The alpha-conotoxins GI and MI distinguish between the nicotinic acetylcholine receptor agonist sites while SI does not.

The alpha-conotoxins are paralytic peptide toxins from Indo-Pacific cone snails. This paper presents a detailed analysis of how alpha-conotoxins inhibit [125I]-alpha-bungarotoxin (125I-BTX) equilibrium binding to the acetylcholine receptor (AChR) from electric organ of Torpedo californica and Torpedo nobiliana. All three alpha-conotoxins studied, SI, GI, and MI, completely inhibited 125I-BTX binding with the same order of potency in both species (MI approximately GI > SI approximately d-tubocurarine). BTX-concentration curves showed that this inhibition is competitive. However, while SI appeared to bind to a homogeneous population of sites, both GI and MI displayed curare-like heterogeneous binding. Studies using partially-blocked AChR demonstrated that both GI and MI display different affinities toward the two agonist sites, much like small curariform antagonists do. The high-affinity site for these two alpha-conotoxins is also the high-affinity d-tubocurarine site, which is believed to be located at the alpha gamma-subunit interface. The high-affinity binding of MI and GI was of the same order of magnitude as that of d-tubocurarine; however, their affinity for the other agonist site was somewhat greater than that of dTC, resulting in less site selectivity. Despite being homologous to GI and MI, SI did not distinguish between the two sites. A possible molecular basis for this difference is presented.