Activation of the Torpedo nicotinic acetylcholine receptor. The contribution of residues alphaArg55 and gammaGlu93

The Torpedo nicotinic acetylcholine receptor is a heteropentamer (alpha2betagammadelta) in which structurally homologous subunits assemble to form a central ion pore. Viewed from the synaptic cleft, the likely arrangement of these subunits is alpha-gamma-alpha-delta-beta lying in an anticlockwise orientation. High affinity binding sites for agonists and competitive antagonists have been localized to the alpha-gamma and alpha-delta subunit interfaces. We investigated the involvement of amino acids lying at an adjacent interface (gamma-alpha) in receptor properties. Recombinant Torpedo receptors, expressed in Xenopus oocytes, were used to investigate the consequences of mutating alphaArg55 and gammaGlu93, residues that are conserved in most species of the peripheral nicotinic receptors. Based on homology modeling, these residues are predicted to lie in close proximity to one another and it has been suggested that they may form a salt bridge in the receptor's three-dimensional structure (Sine et al. 2002 J Biol Chem277, 29 210-29 223). Although substitution of alphaR55 by phenylalanine or tryptophan resulted in approximately a six-fold increase in the EC50 value for acetylcholine activation, the charge reversal mutation (alphaR55E) had no significant effect. In contrast, the replacement of gammaE93 by an arginine conferred an eight-fold increase in the potency for acetylcholine-induced receptor activation. In the receptor carrying the double mutations, alphaR55E-gammaE93R or alphaR55F-gammaE93R, the potency for acetylcholine activation was partially restored to that of the wild-type. The results suggest that, although individually these residues influence receptor activation, direct interactions between them are unlikely to play a major role in the stabilization of different conformational states of the receptor.