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.     

Loss of alpha 2-macroglobulin and epidermal growth factor surface binding induced by phenothiazines and naphthalene sulfonamides

We have found that certain naphthalenesulfonamides [e.g., N-6(-aminohexyl)-5-chloro-1-naphthalenesulfonamide (W-7)] and phenothiazines [e.g., trifluoperazine (TFP)] induce a loss of cell-surface receptors for alpha 2-macroglobulin, and epidermal growth factor (EGF) in fibroblasts. The loss of alpha 2-macroglobulin receptors is independent of receptor occupancy and is rapidly reversed upon removal of these agents from the culture medium. The extent of EGF receptor loss is less than for alpha 2-macroglobulin, and the EGF receptors do not reappear at the surface when W-7 is removed. Receptor loss was measured as a change in the capacity for binding iodinated ligands; no change in affinity of binding was observed. This receptor loss could reflect inactivation of receptors or internalization. W-7 did not induce a loss of cell surface beta 2-microglobulin, a membrane protein which is excluded from coated pits and which is not internalized, indicating that the effect of W-7 was specific for membrane receptors and not a result of bulk depletion of plasma membrane. The loss of alpha 2-macroglobulin and EGF receptors occurs at concentrations which do not cause an increase in the pH of endocytic vesicles or the cytoplasm, indicating that these agents act by a mechanism distinct from the effect of other weak bases. Since both TFP and W-7 are potent inhibitors of calmodulin, we investigated the possibility that inhibition of calmodulin was responsible for the loss of receptors. Three lines of evidence suggest that calmodulin inhibition is not responsible for the inhibition of binding and endocytosis: 1) Promethazine, a phenothiazine that is a poor inhibitor of calmodulin, is nearly as effective as TFP at inhibiting endocytosis; calmidazolium, a potent inhibitor of several calmodulin functions, did not cause a loss of binding; 2) the microinjection of calmodulin into cells did not reverse the effects of W-7; using pressure microinjection, we introduced up to a 100-fold excess of calmodulin over native levels into individual gerbil fibroma cells; using rhodamine-labeled alpha 2-macroglobulin, we saw that the W-7 induced inhibition of receptor-mediated endocytosis was the same in injected and uninjected cells; 3) we injected calcineurin, a calmodulin-binding protein, into cells (1-3 pg/cell) and observed no effect on the receptor-mediated endocytosis of rhodamine-labeled alpha 2-macroglobulin. These data indicated that cell surface receptor numbers can be regulated by a cellular component that is not cytoplasmic calmodulin but that shares some drug sensitivities with calmodulin.     

Phase-shifts of the Bulla ocular circadian pacemaker in the presence of calmodulin antagonists

Previous work has shown that light-induced phase shifts of the Bulla ocular circadian pacemaker require extracellular calcium, suggesting the possibility that the action of calcium as a second messenger via calmodulin is an element in the phase shifting mechanism. The calmodulin antagonists calmidazolium, trifluoperazine (TFP) and W7 were applied with phase shifting light pulses. Light phase shifts were not blocked by calmidazolium or TFP, suggesting that calmodulin does not mediate light-induced phase shifts. Period changes were observed with treatments of both TFP and W7, but not with calmidazolium and are probably not calmodulin-mediated.     

Stage Depandent Inhibition of Plasmodiun falcipaium falciparum by Potent Ca2+ and Calmodulin Modulators

The effects Ca2+ channel blockers, verapamil, nicardipine and diltiazem, and of potent calmodulin (CaM) inhibitors, trifluoperazine (TFP), calmidazolium, W-7 and W-5, on Plasmodium falciparum in culture were examined. Among Ca2+ blockers, nicardipine was the most potent with the 50% inhibitory concentration (IC50) of 4.3 μM at 72 h after culture. Parasites were more sensitive to calmidazolium and W-7 with IC50 of 3.4 and 4.5 μM, respectively, than to TFP and W-5. All Ca2+ blockers and CaM inhibitors suppressed parasite development at later stages. Nicardipine, ditiazem, calmidazolium and W-5 also retarded parasite development at earlier stages and/or subsequent growth following pretreatment. Verapamil, nicardipine, TFP and calmidazolium reduced erythocyte invasion by merozoites. Fluroscence microscopy with the cationic flurescent dye rhodamine 123 revealed that nicardipine. TFP and calmidazolium depolarized both the plasma membrane and mitochondrial membrane potentials of the parasite. It is therefore considered that although al Ca2+ and CaM antagonists tested here influence parasite development at later stages, they are multifunctional, having effects not directly associated with Ca2+ channels or CaM.     

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.     

Stage-dependent inhibition of Plasmodium falciparum by potent Ca2+ and calmodulin modulators

The effects of Ca2+ channel blockers, verapamil, nicardipine and diltiazem, and of potent calmodulin (CaM) inhibitors, trifluoperazine (TFP), calmidazolium, W-7 and W-5, on Plasmodium falciparum in culture were examined. Among Ca2+ blockers, nicardipine was the most potent with the 50% inhibitory concentration (IC50) of 4.3 microM at 72 h after culture. Parasites were more sensitive to calmidazolium and W-7 with IC50 of 3.4 and 4.5 microM, respectively, than to TFP and W-5. All Ca2+ blockers and CaM inhibitors suppressed parasite development at later stages. Nicardipine, diltiazem, calmidazolium and W-5 also retarded parasite development at earlier stages and/or subsequent growth following pretreatment. Verapamil, nicardipine, TFP and calmidazolium reduced erythrocyte invasion by merozoites. Fluorescence microscopy with the cationic fluorescent dye rhodamine 123 revealed that nicardipine, TFP and calmidazolium depolarized both the plasma membrane and mitochondrial membrane potentials of the parasite. It is therefore considered that although all Ca2+ and CaM antagonists tested here influence parasite development at later stages, they are multifunctional, having effects not directly associated with Ca2+ channels or CaM.     

NMDA Receptor Activation Increases Cyclic AMP in Area CA1 of the Hippocampus via Calcium/Calmodulin Stimulation of Adenylyl Cyclase

Abstract: We observed previously that activation of N -methyl- d -aspartate (NMDA) receptors in area CA1 of the hippocampus, through either NMDA application or long-term potentiation (LTP)-inducing high-frequency stimulation (HFS), results in an increase in cyclic AMP. In the present study, we performed experiments to determine the mechanism by which NMDA receptor activation causes this increase in cyclic AMP. As the NMDA receptor-mediated increase in cyclic AMP is dependent upon extracellular calcium, we hypothesized that NMDA receptors are coupled to adenylyl cyclase (AC) via calcium/calmodulin. In membranes prepared from area CA1, AC was stimulated by calcium in the presence of calmodulin, and the effect of calcium/calmodulin on AC in membranes was blocked by the calmodulin antagonists N -(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide (W-7) and trifluopera-zine (TFP). In intact hippocampal slices, W-7 and TFP blocked the increase in cyclic AMP levels caused by both NMDA application and HFS of Schaffer collateral fibers. Exposure of hippocampal slices to elevated extracellular potassium to induce calcium influx also caused increased cyclic AMP levels; the increase in cyclic AMP caused by high potassium was also blocked by W-7 and TFP. These data support the hypothesis that NMDA receptor activation is positively coupled to AC via calcium/calmodulin and are consistent with a role for cyclic AMP metabolism in the induction of NMDA receptor-dependent LTP in area CA1 of the hippocampus.     

Action of triftazin on the physicochemical properties and the membrane proton pump of the synaptic vesicles in the rat brain

The effects of trifluoperazine (TFP) on some membrane processes were studied in the isolated rat brain synaptic vesicles (SV). TFP (10(-5)-10(-4) M) was found to cause a sharp rise in the intensity of light scattering by SV suspension which was due both to an increased vesicle aggregation and to changes in the refraction index of the membrane. In addition, TFP blocked the ATP-dependent proton transport into the vesicles (K0.5 = 10(-6) M) with the concomitant stimulation of the ATPase activity which suggests an uncoupling effect caused by the permeation of this weak base through the membrane and subsequent protonation in an acid interior medium resulting in the elimination of a proton gradient. Thus, the neuroleptic drug--TFP has various effects on membrane processes which are apparently unrelated to its recognized role as a calmodulin antagonist.     

Effect of calmodulin antagonists on phospholipase D activity in SH-SY5Y cells

The aim of this study was to investigate the involvement of calmodulin in phospholipase D activation in SH-SY5Y cells. Cells prelabelled with [3H]-palmitic acid were incubated with calmodulin antagonists and/or other compounds. Phosphatidylethanol, a specific marker for phospholipase D activity, and phosphatidic acid were analysed. The calmodulin antagonists, calmidazolium and trifluoperazine, induced an extensive increase in phosphatidylethanol formation, and thus increased basal phospholipase D activity, in a dose- and time-dependent manner. The effect of calmidazolium on carbachol-induced activation of muscarinic receptors was also studied. Calmidazolium did not significantly affect the amount of phosphatidylethanol formed following carbachol addition. However, taking into account the increase in basal activity observed after calmidazolium addition, calmidazolium probably inhibits the muscarinic receptor-induced phospholipase D activation. In addition to phosphatidylethanol, basal phosphatidic acid levels were also increased after calmidazolium and trifluoperazine addition. Incubation with calmidazolium (10 microM) for 10 min induced a two-fold increase in phosphatidic acid. The calmidazolium-induced increase in basal phospholipase D activity was not affected by the protein kinase inhibitors H7 and staurosporine. On the other hand tyrosine kinase inhibitors abolished the calmidazolium-induced activation of phospholipase D. Calmidazolium also induced tyrosine phosphorylation in parallel to the phospholipase D activation. In conclusion, our data indicate that calmodulin antagonists induce phospholipase D activity in SH-SY5Y cells via a tyrosine kinase dependent pathway. This may point to a negative control of phospholipase D by calmodulin although a calmodulin-independent mechanism cannot be excluded. Calmodulin antagonists may be useful tools to further elucidate the mechanisms of phospholipase D regulation.     

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.     

Topographical segregation of old and new acetylcholine receptors at developing ectopic endplates in adult rat muscle

We have used radioautographic methods to examine the topography of addition and removal of acetylcholine receptors (AChRs) within receptor clusters at developing ectopic synapses in adult rat soleus muscle. After AChRs within a cluster had been pulse-labeled with 125I-alpha- bungarotoxin (125I-alpha-BuTx), the area that they occupied within the cluster shrank with time. Thus the old receptors at new endplates occupy a continually decreasing area of the growing receptor cluster. To localize newly added AChRs, we pretreated the muscles with unlabeled alpha-BuTx, thus blocking the old receptors, and then labeled newly added receptors with 125I-alpha-BuTx 1 or 2 d later. In radioautographs, AChR clusters from these muscles appeared as annuli or "doughnuts," unlike control (unpretreated) clusters, which were more nearly uniformly labeled. This visual impression was confirmed by analyzing the radial grain density distribution. Thus growth and turnover of AChR clusters at ectopic endplates takes place by the addition of receptors at the periphery of the clusters. Our data are most consistent with a model in which receptor removal occurs by endocytosis randomly throughout the cluster.     

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.     

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.     

Dispersal and reformation of acetylcholine receptor clusters of cultured rat myotubes treated with inhibitors of energy metabolism

The effects of energy metabolism inhibitors on the distribution of acetylcholine receptors (AChRs) in the surface membranes of non-innervated, cultured rat myotubes were studied by visualizing the AChRs with monotetramethylrhodamine-alpha-bungarotoxin. Incubation of myotubes with inhibitors of energy metabolism causes a large decrease in the fraction of myotubes displaying clusters of AChR. This decrease is reversible, and is dependent on temperature, the concentration of inhibitor, and the duration of treatment. Cluster dispersal is probably not the result of secondary effects on Ca++ or cyclic nucleotide metabolism, membrane potential, cytoskeletal elements, or protein synthesis. Sequential observations of identified cells treated with sodium azide showed that clusters appear to disperse by movements of receptors within the sarcolemma without accompanying changes in cell shape. AChR clusters dispersed by pretreating cells with sodium azide rapidly reform upon removal of the inhibitor. Reclustering involves the formation of small aggregates of AChR, which act as foci for further aggregation and which appear to be precursors of large AChR clusters. Small AChR aggregates also appear to be precursors of clusters which form on myotubes never exposed to azide. Reclustering after azide treatment does not necessarily occur at the same sites occupied by clusters before dispersal, nor does it employ only receptors which had previously been in clusters. Cluster reformation can be blocked by cycloheximide, colchicine, and drugs which alter the intracellular cation composition.     

Involvement of calpains in the destabilization of the acetylcholine receptor clusters in rat myotubes

The effects of calpain inhibitors on the total number of acetylcholine receptors (AChRs) on cultured rat myotubes and on the stability of AChR clusters in these myotubes were investigated. The degradation rate of total AChRs labeled with (125)I-alpha-bungarotoxin was assessed from radioactivity remaining in the myotubes as a function of time. Treatment with calpain inhibitors resulted in a two- to three-fold increase in the half-life of total AChRs. Incubation with these inhibitors produced 40% increases in intracellular AChRs but no major changes in surface AChRs, indicating that the increased AChR half-life is due to intracellular accumulation. The rate loss of AChRs from the clusters was assessed by measuring the loss of fluorescence intensity in rhodaminated-alpha-bungarotoxin-labeled clusters with time. Treatment with calpain inhibitors resulted in twofold increases in cluster half-life. Thus, there was generally no change in total surface receptors with the calpain inhibitors, whereas cluster half-life was substantially increased. Furthermore, with a low dose of calpeptin there was no change in turnover of total cellular AChRs, whereas cluster half-life was doubled. Taken together, these results suggest that the increased half-life of clusters produced by the calpain inhibitors may be due to retardation of the lateral movement from AChRs in the clusters.     

Inhibition of protein synthesis by antagonists of calmodulin in Ehrlich ascites tumor cells

Several recent publications indicate that Ca2+ is required for protein synthesis in mammalian cells, including the Ehrlich ascites tumor cell. The present communication examines whether the effects of Ca2+ might be mediated through calmodulin or a related protein. Four calmodulin antagonists belonging to different chemical categories were used to provide evidence of calmodulin involvement. Three of the antagonists inhibited protein synthesis in intact cells; 50% inhibitory concentrations were 10 microM calmidazolium, 12 microM N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide (W7) and 17.5 microM trifluoperazine (TFP). Initiation was preferentially inhibited as indicated by an increase in the 80S monomers accompanied by a significant disaggregation of polyribosomes. All the antagonists also inhibited protein synthesis initiation in the cell-free protein-synthesizing system; 50% inhibitory concentrations for compound 48/80, calmidazolium, TFP, and W7 were 10 microM, 125 microM, 300 microM and 500 microM, respectively. A weak analogue of W7 inhibited only 20% at 1000 microM. Inhibition in the cell-free system was reversed by the addition of exogenous calmodulin in all four cases. The levels of 43S complexes were significantly elevated with all four antagonists, indicating a block in the utilization of 43S complexes. The similarity of the effects of four distinct classes of antagonists and their ready reversal by exogenous calmodulin leads us to suggest that there may be a role for calmodulin or a very similar calcium-binding protein in protein synthesis.     

Distribution of alpha-dystroglycan during embryonic nerve-muscle synaptogenesis

The distribution of alpha-dystroglycan (alpha DG) relative to acetylcholine receptors (AChRs) and neural agrin was examined by immunofluorescent staining with mAb IIH6 in cultures of nerve and muscle cells derived from Xenopus embryos. In Western blots probed with mAb IIH6, alpha DG was evident in membrane extracts of Xenopus muscle but not brain. alpha DG immunofluorescence was present at virtually all synaptic clusters of AChRs and neural agrin. Even microclusters of AChRs and agrin at synapses no older than 1-2 h (the earliest examined) had alpha DG associated with them. alpha DG was also colocalized at the submicrometer level with AChRs at nonsynaptic clusters that have little or no agrin. The number of large (> 4 microns) nonsynaptic clusters of alpha DG, like the number of large nonsynaptic clusters of AChRs, was much lower on innervated than on noninnervated cells. When mAb IIH6 was included in the culture medium, the large nonsynaptic clusters appeared fragmented and less compact, but the accumulation of agrin and AChRs along nerve-muscle contacts was not prevented. It is concluded that during nerve-muscle synaptogenesis, alpha DG undergoes the same nerve- induced changes in distribution as AChRs. We propose a diffusion trap model in which the alpha DG-transmembrane complex participates in the anchoring and recruitment of AChRs and alpha DG during the formation of synaptic as well as nonsynaptic AChR clusters.     

Insertion and internalization of acetylcholine receptors at clustered and diffuse domains on cultured myotubes

Two populations of acetylcholine receptors (AChRs) are present in cultured myotubes. One forms large aggregates or clusters and the other has a much lower density of AChRs, which are diffusely distributed. Both clustered and diffuse AChRs are inserted and removed (internalized) from the sarcolemma. To determine the insertion and removal rates of AChRs in these two plasma membrane domains, we used a double label technique to distinguish and quantitate newly inserted and "old" AChRs. Application of our method revealed that the rate of AChR internalization is the same at the clustered and diffuse regions of the plasma membrane, whereas the rate of insertion is threefold greater at the clusters than elsewhere in the plasma membrane. Thus, the increase in AChR number at the clusters is not due to an increase in their half-life, but to an increase in their rate of insertion.     

Subnanosecond polarized fluorescence photobleaching: rotational diffusion of acetylcholine receptors on developing muscle cells.

Polarized fluorescence recovery after photobleaching (PFRAP) is a technique for measuring the rate of rotational motion of biomolecules on living, nondeoxygenated cells with characteristic times previously ranging from milliseconds to many seconds. Although very broad, that time range excludes the possibility of quantitatively observing freely rotating membrane protein monomers that typically should have a characteristic decay time of only several microseconds. This report describes an extension of the PFRAP technique to a much shorter time scale. With this new system, PFRAP experiments can be conducted with sample time as short as 0.4 microseconds and detection of possible characteristic times of less than 2 microseconds. The system is tested on rhodamine-alpha-bungarotoxin-labeled acetylcholine receptors (AChRs) on myotubes grown in primary cultures of embryonic rat muscle, in both endogenously clustered and nonclustered regions of AChR distribution. It is found that approximately 40% of the AChRs in nonclustered regions undergoes rotational diffusion fast enough to possibly arise from unrestricted monomer Brownian motion. The AChRs in clusters, on the other hand, are almost immobile. The effects of rat embryonic brain extract (which contains AChR aggregating factors) on the myotube AChR were also examined by the fast PFRAP system. Brain extract is known to abolish the presence of endogenous clusters and to induce the formation of new clusters. It is found here that rotational diffusion of AChR in the extract-induced clusters is as slow as that in endogenous clusters on untreated cells but that rotational diffusion in the nonclustered regions of extract-treated myotubes remains rapid.     

Molecular regulation of postsynaptic differentiation at the neuromuscular junction

The neuromuscular junction (NMJ) is a synapse that develops between a motor neuron and a muscle fiber. A defining feature of NMJ development in vertebrates is the re-distribution of muscle acetylcholine (ACh) receptors (AChRs) following innervation, which generates high-density AChR clusters at the postsynaptic membrane and disperses aneural AChR clusters formed in muscle before innervation. This process in vivo requires MuSK, a muscle-specific receptor tyrosine kinase that triggers AChR re-distribution when activated; rapsyn, a muscle protein that binds and clusters AChRs; agrin, a nerve-secreted heparan-sulfate proteoglycan that activates MuSK; and ACh, a neurotransmitter that stimulates muscle and also disperses aneural AChR clusters. Moreover, in cultured muscle cells, several additional muscle- and nerve-derived molecules induce, mediate or participate in AChR clustering and dispersal. In this review we discuss how regulation of AChR re-distribution by multiple factors ensures aggregation of AChRs exclusively at NMJs.