The relationship of the postsynaptic 43K protein to acetylcholine receptors in receptor clusters isolated from cultured rat myotubes

We have examined the relationship of acetylcholine receptors (AChR) to the Mr 43,000 receptor-associated protein (43K) in the AChR clusters of cultured rat myotubes. Indirect immunofluorescence revealed that the 43K protein was concentrated at the AChR domains of the receptor clusters in intact rat myotubes, in myotube fragments, and in clusters that had been purified approximately 100-fold by extraction with saponin. The association of the 43K protein with clustered AChR was not affected by buffers of high or low ionic strength, by alkaline pHs up to 10, or by chymotrypsin at 10 micrograms/ml. However, the 43K protein was removed from clusters with lithium diiodosalicylate or at alkaline pH (greater than 10). Upon extraction of 43K, several changes were observed in the AChR population. Receptors redistributed in the plane of the muscle membrane in alkali-extracted samples. The number of binding sites accessible to an anti-AChR monoclonal antibody directed against cytoplasmic epitopes (88B) doubled. Receptors became more susceptible to digestion by chymotrypsin, which destroyed the binding sites for the 88B antibody only after 43K was extracted. These results suggest that in isolated AChR clusters the 43K protein covers part of the cytoplasmic domain of AChR and may contribute to the unique distribution of this membrane protein.     

The postsynaptic 43K protein clusters muscle nicotinic acetylcholine receptors in Xenopus oocytes.

Nicotinic acetylcholine receptors (AChRs) are localized at high concentrations in the postsynaptic membrane of the neuromuscular junction. A peripheral membrane protein of Mr 43,000 (43K protein) is closely associated with AChRs and has been proposed to anchor receptors at postsynaptic sites. We have used the Xenopus oocyte expression system to test the idea that the 43K protein clusters AChRs. Mouse muscle AChRs expressed in oocytes after injection of RNA encoding receptor subunits are uniformly distributed in the surface membrane. Coinjection of AChR RNA and RNA encoding the mouse muscle 43K protein causes AChRs to form clusters of 0.5-1.5 microns diameter. AChR clustering is not a consequence of increased receptor expression in the surface membrane or nonspecific clustering of all membrane proteins. The 43K protein is colocalized with AChRs in clusters when the two proteins are expressed together and forms clusters of similar size even in the absence of AChRs. These results provide direct evidence that the 43K protein causes clustering of AChRs and suggest that regulation of 43K protein clustering may be a key step in neuromuscular synaptogenesis.     

Comparison of the postsynaptic 43-kDa protein from muscle cells that differ in acetylcholine receptor clustering activity

A peripheral membrane protein of Mr = 43,000 (43-kDa protein) is closely associated with the acetylcholine receptor (AChR) in Torpedo electrocyte postsynaptic membranes and may play a role in anchoring receptors at synaptic sites. A component immunologically related to the 43-kDa protein also occurs specifically at mammalian muscle synapses and in association with receptor clusters on cultured muscle cells. We have studied this mammalian protein in two mouse muscle cell lines, C2 and BC3H1, that differ in AChR clustering activity. The 43-kDa-related protein was purified from muscle cell detergent extracts by immunoaffinity chromatography using monoclonal antibodies (mAbs) prepared against the Torpedo 43-kDa protein and identified by immunoblotting. In both C2 and BC3H1 cells, a protein of molecular mass of approximately 43,000 was recognized by two mAbs with different epitope specificity. To measure the 43-kDa protein in mammalian muscle cells, we designed a quantitative immunological assay utilizing these two mAbs. As in Torpedo electric organ, the concentration of the 43-kDa protein and receptor was approximately equimolar in C2 cells and in BC3H1 cells. Furthermore, during differentiation of both muscle cell lines, the appearance of the 43-kDa protein correlated closely with that of the receptor, raising the intriguing possibility that the expression of these two proteins is controlled by similar regulatory mechanisms. These results indicate that the inability of BC3H1 cells to form AChR clusters apparently does not result from a deficiency in the 43-kDa protein.     

Ultrastructure of acetylcholine receptor clusters on cultured muscle fibers

The structure of regions with a high concentration of ACh receptors (clusters) on cultured skeletal muscle myotubes was examined by immunoperoxidase staining of bound alphaBT. The clusters did not appear to differ from the other regions except in their higher concentration of receptor.     

Early events in neuromuscular junction formation in vitro: induction of acetylcholine receptor clusters in the postsynaptic membrane and morphology of newly formed synapses

The development of clusters of acetylcholine (ACh) receptors at newly formed synapses between embryonic chick spinal cord and muscle cells grown in vitro has been studied by iontophoretic mapping with ACh. A semi-automated technique using on-line computer analysis of ACh responses and a photographic system to record the position of each ACh application permit the rapid construction of extensive and detailed maps of ACh sensitivity. Clusters of receptors, evident as peaks of ACh sensitivity, are present on many uninnervated myotubes. The distribution of ACh sensitivity closely parallels the distribution of 125I-alpha-bungarotoxin binding sites on the same muscle cell. In all cases where individual myotubes were adequately mapped before and after synapse formation, ingrowing axons induced new clusters of receptors rather than seeking out preexisting clusters. Synapses can form at active growth cones within 3 h of nerve-muscle contact. New receptor clusters can appear beneath neurites within a few hours. Many of the uninnervated clusters on innervated myotubes disappear with time. In contrast, receptor clusters on uninnervated myotubes remain in the same location for many hours. Synaptic clusters and clusters on uninervated myotubes are stable even though individual receptors are metabolized rapidly. The morphology of several identified sites of transmitter release was examined. At the scanning EM level, synapses appeared as small, rough-surfaced varicosities with filopodia that radiated outwards over the muscle surface. One synapse was studied by transmission EM. Acetylcholinesterase and a basement lamina were present within the synaptic cleft.     

Sciatin: a myotrophic protein increases the number of acetylcholine receptors and receptor clusters in cultured skeletal muscle

Factors present in neural extracts or in media conditioned by neurons have been shown by others to increase both the number of acetylcholine receptors (AChRs) and the number of receptor clusters in cultures of embryonic skeletal muscle. We have recently shown that the glycoprotein, sciatin, exerts trophic effects on developing muscle in vitro. In the present study, we investigated the effect of sciatin on AChRs in aneural cultures of chick skeletal muscle. Sciatin caused a significant increase in the number of AChRs/dish as measured by binding of ¹²⁵I-α-bungarotoxin (α-Btx) and in acetylcholinesterase (AChE) activity/dish in differentiating muscle cells. The increase in AChRs elicited by sciatin was due solely to increased receptor synthesis and incorporation. The rate of AChR synthesis in sciatin-treated cultures was as much as five times the control rate and was significantly reduced by cycloheximide (10 μM). AChR degradation was unaffected by the myotrophic protein. Although the number of AChRs/dish was increased by sciatin during myogenesis, AChR specific activity, expressed as picomoles ¹²⁵I-α-Btx bound/mg cell protein, was only transiently increased by the myotrophic protein. This contrasted with AChE specific activity in sciatin-treated cultures which remained elevated throughout differentiation. Autoradiographs of ¹²⁵I-α-Btx-labeled cultures showed that sciatin caused an increase in the number and size of AChR “hot spots” and maintained the integrity of these AChR clusters in aneural muscle cultures for up to 5 weeks. At this time control cultures had completely degenerated. The mechanism by which sciatin enhanced the synthesis of AChRs appeared to be distinct from that of tetrodotoxin (TTX), an agent which abolishes muscle activity. However, like theophylline, sciatin might evoke increased synthesis of AChRs via regulation of cyclic AMP since the myotrophic protein increased cAMP both in cells and in conditioned medium. The results of this study suggest that sciatin may be related to the diffusible factor(s) from motor neurons described by others which has trophic effects on AChRs. Furthermore, we suggest that this myotrophic protein may be responsible for the clustering of AChRs and maintenance of receptor clusters at neuromuscular junctions in developing avian muscle.     

Association of cytoskeletal proteins with newly formed acetylcholine receptor aggregates induced by embryonic brain extract

Aggregates of acetylcholine receptors (AChR) in muscle cell membranes are associated with accumulations of certain cytoskeletal and peripheral membrane proteins. We treated cultured rat myotubes briefly with embryonic brain extract (EBX) to promote AChR aggregation and determined the distribution of several of these proteins at early stages of aggregation. EBX-treated and control cultures were stained with tetramethylrhodamine-alpha-bungarotoxin to identify AChR aggregates and were then frozen and sectioned on a cryostat. These sections were stained with primary antibodies and fluoresceinated secondary antibodies to localize cytoskeletal proteins. The distributions of AChRs and cytoskeletal proteins was examined qualitatively and analyzed by a semiquantitative assay. Qualitatively, the 43K protein had a distribution that was virtually identical to that of AChR in both control and EBX-treated cultures, and it always colocalized with early AChR aggregates. The 58K protein similarly colocalized with early AChR aggregates, but it was also in aggregate-free areas of muscle membrane. The association of vinculin with the aggregates was quantitatively similar to that of the 43K and 58K proteins, but, qualitatively, its distribution did not follow that of the AChR as closely. Like the 58K protein and vinculin, alpha-actinin, filamin, and actin were concentrated in AChR aggregates and were also enriched elsewhere. However, they were less closely associated with the aggregates, both quantitatively and qualitatively. These results show that AChR aggregates induced by EBX tend to be enriched in the same cytoskeletal proteins that are present at the neuromuscular junction in vivo and at AChR clusters formed at sites of cell-substrate adhesion in vitro. Semiquantitative analysis also revealed that the fractional area of the cell surface associated with vinculin, alpha-actinin, and the 58K protein was the same in controls and EBX-treated myotubes, although the area enriched in AChR and the 43K protein increased about three-fold upon EBX treatment. These results suggest that AChR aggregates may form preferentially in membrane regions that are already enriched in these proteins.     

Distribution of filipin-sterol complexes on cultured muscle cells: cell- substratum contact areas associated with acetylcholine receptor clusters

Specialized areas within broad, close, cell-substratum contacts seen with reflection interference contrast microscopy in cultures of Xenopus embryonic muscle cells were studied. These areas usually contained a distinct pattern of light and dark spots suggesting that the closeness of apposition between the membrane and the substratum was irregular. They coincided with areas containing acetylcholine receptor clusters identified by fluorescence labeled alpha-bungarotoxin. Freeze-fracture of the cells confirmed these observations. The membrane in these areas was highly convoluted and contained aggregates of large P-face intramembrane particles (probably representing acetylcholine receptors). If cells were fixed and then treated with the sterol- specific antibiotic filipin before fracturing, the pattern of filipin- sterol complex distribution closely followed the pattern of cell- substratum contact. Filipin-sterol complexes were in low density in the regions where the membrane contained clustered intramembrane particles. These membrane regions were away from the substratum (bright white areas in reflection interference contrast; depressions of the P-face in freeze-fracture). Filipin-sterol complexes were also in reduced density where the membrane was very close to the substratum (dark areas in reflection interference contrast; bulges of the P-face in freeze- fracture). These areas were not associated with clustered acetylcholine receptors (aggregated particles). This result suggests that filipin treatment causes little or no artefact in either acetylcholine receptor distribution or membrane topography of fixed cells and that the distribution of filipin-sterol complexes may closely parallel the microheterogeneity of membranes that exist in living cells.     

Sodium transport by the acetylcholine receptor of cultured muscle cells.

Activation of the acetylcholine receptors of cultured muscle cells by carbamylcholine increases the rate of passive 22-Na+ uptake into the muscle cells up to 20-fold. The Na+ transport activity of the receptor desensitizes during exposure to carbamylcholine. The rate and extent of desensitization is reduced by lowering the assay temperature from 36 degrees to 2 degrees, allowing accurate measurements of initial rates of Na+ transport by the receptor. Activation of the receptor by carbamylcholine and acetylcholine is significantly cooperative (Hill coefficients of 1.4 to 2.0). Inhibition by D-tubocurarine is not cooperative. The carbamylcholine-induced Na+ transport activity of the receptor is inhibited 50% by 4 muM D-tubocurarine, 100 muM atropine, or 1.6 nM diiodo-alpha-bungarotoxin but is not affected by tetrodotoxin. The initial rate of Na+ transport by the receptor is temperature-independent between 2 degrees and 36 degrees. Receptor Na+ transport is saturable by Na+ at 2 degrees with an apparent Km of 150 plus and minus 20 mM. Saturation by Na+ not observed at 36 degrees at the concentrations tested. Saturation by Na+ is observed at 2 degrees both under conditions of net Na+ influx and under conditions of isotopic exchange at equilibrium. The receptor does not catalyze obligatory exchange diffusion at a detectable rate. Comparison of binding of [125-I]diiodo-alpha-bungarotoxin with rates of Na+ transport indicates a turnover number of 2 times 10-7 ions per min per receptor. These results are discussed in terms of the mechanism of Na+ transport by the receptor.     

Microtubules and the formation of acetylcholine receptor clusters in chick embryonic muscle cells

We have used the microtubule-stabilizing drug taxol to examine the relationship between microtubules and the appearance and cell surface distribution of acetylcholine receptors (AChRs) in primary cultures of chick embryonic muscle cells. Taxol at a 5-microM concentration induced the large scale polymerization of tubulin in muscle cells that was most obvious as intermittent bundles of microtubules along the myotube. Prominent bundles of microtubules were also clearly visible in the fibroblasts. This concentration of taxol had no significant effect on the incorporation rate, increased synthesis induced by brain extract or the total cell surface number of AChRs measured over a 24-h period. Thus, excess polymerization of microtubules does not affect the movement of receptors to the cell surface. However, when cell surface AChR distribution was examined using rhodamine-conjugated alpha-bungarotoxin, taxol treatment of myotubes was shown to induce the aggregation of receptors. If receptors were labeled before taxol addition, aggregation of these prelabeled receptors was also seen, a result indicating that taxol can induce the movement of receptors already in the membrane. We believe this evidence further implicates microtubules as being involved in the movement of these cell surface receptors in the plane of the myotube membrane.     

Treatments that extract the 43K protein from acetylcholine receptor clusters modify the conformation of cytoplasmic domains of all subunits of the receptor.

The nicotinic acetylcholine receptor (AChR) of Torpedo electric organ and vertebrate skeletal muscle is closely associated with a Mr 43,000 protein (43K). In this study, we have examined the effects on the AChR of treatments which remove the 43K protein. We used semiquantitative fluorescence techniques to measure the binding of antibodies to clustered AChR in cultured rat myotubes. We found that labeling by antibodies to the cytoplasmic portions of each of the four receptor polypeptides increased significantly upon extraction of the 43K protein. Labeling by an antibody to an extracellular epitope of the alpha subunits was not affected by removal of the 43K protein, suggesting that changes were restricted to the cytoplasmic domains of the AChR. Increases in labeling by antibodies were more limited following protease treatment, which removes most cytoskeletal structures but leaves the 43K protein bound to the membrane. Competition between an antibody to the beta subunit and an antibody to the gamma and delta subunits suggests that the cytoplasmic portion of the AChR still retains a degree of native structure in the absence of the 43K protein. Our results suggest that, although some of these changes may be due to simply exposing additional epitopes on the AChR, the cytoplasmic portions of all the subunits of the AChR undergo significant conformational changes upon extraction of the 43K protein.     

Interaction of the 43K protein with components of Torpedo postsynaptic membranes

Interactions of the major Mr 43 000 peripheral membrane protein (43K protein) with components of Torpedo postsynaptic membranes have been examined. Treatment of membranes with copper o-phenanthroline promotes the polymerization of 43K protein to dimers and higher oligomers. These high molecular weight forms of 43K protein can be converted to monomers by reduction with dithiothreitol and do not contain any of the other major proteins found in these membranes, including the subunits of the acetylcholine receptor, as shown by immunoblotting with monoclonal antibodies. To study directly its interactions with the membrane, the 43K protein was radioiodinated and purified by immunoaffinity chromatography. Purified 43K protein binds tightly to pure liposomes of various compositions in a manner that is not inhibited by KCl concentrations up to 0.75 M. The binding can be reversed by adjusting the pH of the reaction to 11, the same treatment that removes 43K protein from postsynaptic membranes. Unlabeled 43K protein solubilized from Torpedo membranes with cholate can be reconstituted with exogenously added lipids in the absence of the receptor. The results suggest that 43K protein molecules are amphipathic and that they may interact with each other and with the lipid bilayer. These interactions cannot explain the coextensive distribution of 43K proteins with acetylcholine receptors in situ. However, they could account for the association of the 43K protein with the postsynaptic membrane and may contribute to the maintenance of the structure of the cytoplasmic specialization of which this protein is a major component.     

A role of tyrosine phosphorylation in the formation of acetylcholine receptor clusters induced by electric fields in cultured Xenopus muscle cells

During the development of the neuromuscular junction, acetylcholine receptors (AChRs) become clustered in the postsynaptic membrane in response to innervation. In vitro, several non-neuronal stimuli can also induce the formation of AChR clusters. DC electric field (E field) is one of them. When cultured Xenopus muscle cells are exposed to an E field of 5-10 V/cm, AChRs become clustered along the cathode-facing edge of the cells within 2 h. Recent studies have suggested the involvement of tyrosine kinase activation in the action of several AChR clustering stimuli, including nerve, polymer beads, and agrin. We thus examined the role of tyrosine phosphorylation in E field-induced AChR clustering. An antibody against phosphotyrosine (PY) was used to examine the localization of PY-containing proteins in E field-treated muscle cells. We found that anti-PY staining was colocalized with AChR clusters along the cathodal edge of the cells. In fact, cathodal PY staining could be detected before the first appearance of AChR clusters. When cultures were subjected to E fields in the presence of a tyrosine kinase inhibitor, tyrphostin RG-50864, cathodal AChR clustering was abolished with a half maximal inhibitory dosage of 50 microM. An inactive form of tyrphostin (RG-50862) had no effect on the field-induced clustering. These data suggest that the activation of tyrosine kinases is an essential step in E field-induced AChR clustering. Thus, the actions of several disparate stimuli for AChR clustering seem to converge to a common signal transduction mechanism based on tyrosine phosphorylation at the molecular level.     

Cytoplasmic components of acetylcholine receptor clusters of cultured rat myotubes: the 58-kD protein

A 58-kD protein, identified in extracts of postsynaptic membrane from Torpedo electric organ, is enriched at sites where acetylcholine receptors (AChR) are concentrated in vertebrate muscle (Froehner, S. C., A. A. Murnane, M. Tobler, H. B. Peng, and R. Sealock. 1987. J. Cell Biol. 104:1633-1646). We have studied the 58-kD protein in AChR clusters isolated from cultured rat myotubes. Using immunofluorescence microscopy we show that the 58-kD protein is highly enriched at AChR clusters, but is also present in regions of the myotube membrane lacking AChR. Within clusters, the 58-kD protein codistributes with AChR, and is absent from adjacent membrane domains involved in myotube-substrate contact. Semiquantitative fluorescence measurements suggest that molecules of the 58-kD protein and AChR are present in approximately equal numbers. Differential extraction of peripheral membrane proteins from isolated AChR clusters suggests that the 58-kD protein is more tightly bound to cluster membrane than is actin or spectrin, but less tightly bound than the receptor-associated 43-kD protein. When AChR clusters are disrupted either in intact cells or after isolation, the 58-kD protein still codistributes with AChR. Clusters visualized by electron microscopy after immunogold labeling and quick-freeze, deep-etch replication show that, within AChR clusters, the 58-kD protein is sharply confined to AChR-rich domains, where it is present in a network of filaments lying on the cytoplasmic surface of the membrane. Additional actin filaments overlie, and are attached to, this network. Our results suggest that within AChR domains of clusters, the 58-kD protein lies between AChR and the receptor-associated 43-kD protein, and the membrane-skeletal proteins, beta-spectrin, and actin.     

Determination of the tissue distributions and relative concentrations of the postsynaptic 43-kDa protein and the acetylcholine receptor in Torpedo

A protein of Mr 43,000 (43-kDa protein) occurs on the postsynaptic membrane in close association with the acetylcholine receptor and comprises a major part of the postsynaptic cytoskeletal apparatus. We have devised an immunological assay for the 43-kDa protein to determine if it is confined to receptor-specific sites or if it, like general cytoskeletal proteins, has a more widespread tissue distribution. The assay utilizes monoclonal antibodies (Mab) to the 43-kDa protein that recognize two spatially separate epitopes. One Mab, attached to the well of a microtiter plate, binds the antigen which is then available to bind the biotin-derivatized second Mab. Bound second antibody is detected with either avidin-alkaline phosphatase or a more elaborate system using avidin, rabbit anti-avidin, and anti-rabbit IgG-alkaline phosphatase conjugate. A similar assay was developed for the receptor. The 43-kDa protein and the receptor are found in electric organ and, in 500-fold lower concentrations, in skeletal muscle but are not detectable in heart, liver, pancreas, or brain. In electric organ, the receptor and the 43-kDa protein are present in approximately equimolar concentrations. These results indicate that the 43-kDa protein is not a general membrane-associated cytoskeletal element and that its occurrence, and possibly also its function, is related to the acetylcholine receptor.     

Tyrosine phosphorylation and acetylcholine receptor cluster formation in cultured Xenopus muscle cells

Aggregation of the nicotinic acetylcholine receptor (AChR) at sites of nerve-muscle contact is one of the earliest events to occur during the development of the neuromuscular junction. The stimulus presented to the muscle by nerve and the mechanisms underlying postsynaptic differentiation are not known. The purpose of this study was to examine the distribution of phosphotyrosine (PY)-containing proteins in cultured Xenopus muscle cells in response to AChR clustering stimuli. Results demonstrated a distinct accumulation of PY at AChR clusters induced by several stimuli, including nerve, the culture substratum, and polystyrene microbeads. AChR microclusters formed by external cross- linking did not show PY colocalization, implying that the accumulation of PY in response to clustering stimuli was not due to the aggregation of basally phosphorylated AChRs. A semi-quantitative determination of the time course for development of PY labeling at bead contacts revealed early PY accumulation within 15 min of contact before significant AChR aggregation. At later stages (within 15 h), the AChR signal came to approximate the PY signal. We have reported the inhibition of bead-induced AChR clustering in response to beads by a tyrphostin tyrosine kinase inhibitor (RG50864) (Peng, H. B., L. P. Baker, and Q. Chen. 1991. Neuron. 6:237-246). RG50864 also inhibited PY accumulation at bead contacts, providing evidence for tyrosine kinase activation in response to the bead stimulus. These results suggest that tyrosine phosphorylation may play an important role in the generative stages of cluster formation, and may involve protein(s) other than or in addition to AChRs.     

Comparison of the control and pathways for degradation of the acetylcholine receptor and average protein in cultured muscle cells

In the studies reported here, we investigated whether the degradation of the acetylcholine receptor (AChR) in cultured muscle cells involves similar mechanisms as and is controlled in a manner similar to, the catabolism of the bulk of cell protein. We compared these processes after labeling cell protein with radioactive leucine or phenylalanine for 24 hours, or labeling the acetylcholine receptor with (¹²⁵I)-bungarotoxin. The apparent average half-life of cell protein was 38 ± 2 hours and that of the receptor-toxin complex was 25 ± 1 hours. Incubation in media lacking serum and embryo extract accelerated the degradation of both average protein and the receptor-toxin complex. Insulin reduced the rate of catabolism of both average protein and the receptor-toxin complex toward levels seen in the presence of serum. However, although these two degradative processes seem to be controlled similarly, they probably involve different mechanisms. The protease inhibitors leupeptin and chymostatin, which slowed overall proteolysis in nongrowing muscles and hepatocytes, reduced the degradation of the ACh receptor by 2–11-fold, but had no, or only slight, effects on the catabolism of average protein, even when overall proteolysis was accelerated by omitting serum and embryo extract. Chloroquine, an inhibitor of lysosomal function, also reduced the degradation of AChR, by about 10-fold, but decreased overall protein breakdown by only 20–30%. Incubation of myotubes at lower temperatures reduced both degradative processes, but affected the breakdown of the receptor to a greater extent. Thus the rate-limiting steps in these processes have different activation energies. Incubation with 2-deoxyglucose, an inhibitor of glycolysis, decreased the breakdown of average protein but not that of the receptor-toxin complex. However, the two degradative processes were sensitive to azide, an inhibitor of oxidative phosphorylation. Although the lysosome is the primary site for AChR degradation and perhaps for degradation of other surface proteins, the breakdown of most proteins in myotubes seems to involve a distinct proteolytic system requiring metabolic energy.