Assembly of mutant subunits of the nicotinic acetylcholine receptor lacking the conserved disulfide loop structure.

Each subunit of the nicotinic acetylcholine receptor (AChR) contains two conserved cysteine residues, which are known to form a disulfide bond, in the N-terminal extracellular domain. The role of this retained structural feature in the biogenesis of the AChR was studied by expressing site-directed mutant alpha and beta subunits together with other normal subunits from Torpedo californica AChR in Xenopus oocytes. Mutation of the cysteines at position 128 or 142 in the alpha subunit, or in the beta subunit, did not prevent subunit assembly. All Cys128 and Cys142 mutants of the alpha and beta subunits were able to associate with coexpressed other normal subunits, although associational efficiency of the mutant alpha subunits with the delta subunit was reduced. Functional studies of the mutant AChR complexes showed that the mutations in the alpha subunit abolished detectable 125I-alpha-bungarotoxin (alpha-BuTX) binding in whole oocytes, whereas the mutations in the beta subunit resulted in decreased total binding of 125I-alpha-BuTX and no detectable surface 125I-alpha-BuTX binding. Additionally, all mutant subunits, when co-expressed with the other normal subunits in oocytes, produced small acetylcholine-activated membrane currents, suggesting incorporation of only small numbers of functional mutant AChRs into the plasma membrane. The functional acetylcholine-gated ion channel formed with mutant alpha subunits, but not mutant beta subunits, could not be blocked by alpha-BuTX. Thus, a disulfide bond between Cys128 and Cys142 of the AChR alpha or beta subunits is not needed for acetylcholine-binding. However, this disulfide bond on the alpha subunit is necessary for formation of the alpha-BuTX-binding site. These results also suggest that the most significant effect caused by disrupting the conserved disulfide loop structure is intracellular retention of most of the assembled AChR complexes.     

Acetylcholine receptor binding site contains a disulfide cross-link between adjacent half-cystinyl residues

A conserved feature of all nicotinic receptors is the presence of a readily reducible disulfide bond adjacent to the acetylcholine binding site. Previously we showed that in intact receptor from Torpedo californica electric tissue reduction of this disulfide followed by affinity alkylation with 4-(N-maleimido)benzyltri[3H] methylammonium iodide specifically and uniquely labels the alpha subunit residues Cys-192 and Cys-193. To identify all of the half-cystinyl residues contributing to the binding site disulfide(s), we have now reduced receptor under mild conditions and alkylated with a mixture of 4-(N-maleimido)benzyltri[3H]methylammonium iodide and N-[1-14C]ethylmaleimide and find that Cys-192 and Cys-193 are labeled exclusively. Furthermore, from unreduced receptor we have isolated two cyanogen bromide peptides of alpha, one containing Cys-192 and Cys-193, and the other containing Cys-128 and Cys-142 (which are the other potential contributors to the binding site disulfide(s]. These isolated peptides incorporate iodo[1-14C]acetamide only following reduction by dithiothreitol. Our results demonstrate that: 1) the binding site disulfide is between Cys-192 and Cys-193; 2) Cys-128 is disulfide-cross-linked to Cys-142; and 3) under conditions that reduce Cys-192 and Cys-193 completely, Cys-128 and Cys-142 remain cross-linked. At the acetylcholine binding site, agonists induce a local conformational change that stabilizes the binding site disulfide against reduction. We suggest that a transition between two stable conformations of the vicinal disulfide, both involving a nonplanar cis peptide bond between Cys-192 and Cys-193, is associated with receptor activation by agonists.     

Mutational analysis of muscle nicotinic acetylcholine receptor subunit assembly

The structural elements required for normal maturation and assembly of the nicotinic acetylcholine receptor alpha subunit were investigated by expression of mutated subunits in transfected fibroblasts. Normally, the wild-type alpha subunit acquires high affinity alpha bungarotoxin binding in a time-dependent manner; however, mutation of the 128 and/or 142 cysteines to either serine or alanine, as well as deletion of the entire 14 amino acids in this region abolished all detectable high affinity binding. Nonglycosylated subunits that had a serine to glycine mutation in the consensus sequence also did not efficiently attain high affinity binding to toxin. In contrast, mutation of the proline at position 136 to glycine or alanine, or a double mutation of the cysteines at position 192 and 193 to serines had no effect on the acquisition of high affinity toxin binding. These data suggest that a disulfide bridge between cysteines 128 and 142 and oligosaccharide addition at asparagine 141 are required for the normal maturation of alpha subunit as assayed by high affinity toxin binding. The unassembled wild-type alpha subunit expressed in fibroblasts is normally degraded with a t1/2 of 2 h; upon assembly with the delta subunit, the degradation rate slows significantly (t1/2 greater than 13 h). All mutated alpha subunits retained the capacity to assemble with a delta subunit coexpressed in fibroblasts; however, mutated alpha subunits that were not glycosylated or did not acquire high affinity toxin binding were rapidly degraded (t1/2 = 20 min to 2 h) regardless of whether or not they assembled with the delta subunit. Assembly and rapid degradation of nonglycosylated acetylcholine receptor (AChR) subunits and subunit complexes were also observed in tunicamycin- treated BC3H-1 cells, a mouse musclelike cell line that normally expresses functional AChR. Hence, rapid degradation may be one form of regulation assuring that only correctly processed and assembled subunits accumulate, and ultimately make functional receptors in AChR- expressing cells.     

Epitope mapping employing antibodies raised against short synthetic peptides: a study of the nicotinic acetylcholine receptor

Antibodies were raised against eight synthetic peptides matching preselected portions of the amino acid sequence of nicotinic acetylcholine receptor (nAChR) from Torpedo marmorata. To increase the probability of obtaining antibodies specific for the exact sequence of the immunizing peptide, peptides of only five to seven amino acids in length were employed. Even under these limiting conditions some of the polyclonal rabbit immune sera showed cross-reactivity with other peptides and/or other sequence regions of the receptor. Further studies with polyclonal and monoclonal sera suggested that conformation and charge pattern rather than linear sequence are the essential determinants of antibody epitopes. Application of antibodies for topological studies therefore requires that the antibody specificity for a particular region of the antigen has been firmly established. Epitope mapping with the eight anti-peptide immune sera provides information on the accessibility to antibody of matching sequences within the receptor molecule. We find the sequence portions alpha 81-85, alpha 127-132, and alpha 190-195 to be freely accessible both at membrane-bound and at purified receptor. Binding of anti-alpha 387-392 serum does not prove accessibility of this region as the serum cross-reacts strongly with peptide fragments corresponding to the regions alpha 165-200 and beta 190-200 of nAChR from Torpedo californica. To permit binding of anti-alpha 137-142 immune serum, treatment of the receptor with endoglycosidase is required, showing that Asn-141 indeed is glycosylated in native nAChR. The homologous sequence of the other subunits differing only in one sequence position from alpha 137-142 is not accessible in native nAChR to antibody, indicating clear differences in folding of the receptor polypeptides. Sequence portions alpha 395-401 and alpha 161-166 must first be exposed by appropriate treatment to permit binding of respective serum. These results and previous epitope mapping studies by other laboratories are discussed with respect to the limited sequence specificity of antibodies.     

Localization of a highly immunogenic region on the acetylcholine receptor alpha-subunit

Antibodies to synthetic peptides were employed in order to map domains on the alpha-subunit of the acetylcholine receptor to which several monoclonal antibodies are directed. Five peptides corresponding to residues 1-20, 126-143, 169-181, 330-340 and 351-368 of the receptor alpha-subunit were synthesized and antibodies against them were elicited. The anti-peptide antibodies were employed along with the monoclonal antibodies to identify fragments of S. aureus V8 protease digested- alpha-subunit in immunoblotting experiments. Our results demonstrate that a highly immunogenic region of the alpha-subunit is located on a carboxy-terminal 14 kDa portion of the alpha-subunit. This region also seems to undergo antigenic changes during muscle development. A monoclonal antibody directed against the cholinergic binding site of the acetylcholine receptor reacted with an 18 kDa segment of the alpha-subunit which bound alpha-bungarotoxin as well as antibodies directed against peptide 169-181.     

Monoclonal antibodies directed against a synthetic peptide corresponding to the alpha-bungarotoxin binding region of the acetylcholine receptor

Murine monoclonal antibodies have been produced against a 32 amino acid synthetic peptide corresponding to residues 173-204 on the alpha-subunit of the nicotinic acetylcholine receptor from Torpedo californica. All of the monoclonal antibodies were of the IgM subtype and most cross-reacted with the purified native receptor. None of the antibodies were effective in blocking alpha-bungarotoxin binding to the receptor nor, conversely, did alpha-bungarotoxin interfere with antibody binding. However, two monoclonal antibodies, previously shown to bind near the ligand binding site on the native receptor, did compete partially (50%) with the binding of one of the IgM monoclonal antibodies.     

Analysis of acetylcholine receptor phosphorylation sites using antibodies to synthetic peptides and monoclonal antibodies.

Three peptides corresponding to residues 354-367, 364-374, 373-387 of the acetylcholine receptor (AChR) delta subunit were synthesized. These peptides represent the proposed phosphorylation sites of the cAMP-dependent protein kinase, the tyrosine-specific protein kinase and the calcium/phospholipid-dependent protein kinase respectively. Using these peptides as substrates for phosphorylation by the catalytic subunit of cAMP-dependent protein kinase it was shown that only peptides 354-367 was phosphorylated whereas the other two were not. These results verify the location of the cAMP-dependent protein kinase phosphorylation site within the AChR delta subunit. Antibodies elicited against these peptides reacted with the delta subunit. The antipeptide antibodies and two monoclonal antibodies (7F2, 5.46) specific for the delta subunit were tested for their binding to non-phosphorylated receptor and to receptor phosphorylated by the catalytic subunit of cAMP-dependent protein kinase. Antibodies to peptide 354-367 were found to react preferentially with non-phosphorylated receptor whereas the two other anti-peptide antibodies bound equally to phosphorylated and non-phosphorylated receptors. Monoclonal antibody 7F2 reacted preferentially with the phosphorylated form of the receptor whereas monoclonal antibody 5.46 did not distinguish between the two forms.     

Antibodies against preselected peptides to map functional sites on the acetylcholine receptor

Rabbit immune sera and mouse monoclonal antibodies were raised against the synthetic peptide Tyr-Cys-Glu-Ile-Ile-Val matching in sequence residues 127-132 of the alpha-subunit of all nicotinic acetylcholine receptors sequenced so far. Representative cholinergic ligands did not interfere with the binding of these antibodies to the receptor from Torpedo marmorata, indicating that this sequence is not part of the binding sites for cholinergic ligands. The applicability of antigenic sites analysis to the mapping of functional sites on receptor proteins is discussed.     

Localization and synthesis of the acetylcholine-binding site in the alpha-chain of the Torpedo californica acetylcholine receptor.

The sequence of the alpha-chain of the acetylcholine receptor of T. californica has been determined by recent cloning studies. The integrity of the disulphide bond between Cys-128 and cys-142 has been shown to be important for the maintenance of the binding activity of the receptor, thus implicating the regions around the disulphide bridge in binding with acetylcholine. In the present work, a synthetic peptide containing this loop region (residues 125-147) was synthesized. Solid-phase radiometric binding assays demonstrated a high binding of 125I-labelled alpha-bungarotoxin to the synthetic peptide. It was further shown that the free peptide bound well to [3H]acetylcholine. Additional experiments demonstrated that pretreatment of peptide 125-147 with 2-mercaptoethanol destroyed its binding activity, clearly showing that the integrity of the disulphide structure was essential for binding. Unlabelled acetylcholine also inhibited the binding of labelled acetylcholine to the synthetic peptide. The region 125-147, therefore, contains essential elements of the acetylcholine binding site of the Torpedo receptor.     

Monoclonal antibodies as probes of acetylcholine receptor structure. 1. Peptide mapping

The isolated subunits of the acetylocholine receptor from Torpedo californica were digested with proteolytic enzymes, and the resulting polypeptide fragments were analyzed by gel electrophoresis. We have identified those fragments which contain carbohydrate and those from the alpha subunit which are labelled with the acetylcholine binding site specific reagent [4-(N-maleimido)benzyl]tri[3H]methylammonium iodide. We have tested several monoclonal antibodies raised to the acetylcholine receptor from torpedo, some of which react with the denatured subunits [Tzartos, S.J., & Lindstrom, J.M. (1980) Proc. Natl. Acad. Sci. U.S.A.77, 755; Tzartos, S.J., & Lindstrom, J.M. (1981) in Monoclonal antibodies in Endocrine Research (Fellows, R., & Eisenbarth, G., Eds.) Raven Press (in press)]. The binding specificities of these antibodies to radioiodinated proteolytically generated fragments of the alpha subunit were determined by immunoprecipitation followed by gel electrophoresis. The antibodies tested fell into at least three main groups on the basis of their binding specificities. These antibodies were also tested for their capacity to bind to acetylcholine receptor solubilized in Triton X-100, sodium cholate, or sodium cholate supplemented with exogenous lipids. A monoclonal antibody raised to the denatured delta subunit, was tested for its ability to select radioiodinated proteolytic fragments of these subunits. These molecules provide probes for many sites on the acetylcholine receptor with affinities and specificities comparable to alpha-neurotoxins.     

Assembly in vivo of mouse muscle acetylcholine receptor: identification of an alpha subunit species that may be an assembly intermediate

We have studied assembly of acetylcholine receptor in vivo using subunit-specific monoclonal antibodies and immunoprecipitation with alpha-bungarotoxin and antitoxin. We have identified three distinct forms of the alpha subunit. The newly synthesized alpha subunit species has a sedimentation coefficient of 5S and is recognized only by antibody specific for SDS-denatured alpha subunit. We have called this species alpha 61. The 5S alpha Tx species is not associated with beta subunits and is probably monomeric. alpha Tx is formed from alpha 61 with a half-time of 15 min and an efficiency of approximately equal to 30%. Formation of alpha Tx involves a conformational change, and we suggest that this conformation is dependent upon or stabilized by disulfide bond formation. The assembly of alpha Tx with beta subunits (and probably gamma and delta) into a 9S complex appears to be an efficient but slow process requiring more than 90 min. Unassembled alpha 61 subunits are degraded rapidly. However, subunit degradation is a result of failure to assemble, rather than its cause.     

Antibodies against an alpha-bungarotoxin-binding peptide of the alpha-subunit of the acetylcholine receptor

Polyclonal and monoclonal antibodies were raised against a peptide comprising residues 173-204 of the alpha-subunit of the acetylcholine receptor. The polyclonal and pooled monoclonal antibodies inhibited up to 50% of 125I-alpha-bungarotoxin binding to peptide 173-204. Some of the antibodies recognized native receptor but did not significantly affect alpha-bungarotoxin binding. Epitope mapping revealed that the antibodies are directed against residues 183-194 indicating this region is a major determinant of toxin binding. This region is most likely conformationally constrained in the native receptor.     

Location of antigenic determinants on primary sequences of subunits of nicotinic acetylcholine receptor by peptide mapping

The binding domains of 28 monoclonal antibodies (mAbs) against the alpha, beta, and delta subunits of the Torpedo acetylcholine receptor were mapped on the primary sequences of these subunits. Small peptide fragments (2000-20,000 daltons) of the purified subunits were obtained by digestion with staphylococcal V8 protease and papain, separated on a discontinuous polyacrylamide gel electrophoretic system, and electroblotted onto diaminophenyl thioether paper. The blots were probed with the various monoclonal antibodies and also with antibodies against carboxy-terminal decapeptides of the alpha, beta, and delta subunits to identify the carboxy-terminal fragments. From inspection of the binding patterns of the various antibodies to the subunits fragments and the molecular weights of these fragments, and by using the carboxy termini of the subunits as reference points, it was possible to deduce the regions on the primary sequence of each subunit in which the antibodies bound and in some cases to order the binding sites within these sequences. mAb 148, which inhibits receptor function by cross-linking receptor molecules on the cytoplasmic side, was mapped to the sequence beta 368-406. The main immunogenic region of the native receptor, which is of pathological importance in the autoimmune disease myasthenia gravis, was mapped by using mAb 210 to within 80 amino acid residues (alpha 46-127). The overall antigenic structure of alpha subunits was examined. Synthetic peptides have been used to locate determinants responsible for 83% of the antibodies in antisera to denatured alpha subunits and 46% of the antibodies to denatured alpha subunits in antisera to intact receptor. Theoretical models of the transmembrane orientation of the subunit polypeptide chains were tested by determining whether mapped monoclonal antibodies bound to the extracellular or intracellular surface of receptor-rich membranes. Our results confirm previous reports that the carboxy termini of the subunits are exposed on the intracellular surface, as is part of the region between a putative channel-forming domain (M5) and a putative membrane-spanning region (M3). However, contrary to current theoretical models, the region between M5 and the putative membrane-spanning sequence M4 also appears to be on the intracellular surface, implying that M4 and M5 are not membrane-spanning domains.(ABSTRACT TRUNCATED AT 400 WORDS)     

Purification and characterization of a nicotinic acetylcholine receptor from chick brain

Immunohistochemical studies have previously shown that both the chick brain and chick ciliary ganglion neurons contain a component which shares antigenic determinants with the main immunogenic region of the nicotinic acetylcholine receptor from electric organ and skeletal muscle. Here we describe the purification and initial characterization of this putative neuronal acetylcholine receptor. The component was purified by monoclonal antibody affinity chromatography. The solubilized component sediments on sucrose gradients as a species slightly larger than Torpedo acetylcholine receptor monomers. It was affinity labeled with bromo[3H]acetylcholine. Labeling was prevented by carbachol, but not by alpha-bungarotoxin. Two subunits could be detected in the affinity-purified component, apparent molecular weights 48 000 and 59 000. The 48 000 molecular weight subunit was bound both by a monoclonal antibody directed against the main immunogenic region of electric organ and skeletal muscle acetylcholine receptor and by antisera raised against the alpha subunit of Torpedo receptor. Evidence suggests that there are two alpha subunits in the brain component. Antisera from rats immunized with the purified brain component exhibited little or no cross-reactivity with Torpedo electric organ or chick muscle acetylcholine receptor. One antiserum did, however, specifically bind to all four subunits of Torpedo receptor. Experiments to be described elsewhere (J. Stollberg et al., unpublished results) show that antisera to the purified brain component specifically inhibit the electrophysiological function of acetylcholine receptors in chick ciliary ganglion neurons without inhibiting the function of acetylcholine receptors in chick muscle cells. All of these properties suggest that this component is a neuronal nicotinic acetylcholine receptor with limited structural homology to muscle nicotinic acetylcholine receptor.     

Structural heterogeneity of the alpha subunits of the nicotinic acetylcholine receptor in relation to agonist affinity alkylation and antagonist binding

The structural basis for the heterogeneity of the two agonist binding sites of the Torpedo californica acetylcholine receptor with respect to antagonist binding and reactivity toward affinity alkylating reagents was investigated. There is one agonist binding site on each of the two alpha subunits in a receptor monomer. One of these sites is easily affinity labeled with bromoacetylcholine, while more extreme conditions are required to label the other. Evidence is presented that the site which is easily labeled with bromoacetylcholine is the site with higher affinity for the antagonist d-tubocurarine. Digestion of purified alpha subunits with staphylococcal V8 protease gave two limit fragments with apparent molecular weights of 17K and 19K. Both of these fragments began at residue 46 of the alpha sequence, and both reacted with monoclonal antibodies specific for the sequence alpha 152-159 but not with antibodies specific for alpha 235-242. Their tryptic peptide maps and reactivity with a number of monoclonal antibodies were virtually identical. Only the 17-kilodalton (17-kDa) fragments stained heavily for sugars with Schiff's reagent. However, both fragments bound 125I-labeled concanavalin A. Complete removal of carbohydrate detectable with concanavalin A from V8 protease digests of alpha subunits resulted in two fragments of lower apparent molecular weights, indicating that these fragments differed not only in carbohydrate content but also in their C-termini or by another covalent modification. Covalent labeling of one of the two agonist sites of the intact receptor with bromo[3H]acetylcholine followed by digestion with V8 protease resulted in labeling of only the 19-kDa fragment.(ABSTRACT TRUNCATED AT 250 WORDS)     

The binding site of acetylcholine receptor as visualized in the X-Ray structure of a complex between alpha-bungarotoxin and a mimotope peptide.

We have determined the crystal structure at 1.8 A resolution of a complex of alpha-bungarotoxin with a high affinity 13-residue peptide that is homologous to the binding region of the alpha subunit of acetylcholine receptor. The peptide fits snugly to the toxin and adopts a beta hairpin conformation. The structures of the bound peptide and the homologous loop of acetylcholine binding protein, a soluble analog of the extracellular domain of acetylcholine receptor, are remarkably similar. Their superposition indicates that the toxin wraps around the receptor binding site loop, and in addition, binds tightly at the interface of two of the receptor subunits where it inserts a finger into the ligand binding site, thus blocking access to the acetylcholine binding site and explaining its strong antagonistic activity.     

The main immunogenic region of the nicotinic acetylcholine receptor: interaction of monoclonal antibodies with synthetic peptides

Monoclonal antibodies to the main immunogenic region of the nicotinic acetylcholine receptor have been studied with regard to their binding to synthetic peptides. It was found that monoclonal antibody 210 to the main immunogenic region binds to the synthetic fragment spanning residues 66 to 76 of the alpha subunits of the acetylcholine receptor from human muscle, but not to the homologous sequence from Xenopus. This parallels the reactivities of antibodies to the main immunogenic region with intact receptors from two species, and confirms the biological significance of the weak interactions observed between antibodies to this region and synthetic peptides. It also suggests that N alpha 68 and D alpha 71 are critical contact residues.     

Heterogeneity of antibodies blocking the binding of bungarotoxin to the acetylcholine receptor in myasthenia

Inhibitory effect of myasthenic patients antibodies on alpha-bungarotoxin binding to the human acetylcholine receptor has been demonstrated by radioimmunoassay. By using decamethonium, an acetylcholine agonist, we have shown the existence of two antibody sub-groups reacting with the toxin-binding site: one sub-group is represented by antibodies which block the binding directly, the other by antibodies that inhibit the binding, only in the presence of decamethonium.     

Structural localization of the sequence alpha 235-242 of the nicotinic acetylcholine receptor

Two monoclonal antibodies (mAb 254 and 255) were obtained against a synthetic peptide corresponding to the sequence 235-242 of the alpha-subunit of Torpedo acetylcholine receptor. These mAbs could bind to receptor in native membrane vesicles only when these vesicles were permeabilized, suggesting that the sequence alpha 235-242 is exposed on the cytoplasmic surface of the receptor. Further evidence for the cytoplasmic localization of this sequence was partial competition for binding between these mAbs and mAbs previously demonstrated to bind to the cytoplasmic part of the receptor. A model is proposed which accounts for all the experimental data obtained thus far on the transmembrane orientation of the subunit polypeptide chains.