Luca Pucci

Structural and functional diversity of native brain neuronal nicotinic receptors.

Neuronal nicotinic acetylcholine receptors (nAChRs) are a family of ligand-gated ion channels present in the central and peripheral nervous systems, that are permeable to mono- and divalent cations. They share a common basic structure but their pharmacological and functional properties arise from the wide range of different subunit combinations making up distinctive subtypes. nAChRs are involved in many physiological functions in the central and peripheral nervous systems, and are the targets of the widely used drug of abuse nicotine. In addition to tobacco dependence, changes in their number and/or function are associated with neuropsychiatric disorders, ranging from epilepsy to dementia. Although some of the neural circuits involved in the acute and chronic effects of nicotine have been identified, much less is known about which native nAChR subtypes are involved in specific physiological functions and pathophysiological conditions. We briefly review some recent findings concerning the structure and function of native nAChRs, focusing on the subtypes identified in the mesostriatal and habenulo-interpeduncular pathways, two systems involved in nicotine reinforcement and withdrawal. We also discuss recent findings concerning the effect of chronic nicotine on the expression of native subtypes.

Rodent Habenulo–Interpeduncular Pathway Expresses a Large Variety of Uncommon nAChR Subtypes, But Only the α3β4 and α3β3β4 Subtypes Mediate Acetylcholine Release

Recent studies suggest that the neuronal nicotinic receptors (nAChRs) present in the habenulo–interpeduncular (Hb–IPn) system can modulate the reinforcing effect of addictive drugs and the anxiolytic effect of nicotine. Hb and IPn neurons express mRNAs for most nAChR subunits, thus making it difficult to establish the subunit composition of functional receptors. We used immunoprecipitation and immunopurification studies performed in rat and wild-type (+/+) and β2 knock-out (−/−) mice to establish that the Hb and IPn contain significant β2* and β4* populations of nAChR receptors (each of which is heterogeneous). The β4* nAChR are more highly expressed in the IPn. We also identified novel native subtypes (α2β2*, α4β3β2*, α3β3β4*, α6β3β4*). Our studies on IPn synaptosomes obtained from +/+ and α2, α4, α5, α6, α7, β2, β3, and β4−/− mice show that only the α3β4 and α3β3β4 subtypes facilitate acetylcholine (ACh) release. Ligand binding, immunoprecipitation, and Western blotting studies in β3−/− mice showed that, in the IPn of these mice, there is a concomitant reduction of ACh release and α3β4* receptors, whereas the receptor number remains the same in the Hb. We suggest that, in habenular cholinergic neurons, the β3 subunit may be important for transporting the α3β4* subtype from the medial habenula to the IPn. Overall, these studies highlight the presence of a wealth of uncommon nAChR subtypes in the Hb–IPn system and identify α3β4 and α3β3β4, transported from the Hb and highly enriched in the IPn, as the subtypes modulating ACh release in the IPn.

Stable expression and functional characterization of a human nicotinic acetylcholine receptor with α6β2 properties: discovery of selective antagonists

Despite growing evidence that inhibition of α6β2‐containing (α6β2*) nicotinic acetylcholine receptors (nAChRs) may be beneficial for the therapy of tobacco addiction, the lack of good sources of α6β2*‐nAChRs has delayed the discovery of α6β2‐selective antagonists. Our aim was to generate a cell line stably expressing functional nAChRs with α6β2 properties, to enable pharmacological characterization and the identification of novel α6β2‐selective antagonists.

Engineering of α-conotoxin MII-derived peptides with increased selectivity for native α6β2* nicotinic acetylcholine receptors

α6β2∗ Nicotinic acetylcholine receptors are expressed in selected central nervous system areas, where they are involved in striatal dopamine (DA) release and its behavioral consequences, and other still uncharacterized brain activities. α6β2∗ receptors are selectively blocked by the α‐conotoxins MII and PIA, which bear a characteristic N‐ terminal amino acid tail [arginine (R), aspartic acid (D), and proline (P)]. We synthesized a group of PIA‐related peptides in which R1 was mutated or the RDP motif gradually removed. Binding and striatal DA release assays of native rat α6β2∗ receptors showed that the RDP sequence, and particularly residue R1, is essential for the activity of PIA. On the basis of molecular modeling analyses, we synthesized a hybrid peptide (RDP‐MII) that had increased potency (7‐fold) and affinity (13‐fold) for α6β2∗ receptors but not for the very similar α3β2∗ subtype. As docking studies also suggested that E11 of MII might be a key residue engendering α6β2∗ vs. α3β2∗ selectivity, we prepared MII[E11R] and RDP‐MII[E11R] peptides. Their affinity and potency for native α6β2∗ receptors were similar to those of their parent analogues, whereas, for the oocyte expressed rat α3β2∗ subtype, they showed a 31‐ and 14‐fold lower affinity and 21‐ and 3.5‐fold lower potency. Thus, MII[E11R] and RDP‐MII[E11R] are potent antagonists showing a degree of α6β2∗ vs. α3β2∗ selectivity in vivo.—Pucci, L., Grazioso, G., Dallanoce, C., Rizzi, L., De Micheli, C., Clementi, F., Bertrand, S., Bertrand, D., Longhi, R., De Amici, M., Gotti, C. Engineering of α‐conotoxin MII‐derived peptides with increased selectivity for native α6β2* nicotinic acetylcholine receptors. FASEB J. 25, 3775–3789 (2011). www.fasebj.org

Epiboxidine and novel-related analogues : A convenient synthetic approach and estimation of their affinity at neuronal nicotinic acetylcholine receptor subtypes

Racemic exo-epiboxidine 3, endo-epiboxidine 6, and the two unsaturated epiboxidine-related derivatives 7 and 8 were efficiently prepared taking advantage of a palladium-catalyzed Stille coupling as the key step in the reaction sequence. The target compounds were assayed for their binding affinity at neuronal alpha4beta2 and alpha7 nicotinic acetylcholine receptors. Epiboxidine 3 behaved as a high affinity alpha4beta2 ligand (K(i)=0.4 nM) and, interestingly, evidenced a relevant affinity also for the alpha7 subtype (K(i)=6 nM). Derivative 7, the closest analogue of 3 in this group, bound with lower affinity at both receptor subtypes (K(i)=50 nM for alpha4beta2 and K(i)=1.6 microM for alpha7) evidenced a gain in the alpha4beta2 versus alpha7 selectivity when compared with the model compound.

CC4, a dimer of cytisine, is a selective partial agonist at α4β2/α6β2 nAChR with improved selectivity for tobacco smoking cessation.

Many of the addictive and rewarding effects of nicotine are due to its actions on the neuronal nicotinic ACh receptor (nAChR) subtypes expressed in dopaminergic mesocorticolimbic cells. The partial agonists, cytisine and varenicline, are helpful smoking cessation aids. These drugs have a number of side effects that limit their usefulness. The aim of this study was to investigate the preclinical pharmacology of the cytisine dimer1,2‐bisN‐cytisinylethane (CC4).

Design, synthesis, and pharmacological characterization of novel spirocyclic quinuclidinyl-Δ2-isoxazoline derivatives as potent and selective agonists of α7 nicotinic acetylcholine receptors.

A set of racemic spirocyclic quinuclidinyl‐Δ2‐isoxazoline derivatives was synthesized using a 1,3‐dipolar cycloaddition‐based approach. Target compounds were assayed for binding affinity toward rat neuronal homomeric (α7) and heteromeric (α4β2) nicotinic acetylcholine receptors. Δ2‐Isoxazolines 3 a (3‐Br), 6 a (3‐OMe), 5 a (3‐Ph), 8 a (3‐OnPr), and 4 a (3‐Me) were the ligands with the highest affinity for the α7 subtype (Ki values equal to 13.5, 14.2, 25.0, 71.6, and 96.2 nM, respectively), and showed excellent α7 versus α4β2 subtype selectivity. These compounds, tested in electrophysiological experiments against human α7 and α4β2 receptors stably expressed in cell lines, behaved as partial α7 agonists with varying levels of potency. The two enantiomers of (±)‐3‐methoxy‐1‐oxa‐2,7‐diaza‐7,10‐ethanospiro[4.5]dec‐2‐ene sesquifumarate 6 a were prepared using (+)‐dibenzoyl‐L‐ or (−)‐dibenzoyl‐D‐tartaric acid as resolving agents. Enantiomer (R)‐(−)‐6 a was found to be the eutomer, with Ki values of 4.6 and 48.7 nM against rat and human α7 receptors, respectively.

Design of novel α7-subtype-preferring nicotinic acetylcholine receptor agonists: Application of docking and MM-PBSA computational approaches, synthetic and pharmacological studies

In the search for nicotinic acetylcholine receptor (nAChRs) agonists with a selective affinity for the homomeric alpha7 channels, we carried out the virtual screening of a test set of potential nicotinic ligands, and adopted a simplified MM-PBSA approach to estimate their relative binding free energy values. By means of this procedure, previously validated by a training set of compounds, we reached a realistic compromise between computational accuracy and calculation rate, and singled out a small group of novel structurally related derivatives characterized by a promising theoretical affinity for the alpha7 subtype. Among them, five new compounds were synthesized and assayed in binding experiments at neuronal alpha7 as well as alpha4beta2 nAChRs.

Novel tricyclic Δ2-isoxazoline and 3-oxo-2-methyl-isoxazolidine derivatives: Synthesis and binding affinity at neuronal nicotinic acetylcholine receptor subtypes

A group of novel tricyclic Delta(2)-isoxazolines (4b, 5b, 7a-b, and 8a-b) and 3-oxo-isoxazolidines (6a-b and 9a-b), structurally related to cytisine or norferruginine, was prepared through 1,3-dipolar cycloadditions involving suitable olefins and bromonitrile oxide. The target compounds were assayed at alpha4beta2 and alpha7 neuronal acetylcholine receptors (nAChRs). The results of competition binding experiments indicated for the new derivatives a reduction of the affinity at the alpha4beta2 subtype in comparison with the reference molecules, coupled with an overall negligible affinity at the alpha7 subtype. The binding mode of the bromo-Delta(2)-isoxazolines 4b and 7b, which were the highest affinity ligands in the series (K(i)=0.92 and 0.75 microM, respectively), was analyzed by applying a recently developed model of the alpha4beta2 nAChRs.

Bifunctional compounds targeting both D2 and non-α7 nACh receptors: design, synthesis and pharmacological characterization.

We designed, prepared and tested a set of structural analogs 1-4 as new hybrid compounds by incorporating, through a common alkyl chain of variable length, the pharmacophoric elements of N-n-alkyl nicotinium salts (non-α7 nicotinic acetylcholine receptors antagonists) and of 7-hydroxy-2-(aminomethyl)chromanes (dopaminergic D2 receptor agonists). The target compounds, which were assayed in binding experiments and electrophysiological, functional and Erk1/2 activation tests, essentially combined the pharmacological profiles of their individual receptor ligands. Among the studied derivatives, hybrid 2, one of the shortest homologs, in addition to the antagonist nicotinic profile similar to the other three congeners, behaved as a high affinity ligand at the investigated heteromeric nAChRs and as a low efficacy agonist at D2Rs. These bifunctional derivatives represent novel pharmacological tools in the study of nicotine addiction.