To understand how snake neurotoxins interact with nicotinic acetylcholine receptors, we have elaborated an experimentally based model of the ␣-cobratoxin-␣7 receptor complex. This model was achieved by using (i) a three-dimensional model of the ␣7 extracellular domain derived from the crystallographic structure of the homologous acetylcholine-binding protein, (ii) the previously solved x-ray structure of the toxin, and (iii) nine pairs of residues identified by cycle-mutant experiments to make contacts between the ␣-cobratoxin and ␣7 receptor. Because the receptor loop F occludes entrance of the toxin binding pocket, we submitted this loop to a dynamics simulation and selected a conformation that allowed the toxin to reach its binding site. T he ␣-neurotoxins from snake venom are potent antagonists that block nicotinic acetylcholine receptors (AChRs) and hence affect synaptic transmission (1-3). Despite many studies (reviewed in ref. 4), the molecular process associated with this efficient blockage remains unclear. To approach this question, we previously studied ␣-cobratoxin (␣-Cbtx), an ␣͞K neurotoxin that binds to both muscular and homopentameric neuronal receptors (␣7 and ␣8) with high affinities (4). This toxin, similar to other snake neurotoxins, is folded into three adjacent loops rich in -sheet that emerge from a small globular core in which four disulfide bonds are located (5). By mutational analyses, the residues by which ␣-Cbtx interacts with the muscular-type or neuronal ␣7 receptors were identified previously (6, 7). The present study shows how functional residues account for the antagonistic properties of the toxin toward the ␣7 neuronal receptor. The ␣7 AChR possesses five identical ␣7 subunits (8) that offer five ligand-binding sites located at the interface of two subunits (9). These sites include residues located on the different functional loops described previously on the principal ␣7 (ϩ) face, loops A, B, and C and on the complementary ␣7 (Ϫ) face, loops D, E, and F (refs. 10-13; see Fig. 1). Until now, the residues of the ␣7 receptor involved in snake toxin binding have remained unknown.The aim of the present paper is fourfold. First, by an extensive mutational study we have identified ␣7 receptor residues involved in the interaction with ␣-Cbtx. Second, by using a double-mutant cycle approach we have disclosed several pairs of interacting residues in the toxin-receptor complex. Third, by using the three-dimensional (3D) structure of an AChBP that is similar functionally and structurally to the N-terminal domain of an AChR ␣-subunit (14), we used a 3D model for the ␣7 subunit extracellular region obtained by comparative modeling [see accompanying paper on page 3210 (15)]. Fourth, by using this model, a molecular dynamics simulation of the loop F region, and the constraints derived from our pairwise analysis, we propose an experimentally based 3D model of the complex between the ␣-Cbtx and ␣7 receptor, which explains the antagonistic properties of the snake toxin toward the neuronal recepto...
