their partial agonist activity at nicotinic receptors eliciting dopamine release in rat striatal slices. After almost 50 training sessions with WO 03/062224, there was no clear evidence that an alpha3beta4 receptor agonist could sustain a discriminable stimulus. CONCLUSION: Substitution to the nicotine discriminative stimulus required high-affinity and high intrinsic activity at beta2 but not at beta4- or at alpha7-containing nicotinic receptors.
Authors: W Xu; A Orr-Urtreger; F Nigro; S Gelber; C B Sutcliffe; D Armstrong; J W Patrick; L W Role; A L Beaudet; M De Biasi Journal: J Neurosci Date: 1999-11-01 Impact factor: 6.167
Authors: D L Donnelly-Roberts; P S Puttfarcken; T A Kuntzweiler; C A Briggs; D J Anderson; J E Campbell; M Piattoni-Kaplan; D G McKenna; J T Wasicak; M W Holladay; M Williams; S P Arneric Journal: J Pharmacol Exp Ther Date: 1998-05 Impact factor: 4.030
Authors: J P Sullivan; D Donnelly-Roberts; C A Briggs; D J Anderson; M Gopalakrishnan; M Piattoni-Kaplan; J E Campbell; D G McKenna; E Molinari; A M Hettinger; D S Garvey; J T Wasicak; M W Holladay; M Williams; S P Arneric Journal: Neuropharmacology Date: 1996-06 Impact factor: 5.250
Authors: Ramiro Salas; Avi Orr-Urtreger; Ron S Broide; Arthur Beaudet; Richard Paylor; Mariella De Biasi Journal: Mol Pharmacol Date: 2003-05 Impact factor: 4.436
Authors: K J Jackson; M J Marks; R E Vann; X Chen; T F Gamage; J A Warner; M I Damaj Journal: J Pharmacol Exp Ther Date: 2010-04-16 Impact factor: 4.030
Authors: Colin S Cunningham; Megan J Moerke; Martin A Javors; F Ivy Carroll; Lance R McMahon Journal: Br J Pharmacol Date: 2016-11-06 Impact factor: 8.739
Authors: James Robert Brasić; Yun Zhou; John L Musachio; John Hilton; Hong Fan; Andrew Crabb; Christopher J Endres; Melvin J Reinhardt; Ahmet S Dogan; Mohab Alexander; Olivier Rousset; Marika A Maris; Jeffrey Galecki; Ayon Nandi; Dean F Wong Journal: Synapse Date: 2009-04 Impact factor: 2.562
Authors: Mark G LeSage; David Shelley; Jason T Ross; F Ivy Carroll; William A Corrigall Journal: Pharmacol Biochem Behav Date: 2008-09-09 Impact factor: 3.533