The lipid bilayer of acetylcholine receptor clusters of cultured rat myotubes is organized into morphologically distinct domains

We have studied the composition and organization of the lipid bilayer at the large, substrate-associated clusters of acetylcholine receptors (AChR) that form in cultured rat myotubes. These clusters have a characteristic morphology consisting of alternating linear domains of AChR-rich and AChR-poor membrane, the latter involved in attaching the myotube to the substrate. We partially purified AChR clusters by extracting cultured rat myotubes with the cholesterol-specific detergent, saponin. The lipid bilayer of the cluster preparation was analyzed biochemically and the substructure of the bilayers was studied morphologically using the fluorescent probes, dansyl polymyxin B, and 3,3'-di(C12H25 and C18H37) indocarbocyanine iodide (C12- and C18-diI). Our results demonstrate that preparations of AChR clusters have a lipid composition biochemically similar to that of the surrounding plasma membrane. Morphologically, however, the lipid bilayer appears to be arranged into domains that resemble the interdigitating pattern seen for the AChR. This distinctive lipid organization is not due to the use of saponin to purify clusters, as we obtained similar results with clusters isolated by physically shearing myotube cultures. The domain-like organization of the bilayer at clusters is disrupted by treatments that disperse AChR clusters in intact myotubes or that remove peripheral membrane proteins from isolated clusters. This suggests that such proteins may contribute to the organization of the bilayer. Two additional factors may also contribute to the organization of the bilayer: physical constraints imposed by sites of substrate attachment and, to a lesser extent, "boundary" lipid associated with AChR.     

Microfilaments and actin-associated proteins at sites of membrane-substrate attachment within acetylcholine receptor clusters

Rat myotubes in tissue culture form broad areas of close contact with the substrate. These areas often display two distinct, interdigitating sets of membrane domains. One, the "contact domain", is close to the substrate; the other, termed the "AChR domain", is further from the substrate and is rich in acetylcholine receptors (AChR). We have used fluorescence techniques to study the organization of the cytoskeleton in these areas. Substrate-apposed membrane of the myotubes was exposed either by shearing or by permeabilizing the cells with a neutral detergent. Phalloidin derivatives and affinity-purified polyclonal or monoclonal antibodies specific for cytoskeletal proteins were then applied to the samples. Sheared samples were observed by epifluorescence microscopy; detergent-permeabilized samples were observed by total internal reflection fluorescence microscopy. We found that, like antivinculin, fluorescent phalloidin derivatives and antibodies to alpha-actinin, filamin, and talin preferentially labeled the contact domains. This suggests that bundles of microfilaments associate with the membrane at sites of myotube-substrate attachment. In contrast, a 43K protein, closely associated with AChR, was present only at AChR domains. A monoclonal antibody to actin labeled both AChR and contact domains, suggesting that actin is enriched over both regions. Our results suggest that, like the plasma membrane of AChR clusters, the underlying membrane skeleton is organized into at least two distinct domains.     

Clathrin-coated membrane: a distinct membrane domain in acetylcholine receptor clusters of rat myotubes

We have used antibodies to clathrin light chains in immunocytochemical studies of acetylcholine receptor (AChR) clusters of cultured rat myotubes. Immunofluorescence and ultrastructural experiments show that clathrin is present in coated pits and in large plaques of coated membrane. Coated membrane plaques are spatially and structurally distinct from AChR-rich membrane domains and the bundles of microfilaments that are also present in AChR clusters. Clusters contain a relatively constant amount of clathrin light chain protein, which is not dependent on the amount of AChR. Clathrin plaques remain after AChR domains are disrupted by azide, or after microfilament bundles are destabilized by cytochalasin D. Extraction of myotubes with saponin removes clathrin without disrupting AChR domains. Thus, clathrin plaques, microfilament bundles, and AChR-rich domains are independently stabilized.     

Acetylcholine receptor clusters of rat myotubes have at least three domains with distinctive cytoskeletal and membranous components

Cultured rat myotubes develop high concentrations of acetylcholine receptors (AChR) in specialized areas of attachment to their substrate. We examined the ultrastructure of identified AChR clusters by quick-freeze, deep-etch, rotary replication or by thin sectioning of whole myotubes fixed in the presence of saponin and tannic acid to preserve the cytoskeleton. Our findings show that AChR clusters are composed of at least three distinct domains, differing in their cytoskeletal, intramembrane, and external components. At contact domains, the myotube's ventral membrane lacked AChR and lay within 10-15 nm of the substrate; electron-dense strands connected the two. The overlying cytoplasm contained bundles of parallel microfilaments passing above and through an irregular network of globular material, resembling the relationship of microfilament bundles to focal contacts already described in fibroblasts. Coated-membrane domains lay between the microfilament bundles and were overlain by cytoplasmic plaques of a regular network of polygons having associated coated pits. These plaques closely resembled the network of polymerized clathrin described in fibroblasts and macrophages. Coated membrane also lacked AChR and adhered to the substrate by electron-dense strands, but did not anchor microfilament bundles. The cytoplasm overlying AChR domains contained a complex network composed of at least two layers. The layer closest to the membrane consisted of protrusions from the cytoplasmic surface, some connected by fine filaments less than 5 nm in diameter. An overlying layer contained larger diameter filaments, some forming an anastomotic network reminiscent of the cortical cytoskeleton of erythrocytes. Longer filaments inserting into this network appeared identical to members of nearby microfilament bundles. The morphology of AChR domains supports the idea that AChR are immobilized by a network containing actin and spectrin.     

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.     

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.     

Actin at receptor-rich domains of isolated acetylcholine receptor clusters

Acetylcholine receptor (AChR) clusters of cultured rat myotubes, isolated by extraction with saponin (Bloch, R. J., 1984, J. Cell Biol. 99:984-993), contain a polypeptide that co-electrophoreses with purified muscle actins. A monoclonal antibody against actin reacts in immunoblots with this polypeptide and with purified actins. In indirect immunofluorescence, the antibody stains isolated AChR clusters only at AChR domains, strips of membrane within clusters that are rich in receptor. It also stains the postsynaptic region of the neuromuscular junction of adult rat skeletal muscle. Semiquantitative immunofluorescence analyses show that labeling by antiactin of isolated analyses show that labeling by antiactin of isolated AChR clusters is specific and saturable and that it varies linearly with the amount of AChR in the cluster. Filaments of purified gizzard myosin also bind preferentially at AChR-rich regions, and this binding is inhibited by MgATP. These experiments suggest that actin is associated with AChR-rich regions of receptor clusters. Depletion of actin by extraction of isolated clusters at low ionic strength selectively releases the actin-like polypeptide from the preparation. Simultaneously, AChRs redistribute within the plane of the membrane of the isolated clusters. Similarly, brief digestion with chymotrypsin reduces immunofluorescence staining and causes AChR redistribution. Treatments that deplete AChR from clusters in intact cells also reduce immunofluorescent staining for actin in isolated muscle membrane fragments. Upon reversal of these treatments, cluster reformation occurs in regions of the membrane that also stain for actin. I conclude that actin is associated with AChR domains and that changes in this association are accompanied by changes in the organization of isolated AChR clusters.     

Disruption and reformation of the acetylcholine receptor clusters of cultured rat myotubes occur in two distinct stages

We have examined the redistribution of acetylcholine receptor (AChR) intramembrane particles (IMPs) when AChR clusters of cultured rat myotubes are experimentally disrupted and allowed to reform. In control myotubes, the AChR IMPs are evenly distributed within the AChR domains of cluster membrane. Shortly after addition of azide to disrupt clusters, IMPs become unevenly scattered, with some microaggregation. After longer treatment, IMPs are depleted from AChR domains with no further change in IMP distribution. Contact domains of clusters are relatively poor in IMPs both before and after cluster dispersal. Upon visualization with fluorescent alpha-bungarotoxin, some AChR in azide-treated samples appear as small, bright spots. These spots do not correspond to microaggregates seen in freeze-fracture replicas, and probably represent receptors that have been internalized. The internalization rate is insufficient to account completely for the loss of IMPs from clusters, however. During reformation of AChR clusters upon removal of azide, IMP concentration in receptor domains increases. At early stages of reformation, IMPs appear in small groups containing compact microaggregates. At later times, AChR domains enlarge and IMPs within them assume the evenly spaced distribution characteristic of control clusters. These observations suggest that the disruption of clusters is accompanied by mobilization of AChR from a fixed array, allowing AChR IMPs to diffuse away from the clusters, to form microaggregates, and to become internalized. Cluster reformation appears to be the reverse of this process. Our results are thus consistent with a two-step model for AChR clustering, in which the concentration of IMPs into a small membrane region precedes their rearrangement into evenly spaced sites.     

The localization of acetylcholine receptor clusters in areas of cell-substrate contact in cultures of rat myotubes

We have used interference reflection and fluorescence microscopy to investigate the relationship between cell-substrate contact and the location of clusters of acetylcholine receptors (AChRs) in cultures of rat myotubes. We have found that AChR clusters on the ventral myotube surfaces are always located within broad regions of close cell-substrate contact. Detailed analysis of the fine structure of the AChR cluster and its associated contact region showed that AChRs within a cluster are concentrated between the points of closest cell-substrate apposition. Vinculin, a recently discovered intracellular smooth muscle protein, is also concentrated in broad regions of close contact, interdigitating with AChRs within the clusters.     

The dystroglycan complex is necessary for stabilization of acetylcholine receptor clusters at neuromuscular junctions and formation of the synaptic basement membrane

The dystrophin-associated protein (DAP) complex spans the sarcolemmal membrane linking the cytoskeleton to the basement membrane surrounding each myofiber. Defects in the DAP complex have been linked previously to a variety of muscular dystrophies. Other evidence points to a role for the DAP complex in formation of nerve-muscle synapses. We show that myotubes differentiated from dystroglycan-/- embryonic stem cells are responsive to agrin, but produce acetylcholine receptor (AChR) clusters which are two to three times larger in area, about half as dense, and significantly less stable than those on dystroglycan+/+ myotubes. AChRs at neuromuscular junctions are similarly affected in dystroglycan-deficient chimeric mice and there is a coordinate increase in nerve terminal size at these junctions. In culture and in vivo the absence of dystroglycan disrupts the localization to AChR clusters of laminin, perlecan, and acetylcholinesterase (AChE), but not rapsyn or agrin. Treatment of myotubes in culture with laminin induces AChR clusters on dystroglycan+/+, but not -/- myotubes. These results suggest that dystroglycan is essential for the assembly of a synaptic basement membrane, most notably by localizing AChE through its binding to perlecan. In addition, they suggest that dystroglycan functions in the organization and stabilization of AChR clusters, which appear to be mediated through its binding of laminin.     

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.     

An unusual beta-spectrin associated with clustered acetylcholine receptors

The clustering of acetylcholine receptors (AChR) in the postsynaptic membrane is an early event in the formation of the neuromuscular junction. The mechanism of clustering is still unknown, but is generally believed to be mediated by the postsynaptic cytoskeleton. We have identified an unusual isoform of beta-spectrin which colocalizes with AChR in AChR clusters isolated from rat myotubes in vitro. A related antigen is present postsynaptically at the neuromuscular junction of the rat. Immunoprecipitation, peptide mapping and immunofluorescence show that the beta-spectrin in AChR clusters resembles but is distinct from the beta-spectrin of human erythrocytes. alpha-Spectrin appears to be absent from AChR clusters. Semiquantitative immunofluorescence techniques indicate that there are from two to seven beta-spectrin molecules present for every clustered AChR, the higher values being obtained from rapidly prepared clusters, the lower values from clusters that require several minutes or more for isolation. Upon incubation of isolated AChR clusters for 1 h at room temperature, beta-spectrin is slowly depleted and the AChR redistribute into microaggregates. The beta-spectrin that remains associated with the myotube membrane is concentrated at these microaggregates. beta-Spectrin is quantitatively lost from clusters upon digestion with chymotrypsin, which causes AChR to redistribute in the plane of the membrane. These results suggest that AChR in clusters is closely linked to an unusual isoform of beta-spectrin.     

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.     

Localization of dystrophin relative to acetylcholine receptor domains in electric tissue and adult and cultured skeletal muscle

Two high-affinity mAbs were prepared against Torpedo dystrophin, an electric organ protein that is closely similar to human dystrophin, the gene product of the Duchenne muscular dystrophy locus. The antibodies were used to localize dystrophin relative to acetylcholine receptors (AChR) in electric organ and in skeletal muscle, and to show identity between Torpedo dystrophin and the previously described 270/300-kD Torpedo postsynaptic protein. Dystrophin was found in both AChR-rich and AChR-poor regions of the innervated face of the electroplaque. Immunogold experiments showed that AChR and dystrophin were closely intermingled in the AChR domains. In contrast, dystrophin appeared to be absent from many or all AChR-rich domains of the rat neuromuscular junction and of AChR clusters in cultured muscle (Xenopus laevis). It was present, however, in the immediately surrounding membrane (deep regions of the junctional folds, membrane domains interdigitating with and surrounding AChR domains within clusters). These results suggest that dystrophin may have a role in organization of AChR in electric tissue. Dystrophin is not, however, an obligatory component of AChR domains in muscle and, at the neuromuscular junction, its roles may be more related to organization of the junctional folds.     

Brain extract causes acetylcholine receptor redistribution which mimics some early events at developing neuromuscular junctions

We studied the effect of rat brain extract on rat muscle cells in vitro by light and electron microscope (EM) autoradiography after labeling acetylcholine receptors (AChR's) with 125I-alpha-bungarotoxin. We found that: (a) In the absence of brain extract, peak site densities within AChR clusters usually do not exceed 4,000 sites/micrometer2. (b) Within hours after exposure to brain extract, AChR's redistribute to form clusters in which the peak site densities are greater than 10,000 sites/micrometer2. Receptor concentration within extract-induced clusters is thus within a factor of 2 of that at the neuromuscular junction (nmj). (c) In the absence of extract, the AChR's and AChR clusters are predominantly on the bottom surface of the myotubes (facing the tissue culture dish). After extract treatment, they are predominantly at the top surface. (d) Plasma membrane in regions of high-density AChR clusters is enriched in membrane with enhanced electron density and surface basal lamina whether or not cells are treated with extract. Extract causes an increase in both these specializations on the top surface of the myotubes. (e) Brain extract does not produce an overall increase in AChR site density or a marked change in degradation rate of receptors in either clustered or nonclustered regions. By producing AChR clusters with junctional site densities and enhanced surface specialization, and by causing an overall shift in AChR's distribution, brain extract mimics early events reported at developing neuromuscular junctions.     

Phospholipid Asymmetry in Acetylcholine Receptor Clusters

We modified the lipids of rat myotubes in tissue culture to determine the transmembrane orientation of aminophospholipids in clusters of acetylcholine receptors (AChR). Trinitrobenzenesulfonic acid and N -hydroxysuccinimidobiotin were used to modify the amino groups of phospholipids. Reaction conditions were selected to prevent penetration of the chemical probes into the cell interior. Fluorescence microscopy was used to confirm that the probes remained impermeant. Analysis of aminophospholipids associated with clusters isolated from chemically modified cells and comparisons to results of chemically modifying isolated acetylcholine receptor clusters indicated that at least 77% of plasma membrane aminophospholipids was located in the interior leaflet of the lipid bilayer. We address the possibility that aminophospholipids on the inner lipid leaflet may contribute to the association between the cytoskeleton and the membrane at AChR clusters.     

Antibody-Induced Acetylcholine Receptor Clusters Inhabit Liquid-Ordered and Liquid-Disordered Domains

The distribution of nicotinic acetylcholine receptor (AChR) clusters at the cell membrane was studied in CHO-K1/A5 cells using fluorescence microscopy. Di-4-ANEPPDHQ, a fluorescent probe that differentiates between liquid-ordered (Lo) and liquid-disordered (Ld) phases in model membranes, was used in combination with monoclonal anti-AChR antibody labeling of live cells, which induces AChR clustering. The so-called generalized polarization (GP) of di-4-ANEPPDHQ was measured in regions of the cell-surface membrane associated with or devoid of antibody-induced AChR clusters, respectively. AChR clusters were almost equally distributed between Lo and Ld domains, independently of receptor surface levels and agonist (carbamoylcholine and nicotine) or antagonist (α-bungarotoxin) binding. Cholesterol depletion diminished the cell membrane mean di-4-ANEPPDHQ GP and the number of AChR clusters associated with Ld membrane domains increased concomitantly. Depolymerization of the filamentous actin cytoskeleton by Latrunculin A had the opposite effect, with more AChR clusters associated with Lo domains. AChR internalized via small vesicles having lower GP and lower cholesterol content than the surface membrane. Upon cholesterol depletion, only 12% of the AChR-containing vesicles costained with the fluorescent cholesterol analog fPEG-cholesterol, i.e., AChR endocytosis was essentially dissociated from that of cholesterol. In conclusion, the distribution of AChR submicron-sized clusters at the cell membrane appears to be regulated by cholesterol content and cytoskeleton integrity.     

Mobility and detergent extractability of acetylcholine receptors on cultured rat myotubes: a correlation

On aneurally cultured rat primary myotubes, 10% of the acetylcholine receptors (AChR) are found aggregated and immobilized in endogenous clusters. The remaining receptors are diffusely distributed over the cell membrane and the majority of these are free to diffuse in the plane of the membrane. This study correlates the mobility of AChR (as measured with the fluorescence photobleaching recovery technique, FPR) with the detergent extractability of this receptor. Gentle detergent extraction of the cells removes the lipid membrane and the soluble cytoplasmic proteins but leaves an intact cytoskeletal framework on the substrate. Two studies indicate a correlation between mobility and extractability: (a) mobility of diffusely distributed AChR decreases as myotubes age in culture; previous work showed that extractability of AChR decreases as myotubes age in culture (Prives, J., C. Christian, S. Penman, and K. Olden, 1980, In Tissue Culture in Neurobiology, E. Giacobini, A. Vernadakis, and A. Shahar, editors, Raven Press, New York, 35-52); (b) mobility of clustered AChR increases when cells are treated with metabolic inhibitors such as sodium azide (NaN3); extractability of clustered AChR also increases with this treatment. From these results we suggest the involvement of a cytoskeletal framework in the immobilization of AChR on the cell surface.     

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.     

Antibody-Induced Acetylcholine Receptor Clusters Inhabit Liquid-Ordered and Liquid-Disordered Domains

The distribution of nicotinic acetylcholine receptor (AChR) clusters at the cell membrane was studied in CHO-K1/A5 cells using fluorescence microscopy. Di-4-ANEPPDHQ, a fluorescent probe that differentiates between liquid-ordered (Lo) and liquid-disordered (Ld) phases in model membranes, was used in combination with monoclonal anti-AChR antibody labeling of live cells, which induces AChR clustering. The so-called generalized polarization (GP) of di-4-ANEPPDHQ was measured in regions of the cell-surface membrane associated with or devoid of antibody-induced AChR clusters, respectively. AChR clusters were almost equally distributed between Lo and Ld domains, independently of receptor surface levels and agonist (carbamoylcholine and nicotine) or antagonist (α-bungarotoxin) binding. Cholesterol depletion diminished the cell membrane mean di-4-ANEPPDHQ GP and the number of AChR clusters associated with Ld membrane domains increased concomitantly. Depolymerization of the filamentous actin cytoskeleton by Latrunculin A had the opposite effect, with more AChR clusters associated with Lo domains. AChR internalized via small vesicles having lower GP and lower cholesterol content than the surface membrane. Upon cholesterol depletion, only 12% of the AChR-containing vesicles costained with the fluorescent cholesterol analog fPEG-cholesterol, i.e., AChR endocytosis was essentially dissociated from that of cholesterol. In conclusion, the distribution of AChR submicron-sized clusters at the cell membrane appears to be regulated by cholesterol content and cytoskeleton integrity.