Cloning and Functional Characterisation of Two Novel Nicotinic Acetylcholine Receptor α Subunits from the Insect Pest Myzus persicae

Abstract: Nicotinic acetylcholine receptors play a major role in excitatory neurotransmission in insect CNSs and constitute an important target for insecticides. Here, we report the isolation and functional characterisation of two cDNAs encoding nicotinic acetylcholine receptor α subunits from a major insect pest, the peach-potato aphid Myzus persicae . These two subunits, termed Mpα1 and Mpα2, are respective structural homologues of the Drosophila Dα2/ Schistocerca gregaria αL1 α-subunit pair and the Drosophila ALS α subunit. Xenopus oocyte expression confirmed that each Myzus subunit can form functional acetylcholine- or nicotine-gated channels. However, some electrophysiological and pharmacological properties of the Myzus subunits were distinct from those encoded by the corresponding Drosophila subunits. Coexpression of the Myzus subunits with the chick β2 subunit revealed other differences from the Drosophila system, as only very limited potentiation of agonist-induced currents was observed with Mpα2 and none with Mpα1. Available data therefore indicate that structurally homologous insect nicotinic acetylcholine receptor α subunits from different species can exhibit distinctive physiological and pharmacological characteristics.     

Levels of Benzodiazepine Receptor Subtypes and GABAA Receptor α-Subunit mRNA Do Not Correlate During Development

Abstract: Developmental changes in the pharmacological properties of the GABA_A receptor have been suggested to result from changes in the subunit composition of the receptor complex. The nicotinic acetylcholine receptor is structurally related to the GABA_A receptor and undergoes a developmental subunit switch at the neuromuscular synapse. To examine the mechanistic similarities between these systems we sought to find whether the changes in GABA_A receptor subunits are controlled by changes in messenger RNA levels, as they are for the nicotinic acetylcholine receptor. We found a 10-fold increase in the level of α1-subunit mRNA, and a small increase in levels of GABA_A/benzodiazepine receptors from day 1 to day 24 of rat cerebellar development. We also found that the levels of α1-subunit mRNA were higher than the levels of mRNA encoding other α subunits at all developmental time points. The low levels of messenger RNA for α2, α3, and α5 subunits are inconsistent with the high levels of type II benzodiazepine binding in the rat cerebellum at birth because these α subunits have been shown to form GABA_A receptors with type II benzodiazepine binding. These findings are inconsistent with simple models that would explain the developmental differences in GABA_A receptor pharmacology simply as a result of changes in α-subunit gene expression.     

alpha-bungarotoxin receptors contain alpha7 subunits in two different disulfide-bonded conformations.

Neuronal nicotinic alpha7 subunits assemble into cell-surface complexes that neither function nor bind alpha-bungarotoxin when expressed in tsA201 cells. Functional alpha-bungarotoxin receptors are expressed if the membrane-spanning and cytoplasmic domains of the alpha7 subunit are replaced by the homologous regions of the serotonin-3 receptor subunit. Bgt-binding surface receptors assembled from chimeric alpha7/serotonin-3 subunits contain subunits in two different conformations as shown by differences in redox state and other features of the subunits. In contrast, alpha7 subunit complexes in the same cell line contain subunits in a single conformation. The appearance of a second alpha7/serotonin-3 subunit conformation coincides with the formation of alpha-bungarotoxin-binding sites and intrasubunit disulfide bonding, apparently within the alpha7 domain of the alpha7/serotonin-3 chimera. In cell lines of neuronal origin that produce functional alpha7 receptors, alpha7 subunits undergo a conformational change similar to alpha7/serotonin-3 subunits. alpha7 subunits, thus, can fold and assemble by two different pathways. Subunits in a single conformation assemble into nonfunctional receptors, or subunits expressed in specialized cells undergo additional processing to produce functional, alpha-bungarotoxin-binding receptors with two alpha7 conformations. Our results suggest that alpha7 subunit diversity can be achieved postranslationally and is required for functional homomeric receptors.     

α3, β2, and β4 Form Heterotrimeric Neuronal Nicotinic Acetylcholine Receptors in Xenopus Oocytes

Abstract: One of the problems faced when using heterologous expression systems to study receptors is that the pharmacological and physiological properties of expressed receptors often differ from those of native receptors. In the case of neuronal nicotinic receptors, one or two subunit cDNAs are sufficient for expression of functional receptors in Xenopus oocytes. However, the stoichiometries of nicotinic receptors in neurons are not known and expression patterns of mRNA coding for different nicotinic receptor subunits often overlap. Consequently, one explanation for the discrepancy between properties of native versus heterologously expressed nicotinic receptors is that more than two types of subunit are necessary for correctly functioning receptors. The Xenopus oocyte expression system was used to test the hypothesis that more than two types of subunit can coassemble; specifically, can two different β subunits assemble with an α subunit forming a receptor with unique pharmacological properties? We expressed combinations of cDNA coding for α3, β2, and β4 subunits. β2 and β4, in pairwise combination with α3, are differentially sensitive to cytisine and neuronal bungarotoxin (nBTX). α3β4 receptors are activated by cytisine and are not blocked by low concentrations of nBTX; acetylcholine-evoked currents through α3β2 receptors are blocked by both cytisine and low concentrations of nBTX. Coinjection of cDNA coding for α3, β2, and β4 into oocytes resulted in receptors that were activated by cytisine and blocked by nBTX, thus demonstrating inclusion of both β2 and β4 subunits in functional receptors.     

Sequence and functional expression of a single alpha subunit of an insect nicotinic acetylcholine receptor.

We report the isolation and sequence of a cDNA clone that encodes a locust (Schistocerca gregaria) nervous system nicotinic acetylcholine receptor (AChR) subunit (alpha L1). The calculated molecular weight of the unglycosylated polypeptide, which contains in the proposed extracellular domain two adjacent cysteine residues which are characteristic of alpha (ligand binding) subunits, is 60,641 daltons. Injection into Xenopus oocytes, of RNA synthesized from this clone in vitro, results in expression of functional nicotinic receptors in the oocyte membrane. In these, nicotine opens a cation channel; the receptors are blocked by both alpha-bungarotoxin (alpha-Bgt) and kappa-bungarotoxin (kappa-Bgt). Reversible block of the expressed insect AChR by mecamylamine, d-tubocurarine, tetraethylammonium, bicuculline and strychnine has also been observed. These data are entirely consistent with previously reported electrophysiological studies on in vivo insect nicotinic receptors and also with biochemical studies on an alpha-Bgt affinity purified locust AChR. Thus, a functional receptor exhibiting the characteristic pharmacology of an in vivo insect nicotinic AChR can be expressed in Xenopus oocytes by injection with a single subunit RNA.     

Neuronal nicotinic acetylcholine receptors from Drosophila: two different types of alpha subunits coassemble within the same receptor complex

Although neuronal nicotinic acetylcholine receptors from insects have been reconstituted in vitro more than a decade ago, our knowledge about the subunit composition of native receptors as well as their functional properties still remains limited. Immunohistochemical evidence has suggested that two alpha subunits, alpha-like subunit (ALS) and Drosophila alpha2 subunit (Dalpha2), are colocalized in the synaptic neuropil of the Drosophila CNS and therefore may be subunits of the same receptor complex. To gain further understanding of the composition of these nicotinic receptors, we have examined the possibility that a receptor may imbed more than one alpha subunit using immunoprecipitations and electrophysiological investigations. Immunoprecipitation experiments of fly head extracts revealed that ALS-specific antibodies coprecipitate Dalpha2, and vice versa, and thereby suggest that these two alpha subunits must be contained within the same receptor complex, a result that is supported by investigations of reconstituted receptors in Xenopus oocytes. Discrimination between binary (ALS/beta2 or Dalpha2/beta2) and ternary (ALS/Dalpha2/beta2) receptor complexes was made on the basis of their dose-response curve to acetylcholine as well as their sensitivity to alpha-bungarotoxin or dihydro-beta-erythroidine. These data demonstrate that the presence of the two alpha subunits within a single receptor complex confers new receptor properties that cannot be predicted from knowledge of the binary receptor's properties.     

GABAA receptor channels: from subunits to functional entities.

GABAA receptor channels mediate postsynaptic inhibition. The functional diversity of these receptors rests on differences in subunit composition and on a large repertoire of subunits. Subunit expression patterns in the brain have been found to predict in vivo compositions of GABAA receptors. In addition, molecular determinants underlying the differential binding properties of allosteric ligands to receptor subtypes have been identified.     

Structure-function relationships in nicotinic acetylcholine receptors

1. A combination of molecular, biochemical, electrophysiological and immunological approaches has begun to resolve some of the questions about structure-function relationships of nicotinic acetylcholine receptors (AchRs). 2. Current structural studies suggest that models of the subunits which propose four transmembrane domains are correct. 3. It is also probable that the carboxy termini of the subunits are extracellular, while the putative amphpathic helix is intracellular. 4. Electrophysiological and ligand-binding experiments suggest that the M2 region forms the wall of the ion channel. 5. We have isolated clones from PC12 and rat brain cDNA libraries which we have shown, by functional expression, code for members of a gene family of nicotinic acetylcholine receptor subunits. 6. In situ hybridization studies have shown that the neuronal receptor subunit mRNAs are expressed in the mammalian central nervous system. 7. The muscle and neuronal nicotinic AchR subtypes we have expressed show differences in their pharmacological properties. 8. The isolation and identification of clones which code for receptors and voltage-activated ion channels will help in the understanding of a variety of disease states and assist in the design of drugs which are specific for unique molecular targets.     

GABAA receptor subtypes immunopurified from rat brain with alpha subunit-specific antibodies have unique pharmacological properties.

The unique cytoplasmic loop regions of the alpha 1, alpha 2, alpha 3, and alpha 5 subunits of the GABAA receptor were expressed in bacterial and used to produce subunit-specific polyclonal antisera. Antibodies immobilized on protein A-Sepharose were used to isolate naturally occurring alpha-specific populations of GABAA receptors from rat brain that retained the ability to bind [3H]muscimol, [3H]flunitrazepam, [3H]Ro15-1788, and [125I]iodo-clonazepam with high affinity. Pharmacological characterization of these subtypes revealed marked differences between the isolated receptor populations and was generally in agreement with the reported pharmacological profiles of GABAA receptors in cells transiently transfected with alpha 1 beta 1 gamma 2, alpha 2 beta 1 gamma 2, alpha 3 beta 1 gamma 2, and alpha 5 beta 1 gamma 2 combinations of subunits. Additional subtypes were also identified that bind [3H]muscimol but do not bind benzodiazepines with high affinity. The majority of GABAA receptor oligomers contains only a single type of alpha subunit, and we conclude that alpha 1, alpha 2, alpha 3, and alpha 5 subunits exist in vivo in combination with the beta subunit and gamma 2 subunit.     

Structure and subunit composition of GABA(A) receptors.

GABA(A) receptors are the major inhibitory neurotransmitter receptors in the brain and are the site of action of many clinically important drugs. These receptors are composed of five subunits that can belong to eight different subunit classes. If all GABA(A) receptor subunits could randomly combine with each other, an extremely large number of GABA(A) receptor subtypes with distinct subunit composition and arrangement would be formed. Depending on their subunit composition, these receptors would exhibit distinct pharmacological and electrophysiological properties. Recent evidence, however, indicates that not all subunits can assemble efficiently with each other and form functional homo- or hetero-oligomeric receptors. In addition, the efficiency of formation of hetero-oligomeric assembly intermediates determines the subunit stoichiometry and subunit arrangement for each receptor and thus further reduces the possible heterogeneity of GABA(A) receptors in the brain. Studies investigating the subunit composition of native GABA(A) receptors support this conclusion, but also indicate that receptors composed of one, two, three, four, or five different subunits might exist in the brain. Using a recently established immunodepletion technique, the subunit composition and quantitative importance of native GABA(A) receptor subtypes can be determined. This information, together with studies on the regional, cellular and subcellular distribution of these receptor subtypes, will be the basis for a rational development of drugs that specifically affect the GABAergic system.     

Molecular biology of mammalian amino acid receptors

The amino acid receptor proteins are ubiquitous transducers of most excitatory and inhibitory synaptic transmission in the brain. In July 1987 two reports appeared describing the molecular cloning of a pair of subunits of the GABAA receptor (7) and one subunit of the glycine receptor (13). These papers sparked wide interest and led quickly to the concept of a ligand-gated receptor-ion channel superfamily that includes nicotinic acetylcholine receptors as well as certain amino acid receptors. The identification of additional subunits of each receptor followed; with the recent cloning of a kainate receptor subunit (14), only the NMDA receptor remains elusive. Several disciplines have been brought to bear on these receptor clones, including in situ hybridization and functional expression in Xenopus laevis oocytes and mammalian cell lines. In this review we compare cloning strategies that have been used for amino acid receptors and discuss structural similarities among the receptor subunits. Two findings that have arisen from molecular cloning and expression of these receptors receive special attention. First, the molecular heterogeneity of GABAA receptors is larger than expected from pharmacological studies of native receptors. Second, although the native receptors are thought to be heterooligomers, much like the model proposed for the nicotinic receptors, some individual amino acid receptor subunits can form functional receptor channels, presumably in a homomeric configuration. This review focuses, therefore, on what we have learned from cloning efforts about amino acid receptors and what might lie ahead in this field.     

Structural and functional characterization of the gamma 1 subunit of GABAA/benzodiazepine receptors.

The GABAA receptor gamma 1 subunit of human, rat and bovine origin was molecularly cloned and compared with the gamma 2 subunit in structure and function. Both gamma subunit variants share 74% sequence similarity and are prominently synthesized in often distinct areas of the central nervous system as documented by in situ hybridization. When co-expressed with alpha and beta subunits in Xenopus oocytes and mammalian cells, the gamma variants mediate the potentiation of GABA evoked currents by benzodiazepines and help generate high-affinity binding sites for these drugs. However, these sites show disparate pharmacological properties which, for receptors assembled from alpha 1, beta 1 and gamma 1 subunits, are characterized by the conspicuous loss in affinity for neutral antagonists (e.g. flumazenil) and negative modulators (e.g. DMCM). These findings reveal a pronounced effect of gamma subunit variants on GABAA/benzodiazepine receptor pharmacology.     

Apparent homomeric NR1 currents observed in Xenopus oocytes are caused by an endogenous NR2 subunit

Functional N-methyl-d-aspartate receptors NMDARs are thought to be heteromeric receptor complexes consisting of NR1 and NR2 subunits. However, recombinant NR1 subunits expressed in Xenopus oocytes assemble functional ion channels even without exogenous NR2 subunits and with a different pharmacology, suggesting a homomeric subunit stoichiometry. To explain this phenomenon, we screened oocytes for Xenopus NR2 subunits and found all four subunit-encoding mRNAs (XenNR2A-XenNR2D) to be present endogenously, with those encoding the XenNR2B subunit being particularly abundant. We cloned the full-length XenNR2B cDNA and co-expressed it with NR1 in oocytes. A detailed electrophysiological characterization revealed that the pharmacology of NR1/XenNR2B was identical with that of the presumed homomeric NMDARs expressed from NR1 subunits. By contrast, heteromeric receptors containing the rat NR2B subunit showed significant pharmacological differences compared with NR1/XenNR2B receptors. These results demonstrate that recombinant NR1 subunits expressed in Xenopus oocytes interact with an endogenously expressed NR2B subunit and form hybrid heteromeric NMDARs. These findings confirm the current views that NMDARs are obligatory heteromeric complexes and that functional homomeric NMDARs do not exist.     

Ubiquilin-1 regulates nicotine-induced up-regulation of neuronal nicotinic acetylcholine receptors

Chronic exposure to nicotine, as in tobacco smoking, up-regulates nicotinic acetylcholine receptor surface expression in neurons. This up-regulation has been proposed to play a role in nicotine addiction and withdrawal. The regulatory mechanisms behind nicotine-induced up-regulation of surface nicotinic acetylcholine receptors remain to be determined. It has recently been suggested that nicotine stimulation acts through increased assembly and maturation of receptor subunits into functional pentameric receptors. Studies of muscle nicotinic acetylcholine receptors suggest that the availability of unassembled subunits in the endoplasmic reticulum can be regulated by the ubiquitin-proteosome pathway, resulting in altered surface expression. Here, we describe a role for ubiquilin-1, a ubiquitin-like protein with the capacity to interact with both the proteosome and ubiquitin ligases, in regulating nicotine-induced up-regulation of neuronal nicotinic acetylcholine receptors. Ubiquilin-1 interacts with unassembled alpha3 and alpha4 subunits when coexpressed in heterologous cells and interacts with endogenous nicotinic acetylcholine receptors in neurons. Coexpression of ubiquilin-1 and neuronal nicotinic acetylcholine receptors in heterologous cells dramatically reduces the expression of the receptors on the cell surface. In cultured superior cervical ganglion neurons, expression of ubiquilin-1 abolishes nicotine-induced up-regulation of nicotinic acetylcholine receptors but has no effect on the basal level of surface receptors. Coimmunostaining shows that the interaction of ubiquilin-1 with the alpha3 subunit draws the receptor subunit and proteosome into a complex. These data suggest that ubiquilin-1 limits the availability of unassembled nicotinic acetylcholine receptor subunits in neurons by drawing them to the proteosome, thus regulating nicotine-induced up-regulation.     

Determination of the sites of cAMP-dependent phosphorylation on the nicotinic acetylcholine receptor

The nicotinic acetylcholine receptor is a substrate for cAMP-dependent protein kinase both in vitro and in vivo. Recently, it has been demonstrated that phosphorylation of the nicotinic receptor by this kinase increases its rate of rapid desensitization. We now report the identification of the cAMP-dependent phosphorylation sites on the gamma and delta subunits. Two-dimensional phosphopeptide mapping of the phosphorylated gamma and delta subunits, after limit proteolysis with thermolysin, indicated that each subunit is phosphorylated on a single site. Phosphoamino acid analysis of the 32P-labeled subunits demonstrates that phosphorylation had occurred exclusively on serine residues. Purified phosphorylated subunits were cleaved with cyanogen bromide and the resultant phosphopeptides were purified by reverse-phase high performance liquid chromatography. Shorter phosphopeptides, obtained by secondary digestion with trypsin, were purified and subjected to both automated gas-phase sequencing and manual Edman degradation. The results demonstrate that the gamma subunit was phosphorylated at Ser-353, contained within the sequence Arg-Arg-Ser(P)-Ser-Phe-Ile and that the delta subunit was phosphorylated at Ser-361, contained within the sequence Arg-Ser-Ser(P)-Ser-Val-Gay-Tyr-Ser-Lys. Determination of the sites phosphorylated within the structure of the gamma and delta subunits should contribute to the molecular characterization of the regulation of desensitization of the nicotinic acetylcholine receptor by protein phosphorylation.     

Molecular studies of the neuronal nicotinic acetylcholine receptor family

Nicotinic acetylcholine receptors on neurons are part of a gene family that includes nicotinic acetylcholine receptors on skeletal muscles and neuronal alpha bungarotoxin-binding proteins that in many species, unlike receptors, do not have an acetylcholine-regulated cation channel. This gene superfamily of ligand-gated receptors also includes receptors for glycine and gamma-aminobutyric acid. Rapid progress on neuronal nicotinic receptors has recently been possible using monoclonal antibodies as probes for receptor proteins and cDNAs as probes for receptor genes. These studies are the primary focus of this review, although other aspects of these receptors are also considered. In birds and mammals, there are subtypes of neuronal nicotinic receptors. All of these receptors differ from nicotinic receptors of muscle pharmacologically (none bind alpha bungarotoxin, and some have very high affinity for nicotine), structurally (having only two types of subunits rather than four), and, in some cases, in functional role (some are located presynaptically). However, there are amino acid sequence homologies between the subunits of these receptors that suggest the location of important functional domains. Sequence homologies also suggest that the subunits of the proteins of this family all evolved from a common ancestral protein subunit. The ligand-gated ion channel characteristic of this superfamily is formed from multiple copies of homologous subunits. Conserved domains responsible for strong stereospecific association of the subunits are probably a fundamental organizing principle of the superfamily. Whereas the structure of muscle-type nicotinic receptors appears to have been established by the time of elasmobranchs and has evolved quite conservatively since then, the evolution of neuronal-type nicotinic receptors appears to be in more rapid flux. Certainly, the studies of these receptors are in rapid flux, with the availability of monoclonal antibody probes for localizing, purifying, and characterizing the proteins, and cDNA probes for determining sequences, localizing mRNAs, expressing functional receptors, and studying genetic regulation. The role of nicotinic receptors in neuromuscular transmission is well understood, but the role of nicotinic receptors in brain function is not. The current deluge of data using antibodies and cDNAs is beginning to come together nicely to describe the structure of these receptors. Soon, these techniques may combine with others to better reveal the functional roles of neuronal nicotinic receptors.     

Expression of muscarinic and nicotinic acetylcholine receptors in the mouse urothelium

Acetylcholine (ACh) and its receptors play a crucial role in bladder physiology. Here, we investigated the presence of muscarinic receptor subtypes (MR) and nicotinic acetylcholine receptor (nAChR) alpha-subunits in the mouse urothelium by RT-PCR and immunohistochemistry. With RT-PCR, we detected mRNAs coding for all of the five different MR subtypes and for the nicotinic receptor subunits alpha2, alpha4, alpha5, alpha6, alpha7, alpha9 and alpha10, whereas the alpha3-subunit was not expressed. Using immunohistochemistry, we localised a panel of acetylcholine receptors in the different layers of the murine bladder urothelium, with predominant appearance in the basal plasma membrane of the basal cell layer and in the apical membrane of the umbrella cells. M2R and subunit alpha9 were observed exclusively in the umbrella cells, whereas the MR subtypes 3-5 and the nAChR subunits alpha4, alpha7 and alpha10 were also detected in the intermediate and basal cell layers. The subunit alpha5 was localised only in the basal cell layer. In conclusion, the murine urothelium expresses multiple cholinergic receptors, including several subtypes of both MR and nAChR, which are differentially distributed among the urothelial cell types. Since these receptors have different electrophysiological and pharmacological properties, and therefore are considered to be responsible for different cellular responses to ACh, this differential distribution is expected to confer cell type-specificity of cholinergic regulation in the bladder urothelium.     

Primary structure and expression of beta 2: a novel subunit of neuronal nicotinic acetylcholine receptors

A new subunit, beta 2, of the neuronal nicotinic receptor family has been identified. This subunit has the structural features of a non-agonist-binding subunit. We provide evidence that beta 2 can substitute for the muscle beta 1 subunit to form a functional nicotinic receptor in Xenopus oocytes. Expression studies performed in oocytes have demonstrated that three different neuronal nicotinic acetylcholine receptors can be formed by the pairwise injection of beta 2 mRNA and each of the neuronal alpha subunit mRNAs. The beta 2 gene is expressed in PC12 cells and in areas of the central nervous system where the alpha 2, alpha 3, and alpha 4 genes are expressed. These results lead us to propose that the nervous system expresses diverse forms of neuronal nicotinic acetylcholine receptors by combining beta 2 subunits with different agonist-binding alpha subunits.