Homologous mutations on different subunits cause unequal but additive effects on n-alcohol block in the nicotinic receptor pore.

Hydrophobic antagonists of the nicotinic acetylcholine receptor inhibit channel activity by binding within the transmembrane pore formed by the second of four transmembrane domains (M2) on each of the receptor's subunits. Hydrophobic mutagenesis near the middle (10' locus) of the alpha-subunit M2 domain results in channels that are much more sensitive to block by long-chain alcohols and general anesthetics, indicating that the inhibitory site on wild-type receptors is nearby. To determine whether other receptor subunits also contribute to the blocker site, the hydrophobic mutagenesis strategy was extended to all four subunits at 10' loci. alpha S10'l causes the largest increase in apparent hexanol binding (4.3-fold compared to wild type), approximately twice the size of the change caused by beta T10'l (2.2-fold). gamma A10'l and delta A10'l mutations cause much smaller changes in apparent hexanol binding affinity (about 1.2-fold each), even when corrected for their smaller degree of side-chain hydrophobicity changes. When 10'l mutant subunits are coexpressed, the change from wild type in apparent hexanol binding energy (delta delta Gmixture) is roughly equal to the sum of hexanol binding energy changes for the constituent mutant subunits (sigma delta delta Gsubunits). The simplest model consistent with these results is one in which hydrophobic blockers make simultaneous contact with all five M2 10' residues, but the extent of contact is much greater for the alpha and beta than for gamma and delta side chains.