Newcombe J , Chatzidaki A , Sheppard TD , Topf M , Millar NS .

Wellcome Trust , 105345/Z/14/Z Wellcome Trust , G1001602 Medical Research Council , MR/M019292/1 Medical Research Council , G0600084 Medical Research Council

	Fig. 1. Chemical structures of α7 nAChR PAMs and nAChR mutations. (A) The structure of the three compounds examined by electrophysiological techniques are shown (A-867744, TBS-516, and TQS). In addition, a larger group of PAMs with close chemical similarity to these three compounds (7 compounds similar to A-867744, 3 similar to TBS-516, and 24 similar to TQS) were selected for computer docking studies. Details of the chemical structure of all 37 compounds selected for docking studies is provided in Supplemental Table 1. (B) Location of α7 nAChR amino acids examined by site-directed mutagenesis. Mutated amino acids are indicated as spheres and correspond to W54 (coral), S222 (green), L247 (blue), M253 (yellow), and M260 (red).
	Fig. 2. Competition radioligand binding. Equilibrium radioligand binding was performed with [3H]-α-BTX (1 nM) in human kidney tsA201 cells expressing α7 nAChRs. A-867744 (3 nM to 30 μM) caused no significant displacement of [3H]-α-BTX binding, whereas the orthosteric antagonist MLA caused complete displacement of specific radioligand binding. Data points are means of triplicate samples (±S.E.M.) from a single experiment, and data are typical of three independent experiments.
	Fig. 3. Allosteric modulation of α7M260L by A-867744, TBS-516, and TQS. Mutated α7M260L nAChRs were expressed in Xenopus oocytes and examined by two-electrode voltage-clamp recording. (A) Concentration-response data illustrating agonist activation by TBS-516 and TQS but the absence of agonist activity with A-867744. Data are the mean ± S.E.M. of three independent experiments, each from different oocytes. Data are normalized to the maximum acetylcholine response. (B) Representative traces illustrating responses to acetylcholine (100 μM; left) together with acetylcholine responses from the same oocyte after preapplication (10 seconds) and coapplication of A-867744 (1 μM; right). (C) Representative traces illustrating responses to TQS (30 μM; left) together with TQS responses from the same oocyte after preapplication (10 seconds) and coapplication of A-867744 (1 μM; right). (D) Representative traces illustrating responses to TBS-516 (10 μM; left) together with TBS-516 responses from the same oocyte after preapplication (10 seconds) and coapplication of A-867744 (1 μM; right).
	Fig. 4. Allosteric modulation of α7L247T by A-867744, TBS-516, and TQS. Mutated α7L247T nAChRs were expressed in Xenopus oocytes and examined by two-electrode voltage-clamp recording. (A) Concentration-response data illustrating agonist activation by TBS-516 and TQS but the absence of agonist activity with A-867744. Data are the mean ± S.E.M. of three independent experiments, each from different oocytes. Data are normalized to the maximum acetylcholine response. (B) Representative traces illustrating responses to acetylcholine (10 μM; left) together with acetylcholine responses from the same oocyte after preapplication (10 seconds) and coapplication of A-867744 (1 μM; right). (C) Representative traces illustrating responses to TQS (10 μM; left) together with TQS responses from the same oocyte after preapplication (10 seconds) and coapplication of A-867744 (1 μM; right). (D) Representative traces illustrating responses to TBS-516 (10 μM; left) together with TBS-516 responses from the same oocyte after preapplication (10 seconds) and coapplication of A-867744 (1 μM; right).
	Fig. 5. Allosteric modulation of α7M253L by A-867744, TBS-516, and TQS. Mutated α7M253L nAChRs were expressed in Xenopus oocytes and examined by two-electrode voltage-clamp recording. (A) Representative traces illustrating responses to acetylcholine (100 μM; left), acetylcholine responses after preapplication (10 seconds) and coapplication of TQS (10 μM; middle), and response to acetylcholine after washing (right). (B) Representative traces illustrating responses to acetylcholine (100 μM; left), acetylcholine responses after preapplication (10 seconds) and coapplication of TBS-516 (10 μM; middle), and response to acetylcholine after washing (right). (C) Representative traces illustrating responses to acetylcholine (100 μM; left), and block of acetylcholine responses after preapplication (10 seconds) and coapplication of A-867744 (1 μM; middle). The acetylcholine response did not recover, even after a prolonged (10 minutes) wash (right). (D) Representative traces illustrating responses to acetylcholine (100 μM; left) and after preapplication of TQS (10 seconds), preapplication of A-867744 and TQS (5 seconds), and then coapplication of A-867744 (1 μM) and TQS (10 μM) (middle). TQS was preapplied for 10 seconds and A-867744 for 5 seconds. The acetylcholine response did not recover, even after a prolonged (10 minutes) wash (right). (E) Concentration-response data illustrating inhibition by A-867744 of responses to acetylcholine (100 μM). Data are the mean ± S.E.M. of four independent experiments, each from different oocytes.
	Fig. 6. Allosteric modulation of α7S222M by A-867744, TBS-516, and TQS. Mutated α7S222M nAChRs were expressed in Xenopus oocytes and examined by two-electrode voltage-clamp recording. (A) Representative traces illustrating responses to acetylcholine (100 μM; left), acetylcholine responses after preapplication (10 seconds) and coapplication of TQS (10 μM; middle), and response to acetylcholine after washing (right). (B) Representative traces illustrating responses to acetylcholine (100 μM; left), acetylcholine responses after preapplication (10 seconds) and coapplication of TBS-516 (10 μM; middle), and response to acetylcholine after washing (right). (C) Representative traces illustrating responses to acetylcholine (100 μM; left), block of acetylcholine responses after preapplication (10 seconds) and coapplication of A-867744 (1 μM; middle), and response to acetylcholine after washing (right). (D) Agonist concentration-response curve for acetylcholine in the absence and presence of A-867744 (1.5 μM; preapplied for 10 seconds and then coapplied with acetylcholine). Data are the mean ± S.E.M. of at least three independent experiments and are normalized to the maximum response obtained with ACh in the absence of A-867744. (E) When A-867744 was preapplied and coapplied with acetylcholine, positive modulatory effects (a reduction in agonist-evoked desensitization) was associated with a reduction in peak agonist responses.
	Fig. 7. Allosteric modulation of α7W54A by A-867744, TBS-516, and TQS. Mutated α7W54A nAChRs were expressed in Xenopus oocytes and examined by two-electrode voltage-clamp recording. (A) Concentration-response data illustrating agonist activation by TBS-516 and TQS but the absence of agonist activity with A-867744. Data are the mean ± S.E.M. of three independent experiments, each from different oocytes. Data are normalized to the maximum acetylcholine response. (B) Representative traces illustrating responses to acetylcholine (100 μM; left) together with acetylcholine responses from the same oocyte after preapplication (10 seconds) and coapplication of A-867744 (1 μM; right). (C) Representative traces illustrating responses to TQS (10 μM; left) together with TQS responses from the same oocyte after preapplication (10 seconds) and coapplication of A-867744 (1 μM; right). (D) Representative traces illustrating responses to TBS-516 (10 μM; left) together with TBS-516 responses from the same oocyte after preapplication (10 seconds) and coapplication of A-867744 (1 μM; right).
	Fig. 8. Refinement of the transmembrane domain of the Torpedo nAChR αγ subunit. (A) Sequence alignment and structural superposition of the TM1-TM2 loop region and TM2 helix of the Torpedo αγ subunit (PDB ID 2BG9; chain A) with that of the 5-HT3 receptor (PDB ID 4PIR; chain A) and GLIC (PDB ID 4HFI; chain A). As has been described previously (Supplemental Fig. 21 in Hibbs and Gouaux, 2011), amino acids from the TM1-TM2 loop of the Torpedo nAChR (e.g., Y234) superpose well with homologous amino acids from other pLGIC structures (C239 of 5-HT3R and W217 of GLIC; indicated by a straight line in the sequence alignment). In contrast, amino acids within the nAChR TM2 domain are out of register by ∼1 turn of the α-helix when compared with other pLGIC structures (e.g., compare E262 of the nAChR structure with D267 of 5-HT3R and T241 of GLIC; indicated by an angled line in the sequence alignment). (B) Alignment of amino acid sequence of the β10 strand and TM1 helix of Torpedo nAChR α subunit with that of related pLGICs (top panel). Also shown is the secondary structure before refinement (middle panel) and after refinement (bottom panel) of the Torpedo nAChR structure. Structural information is derived from the following PDB files: nAChR (2BG9; chain A), 5-HT3 receptor (4PIR; chain A), GABAA receptor (4COF; chain A), glycine receptor (3JAD; chain A), and GLIC (4HFI; chain A). Arrows denote β-strands, spirals denote α-helices, conserved residues are highlighted with white text on a red background, and residues with similar properties are highlighted with red text on a white background.
	Fig. 9. Docking of A-867744, TBS-516, and TQS and into α7 structural models. After docking studies with the closed and open models (top and bottom panels, respectively), representatives of binding mode clusters are illustrated for A-867744 (A and D; purple). TBS-516 (B and E; orange), and TQS (C and F; cyan). Amino acids that are discussed in the text are shown in stick representation. Predicted hydrogen bonds are shown with dashed lines. In each case, the principal subunit is shown in khaki (on the left in each panel) and the complimentary subunit is shown in olive (on the right in each panel).
	Fig. 10. Intersubunit transmembrane binding site for PAMs on the α7 nAChR. (A) Representation of the transmembrane domain viewed from above, looking down the axis of the channel pore. Black ellipses indicate the location of the intersubunit allosteric binding site identified in this study. (B) Predicted binding modes in the closed and open receptor models of A-867744 (purple), TBS-516 (orange), and TQS (cyan), shown in relation to transmembrane helices (gray rods) from the principal (+) and the complementary (−) subunit interface. The locations of predicted hydrogen bonds are shown with chain links to denote anchoring of the ligands within the binding site. The locations of amino acids M253, L247, and S222 are shown as yellow, blue, and green circles, respectively. An arrow at the top of TM2 from the complementary subunit denotes the motion required for the change in conformation from the open to the closed channel.

Allen, Implementation of the Hungarian algorithm to account for ligand symmetry and similarity in structure-based design. 2014, Pubmed

Allen, Implementation of the Hungarian algorithm to account for ligand symmetry and similarity in structure-based design. 2014, Pubmed
Althoff, X-ray structures of GluCl in apo states reveal a gating mechanism of Cys-loop receptors. 2014, Pubmed
Anderson, [3H]A-585539 [(1S,4S)-2,2-dimethyl-5-(6-phenylpyridazin-3-yl)-5-aza-2-azoniabicyclo[2.2.1]heptane], a novel high-affinity alpha7 neuronal nicotinic receptor agonist: radioligand binding characterization to rat and human brain. 2008, Pubmed
Barron, An allosteric modulator of alpha7 nicotinic receptors, N-(5-Chloro-2,4-dimethoxyphenyl)-N'-(5-methyl-3-isoxazolyl)-urea (PNU-120596), causes conformational changes in the extracellular ligand binding domain similar to those caused by acetylcholine. 2009, Pubmed , Xenbase
Bertrand, Paradoxical allosteric effects of competitive inhibitors on neuronal alpha7 nicotinic receptor mutants. 1997, Pubmed , Xenbase
Bertrand, Allosteric modulation of nicotinic acetylcholine receptors. 2007, Pubmed
Bertrand, Unconventional pharmacology of a neuronal nicotinic receptor mutated in the channel domain. 1992, Pubmed , Xenbase
Broadbent, Incorporation of the beta3 subunit has a dominant-negative effect on the function of recombinant central-type neuronal nicotinic receptors. 2006, Pubmed , Xenbase
Calimet, A gating mechanism of pentameric ligand-gated ion channels. 2013, Pubmed
Chatzidaki, Allosteric modulation of nicotinic acetylcholine receptors. 2015, Pubmed
Chatzidaki, The influence of allosteric modulators and transmembrane mutations on desensitisation and activation of α7 nicotinic acetylcholine receptors. 2015, Pubmed , Xenbase
Chen, MolProbity: all-atom structure validation for macromolecular crystallography. 2010, Pubmed
Collins, Competitive binding at a nicotinic receptor transmembrane site of two α7-selective positive allosteric modulators with differing effects on agonist-evoked desensitization. 2011, Pubmed , Xenbase
Cooper, Host cell-specific folding of the neuronal nicotinic receptor alpha8 subunit. 1998, Pubmed , Xenbase
Corringer, Atomic structure and dynamics of pentameric ligand-gated ion channels: new insight from bacterial homologues. 2010, Pubmed
Couturier, A neuronal nicotinic acetylcholine receptor subunit (alpha 7) is developmentally regulated and forms a homo-oligomeric channel blocked by alpha-BTX. 1990, Pubmed , Xenbase
Du, Glycine receptor mechanism elucidated by electron cryo-microscopy. 2015, Pubmed
Faghih, Discovery of 4-(5-(4-chlorophenyl)-2-methyl-3-propionyl-1H-pyrrol-1-yl)benzenesulfonamide (A-867744) as a novel positive allosteric modulator of the alpha7 nicotinic acetylcholine receptor. 2009, Pubmed , Xenbase
Faghih, Allosteric modulators of the alpha7 nicotinic acetylcholine receptor. 2008, Pubmed
Farabella, TEMPy: a Python library for assessment of three-dimensional electron microscopy density fits. 2015, Pubmed
Gielen, The desensitization gate of inhibitory Cys-loop receptors. 2015, Pubmed , Xenbase
Gill, Agonist activation of alpha7 nicotinic acetylcholine receptors via an allosteric transmembrane site. 2011, Pubmed , Xenbase
Gill, A series of α7 nicotinic acetylcholine receptor allosteric modulators with close chemical similarity but diverse pharmacological properties. 2012, Pubmed , Xenbase
Gill-Thind, Structurally similar allosteric modulators of α7 nicotinic acetylcholine receptors exhibit five distinct pharmacological effects. 2015, Pubmed , Xenbase
Grønlien, Distinct profiles of alpha7 nAChR positive allosteric modulation revealed by structurally diverse chemotypes. 2007, Pubmed , Xenbase
Hamouda, Multiple transmembrane binding sites for p-trifluoromethyldiazirinyl-etomidate, a photoreactive Torpedo nicotinic acetylcholine receptor allosteric inhibitor. 2011, Pubmed
Haydar, Neuronal nicotinic acetylcholine receptors - targets for the development of drugs to treat cognitive impairment associated with schizophrenia and Alzheimer's disease. 2010, Pubmed
Hibbs, Principles of activation and permeation in an anion-selective Cys-loop receptor. 2011, Pubmed
Houston, Consensus docking: improving the reliability of docking in a virtual screening context. 2013, Pubmed
Hurst, Nicotinic acetylcholine receptors: from basic science to therapeutics. 2013, Pubmed
Joseph, Refinement of atomic models in high resolution EM reconstructions using Flex-EM and local assessment. 2016, Pubmed
Krissinel, Inference of macromolecular assemblies from crystalline state. 2007, Pubmed
Lansdell, Molecular characterization of Dalpha6 and Dalpha7 nicotinic acetylcholine receptor subunits from Drosophila: formation of a high-affinity alpha-bungarotoxin binding site revealed by expression of subunit chimeras. 2004, Pubmed
Lansdell, RIC-3 enhances functional expression of multiple nicotinic acetylcholine receptor subtypes in mammalian cells. 2005, Pubmed , Xenbase
Lester, Cys-loop receptors: new twists and turns. 2004, Pubmed
Lopéz-Blanco, iMODFIT: efficient and robust flexible fitting based on vibrational analysis in internal coordinates. 2013, Pubmed
Malysz, Evaluation of alpha7 nicotinic acetylcholine receptor agonists and positive allosteric modulators using the parallel oocyte electrophysiology test station. 2009, Pubmed , Xenbase
Malysz, In vitro pharmacological characterization of a novel allosteric modulator of alpha 7 neuronal acetylcholine receptor, 4-(5-(4-chlorophenyl)-2-methyl-3-propionyl-1H-pyrrol-1-yl)benzenesulfonamide (A-867744), exhibiting unique pharmacological profile. 2009, Pubmed , Xenbase
Mnatsakanyan, Experimental determination of the vertical alignment between the second and third transmembrane segments of muscle nicotinic acetylcholine receptors. 2013, Pubmed , Xenbase
Morales-Perez, X-ray structure of the human α4β2 nicotinic receptor. 2016, Pubmed
Mowrey, Insights into distinct modulation of α7 and α7β2 nicotinic acetylcholine receptors by the volatile anesthetic isoflurane. 2013, Pubmed
Nirthanan, Identification of binding sites in the nicotinic acetylcholine receptor for TDBzl-etomidate, a photoreactive positive allosteric effector. 2008, Pubmed
Palma, Threonine-for-leucine mutation within domain M2 of the neuronal alpha(7) nicotinic receptor converts 5-hydroxytryptamine from antagonist to agonist. 1996, Pubmed , Xenbase
Pandurangan, RIBFIND: a web server for identifying rigid bodies in protein structures and to aid flexible fitting into cryo EM maps. 2012, Pubmed
Papke, The activity of GAT107, an allosteric activator and positive modulator of α7 nicotinic acetylcholine receptors (nAChR), is regulated by aromatic amino acids that span the subunit interface. 2014, Pubmed , Xenbase
Parri, Research update: Alpha7 nicotinic acetylcholine receptor mechanisms in Alzheimer's disease. 2011, Pubmed
Pellegrini-Calace, PoreWalker: a novel tool for the identification and characterization of channels in transmembrane proteins from their three-dimensional structure. 2009, Pubmed
Pettersen, UCSF Chimera--a visualization system for exploratory research and analysis. 2004, Pubmed
Revah, Mutations in the channel domain alter desensitization of a neuronal nicotinic receptor. 1991, Pubmed , Xenbase
Sali, Comparative protein modelling by satisfaction of spatial restraints. 1993, Pubmed
Shen, Statistical potential for assessment and prediction of protein structures. 2006, Pubmed
Studer, Assessing the local structural quality of transmembrane protein models using statistical potentials (QMEANBrane). 2014, Pubmed
Topf, Protein structure fitting and refinement guided by cryo-EM density. 2008, Pubmed
Trott, AutoDock Vina: improving the speed and accuracy of docking with a new scoring function, efficient optimization, and multithreading. 2010, Pubmed
Unwin, Refined structure of the nicotinic acetylcholine receptor at 4A resolution. 2005, Pubmed
Unwin, Gating movement of acetylcholine receptor caught by plunge-freezing. 2012, Pubmed
Verdonk, Improved protein-ligand docking using GOLD. 2003, Pubmed
Wang, Comprehensive evaluation of ten docking programs on a diverse set of protein-ligand complexes: the prediction accuracy of sampling power and scoring power. 2016, Pubmed
Williams, Positive allosteric modulators as an approach to nicotinic acetylcholine receptor-targeted therapeutics: advantages and limitations. 2011, Pubmed
Young, Species selectivity of a nicotinic acetylcholine receptor agonist is conferred by two adjacent extracellular beta4 amino acids that are implicated in the coupling of binding to channel gating. 2007, Pubmed
Young, Potentiation of alpha7 nicotinic acetylcholine receptors via an allosteric transmembrane site. 2008, Pubmed , Xenbase