Crystal structure of a Cbtx–AChBP complex reveals essential interactions between snake α-neurotoxins and nicotinic receptors

Bourne, Yves; Talley, Todd T.; Hansen, Scott B.; Taylor, Palmer; Marchot, Pierre

doi:10.1038/sj.emboj.7600620

Cited by 298 publications

(304 citation statements)

References 55 publications

(107 reference statements)

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“…The structural basis for coupling between motions in the neurotransmitter-binding domain and pore gating is still largely unknown (18)(19)(20). The distinct activitydependent orientations of the M2 segments and the superposition of the closed-over the open-pore model provide further insights into principal gating motions.…”

Section: Functional and Structural Implications Of The Off-response Cmentioning

confidence: 99%

Pore conformations and gating mechanism of a Cys-loop receptor

Paas

Gibor

Grailhe

et al. 2005

Proc. Natl. Acad. Sci. U.S.A.

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Section: Functional and Structural Implications Of The Off-response Cmentioning

confidence: 99%

Pore conformations and gating mechanism of a Cys-loop receptor

Paas

Gibor

Grailhe

et al. 2005

Proc. Natl. Acad. Sci. U.S.A.

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“…Such interactions are evident in the crystal structures of acetylcholine, carbamylcholine, and other quaternary complexes (16,18), and the energetics have been established through mutagenesis studies modifying the polarizability, and electronegativity of the aromatic side chains in the binding pocket (28,29); (ii) secondary and tertiary amines (19)(20)(21) and imines (21), which, when in a protonated state, hydrogen bond to the backbone carbonyl of W143. The protonated dihydropyridine-bound state for the benzylidene anabaseines has been demonstrated by difference spectroscopy (30); and (iii) peptides, such as the α-conotoxins and α-neurotoxins, stabilized by multiple interactions on the C loop and interfacial residues on both the principal and complementary faces (31)(32)(33)(34). The binding interactions of the 2-aminopyrimidines do not appear to follow the above patterns and therefore these structures constitute a distinct fourth group of ligands.…”

Section: Discussionmentioning

confidence: 99%

Structural basis for cooperative interactions of substituted 2-aminopyrimidines with the acetylcholine binding protein

Kaczanowska

Harel

Radić

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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The nicotinic acetylcholine receptor (nAChR) and the acetylcholine binding protein (AChBP) are pentameric oligomers in which binding sites for nicotinic agonists and competitive antagonists are found at selected subunit interfaces. The nAChR spontaneously exists in multiple conformations associated with its activation and desensitization steps, and conformations are selectively stabilized by binding of agonists and antagonists. In the nAChR, agonist binding and the associated conformational changes accompanying activation and desensitization are cooperative. AChBP, which lacks the transmembrane spanning and cytoplasmic domains, serves as a homology model of the extracellular domain of the nAChRs. We identified unique cooperative binding behavior of a number of 4,6-disubstituted 2-aminopyrimidines to Lymnaea AChBP, with different molecular variants exhibiting positive, n H > 1.0, and negative cooperativity, n H < 1.0. Therefore, for a distinctive set of ligands, the extracellular domain of a nAChR surrogate suffices to accommodate cooperative interactions. X-ray crystal structures of AChBP complexes with examples of each allowed the identification of structural features in the ligands that confer differences in cooperative behavior. Both sets of molecules bind at the agonist-antagonist site, as expected from their competition with epibatidine. An analysis of AChBP quaternary structure shows that cooperative ligand binding is associated with a blooming or flare conformation, a structural change not observed with the classical, noncooperative, nicotinic ligands. Positively and negatively cooperative ligands exhibited unique features in the detailed binding determinants and poses of the complexes.allostery | crystallography | nicotinic receptor

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“…Several structures of agonist (epibatidine, nicotine, lobeline, carbamylcholine) and antagonist (α-conotoxin, methyllycaconitine, α-bungarotoxin) bound to AChBP have been reported [6,[9][10][11][12], and other structures have been resolved at high resolution or are under study. Hence, one now has a fairly comprehensive perspective on structures of the AChBP complexes.…”

Section: Crystal Structures Of Competitive Agonists and Antagonistsmentioning

confidence: 99%

“…Hence, agonists have the requisite flexibility and steric features to allow C loop closure. Antagonists appear to keep the C loop in its open position or extend the C loop in a more radial direction [9,11].…”

Section: Crystal Structures Of Competitive Agonists and Antagonistsmentioning

confidence: 99%

Structure-guided drug design: Conferring selectivity among neuronal nicotinic receptor and acetylcholine-binding protein subtypes

Taylor

Talley

Radić

et al. 2007

Biochemical Pharmacology

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Neuronal nicotinic receptors, encoded by nine genes of the alpha and three of the beta type of subunits, and whose gene products assemble in distinct permutations as pentameric molecules, constitute a fertile area for structure-guided drug design. Design strategies are augmented by a wide variety of peptide, alkaloid and terpenoid toxins from various marine and terrestrial species that interact with nicotinic receptors. Also, acetylcholinebinding proteins from mollusks, as structural surrogates of the receptor that mimic its extracellular domain, provide atomic resolution templates for analysis of structure and response. Herein, we describe a structure-guided approach to nicotinic ligand design that employs crystallography of this protein as the basic template, but also takes into consideration the dynamic properties of the receptor molecules in their biological media. We present the crystallographic structures of several complexes of various agonists and antagonists that associate with the agonist site and can competitively block the action of acetylcholine. In so far as the extracellular domain is involved, we identify additional noncompetitive sites at those subunit interfaces where agonists do not preferentially bind. Ligand association at these interface sites may modulate receptor function. Ligand binding is also shown by solution-based spectroscopic and spectrometric methods to affect the dynamics of discrete domains of the receptor molecule. The surrogate receptor molecules can then be employed to design ligands selective for receptor subtype through the novel methods of freeze-frame, click chemistry that uses the very structure of the target molecule as a template for synthesis of the inhibitor.

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Crystal structure of a Cbtx–AChBP complex reveals essential interactions between snake α-neurotoxins and nicotinic receptors

Cited by 298 publications

References 55 publications

Pore conformations and gating mechanism of a Cys-loop receptor

Pore conformations and gating mechanism of a Cys-loop receptor

Structural basis for cooperative interactions of substituted 2-aminopyrimidines with the acetylcholine binding protein

Structure-guided drug design: Conferring selectivity among neuronal nicotinic receptor and acetylcholine-binding protein subtypes

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