Linking the Acetylcholine Receptor-Channel Agonist-Binding Sites with the Gate

Abstract

The gating isomerization of neuromuscular acetylcholine receptors links the rearrangements of atoms at two transmitter-binding sites with those at a distant gate region in the pore. To explore the mechanism of this reversible process, we estimated the gating rate and equilibrium constants for receptors with point mutations of α-subunit residues located between the binding sites and the membrane domain (N95, A96, Y127, and I49). The maximum energy change caused by a side-chain substitution at αA96 was huge (∼8.6 kcal/mol, the largest value measured so far for any α-subunit amino acid). A Φ-value analysis suggests that αA96 experiences its change in energy (structure) approximately synchronously with residues αY127 and αI49, but after the agonist molecule and other residues in loop A. Double mutant-cycle experiments show that the energy changes at αA96 are strongly coupled with those of αY127 and αI49. We identify a column of mutation-sensitive residues in the α-subunit that may be a pathway for energy transfer through the extracellular domain in the gating isomerization.