NMR mapping and secondary structure determination of the major acetylcholine receptor alpha-subunit determinant interacting with alpha-bungarotoxin

The alpha-subunit of the nicotinic acetylcholine receptor (alphaAChR) contains a binding site for alpha-bungarotoxin (alpha-BTX), a snake-venom-derived alpha-neurotoxin. Previous studies have established that the segment comprising residues 173-204 of alphaAChR contains the major determinant interacting with the toxin, but the precise boundaries of this determinant have not been clearly defined to date. In this study, we applied NMR dynamic filtering to determine the exact sequence constituting the major alphaAChR determinant interacting with alpha-BTX. Two overlapping synthetic peptides corresponding to segments 179-200 and 182-202 of the alphaAChR were complexed with alpha-BTX. HOHAHA and ROESY spectra of these complexes acquired with long mixing times highlight the residues of the peptide that do not interact with the toxin and retain considerable mobility upon binding to alpha-BTX. These results, together with changes in the chemical shifts of the peptide protons upon complex formation, suggest that residues 184-200 form the contact region. At pH 4, the molecular mass of the complex determined by dynamic light scattering (DLS) was found to be 11.2 kDa, in excellent agreement with the expected molecular mass of a 1:1 complex, while at pH >5 the DLS measurement of 20 kDa molecular mass indicated dimerization of the complex. These results were supported by T(2) measurements. Complete resonance assignment of the 11.2 kDa complex of alpha-BTX bound to the alphaAChR peptide comprising residues 182-202 was obtained at pH 4 using homonuclear 2D NMR spectra measured at 800 MHz. The secondary structures of both alpha-BTX and the bound alphaAChR peptide were determined using 2D (1)H NMR experiments. The peptide folds into a beta-hairpin conformation, in which residues (R)H186-(R)V188 and (R)Y198-(R)D200 form the two beta-strands. Residues (R)Y189-(R)T191 form an intermolecular beta-sheet with residues (B)K38-(B)V40 of the second finger of alpha-BTX. These results accurately pinpoint the alpha-BTX-binding site on the alphaAChR and pave the way to structure determination of this important alphaAChR determinant involved in binding acetylcholine and cholinergic agonists and antagonists.     

Design and synthesis of peptides that bind alpha-bungarotoxin with high affinity and mimic the three-dimensional structure of the binding-site of acetylcholine receptor

Alpha-bungarotoxin (alpha-BTX) is a highly toxic snake neurotoxin that binds to acetylcholine receptor (AChR) at the neuromuscular junction, and is a potent inhibitor of this receptor. In the following we review multi-phase research of the design, synthesis and structure analysis of peptides that bind alpha-BTX and inhibit its binding to AChR. Structure-based design concomitant with biological information of the alpha-BTX/AChR system yielded 13-mer peptides that bind to alpha-BTX with high affinity and are potent inhibitors of alpha-BTX binding to AChR (IC(50) of 2 nM). X-Ray and NMR spectroscopy reveal that the high-affinity peptides fold into an anti-parallel beta-hairpin structure when bound to alpha-BTX. The structures of the bound peptides and the homologous loop of acetylcholine binding protein, a soluble analog of AChR, are remarkably similar. Their superposition indicates that the toxin wraps around the binding-site loop, and in addition, binds tightly at the interface of two of the receptor subunits and blocks access of acetylcholine to its binding site. The procedure described in this article may serve as a paradigm for obtaining high-affinity peptides in biochemical systems that contain a ligand and a receptor molecule.     

Synthesis of an antigenic site of native acetylcholine receptor peptide 159-169 of Torpedo acetylcholine receptor alpha-chain.

A region of the alpha-subunit of the nicotinic acetylcholine receptor (AChR) of the Torpedo electric organ, containing residues 161-166, has been proposed to be a major antigenic site in the native AChR protein. We report the synthesis of a peptide corresponding to residues 159-169, which contains the proposed antigenic region. In quantitative radiometric titrations, radiolabelled anti-(native AChR) antibodies from three different species, rabbit, rat and dog, exhibited considerable binding (approx. 15% relative to native AChR) to Sepharose-immobilized peptide 159-169, but did not bind significantly to Sepharose-immobilized unrelated proteins or peptides. Specificity was further confirmed by the finding that no rabbit anti-AChR antibodies bound to the peptide after absorption with native AChR. These data indicate that the region 159-169 contains an antigenic site that is readily accessible in solubilized native Torpedo AChR.     

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)].     

Quantitation of junctional and extrajunctional acetylcholine receptors by electron microscope autoradiography after (125)I-α-bungarotoxin binding at mouse neuromuscular junctions

The distribution and quantitation of 125I-alpha-bungarotoxin (alpha-BTX) binding sites and thus acetylcholine receptor (AChR) were determined in mouse sternomastoid muscle by electron microscope autoradiography. We found that a valid criterion for receptor saturation at the neuromuscular junction was the complete elimination of neurally evoked tetanic muscle contractions, since, when such a criterion was used for the endpoint of toxin incubation, alpha-BTX was bound to approximately 90% of total available endplate sites. When, without implying localization, the presynaptic axonal membrane was used as a convenient reference structure, the concentration of alpha-BTX relative to this membrane was determined to be 46,000 +/- 27% sites/mum2.     

Direct binding of a myasthenia gravis related epitope to MHC class II molecules on living murine antigen-presenting cells.

MHC gene products present antigenic epitopes to the antigen receptor on T cells. Nevertheless, direct binding of such epitopes to MHC class II proteins on normal living antigen-presenting cells (APCs) has not yet been demonstrated. We have previously shown a significant difference in the ability of T cells of myasthenia gravis (MG) patients to proliferate in response to the synthetic peptide p195-212 of the human acetylcholine receptor (AChR) alpha-subunit in comparison to healthy controls. The observed proliferative responses correlated significantly with HLA-DR5. Moreover, lymph node cells of various mouse strains that were primed with the T cell epitope, p195-212, were found to proliferate to different extents. To investigate these observations further, we designed an assay for direct binding of p195-212 to MHC class II proteins on the surface of freshly prepared splenic adherent cells. Binding of a biotinylated p195-212 was monitored using phycoerythrin-avidin by flow cytometry. Fifteen to sixty per cent of the cells were labeled following incubation with the biotinylated peptide. Binding was observed only to splenic adherent cells derived from mouse strains of which T cells were capable of proliferating in response to p195-212. The binding specificity, in terms of epitope structure and its site of interaction on the cells, was shown by its inhibition with an excess of the unlabeled peptide or with the relevant monoclonal anti-I-A antibodies. These results constitute the first direct evidence for the specific binding of a T cell epitope to live APC.     

The mechanism for acetylcholine receptor inhibition by alpha-neurotoxins and species-specific resistance to alpha-bungarotoxin revealed by NMR

The structure of a peptide corresponding to residues 182-202 of the acetylcholine receptor alpha1 subunit in complex with alpha-bungarotoxin was solved using NMR spectroscopy. The peptide contains the complete sequence of the major determinant of AChR involved in alpha-bungarotoxin binding. One face of the long beta hairpin formed by the AChR peptide consists of exposed nonconserved residues, which interact extensively with the toxin. Mutations of these receptor residues confer resistance to the toxin. Conserved AChR residues form the opposite face of the beta hairpin, which creates the inner and partially hidden pocket for acetylcholine. An NMR-derived model for the receptor complex with two alpha-bungarotoxin molecules shows that this pocket is occupied by the conserved alpha-neurotoxin residue R36, which forms cation-pi interactions with both alphaW149 and gammaW55/deltaW57 of the receptor and mimics acetylcholine.     

Structural determinants of alpha-bungarotoxin binding to the sequence segment 181-200 of the muscle nicotinic acetylcholine receptor alpha subunit: effects of cysteine/cystine modification and species-specific amino acid substitutions

The sequence segment 181-200 of the Torpedo nicotinic acetylcholine receptor (nAChR) alpha subunit forms a binding site for alpha-bungarotoxin (alpha-BTX) [e.g., see Conti-Tronconi, B. M., Tang, F., Diethelm, B. M., Spencer, S. R., Reinhardt-Maelicke, S., & Maelicke, A. (1990) Biochemistry 29, 6221-6230]. Synthetic peptides corresponding to the homologous sequences of human, calf, mouse, chicken, frog, and cobra muscle nAChR alpha 1 subunits were tested for their ability to bind 125I-alpha-BTX, and differences in alpha-BTX affinity were determined by using solution (IC50S) and solid-phase (KdS) assays. Panels of overlapping peptides corresponding to the complete alpha 1 subunit of mouse and human were also tested for alpha-BTX binding, but other sequence segments forming the alpha-BTX site were not consistently detectable. The Torpedo alpha 1(181-200) and the homologous frog and chicken peptides bound alpha-BTX with higher affinity (KdS approximately 1-2 microM, IC50s approximately 1-2 microM) than the human and calf peptides (Kds approximately 3-5 microM, IC50s approximately 15 microM). The mouse peptide bound alpha-BTX weakly when attached to a solid support (Kd approximately 8 microM) but was effective in competing for 125I-alpha-BTX in solution (IC50 approximately 1 microM). The cobra nAChR alpha 1-subunit peptide did not detectably bind alpha-BTX in either assay. Amino acid substitutions were correlated with alpha-BTX binding activity peptides from different species. The role of a putative vicinal disulfide bound between Cys-192 and -193, relative to the Torpedo sequence, was determined by modifying the peptides with sulfhydryl reagents. Reduction and alkylation of the peptides decreased alpha-BTX binding, whereas oxidation of the peptides had little effect. Modifications of the cysteine/cystine residues of the cobra peptide failed to induce alpha-BTX binding activity. These results indicate that while the adjacent cysteines are likely to be involved in forming the toxin/alpha 1-subunit interface a vicinal disulfide bound was not required for alpha-BTX binding.     

High affinity binding of alpha-bungarotoxin to the purified alpha-subunit and to its 27,000-dalton proteolytic peptide from Torpedo marmorata acetylcholine receptor. Requirement for sodium dodecyl sulfate

Intact nicotinic acetylcholine receptor (AChR) tightly binds alpha-bungarotoxin. The two toxin-binding sites are presumed to be on the two alpha-subunits, either on or near the ACh-binding sites. Isolated alpha-subunits have been found to maintain weak binding to alpha-bungarotoxin (KD approximately 0.2 microM). We describe here conditions under which the alpha-subunit and a 27,000-dalton proteolytic peptide bound alpha-bungarotoxin with high affinity. The four subunits of Torpedo marmorata AChR, as well as several proteolytic peptides of the alpha-subunit, were first purified by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. We found that the purified alpha-subunit (but not the beta-, gamma- or delta-subunits) and its 27,000-dalton peptide specifically bound 125I-labeled alpha-bungarotoxin with KD approximately 3 and 6 nM, i.e., about two orders of magnitude lower than the intact AChR. Nearly 100% of the sites were recovered. The recovery of this high affinity binding required the presence of SDS (approximately 0.02%) but non-denaturing detergents had a strongly inhibitory effect. Unlabeled alpha-toxins competed with labeled alpha-bungarotoxin, alpha-bungarotoxin being more effective than all the other toxins tested. Decamethonium and hexamethonium competed efficiently with alpha-bungarotoxin binding but carbamylcholine had only a weak effect. The main immunogenic region of the AChR was only partially preserved since conformation-dependent monoclonal antibodies to this region bound the alpha subunit-toxin complexes, but much less efficiently than the intact AChR. We conclude that SDS can be advantageous to the recovery of high toxin binding to the alpha subunit which still has not completely recovered its native conformation.     

T cells reactive with a small synthetic peptide of the acetylcholine receptor can provide help for a clonotypically heterogeneous antibody response and subsequently impaired muscle function

The influence of T cell specificity was evaluated with regard to its role in the antibody response against the acetylcholine receptor (AChR) and resulting AChR-dependent muscle dysfunction. The reactivity of immune Th cells was restricted to a small region of the AChR alpha-subunit (amino acid residues 100-116) reported to be highly immunogenic. T cells primed to this peptide were found to demonstrate significant proliferation when challenged in vitro with either the homologous peptide or the intact AChR. Adoptive transfer of the peptide-immune T cells into immunologically naive recipient rats followed by AChR challenge resulted in the production of anti-AChR antibodies very similar to those produced under the regulation of T cells immune to the entire intact AChR with regard to overall clonotypic heterogeneity (measured by IEF) and their ability to interfere with AChR-dependent muscle contraction. Interestingly, when the threonine at position 106 was substituted with a proline, the resulting peptide continued to be equally, if not exceedingly, capable of stimulating T cell-proliferative responses, but was found to be ineffective at stimulating the levels of anti-AChR antibodies necessary for producing neuromuscular dysfunction.     

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.     

Determinant selection in murine experimental autoimmune myasthenia gravis. Effect of the bm12 mutation on T cell recognition of acetylcholine receptor epitopes.

C57BL/6 (B6) mice respond to immunization with acetylcholine receptor (AChR) from Torpedo californica as measured by T cell proliferation, antibody production, and the development of muscle weakness resembling human myasthenia gravis. The congenic strain B6.C-H-2bm12 (bm12), which differs from B6 by three amino acid substitutions in the beta-chain of the MHC class II molecule I-A, develops a T cell proliferative response but does not produce antibody or develop muscle weakness. By examining the fine specificity of the B6 and bm12 T cell responses to AChR by using T cell clones and synthetic AChR peptides, we found key differences between the two strains in T cell epitope recognition. B6 T cells responded predominantly to the peptide representing alpha-subunit residues 146-162; this response was cross-reactive at the clonal level to peptide 111-126. Based on the sequence homology between these peptides and the T cell response to a set of truncated peptides, the major B6 T cell epitope was determined to be residues 148-152. The cross-reactivity of peptides 146-162 and 111-126 could also be demonstrated in vivo. Immunization of B6 mice with either peptide primed for T cell responses to both peptides. In contrast, immunization of bm12 mice with peptide 111-126 primed for an anti-peptide response, which did not cross-react with 146-162. Peptide-reactive T cells were not elicited after immunization of bm12 mice with 146-162. These results define a major T cell fine specificity in experimental autoimmune myasthenia gravis-susceptible B6 mice to be directed at alpha-subunit residues 148-152. T cells from disease-resistant bm12 mice fail to recognize this epitope but do recognize other portions of AChR. We postulate that alpha-148-152 is a disease-related epitope in murine experimental autoimmune myasthenia gravis. In this informative strain combination, MHC class II-associated determinant selection, rather than Ag responsiveness per se, may play a major role in determining disease susceptibility.     

Myasthenogenicity of human acetylcholine receptor synthetic alpha-subunit peptide 125-147 does not require intramolecular disulfide cyclization

This study reports the synthesis of a disulfide-looped peptide corresponding to residues 125-147 (Cys 128-Cys 142) of the nicotinic acetylcholine receptor (AChR) of human skeletal muscle, H alpha 125-147 (Lys-Ser-Tyr-Cys-Glu-Ile-Ile-Val-Thr-His-Phe-Pro-Phe-Asp-Glu-Gln- Asn-Cys-Ser-Nle-Lys Leu-Gly), and a nondisulfide-looped analogue, H alpha 125-147(S) (Lys-Ser-Tyr-Ser-Glu-Ile-Ile-Val-Thr-His-Phe-Pro-Phe-Asp-Glu- Gln-Asn-Cys-Ser-Nle-Lys-Leu-Gly), in which the amino acid Cys 128 was replaced with serine. Both peptides induced antigen-specific helper T cell responses, as evidenced in vitro by lymph node cell proliferation and in vivo by production of anti-AChR antibodies. Rats immunized with 100 micrograms of either synthetic peptide, without conjugation to a carrier, produced anti-peptide antibodies which bound to native AChR in immunoprecipitation assays and induced modulation of membrane-bound AChR from cultured human myotubes. Both peptides also induced electrophysiologic and biochemical signs of experimental autoimmune myasthenia gravis. Thus, region 125-147 of the AChR alpha-subunit is at least partly exposed extracellularly in human muscle and contains one or more autoantigenic sites capable of stimulating T cells and B cells. Disulfide-linkage between residues Cys 128 and Cys 142 is not essential for myasthenogenicity.     

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.     

Structure of the agonist-binding site of the nicotinic acetylcholine receptor. [3H]acetylcholine mustard identifies residues in the cation-binding subsite.

To characterize the structure of the agonist-binding site of the Torpedo nicotinic acetylcholine receptor (AChR), we have used [3H]acetylcholine mustard [( 3H]AChM), a reactive analog of acetylcholine, to identify residues contributing to the cation-binding subsite. Reaction of [3H]AChM, in its aziridinium form, with AChR-rich membrane suspensions, resulted initially in reversible, high affinity binding (K approximately 0.3 microM) followed by slow alkylation of the acetylcholine-binding site. Incorporation of label into AChR alpha-subunit was inhibited by agonists and competitive antagonists, but not by noncompetitive antagonists, and reaction with 3 microM [3H]AChM for 2 h resulted in specific alkylation of 0.6% of alpha-subunits. Within the alpha-subunit, greater than 90% of specific incorporation was contained within an 18-kDa Staphylococcus aureus V8 proteolytic fragment beginning at Val-46 and containing N-linked carbohydrate. To identify sites of specific alkylation, [3H]AChM-labeled alpha-subunit was digested with trypsin, and the digests were fractionated by reverse phase high pressure liquid chromatography. Specifically labeled material was recovered within a single peak containing a peptide extending from Leu-80 to Lys-107. NH2-terminal amino acid sequencing revealed specific release of 3H in cycle 14 corresponding to alpha-subunit Tyr-93. Identification of Tyr-93 as the site of alkylation was confirmed by radiosequence analysis utilizing o-phthalaldehyde to establish that the released 3H originated from a peptide containing prolines at residues 2 and 9. Because [3H]AChM contains as its reactive group a positively charged quaternary aziridinium, alpha-subunit Tyr-93 is identified as contributing to the cation-binding domain of the AChR agonist-binding site. The selective reaction of [3H]AChM with tyrosyl rather than acidic side chains indicates the importance of aromatic interactions for the binding of the quaternary ammonium group, and the lack of reaction with the tyrosyl or acidic side chains within alpha 190-200 emphasizes the selective orientation of acetylcholine within its binding site.     

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.     

Species specificity of anti-acetylcholine receptor antibodies elicited by synthetic peptides

Two peptides corresponding to amino acid residues 351-368 of the alpha-subunits of Torpedo and human acetylcholine receptor (AChR) were synthesized. These peptides contain a segment (residues 355-364) which displays the greatest variability in amino acid sequence between the two species. Antibodies elicited against the two peptides cross-reacted with the respective native AChRs and were shown to be species specific by radioimmunoassay, immunoblotting, and immunofluorescence microscopy. Thus, antibodies against the Torpedo peptide cross-reacted with Torpedo AChR but did not bind to mammalian or chicken AChR. Antibodies against the human peptide proved to be specific probes for mammalian muscle AChR. They cross-reacted with mammalian AChR (human, calf, mouse, and rat) but not with Torpedo or chicken AChR. These antibodies were also shown to react preferentially with the extrajunctional form of muscle AChR, as compared to their reactivity with junctional muscle AChR. In immunofluorescence experiments, the anti-human peptide antibody stained AChR aggregates in sectioned or ethanol-permeabilized rat and mouse myotubes grown in culture but did not stain living myotubes. This indicates that the sequence 351-368 of the alpha-subunit of mammalian AChR is on the cytoplasmic face of muscle cell membranes, as predicted theoretically.     

Synthetic peptides corresponding to sequences of snake venom neurotoxins and rabies virus glycoprotein bind to the nicotinic acetylcholine receptor

Peptides corresponding to portions of loop 2 of snake venom curare-mimetic neurotoxins and to a structurally similar region of rabies virus glycoprotein were synthesized. Interaction of these peptides with purified Torpedo electric organ acetylcholine receptor was tested by measuring their ability to block the binding of 125I-labeled alpha-bungarotoxin to the receptor. In addition, inhibition of alpha-bungarotoxin binding to a 32-residue synthetic peptide corresponding to positions 173-204 of the alpha-subunit was determined. Neurotoxin and glycoprotein peptides corresponding to toxin loop 2 inhibited labeled toxin binding to the receptor with IC50 values comparable to those of nicotine and the competitive antagonist d-tubocurarine and to the alpha-subunit peptides with apparent affinities between those of d-tubocurarine and alpha-cobratoxin. Substitution of neurotoxin residue Arg37, the proposed counterpart of the quaternary ammonium of acetylcholine, with a negatively charged Glu residue reduced the apparent affinity about 10-fold. Peptides containing the neurotoxin invariant residue Trp29 and 10- to 100-fold higher affinities than peptides lacking this residue. These results demonstrate that relatively short synthetic peptides retain some of the binding ability of the native protein from which they are derived, indicating that such peptides are useful in the study of protein-protein interactions. The ability of the peptides to compete alpha-bungarotoxin binding to the receptor with apparent affinities comparable to those of other cholinergic ligands indicates that loop 2 of the neurotoxins and the structurally similar segment of the rabies virus glycoprotein act as recognition sites for the acetylcholine receptor. Invariant toxin residues Arg37 and Trp29 and their viral homologs play important, although not essential, roles in binding, possibly by interaction with complementary anionic and hydrophobic subsites on the acetylcholine receptor. The alpha-subunit peptide most likely contains all of the determinants for binding of the toxin and glycoprotein peptides present on the alpha-subunit, because these peptides bind to the 32-residue alpha-subunit peptide with the same or greater affinity as to the intact subunit.     

Fine localization of the major alpha-bungarotoxin binding site to residues alpha 189-195 of the Torpedo acetylcholine receptor. Residues 189, 190, and 195 are indispensable for binding

alpha-Bungarotoxin blocks acetylcholine-mediated ion channel opening of peripheral acetylcholine receptors (AChR). A major binding region for alpha-bungarotoxin has been recently identified within parts of the segment 170-204 of the alpha-subunit. We used the Pepscan systematic peptide synthesis system to determine the minimum Torpedo AChR segment required for alpha-bungarotoxin binding and to investigate the role of each residue within this segment. Continuously overlapping decapeptides within alpha 179-203 and several decapeptides covering other alpha-subunit sequences showed that alpha 188-197 and alpha 189-198 exhibited the best 125I-alpha-bungarotoxin binding activity (KD = 7.3 x 10(-8) and 4.3 x 10(-8) M, respectively). Several continuously overlapping nona-, octa-, hepta-, hexa-, and tetrapeptides showed that the heptapeptide alpha 189-195 was the minimum sequence with high binding activity (KD = 5.6 x 10(-8)M). d-Tubocurarine, but not carbamylcholine, blocked toxin binding. Twenty-six analogs of the alpha 188-197, most having 1 residue substituted by Ala or Gly, showed that Tyr189, Tyr190, and especially Asp195 were indispensable for 125I-alpha-bungarotoxin binding. Cys192 and Cys193 could be substituted by other amino acids, proving that the disulfide bond between alpha 192-193 was not required for alpha-bungarotoxin binding. The decreased alpha-bungarotoxin binding capacity of the equivalent human muscle AChR alpha 188-197 peptide was the result of substitution of Tyr by Thr at alpha 189.