Early stages in the formation and stabilization of acetylcholine receptor aggregates on cultured myotubes: sensitivity to temperature and azide

We have studied the effects of temperature and sodium azide on the formation and stability of embryonic brain extract (EBX)2-induced acetylcholine receptor (AChR) aggregates on myotubes. Sequential changes in AChR distribution were studied on living myotubes in culture by video-intensified fluorescence microscopy. Aggregate formation was temperature dependent, increasing sharply from 24-36 degrees, maximal at 36-37 degrees, and virtually blocked at 38-40 degrees. Whereas aggregate size increased rapidly with time (up to 4 hr) at 36 degrees, at 18-24 degrees small (less than or equal to 1 micron) "microaggregates" formed and accumulated for up to 10 hr. Aggregates formed within 1.5 hr at the sites of microaggregates (formed after 4 hr at 23 degrees) if the temperature was raised to 36 degrees. However, if EBX was removed, the microaggregates on 50% of myotubes disassembled within 1.5 hr. The formation of microaggregates at 23 degrees and aggregates at 36 degrees was reversibly inhibited by sodium azide. These results show that clusters of microaggregates are the precursors of aggregates, and suggest that microaggregate clouds represent a discrete, labile, ATP-dependent stage in aggregate formation. Aggregates that had formed after 4 hr in the presence of EBX disassembled slowly (within 12-14 hr) following removal of EBX at 36 degrees, and even more slowly at 23-30 degrees. However, a temperature shift to 38 degrees, or the addition of azide, resulted in a rapid but reversible disassembly of aggregates (within 4 hr). Thus, newly formed aggregates appear to be relatively stable structures, while microaggregate clouds are labile, tending to disassemble or evolve into aggregates.     

Neuregulin inhibits acetylcholine receptor aggregation in myotubes

The high local concentration of acetylcholine receptors (AChRs) at the vertebrate neuromuscular junction results from their aggregation by the agrin/MuSK signaling pathway and their synthetic up-regulation by the neuregulin/ErbB pathway. Here, we show a novel role for the neuregulin/ErbB pathway, the inhibition of AChR aggregation on the muscle surface. Treatment of C2C12 myotubes with the neuregulin epidermal growth factor domain decreased the number of both spontaneous and agrin-induced AChR clusters, in part by increasing the rate of cluster disassembly. Upon cluster disassembly, AChRs were internalized into caveolae (as identified by caveolin-3). Time-lapse microscopy revealed that individual AChR clusters fragmented into puncta, and application of neuregulin accelerated the rate at which AChR clusters decreased in area without affecting the density of AChRs remaining in individual clusters (as measured by the fluorescence intensity/unit area). We propose that this novel action of neuregulin regulates synaptic competition at the developing neuromuscular junction.     

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.     

Immobilization of nicotinic acetylcholine receptors in mouse C2 myotubes by agrin-induced protein tyrosine phosphorylation

Agrin induces the formation of highly localized specializations on myotubes at which nicotinic acetylcholine receptors (AChRs) and many other components of the postsynaptic apparatus at the vertebrate skeletal neuromuscular junction accumulate. Agrin also induces AChR tyrosine phosphorylation. Treatments that inhibit tyrosine phosphorylation prevent AChR aggregation. To examine further the relationship between tyrosine phosphorylation and receptor aggregation, we have used the technique of fluorescence recovery after photobleaching to assess the lateral mobility of AChRs and other surface proteins in mouse C2 myotubes treated with agrin or with pervanadate, a protein tyrosine phosphatase inhibitor. Agrin induced the formation of patches in C2 myotubes that stained intensely with anti-phosphotyrosine antibodies and within which AChRs were relatively immobile. Pervanadate, on the other hand, increased protein tyrosine phosphorylation throughout the myotube and caused a reduction in the mobility of diffusely distributed AChRs, without affecting the mobility of other membrane proteins. Pervanadate, like agrin, caused an increase in AChR tyrosine phosphorylation and a decrease in the rate at which AChRs could be extracted from intact myotubes by mild detergent treatment, suggesting that immobilized receptors were phosphorylated and therefore less extractable. Indeed, phosphorylated receptors were extracted from agrin-treated myotubes more slowly than nonphosphorylated receptors. AChR aggregates at developing neuromuscular junctions in embryonic rat muscles also labeled with anti- phosphotyrosine antibodies, suggesting that tyrosine phosphorylation could mediate AChR aggregation in vivo as well. Thus, agrin appears to induce AChR aggregation by creating circumscribed domains of increased protein tyrosine phosphorylation within which receptors become phosphorylated and immobilized.     

Rapid induction of acetylcholine receptor aggregates by a neural factor and extracellular Ca2+

A soluble fetal brain extract (EBX) induces acetylcholine receptor (AChR) aggregation in cultured rat myotubes within 4 hr at 36 degrees C in a defined medium containing 1.8 mM (normal) extracellular Ca2+ (Olek et al., 1983). The activity of EBX was Ca2+ dependent; reducing extracellular Ca2+ significantly inhibited EBX-induced AChR aggregation and a 15-50% increase in extracellular Ca2+ synergistically enhanced the activity of EBX. Synergism was specific for Ca2+ as increases in other divalent cations (Ba2+, Co2+, Mg2+, Mn2+, Sr2+) had no effect. A large increase (300-500%) in extracellular Ca2+ alone also induced AChR aggregation within 4 hr at 36 degrees C. An equivalent increase in other cations (Ba2+, Co2+, Mg2+, Mn2+, Sr2+) did not promote AChR aggregation. An initial 15-min pulse of increased extracellular Ca2+ alone or with EBX was adequate to induce AChR aggregation. Aggregates induced by EBX, Ca2+ alone, or EBX/Ca2+ were found predominantly on the top surface of the myotube. These treatments did not detectably alter preexisting aggregates present at substrate contact sites on the bottom surface of myotubes. AChR aggregation induced by any treatment was not inhibited by cycloheximide, Ca2+ channel blockers, or protease inhibitors but was blocked by Co2+ and sodium azide.     

Regulation of agrin-induced acetylcholine receptor aggregation by Ca++ and phorbol ester

Agrin, a protein extracted from the electric organ of Torpedo californica, induces the formation of specializations on cultured chick myotubes that resemble the postsynaptic apparatus at the neuromuscular junction. The aim of the studies reported here was to characterize the effects of agrin on the distribution of acetylcholine receptors (AChRs) and cholinesterase as a step toward determining agrin's mechanism of action. When agrin was added to the medium bathing chick myotubes small (less than 4 micron 2) aggregates of AChRs began to appear within 2 h and increased rapidly in number until 4 h. Over the next 12-20 h the number of aggregates per myotube decreased as the mean size of each aggregate increased to approximately 15 micron 2. The accumulation of AChRs into agrin-induced aggregates occurred primarily by lateral migration of AChRs already in the myotube plasma membrane at the time agrin was added to the cultures. Aggregates of AChRs and cholinesterase remained as long as agrin was present in the medium; if agrin was removed the number of aggregates declined slowly. The formation and maintenance of agrin-induced AChR aggregates required Ca++, Co++ and Mn++ inhibited agrin-induced AChR aggregation and increased the rate of aggregate dispersal. Mg++ and Sr++ could not substitute for Ca++. Agrin-induced receptor aggregation also was inhibited by phorbol 12-myristate 13-acetate, an activator of protein kinase C, and by inhibitors of energy metabolism. The similarities between agrin's effects on cultured myotubes and events that occur during formation of neuromuscular junctions support the hypothesis that axon terminals release molecules similar to agrin that induce the differentiation of the postsynaptic apparatus.     

Alpha-galactosidase stimulates acetylcholine receptor aggregation in skeletal muscle cells via PNA-binding carbohydrates

Aggregation of nicotinic acetylcholine receptors (AChRs) in skeletal muscle is an essential step in the formation of the mammalian neuromuscular junction. While proteins that bind to myotube receptors such as agrin and laminin can stimulate AChR aggregation in cultured myotubes, removal of cell surface sialic acids stimulates aggregation in a ligand-independent manner. Here, we show that removal of cell surface alpha-galactosides also stimulates AChR aggregation in the absence of added laminin or agrin. AChR aggregation stimulated by alpha-galactosidase was blocked by peanut agglutinin (PNA), which binds to lactosamine-containing disaccharides, but not by the GalNAc-binding lectin Vicia villosa agglutinin (VVA-B4). AChR aggregation stimulated by alpha-galactosidase potentiated AChR clustering induced by either neural agrin or laminin-1 and could be inhibited by muscle agrin. These data suggest that capping of cell surface lactosamines or N-acetyllactosamines with alpha-galactose affects AChR aggregation much as capping with sialic acids does.     

Neural agrin increases postsynaptic ACh receptor packing by elevating rapsyn protein at the mouse neuromuscular synapse

Fluorescence resonance energy transfer (FRET) experiments at neuromuscular junctions in the mouse tibialis anterior muscle show that postsynaptic acetylcholine receptors (AChRs) become more tightly packed during the first month of postnatal development. Here, we report that the packing of AChRs into postsynaptic aggregates was reduced in 4-week postnatal mice that had reduced amounts of the AChR-associated protein, rapsyn, in the postsynaptic membrane (rapsyn(+/-) mice). We hypothesize that nerve-derived agrin increases postsynaptic expression and targeting of rapsyn, which then drives the developmental increase in AChR packing. Neural agrin treatment elevated the expression of rapsyn in C2 myotubes by a mechanism that involved slowing of rapsyn protein degradation. Similarly, exposure of synapses in postnatal muscle to exogenous agrin increased rapsyn protein levels and elevated the intensity of anti-rapsyn immunofluorescence, relative to AChR, in the postsynaptic membrane. This increase in the rapsyn-to-AChR immunofluorescence ratio was associated with tighter postsynaptic AChR packing and slowed AChR turnover. Acute blockade of synaptic AChRs with alpha-bungarotoxin lowered the rapsyn-to-AChR immunofluorescence ratio, suggesting that AChR signaling also helps regulate the assembly of extra rapsyn in the postsynaptic membrane. The results suggest that at the postnatal neuromuscular synapse agrin signaling elevates the expression and targeting of rapsyn to the postsynaptic membrane, thereby packing more AChRs into stable, functionally-important AChR aggregates.     

Agrin-Deficient Myotube Retains Its Acetylcholine Receptor Aggregation Ability when Challenged with Agrin

Abstract: Agrin is a synapse-organizing molecule that mediates the nerve-induced aggregation of acetylcholine receptors (AChRs) and other postsynaptic components at the developing and regenerating vertebrate neuromuscular junctions. At the neuromuscular junction, three different cell types can express agrin, i.e., neuron, muscle, and Schwann cell. Several lines of evidence suggested that neuron-derived agrin is the AChR-aggregating factor, but the possible roles of muscle-derived agrin in the formation of AChR aggregate are not known. By using the recombinant DNA method, a clonal stable C2C12 cell line transfected with antisense agrin cDNA was created. RNA dot blot and western blot analysis indicated that the expression of agrin in the transfected cell was abolished by DNA transfection. When the agrin-deficient C2C12 cells were induced to form myotubes and subsequently cocultured with agrin cDNA transfected fibroblasts, AChR aggregates were formed in the cocultures. In addition, acetylcholinesterase (AChE) aggregates in agrin-deficient myotubes were also induced by exogenous agrin and the AChE aggregates were colocalized with the AChR aggregates. The agrin-deficient myotubes could also respond to neuron-induced AChR aggregation after coculturing with neuroblastoma cells. Thus, the agrin-deficient myotubes retain their ability to exhibit the agrin- or neuron-induced AChR aggregation. This result suggests that the formation of postsynaptic specializations during development and regeneration is mediated by neuron-derived agrin but not the agrin from muscle.     

Agrin-induced acetylcholine receptor clustering is mediated by the small guanosine triphosphatases Rac and Cdc42

During neuromuscular junction formation, agrin secreted from motor neurons causes muscle cell surface acetylcholine receptors (AChRs) to cluster at synaptic sites by mechanisms that are insufficiently understood. The Rho family of small guanosine triphosphatases (GTPases), including Rac and Cdc42, can mediate focal reorganization of the cell periphery in response to extracellular signals. Here, we investigated the role of Rac and Cdc42 in coupling agrin signaling to AChR clustering. We found that agrin causes marked muscle-specific activation of Rac and Cdc42 in differentiated myotubes, as detected by biochemical measurements. Moreover, this activation is crucial for AChR clustering, since the expression of dominant interfering mutants of either Rac or Cdc42 in myotubes blocks agrin-induced AChR clustering. In contrast, constitutively active Rac and Cdc42 mutants cause AChR to aggregate in the absence of agrin. By indicating that agrin-dependent activation of Rac and Cdc42 constitutes a critical step in the signaling pathway leading to AChR clustering, these findings suggest a novel role for these Rho-GTPases: the coupling of neuronal signaling to a key step in neuromuscular synaptogenesis.     

Implication of nNOS in the enlargement of AChR aggregates but not the initial aggregate formation in a novel coculture model

The aggregation of nicotinic acetylcholine receptors (AChRs) is an early hallmark of the formation of neuromuscular junction (NMJ), and nitric oxide is recently known to play an important role. In many NMJ studies, nerve-muscle coculture model was used, and NG108-15 cells, a neuroblastoma x glioma hybrid cell line, were the most frequently used nerve cells. However, possible contributions from glial cells could not be excluded. In this study, Neuro-2a neuroblastoma cells were used instead of [corrected] coculture with myotubes, and the relationship between AChR aggregation and spatiotemporal expression and activation of nNOS (neuronal nitric oxide synthase) was examined. Upon coculture, AChR aggregates were observed by FITC-conjugated alpha-bungarotoxin, and double labeling of AChRs and neurofilament showed that the neurites of a Neuro-2a cell innervated several myotubes. After treating the cocultures with single dose of L-NAME at the end of 1-day [corrected] coculturing, only slight effect on AChR aggregation could be found indicating that nNOS is not related to the initial formation of AChR aggregates. In contrast, when L-NAME treatment was given at the end of a 3-day coculturing, the day just before reaching the maximum extent of AChR aggregation, new AChR aggregates were hardly formed and the preformed AChR aggregates were even dispersed indicating that the enlargement of AChR aggregates is highly dependent on the nNOS activity. Double-labeling study of nNOS and AChR further showed that the coupling of membranous nNOS to regions nearby the AChR aggregates was essential for the enlargement of AChR aggregates. These results not only revealed the spatiotemporal relationship between AChR aggregation and nNOS activity but also verified the feasibility and usefulness of using Neuro-2a cells in a coculture model.     

Formation of complex AChR aggregates in vitro requires α‐dystrobrevin

Efficient function at the neuromuscular junction requires high‐density aggregates of acetylcholine receptors (AChRs) to be precisely aligned with the motor nerve terminal. A collaborative effort between the motor neuron and muscle intrinsic factors drives the formation and maintenance of these AChR aggregates. α‐Dystrobrevin (αDB), a cytoplasmic protein found at the postsynaptic membrane, has been implicated in the regulation of AChR aggregate density and patterning. To investigate the contribution of αDB to the muscle intrinsic program regulating AChR aggregate development, we analyzed the formation of complex, pretzel‐like AChR aggregates on primary muscle cell cultures derived from αDB knockout (αDB‐KO) mice in the absence of nerve or agrin. In myotubes lacking αDB, complex AChR aggregates failed to form, whereas aggregates formed readily in wildtype myotubes. Five major isoforms of αDB are expressed in skeletal muscle: αDB1, αDB1(?), αDB2, αDB2(?), and αDB3. Expression of αDB1 or αDB1(?) in αDB‐KO myotubes restored formation of complex AChR aggregates similar to those in wildtype myotubes. In contrast, individual expression of αDB2, αDB2(?), αDB3, or an αDB1 phosphorylation mutant resulted in the formation of few, if any, complex AChR aggregates. Collectively, these data suggest that αDB is a significant component of the muscle intrinsic program that mediates the formation of complex AChR aggregates and that αDB's tyrosine phosphorylation sites are of particular functional importance to this program. Although the muscle intrinsic program appears to influence synaptogenesis, the formation of complex mature AChR aggregates in αDB‐KO mice (with the motor neuron present) suggests the motor neuron, not the muscle intrinsic program, is the major stimulus driving the maturation of AChRs from plaque to pretzel in vivo. © 2009 Wiley Periodicals, Inc. Develop Neurobiol 2009     

Agrin elicits membrane lipid condensation at sites of acetylcholine receptor clusters in C2C12 myotubes

The formation of the neuromuscular junction is characterized by the progressive accumulation of nicotinic acetylcholine receptors (AChRs) in the postsynaptic membrane facing the nerve terminal, induced predominantly through the agrin/muscle-specific kinase (MuSK) signaling cascade. However, the cellular mechanisms linking MuSK activation to AChR clustering are still poorly understood. Here, we investigate whether lipid rafts are involved in agrin-elicited AChR clustering in a mouse C2C12 cell line. We observed that in C2C12 myotubes, both AChR clustering and cluster stability were dependent on cholesterol, because depletion by methyl-beta-cyclodextrin inhibited cluster formation or dispersed established clusters. Importantly, AChR clusters resided in ordered membrane domains, a biophysical property of rafts, as probed by Laurdan two-photon fluorescence microscopy. We isolated detergent-resistant membranes (DRMs) by three different biochemical procedures, all of which generate membranes with similar cholesterol/GM1 ganglioside contents, and these were enriched in several postsynaptic components, notably AChR, syntrophin, and raft markers flotillin-2 and caveolin-3. Agrin did not recruit AChRs into DRMs, suggesting that they are present in rafts independently of agrin activation. Consequently, in C2C12 myotubes, agrin likely triggers AChR clustering or maintains clusters through the coalescence of lipid rafts. These data led us to propose a model in which lipid rafts play a pivotal role in the assembly of the postsynaptic membrane at the neuromuscular junction upon agrin signaling.     

The role of lateral migration in the formation of acetylcholine receptor clusters induced by basic polypeptide-coated latex beads

During the formation of the neuromuscular junction, the nerve induces the clustering of acetylcholine receptors (AChR) in the postsynaptic membrane. This process can be mimicked by treating cultured Xenopus myotomal muscle cells with basic polypeptide-coated latex beads. Using this bead-muscle coculture system, we examined the role of lateral migration of AChRs in the formation of the clusters. First, we studied the contributions of the preexisting and newly inserted AChRs. After the cluster formation was triggered by the addition of the beads, preexisting receptors were immediately recruited to the bead-muscle contacts and they remained to be the dominant contributor during the first 24 hr. New AChRs, which were inserted after the addition of the beads, appeared at the clusters after a 4-hr delay and, thereafter, there was a steady increase in their contribution. After 24-48 hr, newly inserted AChRs could be detected at the bead-induced clusters to the same extent as the preexisting AChRs. During this period, new receptors were continuously inserted into the plasma membrane, but there was no evidence of a local insertion at sites of new cluster formation. Concanavalin A (Con A) at a concentration of 100 micrograms/ml caused a fivefold decrease in the fraction of mobile AChRs and a large decrease in their diffusion coefficient. Pretreatment of cells with Con A suppressed clustering of preexisting AChRs, but left intact the contribution of the mobile newly inserted AChRs. Succinyl Con A, the divalent derivative of Con A which affected the mobility to a much less extent than Con A, had little effect on the clustering process. These results show that the formation of AChR clusters in Xenopus is mediated by lateral migration of AChRs within the plasma membrane and are consistent with the diffusion-trap hypothesis, which depicts freely diffusing AChR aggregating at the bead-muscle contacts where they bind to other localized molecular specializations induced by the beads.     

Agrin released by motor neurons induces the aggregation of acetylcholine receptors at neuromuscular junctions.

To test the hypothesis that agrin mediates motor neuron-induced aggregation of acetylcholine receptors (AChRs) in skeletal muscle fibers and to determine whether the agrin active in this process is released by motor neurons, we raised polyclonal antibodies to purified ray agrin that blocked its receptor aggregating activity. When the antibodies were applied to chick motor neuron--chick myotube cocultures, they inhibited the formation of AChR aggregates at and near neuromuscular contacts, demonstrating that agrin plays a role in the induction of the aggregates. Rat motor neurons, like chick motor neurons, induce AChR aggregates on chick myotubes. This effect was not inhibited by our antibodies, indicating that, although the antibodies inhibited the activity of chick agrin, they did not have a similar effect on rat agrin. We conclude that agrin released by rat motor neurons induced the chick myotubes to aggregate AChRs.     

Agrin induces phosphorylation of the nicotinic acetylcholine receptor.

Agrin causes acetylcholine receptors (AChRs) on chick myotubes in culture to aggregate, forming specializations that resemble the postsynaptic apparatus at the vertebrate skeletal neuromuscular junction. Here we report that treating chick myotubes with agrin caused an increase in phosphorylation of the AChR beta, gamma, and delta subunits. H-7, a potent inhibitor of several protein serine kinases, blocked agrin-induced phosphorylation of the gamma and delta subunits, but did not prevent either agrin-induced AChR aggregation or phosphorylation of the beta subunit. Experiments with anti-phosphotyrosine antibodies demonstrated that agrin caused an increase in tyrosine phosphorylation of the beta subunit that began within 30 min of adding agrin to the myotube cultures, reached a plateau by 3 hr, and was blocked by treatments known to block agrin-induced AChR aggregation. Anti-phosphotyrosine antibodies labeled agrin-induced specializations as they do the postsynaptic apparatus. These results suggest that agrin-induced tyrosine phosphorylation of the beta subunit may play a role in regulating AChR distribution.     

Recycling of acetylcholine receptors at ectopic postsynaptic clusters induced by exogenous agrin in living rats

During the development of the neuromuscular junction, motor axons induce the clustering of acetylcholine receptors (AChRs) and increase their metabolic stability in the muscle membrane. Here, we asked whether the synaptic organizer agrin might regulate the metabolic stability and density of AChRs by promoting the recycling of internalized AChRs, which would otherwise be destined for degradation, into synaptic sites. We show that at nerve-free AChR clusters induced by agrin in extrasynaptic membrane, internalized AChRs are driven back into the ectopic synaptic clusters where they intermingle with pre-existing and new receptors. The extent of AChR recycling depended on the strength of the agrin stimulus, but not on the development of junctional folds, another hallmark of mature postsynaptic membranes. In chronically denervated muscles, in which both AChR stability and recycling are significantly decreased by muscle inactivity, agrin maintained the amount of recycled AChRs at agrin-induced clusters at a level similar to that at denervated original endplates. In contrast, AChRs did not recycle at agrin-induced clusters in C2C12 or primary myotubes. Thus, in muscles in vivo, but not in cultured myotubes, neural agrin promotes the recycling of AChRs and thereby increases their metabolic stability.     

Formation of acetylcholine receptor clusters at neuromuscular junction in Xenopus cultures

The formation of acetylcholine receptor (AChR) clusters at the neuromuscular junction was investigated by observing the sequential changes in AChR cluster distribution on cultured Xenopus muscle cells. AChRs were labeled with tetramethylrhodamine-conjugated alpha-bungarotoxin (TMR-alpha BT). Before innervation AChRs were distributed over the entire surface of muscle cells with occasional spots of high density (hot spots). When the nerve contacted the muscle cell, the large existing hot spots disappeared and small AChR clusters (less than 1 micron in diameter) initially emerged from the background along the area of nerve contact. They grew in size, increased in number, and fused to form larger clusters over a period of 1 or 2 days. Receptor clusters did not migrate as a whole as observed during "cap" formation in B lymphocytes. The rate of recruitment of AChRs at the nerve-muscle junction varied from less than 50 binding sites to 1000 sites/hr for alpha BT. In this study the diffusion-trap mechanism was tested for the nerve-induced receptor accumulation. The diffusion coefficient of diffusely distributed AChRs was measured using the fluorescence photobleaching recovery method and found to be 2.45 X 10(-10) cm2/sec at 22 degrees C. There was no significant difference in these values among the muscle cells cultured without nerve, the non-nerve-contacted muscle cells in nerve-muscle cultures, and the nerve-contacted muscle cells. It was found that the diffusion of receptors in the membrane is not rate-limiting for AChR accumulation.     

Acetylcholine receptor clustering in C2 muscle cells requires chondroitin sulfate

Proteoglycans have been implicated in the clustering of acetylcholine receptors (AChRs) on cultured myotubes and at the neuromuscular junction. We report that the presence of chondroitin sulfate is associated with the ability of cultured myotubes to form spontaneous clusters of AChRs. Three experimental manipulations of wild type C2 cells in culture were found to affect both glycosaminoglycans (GAGs) and AChR clustering in concert. Chlorate was found to have dose-dependent negative effects both on GAG sulfation and on the frequency of AChR clusters. When extracellular calcium was raised from 1.8 to 6.8 mM in cultures of wild-type C2 myotubes, increases were observed both in the level of cell layer-associated chondroitin sulfate and in the frequency of AChR clusters. Culture of wild-type C2 myotubes in the presence of chondroitinase ABC eliminated cell layer-associated chondroitin sulfate while leaving heparan sulfate intact and simultaneously prevented the formation of AChR clusters. Treatment with either chlorate or chondroitinase inhibited AChR clustering only if begun prior to the spontaneous formation of clusters. We propose that chondroitin sulfate plays an essential role in the initiation of AChR clustering and in the early events of synapse formation on muscle. © 1995 John Wiley & Sons, Inc.     

Acetylcholine receptor clustering is required for the accumulation and maintenance of scaffolding proteins

The maintenance of a high density of postsynaptic receptors is essential for proper synaptic function. At the neuromuscular junction, acetylcholine receptor (AChR) aggregation is induced by nerve-clustering factors and mediated by scaffolding proteins. Although the mechanisms underlying AChR clustering have been extensively studied, the role that the receptors themselves play in the clustering process and how they are organized with scaffolding proteins is not well understood. Here, we report that the exposure of AChRs labeled with Alexa 594 conjugates to relatively low-powered laser light caused an effect similar to chromaphore-assisted light inactivation (CALI) , which resulted in the unexpected dissipation of the illuminated AChRs from clusters on cultured myotubes. This technique enabled us to demonstrate that AChR removal from illuminated regions induced the removal of scaffolding proteins and prevented the accumulation of new AChRs and associated scaffolding proteins. Further, the dissipation of clustered AChRs and scaffold was spatially restricted to the illuminated region and had no effect on neighboring nonilluminated AChRs. These results provide direct evidence that AChRs are essential for the local maintenance and accumulation of intracellular scaffolding proteins and suggest that the scaffold is organized into distinct modular units at AChR clusters.