Nucleus-specific translation and assembly of acetylcholinesterase in multinucleated muscle cells.

Multinucleated skeletal muscle fibers synthesize cell surface and secreted oligomeric forms of acetylcholinesterase (AChE) that accumulate at specialized locations on the cell surface, such as sites of nerve-muscle contact. Using allelic variants of the AChE polypeptide chains as genetic markers, we show that nuclei homozygous for either the alpha or beta alleles residing in chimeric myotubes preferentially translate their AChE mRNAs on their respective ERs. These results indicate that the events of transcription, translation, and assembly of this membrane protein are compartmentalized into nuclear domains in multinucleated cells, and provide the structural basis for the possible localized expression and regulation of synaptic components at the neuromuscular junctions of vertebrate skeletal muscle fibers.

Cell surface acetylcholinesterase molecules on multinucleated myotubes are clustered over the nucleus of origin.

Multinucleated skeletal muscle fibers are compartmentalized with respect to the expression and organization of several intracellular and cell surface proteins including acetylcholinesterase (AChE). Mosaic muscle fibers formed from homozygous myoblasts expressing two allelic variants of AChE preferentially translate and assemble the polypeptides in the vicinity of the nucleus encoding the mRNA (Rotundo, R. L. 1990. J. Cell Biol. 110:715-719). To determine whether the locally synthesized AChE molecules are targeted to specific regions of the myotube surface, primary quail myoblasts were mixed with mononucleated cells of the mouse muscle C2/C12 cell line and allowed to fuse, forming heterospecific mosaic myotubes. Cell surface enzyme was localized by immunofluorescence using an avian AChE-specific monoclonal antibody. HOECHST 33342 was used to distinguish between quail and mouse nuclei in myotubes. Over 80% of the quail nuclei exhibited clusters of cell surface AChE in mosaic quail-mouse myotubes, whereas only 4% of the mouse nuclei had adjacent quail AChE-positive regions of membrane, all of which were located next to a quail nucleus. In contrast, membrane proteins such as Na+/K+ ATPase, which are not restricted to specific regions of the myotube surface, are free to diffuse over the entire length of the fiber. These studies indicate that the AChE molecules expressed in multinucleated muscle fibers are preferentially transported and localized to regions of surface membrane overlying the nucleus of origin. This targeting could play an important role in establishing and maintaining specialized cell surface domains such as the neuromuscular and myotendinous junctions.

Transplantation of quail collagen-tailed acetylcholinesterase molecules onto the frog neuromuscular synapse.

The highly organized pattern of acetylcholinesterase (AChE) molecules attached to the basal lamina of the neuromuscular junction (NMJ) suggests the existence of specific binding sites for their precise localization. To test this hypothesis we immunoaffinity purified quail globular and collagen-tailed AChE forms and determined their ability to attach to frog NMJs which had been pretreated with high-salt detergent buffers. The NMJs were visualized by labeling acetylcholine receptors (AChRs) with TRITC-alpha-bungarotoxin and AChE by indirect immunofluorescence; there was excellent correspondence (>97%) between the distribution of frog AChRs and AChE. Binding of the exogenous quail AChE was determined using a species-specific monoclonal antibody. When frog neuromuscular junctions were incubated with the globular G4/G2 quail AChE forms, there was no detectable binding above background levels, whereas when similar preparations were incubated with the collagen-tailed A12 AChE form >80% of the frog synaptic sites were also immunolabeled for quail AChE attached. Binding of the A12 quail AChE was blocked by heparin, yet could not be removed with high salt buffer containing detergent once attached. Similar results were obtained using empty myofiber basal lamina sheaths produced by mechanical or freeze-thaw damage. These experiments show that specific binding sites exist for collagen-tailed AChE molecules on the synaptic basal lamina of the vertebrate NMJ and suggest that these binding sites comprise a "molecular parking lot" in which the AChE molecules can be released, retained, and turned over.

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.

Acetylcholinesterase clustering at the neuromuscular junction involves perlecan and dystroglycan.

Formation of the synaptic basal lamina at vertebrate neuromuscular junction involves the accumulation of numerous specialized extracellular matrix molecules including a specific form of acetylcholinesterase (AChE), the collagenic-tailed form. The mechanisms responsible for its localization at sites of nerve- muscle contact are not well understood. To understand synaptic AChE localization, we synthesized a fluorescent conjugate of fasciculin 2, a snake alpha-neurotoxin that tightly binds to the catalytic subunit. Prelabeling AChE on the surface of Xenopus muscle cells revealed that preexisting AChE molecules could be recruited to form clusters that colocalize with acetylcholine receptors at sites of nerve-muscle contact. Likewise, purified avian AChE with collagen-like tail, when transplanted to Xenopus muscle cells before the addition of nerves, also accumulated at sites of nerve-muscle contact. Using exogenous avian AChE as a marker, we show that the collagenic-tailed form of the enzyme binds to the heparan-sulfate proteoglycan perlecan, which in turn binds to the dystroglycan complex through alpha-dystroglycan. Therefore, the dystroglycan-perlecan complex serves as a cell surface acceptor for AChE, enabling it to be clustered at the synapse by lateral migration within the plane of the membrane. A similar mechanism may underlie the initial formation of all specialized basal lamina interposed between other cell types.

Absence of alpha-syntrophin leads to structurally aberrant neuromuscular synapses deficient in utrophin.

The syntrophins are a family of structurally related proteins that contain multiple protein interaction motifs. Syntrophins associate directly with dystrophin, the product of the Duchenne muscular dystrophy locus, and its homologues. We have generated alpha-syntrophin null mice by targeted gene disruption to test the function of this association. The alpha-Syn(-/)- mice show no evidence of myopathy, despite reduced levels of alpha-dystrobrevin-2. Neuronal nitric oxide synthase, a component of the dystrophin protein complex, is absent from the sarcolemma of the alpha-Syn(-/)- mice, even where other syntrophin isoforms are present. alpha-Syn(-/)- neuromuscular junctions have undetectable levels of postsynaptic utrophin and reduced levels of acetylcholine receptor and acetylcholinesterase. The mutant junctions have shallow nerve gutters, abnormal distributions of acetylcholine receptors, and postjunctional folds that are generally less organized and have fewer openings to the synaptic cleft than controls. Thus, alpha-syntrophin has an important role in synapse formation and in the organization of utrophin, acetylcholine receptor, and acetylcholinesterase at the neuromuscular synapse.

Compartmentalization of acetylcholinesterase mRNA and enzyme at the vertebrate neuromuscular junction.

Acetylcholinesterase (AChE) is concentrated at the vertebrate neuromuscular synapse. To determine whether increased transcript levels could underlie this selective accumulation, we employed a quantitative reverse transcription polymerase chain reaction-based assay to determine mRNA copy number in samples as small as single neuromuscular junctions (NMJs) and a microassay to measure AChE enzyme activity at single synapses. Our results show that AChE mRNA is an intermediate transcript at NMJs, whereas in noninnervated regions of muscle fibers, AChE transcripts are either undetectable or rare. In contrast, alpha-actin transcript levels in the same samples are similar in junctional and extrajunctional regions. However, compared with AChE enzyme activity and alpha-actin mRNA levels, the levels of AChE transcripts at NMJs are highly variable. These results indicate that AChE mRNA and protein expression are compartmentalized at the vertebrate NMJ and provide a direct approach toward dissecting the molecular events leading from synaptic activation to plastic changes in gene expression at single vertebrate synapses.

Assembly and regulation of acetylcholinesterase at the vertebrate neuromuscular junction.

The collagen-tailed form of acetylcholinesterase (ColQ-AChE) is the major if not unique form of the enzyme associated with the neuromuscular junction (NMJ). This enzyme form consists of catalytic and non-catalytic subunits encoded by separate genes, assembled as three enzymatic tetramers attached to the three-stranded collagen-like tail (ColQ). This synaptic form of the enzyme is tightly attached to the basal lamina associated with the glycosaminoglycan perlecan. Fasciculin-2 is a snake toxin that binds tightly to AChE. Localization of junctional AChE on frozen sections of muscle with fluorescent Fasciculin-2 shows that the labeled toxin dissociates with a half-life of about 36 h. The fluorescent toxin can subsequently be taken up by the muscle fibers by endocytosis giving the appearance of enzyme recycling. Newly synthesized AChE molecules undergo a lengthy series of processing events before final transport to the cell surface and association with the synaptic basal lamina. Following co-translational glycosylation the catalytic subunit polypeptide chain interacts with several molecular chaperones, glycosidases and glycosyltransferases to produce a catalytically active enzyme that can subsequently bind to one of two non-catalytic subunits. These molecular chaperones can be rate limiting steps in the assembly process. Treatment of muscle cells with a synthetic peptide containing the PRAD attachment sequence and a KDEL retention signal results in a large increase in assembled and exportable AChE, providing an additional level of post-translational control. Finally, we have found that Pumilio2, a member of the PUF family of RNA-binding proteins, is highly concentrated at the vertebrate neuromuscular junction where it plays an important role in regulating AChE translation through binding to a highly conserved NANOS response element in the 3'-UTR. Together, these studies define several new levels of AChE regulation in electrically excitable cells.

Local control of acetylcholinesterase gene expression in multinucleated skeletal muscle fibers: individual nuclei respond to signals from the overlying plasma membrane.

Nuclei in multinucleated skeletal muscle fibers are capable of expressing different sets of muscle-specific genes depending on their locations within the fiber. Here we test the hypothesis that each nucleus can behave autonomously and responds to signals generated locally on the plasma membrane. We used acetylcholinesterase (AChE) as a marker because its transcripts and protein are concentrated at the neuromuscular and myotendenous junctions. First, we show that tetrodotoxin (TTX) reversibly suppresses accumulation of cell surface AChE clusters, whereas veratridine or scorpion venom (ScVn) increase them. AChE mRNA levels are also regulated by membrane depolarization. We then designed chambered cultures that allow application of sodium channel agonists or antagonists to restricted regions of the myotube surface. When a segment of myotube is exposed to TTX, AChE cluster formation is suppressed only on that region. Conversely, ScVn increases AChE cluster formation only where in contact with the muscle surface. Likewise, both the synthesis and secretion of AChE are shown to be locally regulated. Moreover, using in situ hybridization, we show that the perinuclear accumulation of AChE transcripts also depends on signals that each nucleus receives locally. Thus AChE can be up- and downregulated in adjacent regions of the same myotubes. These results indicate that individual nuclei are responding to locally generated signals for cues regulating gene expression.

Acetylcholinesterase biosynthesis and transport in tissue culture.

The enzyme acetylcholinesterase consists of a family of molecular forms differing in subunit composition, solubility properties, and subcellular location. The use of a variety of reversible or irreversible active site-directed ligands with different membrane permeability properties permits the selective inactivation of separate pools of enzyme molecules. The application of these inhibitors together with standard biochemical techniques has permitted a detailed characterization of the synthesis and metabolism of the secretory and membrane-bound acetylcholinesterase in tissue-cultured cells. These techniques, with minor modifications and appropriate controls, can also be applied to the study of AChE metabolism in organ culture and in vivo.

Targeting acetylcholinesterase molecules to the neuromuscular synapse.

The functional integrity of the neuromuscular synapse requires that sufficient numbers of acetylcholinesterase (AChE) molecules be localized on the specialized extracellular matrix between the nerve terminal and the post-synaptic membrane. Multiple interrelated levels of regulation are necessary to accomplish this complex task including the spatial and temporal restriction of AChE mRNA expression within the muscle fiber, local translation and assembly of AChE polypeptides, and focused accumulation of AChE molecules on the extracellular matrix. This is accomplished in part through the organization of other extracellular matrix molecules into a complex which further associates with acetylcholine receptors and their accompanying molecules. Finally, the mature neuromuscular junction contains molecules which can act as receptors for the attachment of AChE which in turn may allow for the turnover of this enzyme at the synapse. This brief review will focus mainly on contributions from our laboratory towards understanding the mechanisms involved in organizing AChE molecules at the neuromuscular synapse.

Asymmetric acetylcholinesterase is assembled in the Golgi apparatus.

The synthesis, assembly, and processing of the multiple molecular forms of acetylcholinesterase (AcChoEase; acetylcholine acetylhydrolase, EC 3.1.1.7) in quail muscle cultures was studied by using lectins to distinguish enzyme molecules residing in different subcellular compartments. Special emphasis was given to the assembly of asymmetric AcChoEase molecules because these appear to be the predominant, if not unique, forms of AcChoEase at the vertebrate neuromuscular junction. All cell surface and secreted AcChoEase forms bind to immobilized wheat germ agglutinin, ricin, and concanavalin A, indicating that they have complex oligosaccharides. After treatment of muscle cells with a membrane-permeable irreversible AcChoEase inhibitor, there is a rapid reappearance of the globular monomeric, dimeric, and tetrameric AcChoEase forms. However, the collagen-tailed asymmetric form does not appear until about 90 min after treatment. Analysis of the AcChoEase oligosaccharides with lectins indicates maturation to complex forms over a 90-min period. A large fraction of the intracellular globular AcChoEase molecules bind only to concanavalin A, indicating that they are assembled in the rough endoplasmic reticulum. In contrast, all intracellular asymmetric AcChoEase binds to wheat germ agglutinin, and a significant fraction binds to ricin, indicating that this unique AcChoEase form is assembled from subunits that have previously acquired complex sugars. I conclude that assembly of asymmetric AcChoEase, hence acquisition of information specifying basal lamina localization, occurs in the Golgi apparatus.

Purification and properties of the membrane-bound form of acetylcholinesterase from chicken brain. Evidence for two distinct polypeptide chains.

The major molecular form of acetylcholinesterase (AChE) from chicken brain is a membrane-bound glycoprotein with an apparent sedimentation coefficient of 11.4 S. Analysis of the purified protein by gel filtration, velocity sedimentation, and sodium dodecyl sulfate-gel electrophoresis shows that the solubilized enzyme is a globular tetramer with an apparent Mr = 420,000. This membrane-bound form of AChE is hydrophobic and readily aggregates in the absence of detergent. These aggregates are concentration-dependent, relatively stable in the presence of high salt concentrations, yet readily dissociate upon addition of detergent to the 11.4 S form, indicating that the interactions are hydrophobic. Polyclonal and monoclonal antibodies raised against chicken brain AChE purified by ion exchange chromatography, affinity chromatography, and preparative gel electrophoresis precipitate AChE enzyme activity. However, these antibodies do not cross-react with the enzyme from chicken muscle which preferentially hydrolyses butyrylcholine. Immunoprecipitation of isotopically labeled enzyme molecules from tissue cultured brain cells and analysis by sodium dodecyl sulfate-gel electrophoresis shows that AChE consists of two polypeptide chains with apparent Mr = 105,000 (alpha) and 100,000 (beta) in a 1:1 ratio. Immunoblotting of brain AChE with either the polyclonal or monoclonal antibodies indicates that the alpha and beta chains share antigenic determinants. Furthermore, both polypeptide chains can be labeled with [3H]diisopropyl fluorophosphate, indicating that they each contain a catalytic site. This is the first indication that globular forms of AChE may consist of multiple polypeptide chains.

Biogenesis of acetylcholinesterase molecular forms in muscle. Evidence for a rapidly turning over, catalytically inactive precursor pool.

Tissue-cultured chicken embryo muscle cells synthesize several molecular forms of acetylcholinesterase (AChE) which differ in oligomeric structure and fate as membrane-bound or secreted molecules. Using irreversible inhibitors to inactivate AChE molecules we show that muscle cells rapidly synthesize and assemble catalytically active oligomers which transit an obligatory pathway through the Golgi apparatus. These oligomers acquire complex oligosaccharides and are ultimately localized on the cell surface or secreted into the medium. Immunoprecipitation of isotopically labeled AChE shows that the oligomers are assembled shortly after synthesis from two allelic polypeptide chains. About two-thirds of the newly synthesized molecules are assembled into dimers and tetramers, and once assembled these forms do not interconvert. Comparison of newly synthesized catalytically active AChE molecules with isotopically labeled ones indicates that a large fraction of the immature molecules are catalytically inactive. Pulse-chase studies measuring both catalytic activity and isotopic labeling indicate that only the catalytically active oligomers are further processed by the cell, whereas inactive molecules are rapidly degraded intracellularly by an as yet unknown mechanism. Approximately 70-80% of the newly synthesized AChE molecules are degraded in this manner and do not transit the Golgi apparatus. These studies indicate that muscle cells synthesize an excess of this important synaptic component over that which is necessary for maintaining normal levels of this protein. In addition, these studies indicate the existence of an intracellular route of protein degradation which may function as a post-translational regulatory step in the control of exportable proteins.

Transient interactions between collagen-tailed acetylcholinesterase and sulfated proteoglycans prior to immobilization on the extracellular matrix.

Heparin is capable of solubilizing a subset of collagen-tailed (A12) acetylcholinesterase (AChE) molecules from skeletal basal lamina (Rossi, S. G., and Rotundo, R. L. (1993) J. Biol. Chem. 268, 19152-19159). In the present study, we used tissue-cultured quail myotubes to show that, like adult fibers, neither heparin- nor high salt-containing buffers detached AChE molecules from cell-surface clusters. Prelabeling clustered AChE molecules with anti-AchE monoclonal antibody 1A2 followed by incubation in heparin-containing medium showed that there was no reduction in the number or size of preexisting AChE clusters. In contrast, incubation of myotubes with culture medium containing heparin for up to 4 days reversibly blocked the accumulation of new cell-surface AChE molecules without affecting the rate of AChE synthesis or assembly. Newly synthesized A12 AChE becomes tightly attached to the extracellular matrix following externalization. However, in the presence of heparin, blocking the initial interactions between A12 AChE and the extracellular matrix results in release of AChE into the medium with a t1/2 of approximately 3 h. Together, these results suggest that once A12 AChE is localized on the cell surface, initially attached via electrostatic interactions, additional factors or events are responsible for its selective and more permanent retention on the basal lamina.

Regulation of acetylcholinesterase synthesis and assembly by muscle activity. Effects of tetrodotoxin.

The abundance and distribution of acetylcholinesterase (AChE) oligomeric forms expressed in skeletal muscle is strongly dependent upon the activity state of the cells. In this study, we examined several stages of AChE biogenesis to determine which ones were regulated by muscle activity. Inhibiting spontaneous contraction of tissue-cultured quail myotubes with tetrodotoxin (TTX) reduces AChE activity by approximately 30% of the levels found in actively contracting cells. This decrease is due primarily to the loss of 20 S asymmetric (collagen-tailed) AChE from TTX-treated cultures and is reflected in reduced pool sizes for both cell surface and intracellular AChE molecules. Using monoclonal anti-AChE antibodies to immunoprecipitate and quantify isotopically labeled enzyme molecules, we show that AChE down-regulation by TTX is not mediated through changes in the rates of synthesis or degradation of AChE polypeptide chains. Newly synthesized AChE polypeptides acquire enzymatic activity at the same rate in TTX-treated cultures as in actively contracting cells, however, a larger percentage of catalytically active dimers and tetramers are secreted from TTX-treated cultures compared with controls. These results suggest that TTX-induced down-regulation of asymmetric AChE occurs at the level of assembly of globular AChE molecules with collagen-like tail subunits in the Golgi apparatus, rather than through changes in the availability of catalytic subunits. Thus, post-translational mechanisms appear to play an important role in regulating the abundance and distribution of this important synaptic component in skeletal muscle.

Neurons segregate clusters of membrane-bound acetylcholinesterase along their neurites.

Immunocytochemical studies with a monoclonal antibody show that acetylcholinesterase (AcChoEase; EC 3.1.1.7) is distributed in clusters along the fibers of cultured sympathetic neurons but is essentially absent from cell bodies. Although tissue-cultured sympathetic neurons synthesize several oligomeric forms of AcChoEase, only the hydrophobic globular (G4) form of AcChoEase is present within these clusters. This G4 form is asymmetrically distributed within neurons and is transported preferentially into nerve fibers following its synthesis in the cell bodies. Thus G4 is found in clusters on neurons and is readily distinguishable from the hydrophilic forms on the surfaces of myotubes. The association of a specialized form of AcChoEase in densities on neurons in culture indicates that neurons and myotubes have distinct mechanisms for localizing AcChoEase molecules on their surfaces and suggests that these two types of electrically excitable cells have different requirements for organizing synaptic components on their plasma membranes.

Molecular forms of chicken embryo acetylcholinesterase in vitro and in vivo. Isolation and characterization.

The four molecular forms of chick embryo leg muscle acetylcholinesterase have been isolated by velocity sedimentation; their apparent sedimentation coefficients are 19.5 S, 11.5 S, 7.1 S, and 5.4 S. All four forms are glycoproteins, exhibit the same Km for acetylcholine, and are inhibited to the same extent by specific inhibitors of acetyl- and buryrylcholinesterase. Treatment of the 19.5 S form of acetylcholinesterase with trypsin generates an array of molecular forms, several of which have sedimentation coefficients identical with the naturally occurring forms. Collagenase treatment of the 19.5 S acetylcholinesterase results in a somewhat different pattern of acetylcholinesterase forms including a novel 20.6 S form. Only the 19.5 S acetylcholinesterase is sensitive to collagenase treatment. Our results indicate that the several acetylcholinesterase forms share a common catalytic subunit, and suggest that the molecular forms of acetylcholinesterase in the chick represent different ensembles of a common monomer. In culture, the muscle cells contain only the 11.5 and 7.1 S acetylcholinesterase forms; however, they also secrete substantial amounts of enzyme into the medium. These secreted acetylcholinesterases have sedimentation coefficients of 9 S and 15 S. The relative abundance of the different acetylcholinesterase molecular forms changes during muscle development, both in vivo and in vitro, suggesting that the assembly and distribution of this family of membrane glycoproteins is developmentally regulated.

Synthesis, transport and fate of acetylcholinesterase in cultured chick embryos muscle cells.

We have found that approximately one third of the total cell-associated acetylcholinesterase (AChE) is located on the plasma membrane of cultured chick embryo muscle, the remaining two thirds being found within the cells. This cell surface AChE appears to be an integral membrane protein. The surface enzyme is synthesized by the muscle cells in culture and is transported over a 2-3 hr period to the plasma membrane, where it accumulates at the rate of 2-3% of total surface AChE per hour. Once on the plasma membrane the AChE molecules are degraded by a process that exhibits first-order decay kinetics with a half-life of about 50 hr. Under the same experimental conditions, the acetylcholine receptor, a well described muscle cell integral membrane protein, has a half-life of approximately 19 hr. These studies provide the first direct evidence that the numbers of different muscle plasma membrane glycoprotein molecules are determined not only by differential rates of biosynthesis but also by differential rates of degradation. The intracellular AChE constitutes a rapidly turning-over pool of molecules. The rate of synthesis of AChE in culture is approximately 20% of the total cell-associated enzyme per hour, most of which is destined for secretion into the medium. Only a small portion of the newly synthesized AChE is retained on the plasma membrane. The time from synthesis to release of the enzyme is 2-3 hr. Using 3H-DFP to label the newly synthesized AChE, we can also show a quantitative transfer of AChE molecules from the intracellular to the extracellular compartments without any detectable residence time on the plasma membrane. By studying the synthesis transport and externalization of AChE we have defined the intracellular transport pathway and metabolic requirements for secretion in cultured muscle cells. These studies form the basis for a comparison of the metabolism of membrane-bound and secreted glycoproteins from this cell type.

Secretion of acetylcholinesterase: relation to acetylcholine receptor metabolism.

Acetylcholinesterase (AChE) and acetylcholine receptors (AChR) are muscle-specific glycoproteins present (AChR) are muscle-specific glycoproteins present in cultured chick embryo muscle cells. The first is found as both a secreted and a membrane-bound enzyme whereas the ACh receptor is strictly an integral membrane protein. We have studied the transport and externalization of these two proteins in the same cells using several compounds known to affect secretory processes: colchicine, tunicamycin and the ionophores X-537A, Nigericin and Monensin. Under all experimental conditions, any change in the rate of AChE secretion was accompanied by an identical change in the rate of ACh receptor incorporation into the plasma membrane. These studies were designed to test directly the hypothesis that secreted and integral membrane proteins are transported together to the plasma membrane. Our results are consistent with a single transport pathway in muscle cells for the externalization of membrane and secreted proteins.