scholarly journals Acetylcholine receptor aggregation parallels the deposition of a basal lamina proteoglycan during development of the neuromuscular junction.

1984 ◽  
Vol 99 (5) ◽  
pp. 1769-1784 ◽  
Author(s):  
M J Anderson ◽  
F G Klier ◽  
K E Tanguay
Keyword(s):  
Neuromuscular Junction ◽  
Basal Lamina ◽  
Acetylcholine Receptors ◽  
Time Course ◽  
Synapse Formation ◽  
Muscle Cells ◽  
Postsynaptic Membrane ◽  
Receptor Aggregation ◽  
Nerve Muscle ◽  
Alpha Bungarotoxin

To determine the time course of synaptic differentiation, we made successive observations on identified, nerve-contacted muscle cells developing in culture. The cultures had either been stained with fluorescent alpha-bungarotoxin, or were maintained in the presence of a fluorescent monoclonal antibody. These probes are directed at acetylcholine receptors (AChR) and a basal lamina proteoglycan, substances that show nearly congruent surface organizations at the adult neuromuscular junction. In other experiments individual muscle cells developing in culture were selected at different stages of AChR accumulation and examined in the electron microscope after serial sectioning along the entire path of nerve-muscle contact. The results indicate that the nerve-induced formation of AChR aggregates and adjacent plaques of proteoglycan is closely coupled throughout early stages of synapse formation. Developing junctional accumulations of AChR and proteoglycan appeared and grew progressively, throughout a perineural zone that extended along the muscle surface for several micrometers on either side of the nerve process. Unlike junctional AChR accumulations, which disappeared within a day of denervation, both junctional and extrajunctional proteoglycan deposits were stable in size and morphology. Junctional proteoglycan deposits appeared to correspond to discrete ultrastructural plaques of basal lamina, which were initially separated by broad expanses of lamina-free muscle surface. The extent of this basal lamina, and a corresponding thickening of the postsynaptic membrane, also increased during the accumulation of AChR and proteoglycan along the path of nerve contact. Presynaptic differentiation of synaptic vesicle clusters became detectable at the developing neuromuscular junction only after the formation of postsynaptic plaques containing both AChR and proteoglycan. It is concluded that motor nerves induce a gradual formation and growth of AChR aggregates and stable basal lamina proteoglycan deposits on the muscle surface during development of the neuromuscular junction.

scholarly journals Acetylcholinesterase Clustering at the Neuromuscular Junction Involves Perlecan and Dystroglycan

1999 ◽  
Vol 145 (4) ◽  
pp. 911-921 ◽  
Author(s):  
H. Benjamin Peng ◽  
Hongbo Xie ◽  
Susanna G. Rossi ◽  
Richard L. Rotundo
Keyword(s):  
Neuromuscular Junction ◽  
Basal Lamina ◽  
Acetylcholine Receptors ◽  
Muscle Cells ◽  
Cell Types ◽  
Specific Form ◽  
Lateral Migration ◽  
Extracellular Matrix Molecules ◽  
A Cell ◽  
Nerve Muscle

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 α-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 α-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.

scholarly journals Purification and characterization of a polypeptide from chick brain that promotes the accumulation of acetylcholine receptors in chick myotubes.

1986 ◽  
Vol 103 (2) ◽  
pp. 493-507 ◽  
Author(s):  
T B Usdin ◽  
G D Fischbach
Keyword(s):  
Acetylcholine Receptors ◽  
Synapse Formation ◽  
Neuromuscular Junctions ◽  
Surface Membrane ◽  
Postsynaptic Membrane ◽  
Size Exclusion ◽  
Response Curves ◽  
Sds Page ◽  
Nerve Muscle ◽  
Receptor Clusters

Acetylcholine receptors (AChRs) are packed in the postsynaptic membrane at neuromuscular junctions at a density of approximately 20,000/micron 2, whereas the density a few micrometers away is less than 20/micron 2. To understand how this remarkable distribution comes about during nerve-muscle synapse formation, we have attempted to isolate factors from neural tissue that can promote the accumulation of AChRs and/or alter their distribution. In this paper we report the purification of a polypeptide from chick brains that can increase the rate of insertion of AChR into membranes of cultured chick myotubes at a concentration of less than 0.5 ng/ml. Based on SDS PAGE and the action of neuraminidase, the acetylcholine receptor-inducing activity (ARIA) appears to be a 42,000-D glycoprotein. ARIA was extracted in a trifluoroacetic acid-containing cocktail and purified to homogeneity by reverse-phase, ion exchange, and size exclusion high pressure liquid chromatography. Dose response curves indicate that the activity has been purified 60,000-fold compared with the starting acid extract and approximately 1,500,000-fold compared with a saline extract prepared from the same batch of brains. Although the ARIA was purified on the basis of its ability to increase receptor incorporation, we found that it increased the number and size of receptor clusters as well. It is not yet clear if the two effects are independent. The 42-kD ARIA is extremely stable: it was not destroyed by exposure to intact myotubes, low pH, organic solvents, or SDS. Its action appears to be selective in that the increase in the rate of receptor insertion was not accompanied by an increase in the rate of protein synthesis. Moreover, there was no change in cellular, surface membrane, or secreted acetylcholinesterase. The effect of ARIA is apparently independent of the state of activity of the target myotubes as its effect on receptor incorporation added to that of maximal concentrations of tetrodotoxin.

scholarly journals Degradation rates of acetylcholine receptors can be modified in the postjunctional plasma membrane of the vertebrate neuromuscular junction.

1986 ◽  
Vol 103 (4) ◽  
pp. 1399-1403 ◽  
Author(s):  
M M Salpeter ◽  
D L Cooper ◽  
T Levitt-Gilmour
Keyword(s):  
Neuromuscular Junction ◽  
Acetylcholine Receptors ◽  
Degradation Rate ◽  
Postsynaptic Membrane ◽  
Nerve Crush ◽  
Adult Mice ◽  
Vertebrate Muscle ◽  
Degradation Rates ◽  
Alpha Bungarotoxin ◽  
Two Populations

Denervation of vertebrate muscle causes an acceleration of acetylcholine receptor turnover at the neuromuscular junction. This acceleration reflects the composite behavior of two populations of receptors: "original receptors" present at the junction at the time of denervation, and "new receptors" inserted into the denervated junction to replace the original receptors as they are degraded (Levitt, T. A., and M. M. Salpeter, 1981, Nature (Lond.), 291:239-241). The present study examined the degradation rate of original receptors to determine whether reinnervation could reverse the effect of denervation. Sternomastoid muscles in adult mice were denervated by either cutting or crushing the nerve, and the nerves either allowed to regenerate or ligated to prevent regeneration. The original receptors were labeled with 125I-alpha-bungarotoxin at the time of denervation, and their degradation rate followed by gamma counting. We found that when the nerve was not allowed to regenerate, the degradation decreased from a t1/2 of approximately 8-10 d to one of approximately 3 d (as reported earlier for denervated original receptors) and remained at that half-life throughout the experiment (approximately 36 d). If the axons were allowed to regenerate (which occurred asynchronously between day 14 and day 30 after nerve cut and between day 7 and 13 after nerve crush), the accelerated degradation rate of the original receptors reverted to a t1/2 of approximately 8 d. Our data lead us to conclude that the effect of denervation on the degradation rate of original receptors can be reversed by reinnervating. The nerve can thus slow the degradation rate of receptors previously inserted into the postsynaptic membrane.

Acetylcholine receptors at the rat neuromuscular junction as revealed by deep etching

1982 ◽  
Vol 215 (1199) ◽  
pp. 147-154 ◽  
Keyword(s):  
Neuromuscular Junction ◽  
Basal Lamina ◽  
Acetylcholine Receptors ◽  
Postsynaptic Membrane ◽  
Muscle Fibres ◽  
Nerve Terminals ◽  
Single Muscle ◽  
Deep Etching ◽  
Collagenase Treatment ◽  
Regular Arrangement

Collagenase treatment of rat intercostal muscles yielded single muscle fibres in which the nerve terminals and basal lamina were removed allowing an unimpeded view of the ecternal surface of the postsynaptic membrane. This was revealed by deep etching of freeze-fractured preparations and appeared as a maze of folds separated by deep troughs, showing on the crests of the folds a densely packed population of protrusions about 8⋅5 nm in diameter. These densely packed protrusions ( ca . 9000 μm -2 ) are mainly confined to the postsynaptic regions of the sarcolemma and presumably represent the acetycholine receptor molecules, which are highly concenrated in these areas. The protrusions are generally tightly packed without obvious regular arrangement, but in some areas, usually on the tops of the crests, they are arranged into irregular rows normal to the long axis of the folds.

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

1979 ◽  
Vol 83 (1) ◽  
pp. 143-158 ◽  
Author(s):  
E Frank ◽  
G D Fischbach
Keyword(s):  
Synapse Formation ◽  
Synaptic Cleft ◽  
Postsynaptic Membrane ◽  
Active Growth ◽  
Before And After ◽  
Nerve Muscle ◽  
Scanning Em ◽  
Receptor Clusters ◽  
Alpha Bungarotoxin

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

scholarly journals Characterisation of alpha-dystrobrevin in muscle

1998 ◽  
Vol 111 (17) ◽  
pp. 2595-2605 ◽  
Author(s):  
R. Nawrotzki ◽  
N.Y. Loh ◽  
M.A. Ruegg ◽  
K.E. Davies ◽  
D.J. Blake
Keyword(s):  
Skeletal Muscle ◽  
Neuromuscular Junction ◽  
Cell Surface ◽  
Acetylcholine Receptor ◽  
Acetylcholine Receptors ◽  
Synapse Formation ◽  
Electric Organ ◽  
Postsynaptic Membrane ◽  
Related Protein ◽  
Receptor Clustering

Dystrophin-related and associated proteins are important for the formation and maintenance of the mammalian neuromuscular junction. Initial studies in the electric organ of Torpedo californica showed that the dystrophin-related protein dystrobrevin (87K) co-purifies with the acetylcholine receptors and other postsynaptic proteins. Dystrobrevin is also a major phosphotyrosine-containing protein in the postsynaptic membrane. Since inhibitors of tyrosine protein phosphorylation block acetylcholine receptor clustering in cultured muscle cells, we examined the role of alpha-dystrobrevin during synapse formation and in response to agrin. Using specific antibodies, we show that C2 myoblasts and early myotubes only produce alpha-dystrobrevin-1, the mammalian orthologue of Torpedo dystrobrevin, whereas mature skeletal muscle expresses three distinct alpha-dystrobrevin isoforms. In myotubes, alpha-dystrobrevin-1 is found on the cell surface and also in acetylcholine receptor-rich domains. Following agrin stimulation, alpha-dystrobrevin-1 becomes re-localised beneath the cell surface into macroclusters that contain acetylcholine receptors and another dystrophin-related protein, utrophin. This redistribution is not associated with tyrosine phosphorylation of alpha-dystrobrevin-1 by agrin. Furthermore, we show that alpha-dystrobrevin-1 is associated with both utrophin in C2 cells and dystrophin in mature skeletal muscle. Thus alpha-dystrobrevin-1 is a component of two protein complexes in muscle, one with utrophin at the neuromuscular junction and the other with dystrophin at the sarcolemma. These results indicate that alpha-dystrobrevin-1 is not involved in the phosphorylation-dependent, early stages of receptor clustering, but rather in the stabilisation and maturation of clusters, possibly via an interaction with utrophin.

scholarly journals Aggregates of acetylcholine receptors are associated with plaques of a basal lamina heparan sulfate proteoglycan on the surface of skeletal muscle fibers.

1983 ◽  
Vol 97 (5) ◽  
pp. 1396-1411 ◽  
Author(s):  
M J Anderson ◽  
D M Fambrough
Keyword(s):  
Skeletal Muscle ◽  
Neuromuscular Junction ◽  
Heparan Sulfate ◽  
Basal Lamina ◽  
Acetylcholine Receptors ◽  
Muscle Fibers ◽  
Muscle Cells ◽  
Heparan Sulfate Proteoglycan ◽  
Sulfate Proteoglycan ◽  
Skeletal Muscle Fibers

Hybridoma techniques have been used to generate monoclonal antibodies to an antigen concentrated in the basal lamina at the Xenopus laevis neuromuscular junction. The antibodies selectively precipitate a high molecular weight heparan sulfate proteoglycan from conditioned medium of muscle cultures grown in the presence of [35S]methionine or [35S]sulfate. Electron microscope autoradiography of adult X. laevis muscle fibers exposed to 125I-labeled antibody confirms that the antigen is localized within the basal lamina of skeletal muscle fibers and is concentrated at least fivefold within the specialized basal lamina at the neuromuscular junction. Fluorescence immunocytochemical experiments suggest that a similar proteoglycan is also present in other basement membranes, including those associated with blood vessels, myelinated axons, nerve sheath, and notochord. During development in culture, the surface of embryonic muscle cells displays a conspicuously non-uniform distribution of this basal lamina proteoglycan, consisting of large areas with a low antigen site-density and a variety of discrete plaques and fibrils. Clusters of acetylcholine receptors that form on muscle cells cultured without nerve are invariably associated with adjacent, congruent plaques containing basal lamina proteoglycan. This is also true for clusters of junctional receptors formed during synaptogenesis in vitro. This correlation indicates that the spatial organization of receptor and proteoglycan is coordinately regulated, and suggests that interactions between these two species may contribute to the localization of acetylcholine receptors at the neuromuscular junction.

scholarly journals Proteolytic disruption of laminin-integrin complexes on muscle cells during synapse formation.

1996 ◽  
Vol 16 (9) ◽  
pp. 4972-4984 ◽  
Author(s):  
M J Anderson ◽  
Z Q Shi ◽  
S L Zackson
Keyword(s):  
Basal Lamina ◽  
Synapse Formation ◽  
Neuromuscular Junctions ◽  
Surrounding Medium ◽  
Muscle Cells ◽  
Cell Contact ◽  
Neural Modulation ◽  
Ligand Interactions ◽  
Nerve Muscle ◽  
Integrin Ligand

To explore whether a neural modulation of muscle integrins' extracellular ligand interactions contributes to synapse induction, we compared the distributions of beta1-integrins and basal lamina proteins on Xenopus myotomal myocytes developing in culture. beta1-Integrins formed numerous organized aggregates scattered over the entire muscle surface, with particularly dense accumulations at specialized sites resembling myotendinous and neuromuscular junctions. Integrin aggregates on muscle cells differed from those on surrounding fibroblasts and epithelial cells, both in their lack of response to cross-linking by multivalent ligands and in their consistent association with the cells' own extracellular matrices. Muscle integrin clusters were usually associated with congruent basal lamina accumulations containing laminin and a heparan sulfate proteoglycan (HSPG), sometimes including fibronectin and vitronectin acquired from the surrounding medium. Immediately prior to synaptic differentiation, any existing laminin and HSPG accumulations along the path of cell contact were eliminated, disrupting otherwise stable laminin-integrin complexes. This apparently proteolytic modulation of integrins' extracellular ligand interactions was soon followed by the accumulation of new congruent accumulations of laminin and HSPG in the developing synaptic basal lamina. Combining these results with earlier findings, we consider the possibility that postsynaptic differentiation is induced, at least in part, by the proteolytic disruption of integrin-ligand complexes at sites of nerve-muscle contact.

Induction of a specialized muscle basal lamina at chimaeric synapses in culture

Development ◽  
1990 ◽  
Vol 110 (1) ◽  
pp. 51-61 ◽  
Author(s):  
L.E. Swenarchuk ◽  
S. Champaneria ◽  
M.J. Anderson
Keyword(s):  
Monoclonal Antibodies ◽  
Basal Lamina ◽  
Acetylcholine Receptors ◽  
Muscle Cells ◽  
Synaptic Cleft ◽  
Sulfate Proteoglycan ◽  
Cellular Origin ◽  
Initial Deposition ◽  
Species Specific ◽  
Nerve Muscle

To identify mechanisms that regulate the formation of the neuromuscular junction, we examined the cellular origin of a heparan sulfate proteoglycan (HSPG) that becomes highly concentrated within the synaptic cleft during the initial deposition of the junctional basal lamina. Using cultured nerve and muscle cells from anuran and urodele embryos, we prepared species-chimaeric synapses that displayed spontaneous cholinergic potentials, and eventually developed organized accumulations of acetylcholine receptors and HSPG at the sites of nerve-muscle contact. To determine the cellular origin of synaptic HSPG molecules, these chimaeric junctions were stained with both species-specific and cross-reactive monoclonal antibodies, labeled with contrasting fluorochromes. Our results demonstrate that synaptic HSPG is derived almost exclusively from muscle. Since it has already been shown that muscle cells can assemble virtually all of the known constituents of the junctional basal lamina into organized surface accumulations, without any input from nerve cells, we consider the possibility that the specialized synaptic basal lamina may be generated primarily by the myofibre, in response to another ‘inductive’ positional signal at the site of nerve-muscle contact.

scholarly journals Processing of ARIA and release from isolated nerve terminals

1999 ◽  
Vol 354 (1381) ◽  
pp. 411-416 ◽  
Author(s):  
Bomie Han ◽  
Gerald D. Fischbach
Keyword(s):  
Neuromuscular Junction ◽  
Action Potential ◽  
Acetylcholine Receptors ◽  
Molecular Layer ◽  
Postsynaptic Membrane ◽  
High Density ◽  
Small Contribution ◽  
Presynaptic Nerve Terminal ◽  
Voltage Gated

The neuromuscular junction is a specialized synapse in that every action potential in the presynaptic nerve terminal results in an action potential in the postsynaptic membrane, unlike most interneuronal synapses where a single presynaptic input makes only a small contribution to the population postsynaptic response. The postsynaptic membrane at the neuromuscular junction contains a high density of neurotransmitter (acetylcholine) receptors and a high density of voltage–gated Na + channels. Thus, the large acetylcholine activated current occurs at the same site where the threshold for action potential generation is low. Acetylcholine receptor inducing activity (ARIA), a 42 kD protein, that stimulates synthesis of acetylcholine receptors and voltage–gated Na + channels in cultured myotubes, probably plays the same roles at developing and mature motor endplates in vivo . ARIA is synthesized as part of a larger, transmembrane, precursor protein called proARIA. Delivery of ARIA from motor neuron cell bodies in the spinal cord to the target endplates involves several steps, including proteolytic cleavage of proARIA. ARIA is also expressed in the central nervous system and it is abundant in the molecular layer of the cerebellum. In this paper we describe our first experiments on the processing and release of ARIA from subcellular fractions containing synaptosomes from the chick cerebellum as a model system.

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