Stoichiometry for α-bungarotoxin block of α7 acetylcholine receptors.

α-Bungarotoxin (α-Btx) binds to the five agonist binding sites on the homopentameric α7-acetylcholine receptor, yet the number of bound α-Btx molecules required to prevent agonist-induced channel opening remains unknown. To determine the stoichiometry for α-Btx blockade, we generate receptors comprised of wild-type and α-Btx-resistant subunits, tag one of the subunit types with conductance mutations to report subunit stoichiometry, and following incubation with α-Btx, monitor opening of individual receptor channels with defined subunit stoichiometry. We find that a single α-Btx-sensitive subunit confers nearly maximal suppression of channel opening, despite four binding sites remaining unoccupied by α-Btx and accessible to the agonist. Given structural evidence that α-Btx locks the agonist binding site in an inactive conformation, we conclude that the dominant mechanism of antagonism is non-competitive, originating from conformational arrest of the binding sites, and that the five α7 subunits are interdependent and maintain conformational symmetry in the open channel state.

Single-channel and structural foundations of neuronal α7 acetylcholine receptor potentiation.

Potentiation of neuronal nicotinic acetylcholine receptors by exogenous ligands is a promising strategy for treatment of neurological disorders including Alzheimer's disease and schizophrenia. To gain insight into molecular mechanisms underlying potentiation, we examined ACh-induced single-channel currents through the human neuronal α7 acetylcholine receptor in the presence of the α7-specific potentiator PNU-120596 (PNU). Compared to the unusually brief single-channel opening episodes elicited by agonist alone, channel opening episodes in the presence of agonist and PNU are dramatically prolonged. Dwell time analysis reveals that PNU introduces two novel components into open time histograms, indicating at least two degrees of PNU-induced potentiation. Openings of the longest potentiated class coalesce into clusters whose frequency and duration change over a narrow range of PNU concentration. At PNU concentrations approaching saturation, these clusters last up to several minutes, prolonging the submillisecond α7 opening episodes by several orders of magnitude. Mutations known to reduce PNU potentiation at the whole-cell level still give rise to multisecond-long single-channel clusters. However mutation of five residues lining a cavity within each subunit's transmembrane domain abolishes PNU potentiation, defining minimal structural determinants of PNU potentiation.

Binding to gating transduction in nicotinic receptors: Cys-loop energetically couples to pre-M1 and M2-M3 regions.

The nicotinic acetylcholine receptor (AChR) transduces binding of nerve-released ACh into opening of an intrinsic ion channel, yet the intraprotein interactions behind transduction remain to be fully elucidated. Attention has focused on the region of the AChR in which the beta1-beta2 and Cys-loops from the extracellular domain project into a cavity framed by residues preceding the first transmembrane domain (pre-M1) and the linker spanning transmembrane domains M2 and M3. Previous studies identified a principal transduction pathway in which the pre-M1 domain is coupled to the M2-M3 linker through the beta1-beta2 loop. Here we identify a parallel pathway in which the pre-M1 domain is coupled to the M2-M3 linker through the Cys-loop. Mutagenesis, single-channel kinetic analyses and thermodynamic mutant cycle analyses reveal energetic coupling among alphaLeu 210 from the pre-M1 domain, alphaPhe 135 and alphaPhe 137 from the Cys-loop, and alphaLeu 273 from the M2-M3 linker. Residues at equivalent positions of non-alpha-subunits show negligible coupling, indicating these interresidue couplings are specific to residues in the alpha-subunit. Thus, the extracellular beta1-beta2 and Cys-loops bridge the pre-M1 domain and M2-M3 linker to transduce agonist binding into channel gating.

Nicotinic receptor interloop proline anchors beta1-beta2 and Cys loops in coupling agonist binding to channel gating.

Nicotinic acetylcholine receptors (AChRs) mediate rapid excitatory synaptic transmission throughout the peripheral and central nervous systems. They transduce binding of nerve-released ACh into opening of an intrinsic channel, yet the structural basis underlying transduction is not fully understood. Previous studies revealed a principal transduction pathway in which alphaArg 209 of the pre-M1 domain and alphaGlu 45 of the beta1-beta2 loop functionally link the two regions, positioning alphaVal 46 of the beta1-beta2 loop in a cavity formed by alphaPro 272 through alphaSer 269 of the M2-M3 loop. Here we investigate contributions of residues within and proximal to this pathway using single-channel kinetic analysis, site-directed mutagenesis, and thermodynamic mutant cycle analysis. We find that in contributing to channel gating, alphaVal 46 and alphaVal 132 of the signature Cys loop couple energetically to alphaPro 272. Furthermore, these residues are optimized in both their size and hydrophobicity to mediate rapid and efficient channel gating, suggesting naturally occurring substitutions at these positions enable a diverse range of gating rate constants among the Cys-loop receptor superfamily. The overall results indicate that alphaPro 272 functionally couples to flanking Val residues extending from the beta1-beta2 and Cys loops within the ACh binding to channel opening transduction pathway.

Initial coupling of binding to gating mediated by conserved residues in the muscle nicotinic receptor.

We examined functional consequences of intrasubunit contacts in the nicotinic receptor alpha subunit using single channel kinetic analysis, site-directed mutagenesis, and structural modeling. At the periphery of the ACh binding site, our structural model shows that side chains of the conserved residues alphaK145, alphaD200, and alphaY190 converge to form putative electrostatic interactions. Structurally conservative mutations of each residue profoundly impair gating of the receptor channel, primarily by slowing the rate of channel opening. The combined mutations alphaD200N and alphaK145Q impair channel gating to the same extent as either single mutation, while alphaK145E counteracts the impaired gating due to alphaD200K, further suggesting electrostatic interaction between these residues. Interpreted in light of the crystal structure of acetylcholine binding protein (AChBP) with bound carbamylcholine (CCh), the results suggest in the absence of ACh, alphaK145 and alphaD200 form a salt bridge associated with the closed state of the channel. When ACh binds, alphaY190 moves toward the center of the binding cleft to stabilize the agonist, and its aromatic hydroxyl group approaches alphaK145, which in turn loosens its contact with alphaD200. The positional changes of alphaK145 and alphaD200 are proposed to initiate the cascade of perturbations that opens the receptor channel: the first perturbation is of beta-strand 7, which harbors alphaK145 and is part of the signature Cys-loop, and the second is of beta-strand 10, which harbors alphaD200 and connects to the M1 domain. Thus, interplay between these three conserved residues relays the initial conformational change from the ACh binding site toward the ion channel.