The main immunogenic region (MIR) of the nicotinic acetylcholine receptor and the anti-MIR antibodies

Myasthenia gravis (MG) is caused by autoantibodies against the nicotinic acetylcholine receptor (AChR) of the neuromuscular junction. The anti-AChR antibodies are heterogeneous. However, a small region on the extracellular part of the AChR alpha subunit, called the main immunogenic region (MIR), seems to be the major target of the anti-AChR antibodies, but not of the specific T-cells, in experimental animals and possibly in MG patients. The major loop of the overlapping epitopes for all testable anti-MIR monoclonal antibodies (MAbs) was localized within residues 67-76 (WNPADYGGIK for Torpedo and WNPDDYGGVK for human AChR) of the alpha subunit. The N-terminal half of alpha 67-76 is the most critical, Asn68 and Asp71 being indispensable for binding. Yet anti-MIR antibodies are functionally and structurally quite heterogeneous. Anti-MIR MAbs do not affect channel gating, but they are very potent in mediating acceleration of AChR degradation (antigenic modulation) in cell cultures and in transferring experimental MG in animals. Fab fragments of anti-MIR MAbs bound to the AChR prevent the majority of the MG patients' antibodies from binding to and causing loss of the AChR. Whether this inhibition means that most MG antibodies bind on the same small region or is a result of broad steric/allosteric effects is under current investigation.     

Antigenic role of single residues within the main immunogenic region of the nicotinic acetylcholine receptor.

The target of most of the autoantibodies against the acetylcholine receptor (AChR) in myasthenic sera is the main immunogenic region (MIR) on the extracellular side of the AChR alpha-subunit. Binding of anti-MIR monoclonal antibodies (mAbs) has been recently localized between residues alpha 67 and alpha 76 of Torpedo californica electric organ (WNPADYGGIK) and human muscle (WNPDDYGGVK) AChR. In order to evaluate the contribution of each residue to the antigenicity of the MIR, we synthesized peptides corresponding to residues alpha 67-76 from Torpedo and human AChRs, together with 13 peptide analogues. Nine of these analogues had one residue of the Torpedo decapeptide replaced by L-alanine, three had a structure which was intermediate between those of the Torpedo and human alpha 67-76 decapeptides, and one had D-alanine in position 73. Binding studies employing six anti-MIR mAbs and all 15 peptides revealed that some residues (Asn68 and Asp71) are indispensable for binding by all mAbs tested, whereas others are important only for binding by some mAbs. Antibody binding was mainly restricted to residues alpha 68-74, the most critical sequence being alpha 68-71. Fish electric organ and human MIR form two distinct groups of strongly overlapping epitopes. Some peptide analogues enhanced mAb binding compared with Torpedo and human peptides, suggesting that the construction of a very antigenic MIR is feasible.     

Role of the main immunogenic region of acetylcholine receptor in myasthenia gravis. An Fab monoclonal antibody protects against antigenic modulation by human sera

Antigenic modulation of acetylcholine receptor (AChR), i.e., acceleration of its internalization and degradation rate by antibody-cross-linking, is considered to be one of the two main causes of AChR loss in myasthenia gravis (MG). The majority of the antibodies to AChR are directed to the main immunogenic region (MIR) on the alpha-subunit of the receptor. We here examine the relative contribution of the anti-MIR antibody fraction (as well as of another fraction) to the antigenic modulation caused by MG patients' sera. Fab fragments of an anti-MIR monoclonal antibody (mAb) or a mAb to the beta-subunit (neither of which causes antigenic modulation) were allowed to shield their corresponding regions on the AChR on the mouse muscle cell line BC3H1. The 27 MG sera subsequently added thus bound to all other regions except to the protected one, and the resulting antigenic modulation was measured. The anti-MIR mAb protected the AChR by 68 +/- 16%. This is interpreted as the contribution to antigenic modulation of the anti-MIR antibody fraction in the human sera. This percentage correlated very well with the occurrence of the anti-MIR antibodies in the same sera. The anti-beta mAb gave only small protection of the AChR. No significant pattern differences were observed between sexes, early and recent onset of the disease, or high and low antibody titers. It is concluded that as far as it concerns the one of the pathogenic mechanisms in MG, i.e., the antigenic modulation, the MIR seems to be the main pathogenic region. The observation that a single mAb can efficiently protect the AChR in this system may prove to be of therapeutic interest.     

Molecular modeling of the complex between Torpedo acetylcholine receptor and anti-MIR Fab198

Myasthenia gravis is a neuromuscular disorder caused by an antibody-mediated autoimmune response to the muscle-type nicotinic acetylcholine receptor (AChR). The majority of monoclonal antibodies (mAbs) produced in rats immunized with intact AChR compete with each other for binding to an area of the alpha-subunit called the main immunogenic region (MIR). The availability of a complex between the AChR and Fab198 (Fab fragment of the anti-MIR mAb198) would help understand how the antigen and antibody interact and in designing improved antibody fragments that protect against the destructive activity of myasthenic antibodies. In the present study, we modeled the Torpedo AChR/Fab198 complex, based primarily on the recent 4A resolution structure of the Torpedo AChR. In order to computationally dock the two structures, we used the ZDOCK software. The total accessible surface area change of the complex compared to those of experimentally determined antigen-antibody complexes indicates an intermediate size contact surface. CDRs H3 and L3 seem to contribute most to the binding, while L2 seems to contribute least. These data suggest mutagenesis experiments aimed at validating the model and improving the binding affinity of Fab198 for the AChR.     

Myasthenia Gravis: Effect on Antibody Binding of Conservative Substitutions of Amino Acid Residues Forming the Main Immunogenic Region of the Nicotinic Acetylcholine Receptor

Abstract

In Myasthenia Gravis most anti-acetylcholine receptor (AChR) antibodies are against a highly conserved area of the AChR α-subunit called the Main Immunogenic Region (MIR). Amino acid residues critical for MIR formation have been located within the sequence α67–76. In the present study, binding of anti-AChR monoclonal antibodies (mAbs) to synthetic peptide analogues of the sequence α67–76 of human and Torpedo AChRs containing conservative single-residue substitutions identified the amino acid residues most important to the antigenicity of the MIR sequence, and offered clues to its tridimensional structure.

Conservative substitutions of residues Asn₆₈ and Asp₇₁ greatly diminished mAb binding, identifying them as critical contact residues for anti-MIR mAbs. Substitutions at Asp₇₀ and Tyr₇₂ moderately affected binding. Cross-reactive mAbs originally raised against Electrophorus AChR bound single residue-substituted synthetic peptides in a manner consistent with the possibility that Electrophorus AChR may have a glutamic acid residue at position α70 or α71. Substitutions at residues Asp/Ala₇₀ and Val/Ile₇₀ between human and Torpedo α-subunits may be size-compensating, suggesting these amino acids in the native AChR may be in closer proximity than proposed in previous models of the MIR.     

Amino Acid Residues Within the Sequence Region α55–74 of Torpedo Nicotinic Acetylcholine Receptor Interacting with Antibodies to the Main Immunogenic Region and with Snake α-Neurotoxins

Abstract

The sequence region 55–74 of the α-subunit of the acetylcholine receptor (AChR) from Torpedo californica electroplax comprises the amino-terminal end of a sequence segment—residues α67–76—forming the main immunogenic region (MIR), which is most frequently recognized by anti-AChR autoantibodies in myasthenia gravis. The synthetic sequence α55–74 of Torpedo AChR binds α-bungarotoxin (αBTX), suggesting that amino acid residues within this sequence region may contribute to formation of an αBTX binding site.

Using single-residue substituted synthetic analogues of the sequence α55–74 of Torpedo AChR, in which each residue was sequentially substituted by either glycine or alanine, we sought identification of the amino acids involved in interaction with α-neurotoxins and with three different anti-MIR monoclonal antibodies (mAbs 6, 22, and 198). Substitution of Arg₅₅, Arg₅₇, Trp₆₀, Arg₆₄, Leu₆₅, Arg₆₆, Trp₆₇, or Asn₆₈ strongly inhibited α-toxin binding, whereas substitutions of Ile₆₁, Val₆₃, Pro₆₉, Ala₇₀, Asp₇₁, or Tyr₇₂ had marginal effects. Substitutions within the region α68–72 significantly diminished binding of anti-MIR mAbs, although residue preferences differed among mAbs. Further, substituting Trp₆₀ substantially reduced binding of mAb 198, and moderately affected binding of mAb 6, and substitution of Asp₆₂ slightly but consistently affected binding of mAbs 6 and 22.     

The third-dimensional structure of the complex between an Fv antibody fragment and an analogue of the main immunogenic region of the acetylcholine receptor: a combined two-dimensional NMR, homology, and molecular modeling approach

Binding of autoantibodies to the acetylcholine receptor (AChR) plays a major role in the autoimmune disease Myasthenia gravis (MG). In this paper, we propose a structure model of a putative immunocomplex that gives rise to the reduction of functional AChR molecules during the course of MG. The model complex consists of the [G(70), Nle(76)] decapeptide analogue of the main immunogenic region (MIR), representing the major antigenic epitope of AChR, and the single chain Fv fragment of monoclonal antibody 198, a potent MG autoantibody. The structure of the complexed decapeptide antigen [G(70), Nle(76)]MIR was determined using two-dimensional nmr, whereas the antibody structure was derived by means of homology modeling. The final complex was constructed using calculational docking and molecular dynamics. We termed this approach "directed modeling," since the known peptide structure directs the prestructured antibody binding site to its final conformation. The independently derived structures of the peptide antigen and antibody binding site already showed a high degree of surface complementarity after the initial docking calculation, during which the peptide was conformationally restrained. The docking routine was a soft algorithm, applying a combination of Monte Carlo simulation and energy minimization. The observed shape complementarity in the docking process suggested that the structure assessments already led to anti-idiotypic conformations of peptide antigen and antibody fragment. Refinement of the complex by dynamic simulation yielded improved surface adaptation by small rearrangements within antibody and antigen. The complex presented herein was analyzed in terms of antibody-antigen interactions, properties of contacting surfaces, and segmental mobility. The structural requirements for AChR complexation by autoantibodies were explored and compared with experimental data from alanine scans of the MIR peptides. The analysis revealed that the N-terminal loop of the peptide structure, which is indispensable for antibody recognition, aligns three hydrophobic groups in a favorable arrangement leading to the burial of 40% of the peptide surface in the binding cleft upon complexation. These data should be valuable in the rational design of an Fv mutant with much improved affinity for the MIR and AChR to be used in therapeutic approaches in MG.     

The main immunogenic region of the nicotinic acetylcholine receptor. Identification of amino acid residues interacting with different antibodies

In myasthenia gravis a highly conserved area of the nicotinic receptor (AcChR) dominates the autoantibody response (main immunogenic region, MIR), and it is formed by residues within the sequence segment 67-76 of the AcChR alpha-subunit. We have studied the binding of eight anti-MIR mAb to synthetic peptides containing the sequence segment 67-76 of the human alpha-subunit, and peptide analogues containing single residue substitutions of this sequence. We used also a peptide where both Asp70 and Asp71 were substituted by glycine residues. The binding of six anti-MIR mAb was strongly influenced by several substitutions. All these mAb required residues Asn68, and Pro69 for binding. Five of them required also Asp71 and Tyr72. Substitution of Asp70, which is an Ala residue in Torpedo AcChR, was irrelevant for the binding of an anti-Torpedo and an anti-Electrophorus mAb, and moderately reduced the binding of an anti-human mAb (no. 203). Substitution of Trp67 moderately reduced the binding of some of these mAbs. A mAb of this group (the antihuman mAb no. 198) bound in a manner only slightly influenced by ionic strength, whereas the binding of the other five mAb of this group was very sensitive to the ionic strength. Two anti-Electrophorus MIR mAb bound similarly to all peptide analogues in low ionic strength. At high ionic strength only the peptide analogue where Asp 70 was changed to a Gly residue bound significantly. This may indicate that the Electrophorus MIR has an uncharged residue at this position, as does Torpedo AcChR. Residues at position 73, 74, 75, and 76 were of little or no importance for the binding of all anti-MIR mAb. A free amino terminus was essential for the binding of most mAb. The results of competition experiments between different peptides and native AcChR for mAb binding were consistent with those obtained in direct binding experiments.     

Main Immunogenic Region of Torpedo Electroplax and Human Muscle Acetylcholine Receptor: Localization and Microheterogeneity Revealed by the Use of Synthetic Peptides

Most anti-nicotinic acetylcholine receptor (AChR) antibodies in myasthenia gravis are directed against an immunodominant epitope or epitopes [main immunogenic region (MIR)] on the AChR alpha-subunit. Thirty-two synthetic peptides, corresponding to the complete Torpedo alpha-subunit sequence and to a segment of human muscle alpha-subunit, were used to map the epitopes for 11 monoclonal antibodies (mAbs) directed against the Torpedo and/or the human MIR and for a panel of anti-AChR mAbs directed against epitopes on the alpha-subunit other than the MIR. A main constituent loop of the MIR was localized within residues alpha 67-76. Residues 70 and 75, which are different in the Torpedo and human alpha-subunits, seem to be crucial in determining the binding profile for several mAbs whose binding to the peptides correlated very well with their binding pattern to native Torpedo and human AChRs. This strongly supports the identification of the peptide loop alpha 67-76 as the actual location of the MIR on the intact AChR molecule. Residues 75 and 76 were necessary for binding of some mAbs and irrelevant for others, in agreement with earlier suggestions that the MIR comprises overlapping epitopes. Structural predictions for the sequence segment alpha 67-76 indicate that this segment has a relatively high segmental mobility and a very strong turning potential centered around residues 68-71. The most stable structure predicted for this segment, in both the Torpedo and human alpha-subunits, is a hairpin loop, whose apex is a type I beta-turn and whose arms are beta-strands. This loop is highly hydrophilic, and its apex is negatively charged. All these structural properties have been proposed as characteristic of antibody binding sites. We also localized the epitopes for mAbs against non-MIR regions. Among these, the epitope for a monoclonal antibody (mAb 13) that noncompetitively inhibits channel function was localized within residues alpha 331-351.     

Monoclonal antibodies to the main immunogenic region of the nicotinic acetylcholine receptor bind to residues 61-76 of the alpha subunit

Monoclonal antibodies (mAbs) to the main immunogenic region (MIR) bind to fusion proteins containing region 37-200 of the alpha chain of Torpedo, mouse, and chicken nicotinic acetylcholine receptor. In the case of the mouse alpha chain, these mAbs react with sequence 61-216 but not with 74-216. A synthetic peptide M1, containing residues 61-76 of the mouse alpha chain, also binds these anti-MIR mAbs, showing that all or part of their binding site is included in this region. The conformational dependence and epitope specificity of the mAbs are discussed.     

Structure and transmembrane nature of the acetylcholine receptor in amphibian skeletal muscle as revealed by cross-reacting monoclonal antibodies

A collection of 126 monoclonal antibodies (mAbs) made against acetylcholine receptors (AChRs) from the electric organs of Torpedo californica or Electrophorus electricus was tested for cross-reactivity with AChRs in cryostat sections of skeletal muscle from Rana pipiens and Xenopus laevis by indirect immunofluorescence. 49 mAbs (39%) cross-reacted with AChRs from Rana, and 25 mAbs (20%) cross-reacted with AChRs from Xenopus. mAbs specific for each of the four subunits of electric organ AChR (alpha, beta, gamma, delta) cross-reacted with AChRs from each amphibian species. mAbs cross-reacting with Xenopus AChRs were, with one exception, a subset of the mAbs cross-reacting with Rana AChRs. The major difference detected between the two species was in binding by mAbs specific for the main immunogenic region (MIR) of the alpha-subunit. Whereas 22 of 33 anti-MIR mAbs tested cross-reacted with Rana AChRs, only one of these mAbs cross-reacted with Xenopus AChRs. Some (32) of the cross-reacting mAbs were tested for binding to AChRs in intact muscle. 21 of these mAbs bound to AChRs only when membranes were made permeable with saponin. Electron microscopy using immunoperoxidase or colloidal gold techniques revealed that these mAbs recognize cytoplasmic determinants and that mAbs that do not require saponin in order to bind AChRs in intact muscle recognize extracellular determinants. These results suggest that AChRs in skeletal muscle of Rana and Xenopus are composed of subunits corresponding to the alpha-, beta-, gamma-, and delta-subunits of AChRs from fish electric organs. The subunit specificity of mAbs whose binding was examined by electron microscopy suggests that parts of each subunit (alpha, beta, gamma, delta) are exposed on the cytoplasmic surface and that, as in AChRs from fish electric organs and mammalian muscle, the MIR on alpha-subunits of Rana AChRs is exposed on the extracellular surface.     

Two-dimensional 1H-NMR study of antigen-antibody interactions: binding of synthetic decapeptides to an anti-acetylcholine receptor monoclonal antibody

Two-dimensional NMR experiments [correlated spectroscopy (COSY) and two-dimensional transferred nuclear Overhauser enhancement spectroscopy (TR-NOESY)] have been applied to study the interactions of a monoclonal antibody (mAb) directed to the main immunogenic region (MIR) of the acetylcholine receptor (AChR), and four synthetic decapeptides from the MIR. The decapeptides were the Torpedo AChR alpha 67-76 fragment (W67-N68-P69-A70-D71-Y72-G73-+ ++G74-I75-K76) and its three [A69], [A73], and [A76] analogues. The results led to the following conclusions: (1) the magnitude of the TR-NOE cross peaks does not depend only on the structuration of the peptide in the bound state, but also on restrictions of the mobility, i.e., on the correlation time tau c, which can be different for every residue; (2) the binding capacity of the synthetic peptides to mAbs measured by radioimmunoassay is directly correlated to the NOE magnitude; and (3) the combined interpretation of the COSY and TR-NOESY experiments gives a qualitative information about the nature and the overall conformation of the sequence which is in contact with the mAb binding site.     

Conformational requirements for molecular recognition of acetylcholine receptor main immunogenic region (MIR) analogues by monoclonal anti-MIR antibody: A two-dimensional nuclear magnetic resonance and molecular dynamics approach

The conformational properties of two [D -A⁷⁰, A⁷⁶] and [Aib⁷⁰, A⁷⁶] analogues of the α67–76 Torpedo acetylcholine receptor fragment, with low binding capacity for the anti main immunogenic region (MIR) antibodies, were studied in DMSO by two-dimensional nmr techniques and molecular dynamics simulations. The results were compared to the free and bound conformations of the [A⁷⁶] analogue, which has twice more affinity for the anti-MIR monoclonal antibody 6 (mAb6), than the natural Torpedo sequence. It appeared that a single substitution of the A⁷⁰, at a crucial position, by the D -A⁷⁰ or Aib⁷⁰, could modify completely the conformational behavior of the peptide and reduced its recognition by the anti-MIR antibody. The WNPADY rigid structure at the N-terminal part was essential for antibody recognition. The adjacent more flexible C-terminal sequence (GGIK) gives additional stability to the monoclonal antibody–peptide complex probably due to an adequate orientation of the peptide side chains in the complex, by setting them in close contact with the antibody. © 1993 John Wiley & Sons, Inc.     

Monoclonal anti-idiotopic antibodies against myasthenia-inducing anti-acetylcholine receptor monoclonal antibodies. Preponderance of nonparatope-directed antibodies affecting antigen binding

To analyze components of the idiotypic network in experimental autoimmune disease, we produced 17 isogeneic anti-idiotopic monoclonal antibodies (anti-Id) against two experimental autoimmune myasthenia gravis-producing anti-acetylcholine receptor (anti-AChR) monoclonal antibodies. We studied the binding of five of the anti-Id to the anti-AChR monoclonal antibodies bearing the complementary idiotopes (Id-mAb). They bound with Kd values ranging from 0.06 to 0.86 nM, values comparable to those of Id-mAb:AChR complexes (0.26 and 0.34 nM). All of the anti-Id tested moderately inhibited the binding of AChR to Id-mAb, whereas for each anti-Id, AChR either strongly inhibited anti-Id binding or had no effect on anti-Id binding. Hence, the inhibition of Id-mAb:AChR binding by anti-Id was not reciprocal with the inhibition of anti-Id:Id-mAb binding by AChR. For each anti-Id, the relative affinities of anti-Id and AChR for Id-mAb together with the lack of symmetry of inhibition by anti-Id compared to inhibition by AChR indicate that these two "ligands" are not competitive inhibitors. Consequently, anti-Id and AChR do not bind to overlapping sites on the Id-mAb, suggesting that the observed inhibition is mediated allosterically. This may be a common mechanism of anti-Id:Id binding, which would have important implications for the mechanism of anti-Id-induced suppression.     

Monoclonal antibodies to Torpedo acetylcholine receptor. Characterisation of antigenic determinants within the cholinergic binding site

Thirteen monoclonal antibodies (mAb) to the acetylcholine receptor (AChR) from Torpedo marmorata showed high avidity for the receptor but none exhibited binding to muscle AChR solubilised from seven other animal species. Five mAb and Fab monomer fragments prepared from two of them, inhibited alpha-bungarotoxin (alpha BuTx) binding to receptor by a maximum of 50%. In the presence of excess mAb the 125I-alpha BuTx bound could be precipitated by anti-IgG indicating that the mAb bound to only one of the two alpha BuTx binding sites on each AChR monomer. This site appeared to have a lower affinity for d-tubocurarine and decamethonium than the non-mAb site. Binding of five anti-site mAb was mutually competitive and four of them (AS2-AS5) were inhibited by other cholinergic ligands and influenced by four non-toxin binding site antibodies. One (AS1) bound within the toxin binding site yet outside the main neurotransmitter binding region. It is concluded that these five mAb distinguish between the two alpha BuTx binding sites on the Torpedo AChR, and bind only to the site which displays lower affinity for d-tubocurarine and other competitive ligands.     

Microfilaments and actin-associated proteins at sites of membrane-substrate attachment within acetylcholine receptor clusters

Rat myotubes in tissue culture form broad areas of close contact with the substrate. These areas often display two distinct, interdigitating sets of membrane domains. One, the "contact domain", is close to the substrate; the other, termed the "AChR domain", is further from the substrate and is rich in acetylcholine receptors (AChR). We have used fluorescence techniques to study the organization of the cytoskeleton in these areas. Substrate-apposed membrane of the myotubes was exposed either by shearing or by permeabilizing the cells with a neutral detergent. Phalloidin derivatives and affinity-purified polyclonal or monoclonal antibodies specific for cytoskeletal proteins were then applied to the samples. Sheared samples were observed by epifluorescence microscopy; detergent-permeabilized samples were observed by total internal reflection fluorescence microscopy. We found that, like antivinculin, fluorescent phalloidin derivatives and antibodies to alpha-actinin, filamin, and talin preferentially labeled the contact domains. This suggests that bundles of microfilaments associate with the membrane at sites of myotube-substrate attachment. In contrast, a 43K protein, closely associated with AChR, was present only at AChR domains. A monoclonal antibody to actin labeled both AChR and contact domains, suggesting that actin is enriched over both regions. Our results suggest that, like the plasma membrane of AChR clusters, the underlying membrane skeleton is organized into at least two distinct domains.     

Mapping of a cholinergic binding site by means of synthetic peptides, monoclonal antibodies, and alpha-bungarotoxin

Previous studies by several laboratories have identified a narrow sequence region of the nicotinic acetylcholine receptor (AChR) alpha subunit, flanking the cysteinyl residues at positions 192 and 193, as containing major elements of, if not all, the binding site for cholinergic ligands. In the present study, we used a panel of synthetic peptides as representative structural elements of the AChR to investigate whether additional segments of the AChR sequences are able to bind alpha-bungarotoxin (alpha-BTX) and several alpha-BTX-competitive monoclonal antibodies (mAbs). The mAbs used (WF6, WF5, and W2) were raised against native Torpedo AChR, specifically recognize the alpha subunit, and bind to AChR is inhibited by all cholinergic ligands. WF6 competes with agonists, but not with low mol. wt. antagonists, for AChR binding. The synthetic peptides used in this study were approximately 20 residue long, overlapped each other by 4-6 residues, and corresponded to the complete sequence of Torpedo AChR alpha subunit. Also, overlapping peptides, corresponding to the sequence segments of each Torpedo AChR subunit homologous to alpha 166-203, were synthesized. alpha-BTX bound to a peptide containing the sequence alpha 181-200 and also, albeit to a lesser extent, to a peptide containing the sequence alpha 55-74. WF6 bound to alpha 181-200 and to a lesser extent to alpha 55-74 and alpha 134-153. The two other mAbs predominantly bound to alpha 55-74, and to a lesser extent to alpha 181-200. Peptides alpha 181-200 and alpha 55-74 both inhibited binding of 125I-alpha-BTX to native Torpedo AChR. None of the peptides corresponding to sequence segments from other subunits bound alpha-BTX or WF6, or interfered with their binding. Therefore, the cholinergic binding site is not a single narrow sequence region, but rather two or more discontinuous sequence segments within the N-terminal extracellular region of the AChR alpha subunit, folded together in the native structure of the receptor, contribute to form a cholinergic binding region. Such a structural arrangement is similar to the "discontinuous epitopes" observed by X-ray diffraction studies of antibody-antigen complexes [reviewed in Davies et al. (1988)].     

Assembly of Torpedo acetylcholine receptors in Xenopus oocytes

To study pathways by which acetylcholine receptor (AChR) subunits might assemble, Torpedo alpha subunits were expressed in Xenopus oocytes alone or in combination with beta, gamma, or delta subunits. The maturation of the conformation of the main immunogenic region (MIR) on alpha subunits was measured by binding of mAbs and the maturation of the conformation of the AChR binding site on alpha subunits was measured by binding of alpha-bungarotoxin (alpha Bgt) and cholinergic ligands. The size of subunits and subunit complexes was assayed by sedimentation on sucrose gradients. It is generally accepted that native AChRs have the subunit composition alpha 2 beta gamma delta. Torpedo alpha subunits expressed alone resulted in an amorphous range of complexes with little affinity for alpha Bgt or mAbs to the MIR, rather than in a unique 5S monomeric assembly intermediate species. A previously recognized temperature-dependent failure in alpha subunit maturation may cause instability of the monomeric assembly intermediate and accumulation of aggregated denatured alpha subunits. Coexpression of alpha with beta subunits also resulted in an amorphous range of complexes. However, coexpression of alpha subunits with gamma or delta subunits resulted in the efficient formation of 6.5S alpha gamma or alpha delta complexes with high affinity for mAbs to the MIR, alpha Bgt, and small cholinergic ligands. These alpha gamma and alpha delta subunit pairs may represent normal assembly intermediates in which Torpedo alpha is stabilized and matured in conformation. Coexpression of alpha, gamma, and delta efficiently formed 8.8S complexes, whereas complexes containing alpha beta and gamma or alpha beta and delta subunits are formed less efficiently. Assembly of beta subunits with complexes containing alpha gamma and delta subunits may normally be a rate-limiting step in assembly of AChRs.     

Mapping the extracellular topography of the α-chain in free and in membrane-bound acetylcholine receptor by antibodies against overlapping peptides spanning the entire extracellular parts of the chain

The extracellular surface of theα-chain ofTorpedo california acetylcholine receptor (AChR) was mapped for regions that are accessible to binding with antibodies against a panel of synthetic overlapping peptides which encompassed the entire extracellular parts of the chain. The binding of the antipeptide antibodies to membrane-bound AChR (mbAChR) and to isolated, soluble AChR. was determined. The specificity of each antiserum was narrowed down by determining the extent of its cross-reaction with the two adjacent peptides that overlap the immunizing peptide. With mbAChR, high antibody reactivity was obtained with antisera against peptidesα1–16,α89–104,α158–174,α262–276, andα388–408. Lower, but significant, levels of reactivity were obtained with antibodies against peptidesα67–82,α78–93,α100–115, andα111–126. On the other hand, free AChR bound high levels of antibodies against peptidesα34–49,α78–93,α134–150,α170–186, andα194–210. It also bound moderate levels of antibodies against peptidesα262–276 andα388–408. Low, yet significant, levels of binding were exhibited by antibodies against peptidesα45–60,α111–126, andα122–138. These binding studies, which enabled a comparison of the accessible regions in mbAChR and free AChR, revealed that the receptor undergoes considerable changes in conformation upon removal from the cell membrane. The exposed regions found here are discussed in relation to the functional sites of AChR (i.e., the acetylcholine binding site, the regions that are recognized by anti-AChR antibodies, T-cells and autoimmune responses and the regions that bind short and long neurotoxins).