Modal shifts in acetylcholine receptor channel gating confer subunit-dependent desensitization

Structural basis of the different gating kinetics of fetal and adult acetylcholine receptors

Structure-function studies have identified key functional motifs in the acetylcholine receptor, including residues that contribute to the ion channel and to the ligand-binding sites. Little is known, however, about determinants of channel gating kinetics. To identify structural correlates of gating, we examined the structural basis of the fetal-to-adult decrease in channel open time conferred by the presence of the epsilon subunit in place of the gamma subunit. By constructing chimeras composed of segments of the epsilon and gamma subunits, we show that the main determinant of this kinetic change is a 30 residue segment of a predicted amphipathic helix located between transmembrane domains M3 and M4. Further subdividing the amphipathic helix revealed that either multiple residues or its overall conformation confers this regulation of channel kinetics. We also show that L440 and M442, conserved residues within M4 of the gamma subunit, contribute to long duration openings characteristic of the fetal receptor.

A cAMP-dependent Ca2+ signalling pathway at the endplate provided by the gamma to epsilon subunit switch in ACh receptors

During development of neuromuscular junctions there is a switch in the expression of acetylcholine receptors (AChR) from an embryonic form (gamma-AChR) to an adult form (epsilon-AChR). Studies with gamma- and epsilon-AChRs expressed in Xenopus oocytes showed that the gamma to epsilon subunit switch accelerates rates of desensitization and increases Ca2+ permeability. Site-directed mutagenesis of the gamma and epsilon subunits suggests that these changes are regulated by cAMP-dependent phosphorylation on the epsilon subunit. These results suggest that the gamma to epsilon subunit switch could provide for a cAMP-dependent Ca2+ signalling pathway at the endplate.

Sodium channel regulation in the nervous system: how the action potential keeps in shape

Multiple Na+ channel types, differing in functional properties, have been identified in the nervous system. The role of distinct alpha subunits in generating this functional diversity is discussed in light of the recent finding that the beta 1 subunit modulates Na+ channel function. Possible mechanisms involved in the regulation of the genes coding for the different subunits are also discussed.