Abstract
Transmitter molecules bind to synaptic acetylcholine receptor channels (AChRs) to promote a global channel-opening conformational change. Although the detailed mechanism that links ligand binding and channel gating is uncertain, the energy changes caused by mutations appear to be more symmetrical between subunits in the transmembrane domain compared with the extracellular domain. The only covalent connection between these domains is the pre-M1 linker, a stretch of five amino acids that joins strand β10 with the M1 helix. In each subunit, this linker has a central Arg (Arg(3')), which only in the non-α-subunits is flanked by positively charged residues. Previous studies showed that mutations of Arg(3') in the α-subunit alter the gating equilibrium constant and reduce channel expression. We recorded single-channel currents and estimated the gating rate and equilibrium constants of adult mouse AChRs with mutations at the pre-M1 linker and the nearby residue Glu(45) in non-α-subunits. In all subunits, mutations of Arg(3') had similar effects as in the α-subunit. In the ε-subunit, mutations of the flanking residues and Glu(45) had only small effects, and there was no energy coupling between εGlu(45) and εArg(3'). The non-α-subunit Arg(3') residues had Φ-values that were similar to those for the α-subunit. The results suggest that there is a general symmetry between the AChR subunits during gating isomerization in this linker and that the central Arg is involved in expression more so than gating. The energy transfer through the AChR during gating appears to mainly involve Glu(45), but only in the α-subunits.
Highlights
Grant NS-23513. 1 To whom correspondence should be addressed: Dept. of Physiology and Biophysics, State University of New York at Buffalo, 309 Cary Hall, Buffalo, NY 14214
Several structures have revealed important features that are relevant to understanding the mechanism of energy transfer through the protein in the gating isomerization, including the Torpedo acetylcholine receptor channels (AChRs) [4], two prokaryotic pentameric ligand-gated ion channels crystallized in either a non-conducting (ELIC) [5] or a presumably conducting conformation (GLIC) [6, 7], an extracellular domain (ECD) fragment of the mouse AChR ␣-subunit [8], and the ECD homolog, the acetylcholine-binding protein [9]
A comparison of the ELIC and GLIC x-ray structures suggests that the porelining M2 helices tilt tangentially and radially as part of the channel-opening process [6, 7]
Summary
Mutagenesis and Expression—A detailed description of our methods is described by Jha et al [27]. The pipette solution contained 0.5 mM acetylcholine, 20 mM choline, or 5 mM carbamylcholine These agonist concentrations are approximately five times the corresponding equilibrium dissociation constants (Kd); almost all currents arose from diliganded AChRs. Because the mutations were far from the binding site, we assumed that they did not change Kd. The high concentration of agonist caused partial channel block, which decreases both the apparent single-channel current amplitude and the apparent closing rate constant. Choline was used to measure the diliganded opening rate constant for AChR mutants where E2 was larger than or equal to the WT; acetylcholine was used for mutants where E2 was less than the WT; and carbamylcholine was used to measure mutants where E2 was approximately equal to the WT It has been shown for many non-binding site mutations that different agonists support the same ⌽-values and fold-changes in E2 [21]. The coupling free energy was calculated as ⌬⌬G (kcal/mol) ϭ Ϫ0.59 ln((Edouble mutant)/(Emutant 1*Emutant 2))
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