Amino acid residues that confer high selectivity of the alpha6 nicotinic acetylcholine receptor subunit to alpha-conotoxin MII[S4A,E11A,L15A].

Nicotinic acetylcholine receptors (nAChRs) containing alpha3 and beta2 subunits are found in autonomic ganglia and mediate ganglionic transmission. The closely related alpha6 nAChR subtype is found in the central nervous system where changes in its level of expression are observed in Parkinson's disease. To obtain a ligand that discriminates between these two receptors, we designed and synthesized a novel analog ofalpha-conotoxin MII, MII[S4A,E11A,L15A], and tested it on nAChRs expressed in Xenopus oocytes. The peptide blocked chimeric alpha6/alpha3beta2beta3 nAChRs with an IC(50) of 1.2 nm; in contrast, its IC(50) on the closely related alpha3beta2 as well as non-alpha6 nAChRs was three orders of magnitude higher. We identified the residues in the receptors that are responsible for their differential sensitivity to the peptide. We constructed chimeras with increasingly longer fragments of the N-terminal ligand binding domain of the alpha3 subunit inserted into the homologous positions of the alpha6 subunit, and these were used to determine that the region downstream of the first 140 amino acids was involved. Further mutagenesis of this region revealed that the alpha6 subunit residues Glu-152, Asp-184, and Thr-195 were critical, and replacement of these three residues with their homologs from the alpha3 subunit increased the IC(50) of the peptide by >1000-fold. Conversely, when these key residues inalpha3 were replaced with those fromalpha6, the IC(50) decreased by almost 150-fold. Similar effects were seen with other alpha6-selective conotoxins, suggesting the general importance of thesealpha6 residues in conferring selective binding.