Efficiency of acetylcholine receptor subunit assembly and its regulation by cAMP

Assembly of nicotinic acetylcholine receptor (AChR) subunits was investigated using mouse fibroblast cell lines stably expressing either Torpedo (All-11) or mouse (AM-4) alpha, beta, gamma, and delta AChR subunits. Both cell lines produce fully functional cell surface AChRs. We find that two independent treatments, lower temperature and increased intracellular cAMP can increase AChR expression by increasing the efficiency of subunit assembly. Previously, we showed that the rate of degradation of individual subunits was decreased as the temperature was lowered and that Torpedo AChR expression was acutely temperature sensitive, requiring temperatures lower than 37 degrees C. We find that Torpedo AChR assembly efficiency increases 56-fold as the temperature is decreased from 37 to 20 degrees C. To determine how much of this is a temperature effect on degradation, mouse AChR assembly efficiencies were determined and found to be only approximately fourfold more efficient at 20 than at 37 degrees C. With reduced temperatures, we can achieve assembly efficiencies of Torpedo AChR in fibroblasts of 20-35%. Mouse AChR in muscle cells is also approximately 30% and we obtain approximately 30% assembly efficiency of mouse AChR in fibroblasts (with reduced temperatures, this value approaches 100%). Forskolin, an agent which increases intracellular cAMP levels, increased subunit assembly efficiencies twofold with a corresponding increase in cell surface AChR. Pulse-chase experiments and immunofluorescence microscopy indicate that oligomer assembly occurs in the ER and that AChR oligomers remain in the ER until released to the cell surface. Once released, AChRs move rapidly through the Golgi membrane to the plasma membrane. Forskolin does not alter the intracellular distribution of AChR. Our results indicate that cell surface expression of AChR can be regulated at the level of subunit assembly and suggest a mechanism for the cAMP-induced increase in AChR expression.     

Fibroblasts transfected with Torpedo acetylcholine receptor beta-, gamma-, and delta-subunit cDNAs express functional receptors when infected with a retroviral alpha recombinant

Torpedo californica acetylcholine receptor (AChR) alpha-, beta-, gamma- , and delta-subunit cDNAs were each stably introduced into muscle and/or fibroblast cell lines using recombinant retroviral vectors and viral infection, or using SV-40 vectors and DNA-mediated cotransfection. The expressed proteins were characterized in terms of their molecular mass, antigenicity, posttranslational processing, cell surface expression, stability in fibroblasts, stability in differentiated and undifferentiated muscle cells, and ability (of alpha) to bind alpha-bungarotoxin (BuTx). We demonstrated that the alpha, beta, gamma, and delta polypeptides acquired one, one, two, and three units of oligosaccharide, respectively. If all four subunits were expressed in the same cell, fully functional cell surface AChRs were produced which had a Kd for BuTx of 7.8 X 10(-11) M. In contrast, subunits expressed individually were not detected on the surface of fibroblasts and the Kd for BuTx binding to individual alpha polypeptides was only approximately 4 X 10(-7) M. The half-lives of the alpha, gamma, and delta subunits at 37 degrees C were all found to be quite short (approximately 43 min), while the half-life of the beta subunit was found to be even shorter (approximately 12 min). The unique half-life of the beta subunit suggests that it might perform a key regulatory role in the process of AChR subunit assembly. One stable fibroblast cell line was established by transfection that expressed beta, gamma, and delta subunits simultaneously. When this cell line was infected with a retroviral alpha recombinant, fully functional cell surface AChRs were produced. The successful expression of this pentameric protein complex combining transfection and infection techniques demonstrates one strategy for stably introducing the genes of a heterologous multisubunit protein complex into cells.     

Acetylcholine receptor assembly is stimulated by phosphorylation of its gamma subunit

Different combinations of Torpedo acetylcholine receptor (AChR) subunits stably expressed in mouse fibroblasts were used to establish a role for phosphorylation in AChR biogenesis. When cell lines expressing fully functional AChR complexes (alpha 2 beta gamma delta) were labeled with 32P, only gamma and delta subunits were phosphorylated. Forskolin, which causes a 2- to 3-fold increase in AChR expression by stimulating subunit assembly, increased unassembled gamma phosphorylation, but had little effect on unassembled delta. The forskolin effect on subunit phosphorylation was rapid, significantly preceding its effect on expression. The pivotal role of the gamma subunit was established by treating alpha beta gamma and alpha beta delta cell lines with forskolin and observing increased expression of only alpha beta gamma complexes. This effect was also observed in alpha gamma, but not alpha delta cells. We conclude that the cAMP-induced increase in expression of cell surface AChRs is due to phosphorylation of unassembled gamma subunits, which leads to increased efficiency of assembly of all four subunits.     

Analysis of early events in acetylcholine receptor assembly

Mammalian cell lines expressing nicotinic acetylcholine receptor (AChR) subunit cDNAs from Torpedo californica were used to study early events in AChR assembly. To test the hypothesis that individual subunits form homooligomeric intermediates before assembling into alpha 2 beta gamma delta pentamers, we analyzed the sedimentation on sucrose density gradients of each subunit expressed separately in cell lines. We have shown previously that the acute temperature sensitivity of Torpedo AChR subunit assembly is due, in part, to misfolding of the polypeptide chains (Paulson, H.L., and T. Claudio. 1990. J. Cell Biol. 110:1705-1717). We use this phenomenon to further analyze putative assembly-competent intermediates. In nonionic detergent at an assembly-permissive temperature, the majority of alpha, beta, gamma, and delta subunits sediment neither as 3-4S monomers nor as 9S complexes, but rather as 6S species whether synthesized in fibroblasts, myoblasts, or differentiated myosyncytia. Several results indicate that the 6S species are complexes comprised predominantly of incorrectly folded subunit polypeptides. The complexes represent homoaggregates which form rapidly within the cell, are stable to mild SDS treatment and, in the case of alpha, contain some disulfide-linked subunits. The coprecipitation of alpha subunit with BiP or GRP78, a resident protein of the ER, further indicates that at least some of these internally sequestered subunits also associated with an endogenous protein implicated in protein folding. The majority of subunits expressed in these cell lines appear to be aggregates of subunits which are not assembly intermediates and are not assembly-competent. The portion which migrates as monomer, in contrast, appears to be the fraction which is assembly competent. This fraction increases at temperatures more permissive for assembly, further indicating the importance of the monomer as the precursor to assembly of alpha 2 beta gamma delta pentamers.     

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.     

Extracellular synaptic factors induce clustering of acetylcholine receptors stably expressed in fibroblasts

The clustering of nicotinic acetylcholine receptors (AChRs) is one of the first events observed during formation of the neuromuscular junction. To determine the mechanism involved in AChR clustering, we established a nonmuscle cell line (mouse fibroblast L cells) that stably expresses just one muscle-specific gene product, the AChR. We have shown that when Torpedo californica AChRs are expressed in fibroblasts, their immunological, biochemical, and electrophysiological properties all indicate that fully functional cell surface AChRs are produced. In the present study, the cell surface distribution and stability of Torpedo AChRs expressed in fibroblasts (AChR-fibroblasts) were analyzed and shown to be similar to nonclustered AChRs expressed in muscle cells. AChR-fibroblasts incubated with antibodies directed against the AChR induced the formation of small AChR microclusters (less than 0.5 micron 2) and caused an increase in the internalization rate and degradation of surface AChRs (antigenic modulation) in a manner similar to that observed in muscle cells. Two disparate sources of AChR clustering factors, extracellular matrix isolated from Torpedo electric organ and conditioned media from a rodent neuroblastoma-glioma hybrid cell line, each induced large (1-3 microns 2), stable AChR clusters with no change in the level of surface AChR expression. By exploiting the temperature-sensitive nature of Torpedo AChR assembly, we were able to demonstrate that factor-induced clusters were produced by mobilization of preexisting surface AChRs, not by directed insertion of newly synthesized AChRs. AChR clusters were never observed in the absence of extracellular synaptic factors. Our results suggest that these factors can interact directly with the AChR.     

The antigenic structure of the acetylcholine receptor from Torpedo californica

The immunological structure of the acetylcholine receptor (AChR) from the electric organ of Torpedo californica was studied using a large number of monoclonal antibodies which were initially selected for their abilities to bind to intact AChRs. The monoclonal antibodies were tested for their ability to bind to denatured AChR subunits labeled with 125I. Antibodies derived from rats immunized with individual denatured subunits or a mixture of subunits of Torpedo AChR reacted well in the assay. A much smaller proportion of antibodies derived from rats immunized with native Torpedo AChR or native AChR from Electrophorus electricus electric organ, bovine muscle, or human muscle reacted with denatured subunits of Torpedo AChR. Many monoclonal antibodies reacted with more than one subunit, but they always reacted best with the subunit used for immunization. Those monoclonal antibodies that bound to intact subunits were mapped more precisely by their ability to bind characteristic fragments of each subunit generated by proteolysis with Staphylococcal V8 protease. These fragments were analyzed by SDS polyacrylamide gel electrophoresis, and monoclonal antibodies that precipitated the same fragment pattern were placed in groups. By this method, we define a minimum of 28 determinants on Torpedo AChR.     

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.     

Antisera against an acetylcholine receptor alpha 3 fusion protein bind to ganglionic but not to brain nicotinic acetylcholine receptors

Neuronal nicotinic acetylcholine receptor (AChR) subtypes have been defined pharmacologically, immunologically, and by DNA cloning, but the correlations between these approaches are incomplete. Vertebrate neuronal AChRs that have been isolated are composed of structural subunits and ACh-binding subunits. A single kind of subunit can be used in more than one AChR subtype. Monoclonal antibody (mAb) 35 binds to structural subunits of subtypes of AChRs from both chicken brain and ganglia. By using antisera to a unique sequence of alpha 3 ACh-binding subunits expressed in bacteria, we show that ganglionic AChRs contain alpha 3 ACh-binding subunits, whereas the brain AChR subtype that binds mAb 35 does not. Subunit-specific antisera raised against recombinant proteins should be a valuable approach for identifying the subunit composition of receptors in multigene, multisubunit families.     

Analysis of specificity of antibodies against synthetic fragments of different neuronal nicotinic acetylcholine receptor subunits

We have compared specificity of a panel of polyclonal antibodies against synthetic fragments of the alpha7 subunit of homooligomeric acetylcholine receptor (AChR) and some subunits of heteromeric AChRs. The antibody interaction with extracellular domain of alpha7 subunit of rat AChR (residues 7-208) produced by heterologous expression in E. coli and rat adrenal membranes was investigated by the ELISA method. For comparison, membranes from the Torpedo californica ray electric organ enriched in muscle-type AChR and polyclonal antibodies raised against the extracellular domain (residues 1-209) of the T. californica AChR alpha1 subunit were also used. Antibody specificity was also characterized by Western blot analysis using rat AChR extracellular domain alpha7 (7-208) and the membrane-bound T. californica AChR. Epitope localization was analyzed within the framework of AChR extracellular domain model based on the crystal structure of acetylcholine-binding protein available in the literature. According to this analysis, the 179-190 epitope is located on loop C, which is exposed and mobile. Use of antibodies against alpha7 (179-190) revealed the presence of alpha7 AChR in rat adrenal membranes.     

Identification of two amino acid residues in the epsilon subunit that promote mammalian muscle acetylcholine receptor assembly in COS cells

We have used a species difference in epsilon subunits of the acetylcholine receptor (AChR) to investigate regions of the subunit protein that are important in receptor assembly. Upon transient transfection of COS cells, mouse epsilon subunit cDNA is approximately 10 times more effective than that of the rat in supporting expression of surface AChRs when the other subunits are from either mouse or rat. In cells transfected with only alpha and epsilon subunit cDNAs, the formation of an alpha epsilon heterodimer, a presumed assembly intermediate, is also less efficient with rat than with mouse epsilon subunit. By site-directed mutagenesis, we have found that these differences can be accounted for by 2 amino acid differences in the N-terminal domain at positions 106 and 115 of the rat and mouse epsilon subunits, suggesting that the region near these 2 amino acid residues is important for AChR assembly.     

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)].     

A universal oligonucleotide probe for acetylcholine receptor genes. Selection and sequencing of cDNA clones for the mouse muscle beta subunit

A region of 25 nucleotides is highly conserved in genes coding for the alpha, beta, gamma, and delta subunits of the nicotinic acetylcholine receptor (AChR) of human, mouse, calf, chicken, and Torpedo. Based on this observation, a 2-fold degenerate oligonucleotide was synthesized and used as a probe to screen a cDNA library made from a mouse myogenic cell line. Clones coding for the beta, gamma, and delta subunits were identified by the probe. The protein sequence deduced from the beta subunit clones codes for a precursor polypeptide of 501 amino acids with a calculated molecular weight of 56,930 daltons, which includes a signal peptide of 23 amino acids. The protein sequence and structural features of the beta subunits of mouse, calf, and Torpedo are conserved. A clone coding for the mouse gamma subunit was isolated, and its identity was confirmed by alignment of its sequence to previously published cDNA sequences for the mouse and calf gamma subunits. The clone contained approximately 200 nucleotides more at its 3' end untranslated region than a mouse gamma clone recently described. Northern blot analysis, utilizing as probes these beta and gamma subunit cDNAs and previously characterized alpha and delta subunit cDNAs, shows that the steady-state levels of the four AChR mRNAs increase coordinately during terminal differentiation of cultured C2 and C2i mouse myoblasts. The increase in mRNA levels can account for the rise of cell surface receptors during myogenesis and suggests that the muscle AChR genes may be regulated during development by a common mechanism. Utilization of this oligonucleotide probe should prove useful for screening a variety of libraries made from different species and tissues which are known to express AChRs.     

Rapsyn-mediated clustering of acetylcholine receptor subunits requires the major cytoplasmic loop of the receptor subunits

During synaptogenesis at the neuromuscular junction, nicotinic acetylcholine receptors (AChRs) are organized into high-density postsynaptic clusters that are critical for efficient synaptic transmission. Rapsyn, an AChR associated cytoplasmic protein, is essential for the aggregation and immobilization of AChRs at the neuromuscular junction. Previous studies have shown that when expressed in nonmuscle cells, both assembled and unassembled AChR subunits are clustered by rapsyn, and the clustering of the alpha subunit is dependent on its major cytoplasmic loop. In the present study, we investigated the mechanism of rapsyn-induced clustering of the AChR beta, gamma, and delta subunits by testing mutant subunits for the ability to cocluster with rapsyn in transfected QT6 cells. For each subunit, deletion of the major cytoplasmic loop, between the third and fourth transmembrane domains, dramatically reduced coclustering with rapsyn. Furthermore, each major cytoplasmic loop was sufficient to mediate clustering of an unrelated transmembrane protein. The AChR subunit mutants lacking the major cytoplasmic loops could assemble into alphadelta dimers, but these were poorly clustered by rapsyn unless at least one mutant was replaced with its wild-type counterpart. These results demonstrate that the major cytoplasmic loop of each AChR subunit is both necessary and sufficient for mediating efficient clustering by rapsyn, and that only one such domain is required for rapsyn-mediated clustering of an assembly intermediate, the alphadelta dimer.     

Functional properties of human nicotinic AChRs expressed by IMR-32 neuroblastoma cells resemble those of alpha3beta4 AChRs expressed in permanently transfected HEK cells.

We characterized the functional and molecular properties of nicotinic acetylcholine receptors (AChRs) expressed by IMR-32, a human neuroblastoma cell line, and compared them to human alpha3 AChRs expressed in stably transfected human embryonic kidney (HEK) cells. IMR-32 cells, like neurons of autonomic ganglia, have been shown to express alpha3, alpha5, alpha7, beta2, and beta4 AChR subunits. From these subunits, several types of alpha3 AChRs as well as homomeric alpha7 AChRs could be formed. However, as we show, the properties of functional AChRs in these cells overwhelmingly reflect alpha3beta4 AChRs. alpha7 AChR function was not detected, yet we estimate that there are 70% as many surface alpha7 AChRs in IMR-32 when compared with alpha3 AChRs. Agonist potencies (EC(50) values) followed the rank order of 1,1-dimethyl-4-phenylpiperazinium (DMPP; 16+/-1 microM) > nicotine (Nic; 48 +/- 7 microM) > or = cytisine (Cyt; 57 +/- 3 microM) = acetylcholine (ACh; 59 +/- 6 microM). All agonists exhibited efficacies of at least 80% relative to ACh. The currents showed strong inward rectification and desensitized at a rate of 3 s(-1) (300 microM ACh; -60 mV). Assays that used mAbs confirmed the predominance of alpha3- and beta4-containing AChRs in IMR-32 cells. Although 18% of total alpha3 AChRs contained beta2 subunits, no beta2 subunit was detected on the cell surface. Chronic Nic incubation increased the amount of total, but not surface alpha3beta2 AChRs in IMR-32 cells. Nic incubation and reduced culture temperature increased total and surface AChRs in alpha3beta2 transfected HEK cells. Characterization of various alpha3 AChRs expressed in HEK cell lines revealed that the functional properties of the alpha3beta4 cell line best matched those found for IMR-32 cells. The rank order of agonist potencies (EC(50) values) for this line was DMPP (14 +/- 1 microM) = Cyt (18 +/- 1 microM) > Nic (56 +/- 15 microM > ACh (79 +/- 8 microM). The efficacies of both Cyt and DMPP were approximately 80% when compared with ACh and the desensitization rate was 2 s(-1). These data show that even with the potential to express several human nicotinic AChR subtypes, the functional properties of AChRs expressed by IMR-32 are completely attributable to alpha3beta4 AChRs.     

Monoclonal antibodies to cytoplasmic domains of the acetylcholine receptor

Fourteen clonal hybridoma lines that secrete monoclonal antibodies (mabs) to the Torpedo acetylcholine receptor (AChR) have been isolated. When analyzed by an immunoreplica technique, two mabs recognized the alpha subunit, three reacted with the beta subunit, one reacted with the gamma chain, and five recognized the delta subunit. One mab failed to react with any of the subunits using this assay and two mabs recognized determinants found on both the gamma and the delta subunits. These were classified according to their reactivities with the membrane-bound Torpedo AChR. One category is comprised of mabs (including both anti-alpha mabs) that recognize extracellular epitopes. A second classification included mabs that are unable to bind the membrane-associated AChR. The third category is comprised of mabs directed against cytoplasmic epitopes of the AChR. The latter mabs, all of which recognize the gamma or delta subunits or both, bind only slightly to sealed, outside-out Torpedo vesicles. The binding is increased 10-20-fold by either alkaline extraction or treatment of the vesicles with 10 mM lithium diiodosalicylate but not by permeabilization of the vesicles with saponin. Three of the six mabs in this category react with frog muscle endplates but only if the cytoplasmic surface of the membrane is accessible.     

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.