The MA Helix Is Important for Receptor Assembly and Function in the α4ß2 nACh Receptor.

Pentameric ligand-gated ion channels (pLGICs) are expressed throughout the central and peripheral nervous systems of vertebrates and modulate many aspects of human health and disease. Recent structural and computational data indicate that cation-selective pLGICs contain a long helical extension (MA) of one of the transmembrane helices. The MA helix has been shown to affect both the membrane expression of, and ion conductance levels through, these pLGICs. Here we probe the functional effects of 68 mutations in the MA region of the α4ß2 nicotinic acetylcholine receptor (nAChR), using a voltage-sensitive membrane dye and radioligand binding to measure receptor function and expression/assembly. We found seven alanine mutations in a stretch of the MA helix that prevent correct receptor folding and/or assembly, as evidenced by the lack of both function and ligand binding. A further two alanine mutations resulted in receptors that were capable of binding ligand but showed no functional response, and we propose that, in these mutants, ligand binding is insufficient to trigger channel opening. The data clarify the effect of the MA helix, and as the effects of some of our mutations in the α4ß2 nAChR differ from the effects of equivalent mutations in other cation-selective pLGICs, we suggest that residues in the MA helix may play subtly different roles in different receptors.

Residues in the 1st Transmembrane-Spanning Helix Are Important for GABAAρ Receptor Function.

GABAAρ receptors are a subfamily of the GABAA receptor family of pentameric ligand-gated ion channels (pLGICs). Each subunit has a common structure, including a transmembrane domain of four α-helices (M1-M4). The aim of this study was to identify important M1 residues in the GABAAρ receptor (GABAAρR), using mutagenesis and functional assays combined with bioinformatic approaches. Alanine substitution of 12 of the 23 M1 residues yielded receptors with altered functional parameters, indicating these residues contribute to GABAAρR function. Further mutations reveal the properties that are important for function in critical residues, and, using a GABAAρR homology model, we suggest amino acid interactions that could be important. Phylogenetic analysis comparing GABAAR and other pLGICs subunits reveals most M1 residue properties linked to GABAAρR function are ancestrally ancient, but some are more recent acquisitions. Multiple sequence alignment of M1 residues across GABAAR subunits reveal three residues are well conserved except in GABAAR α subunits. Substitution of ρ1 subunit residues to their α1 subunit equivalents showed one alters functional parameters. Overall, the data provide a comprehensive picture of M1 residues that contribute to GABAAρR function, and illustrate how they might do so.

5-HT3 Receptor MX Helix Contributes to Receptor Function.

5-HT3 receptors are members of the family of pentameric ligand-gated ion channels. Each subunit has an extracellular, transmembrane, and intracellular domain. Only part of the intracellular domain structure has been solved, revealing it contains two α-helical segments; one, the MA helix, is an extension of M4, while the other, the MX helix, is formed from residues located close to the end of M3. This MX helix is in distinct locations in open and closed receptor structures, suggesting it may play a role in function. Here, we explore this hypothesis using functional responses of Ala-substituted mutant receptors expressed in HEK293 cells. The data show altering many of the MX residues results in a small decrease in EC50 (up to 5-fold), although in one (H232A) this is increased. Radiolabeled ligand binding on selected mutants showed no change in binding affinity, indicating an effect on gating and not binding. In addition, five mutations (P316A, V317A, P318A, D319A, and H323A) initially resulted in nonfunctional receptors, but the function could be rescued by coexpression with a chaperone protein, suggesting a likely role in assembly or folding. Examination of previously obtained MD simulation data shows that the extent of MX encompassed by membrane lipids differs considerably in the open and closed structures, suggesting that lipid-protein interactions in this region could have a major effect on channel opening propensity. We conclude that the MX helix can modulate the function of the receptor and propose that its interactions with membrane lipids play a major role in this.

Mutations of the nACh Receptor M4 Helix Reveal Different Phenotypes in Different Expression Systems: Could Lipids be Responsible?

The role of the outermost helix (M4) in the pentameric ligand-gated ion channel (pLGIC) family is currently not fully understood. It is known that M4 is important for receptor assembly, possibly via interactions with neighboring M1 and M3 helices. M4 can also transmit information on the lipid content of the membrane to the gating mechanism, and it may form a link to the extracellular domain via the Cys-loop. Our previous study examining the α4ß2 nACh receptor M4 helix using HEK cells indicated M4 here is more sensitive to change than those of other pLGIC. Many of these other studies, however, were performed in Xenopus oocytes. Here we examine the nine previously identified nonfunctional α4ß2 nACh receptor M4 mutant receptors using this system. The data reveal that seven of these mutant receptors do function when expressed in oocytes, with only 2, the conserved Asp at the intracellular end of M4 and a Phe in the center, having a similar phenotype (nonfunctional) in both HEK cells and oocytes. The oocyte data are more consistent with studies in other pLGIC and demonstrate the importance of the expression system used. Of the many differences between these two expression systems, we suggest that the different lipid content of the plasma membrane is a possible candidate for explaining these discrepancies.

A Single Mutation in the Outer Lipid-Facing Helix of a Pentameric Ligand-Gated Ion Channel Affects Channel Function Through a Radially-Propagating Mechanism.

Pentameric ligand-gated ion channels (pLGICs) mediate fast synaptic transmission and are crucial drug targets. Their gating mechanism is triggered by ligand binding in the extracellular domain that culminates in the opening of a hydrophobic gate in the transmembrane domain. This domain is made of four α-helices (M1 to M4). Recently the outer lipid-facing helix (M4) has been shown to be key to receptor function, however its role in channel opening is still poorly understood. It could act through its neighboring helices (M1/M3), or via the M4 tip interacting with the pivotal Cys-loop in the extracellular domain. Mutation of a single M4 tyrosine (Y441) to alanine renders one pLGIC-the 5-HT3A receptor-unable to function despite robust ligand binding. Using Y441A as a proxy for M4 function, we here predict likely paths of Y441 action using molecular dynamics, and test these predictions with functional assays of mutant receptors in HEK cells and Xenopus oocytes using fluorescent membrane potential sensitive dye and two-electrode voltage clamp respectively. We show that Y441 does not act via the M4 tip or Cys-loop, but instead connects radially through M1 to a residue near the ion channel hydrophobic gate on the pore-lining helix M2. This demonstrates the active role of the M4 helix in channel opening.

M4, the Outermost Helix, is Extensively Involved in Opening of the α4ß2 nACh Receptor.

Nicotinic acetylcholine receptors (nAChR) are the archetypal members of the pentameric ligand-gated ion channel (pLGIC) family, an important class of cell signaling proteins. In all members of this family, each of the five subunits has four transmembrane α-helices (M1-M4), with M2 lining the pore, then M1 and M3, and with M4 outermost and adjacent to the membrane lipids. Despite its remote location, M4 contributes both to receptor assembly and gating in pLGICs where it has been examined. This study probes the role of M4 residues in the α4ß2 nAChR using site-directed mutagenesis to individually mutate each residue to alanine, followed by expression in HEK293 cells and then characterization using membrane potential sensitive dye and radioligand binding. Two of the resulting mutant receptors showed altered EC50s, while 13 were nonfunctional, although coexpression with the chaperones RIC3 and nAChO resulted in 4 of these responding to agonist. Of the remaining 9, radioligand binding with epibatidine showed that 8 were expressed, suggesting these residues may play a role in channel opening. These data differ from similar studies in other pLGIC, where few or no Ala mutants in M4 ablate function, and they suggest that the α4ß2 nAChR M4 may play a more significant role than in related receptors.

Many Proline Residues in the Extracellular Domain Contribute to Glycine Receptor Function.

Prolines in signaling proteins are of particular interest because they have a range of unique properties that may be critical for function. Here we show that many proline residues in the extracellular domain (ECD) of the glycine receptor are involved in the correct functioning of this ligand-gated ion channel. We explore their role by creating mutant receptors, expressing them in cells, and using fluorescent membrane potential sensitive dye to monitor receptor activity. We then interpret the changes in receptor parameters using structural information from the open and closed states of the receptor. The data reveal that substitution with alanine of ten of the 13 Pro residues in the ECD alters the function of the receptor: one substitution ablates function, six cause a decrease in the EC50, and three cause an increase. Only three of these mutants result in EC50 values similar to WT. The nonfunctional mutant, Pro30Ala, was further probed in oocytes, and the data suggest a role in both expression and function. Examination of the locations of sensitive Pro residues in the receptor and identification of potential interactions with nearby residues reveal how these residues could contribute to the correct functioning of this typical pentameric ligand-gated ion channel.

The M4 Helix Is Involved in α7 nACh Receptor Function.

Nicotinic acetylcholine receptors (nAChR) are the archetypal members of the pentameric ligand-gated ion channel (pLGIC) family, an important class of cell signaling proteins. In all members of this family, each of the five subunits has four transmembrane α-helices (M1-M4) with M2 lining the pore and then M1 and M3, with M4 outermost and adjacent to the membrane lipids. M4 has a variety of roles: its interaction with neighboring M1 and M3 helices is important for receptor assembly, it can a transmit information on the lipid content of the membrane to the gating mechanism, and it may form a vital link to the extracellular domain via the Cys-loop. This study examines the role of M4 receptor residues in the α7 nAChR using site-directed mutagenesis and subsequent expression in Xenopus oocytes. The data indicate that many of the residues in M4 play a role in receptor function, as substitution with Ala can modify functional parameters; 11 of 24 mutants showed a small gain of function (<10-fold decrease in EC50), and 1 (D446A) did not respond to the agonist; it was also not expressed at the cell surface. Removal or addition of aromatic residues had small or no effects. These results demonstrate the α7 nAChR M4 has a role in receptor function, and a structural model suggests possible interactions of some of these residues with their neighbors.

Characterization of Residues in the 5-HT3 Receptor M4 Region That Contribute to Function.

5-HT3 receptors are members of the family of pentameric ligand gated ion channels (pLGICs). Each subunit has four transmembrane α-helices (M1-M4), with M4 being most distant from the central pore. Residues in this α-helix interact with adjacent lipids and the neighboring M1 and M3 helices, contributing to both receptor assembly and channel function. This study probes the role of each M4 receptor residue in the 5-HT3A receptor using mutagenesis and subsequent expression in HEK293 cells, probing functional parameters using fluorescence membrane potential sensitive dye. The data show that only one residue in M4 (Y441) and two flanking residues (D434 and W459) result in nonfunctional receptors when substituted with Ala: D434A and W459A-containing receptors ablate expression, while Y441A-containing receptor do not, suggesting the latter is involved in channel gating. Most other altered residues have wild-type-like properties, which is inconsistent with data from other pLGICs. Substitution of Y441 and W459 with other aromatics restores function, suggesting the π ring is important. Further substitutions indicate interactions of Y441 with D238 in M1, W459 with F144 in the Cys loop, and D434 with R251 in M2, data consistent with recently published structures. These regions are critical for transducing binding into gating, and thus interactions of these residues can explain their importance in the function of the 5-HT3 receptor. We also conclude that the small number of critical M4 residues compared to related receptors supports the hypothesis that M4 does not behave identically in all pLGICs.