In vivo regulation of acetylcholinesterase insertion at the neuromuscular junction

The efficiency of synaptic transmission between nerve and muscle depends on the number and density of acetylcholinesterase molecules (AChE) at the neuromuscular junction. However, little is known about the way this density is maintained and regulated in vivo. By using time lapse and quantitative fluorescence imaging assays in living mice, we demonstrated that insertion of new AChEs occurs within hours of saturating pre-existing AChEs with fasciculin2, a snake toxin that selectively labels AChE. In the absence of muscle postsynaptic activity or evoked nerve presynaptic neurotransmitter release, AChE insertion was decreased significantly, whereas direct stimulation of the muscle completely restored AChE insertion to control levels. This activity-dependent AChE insertion is mediated by intracellular calcium. In muscle stimulated in the presence of a Ca2+ channel blocker or calcium-permeable Ca2+ chelator, AChE insertion into synapses was significantly decreased, whereas ryanodine or ionophore A12387 treatment of blocked and unstimulated synapses significantly increased AChE insertion. These results demonstrated that synaptic activity is critical for AChE insertion and indicated that a rise in intracellular calcium either through voltage-gated calcium channels or from intracellular stores is critical for proper AChE insertion into the adult synapse.     

The dynamics of recycled acetylcholine receptors at the neuromuscular junction in vivo

At the peripheral neuromuscular junction (NMJ), a significant number of nicotinic acetylcholine receptors (AChRs) recycle back into the postsynaptic membrane after internalization to intermingle with not-yet-internalized ;pre-existing' AChRs. However, the way in which these receptor pools are maintained and regulated at the NMJ in living animals remains unknown. Here, we demonstrate that recycled receptors in functional synapses are removed approximately four times faster than pre-existing receptors, and that most removed recycled receptors are replaced by new recycled ones. In denervated NMJs, the recycling of AChRs is significantly depressed and their removal rate increased, whereas direct muscle stimulation prevents their loss. Furthermore, we show that protein tyrosine phosphatase inhibitors cause the selective accumulation of recycled AChRs in the peri-synaptic membrane without affecting the pre-existing AChR pool. The inhibition of serine/threonine phosphatases, however, has no effect on AChR recycling. These data show that recycled receptors are remarkably dynamic, and suggest a potential role for tyrosine dephosphorylation in the insertion and maintenance of recycled AChRs at the postsynaptic membrane. These findings may provide insights into long-term recycling processes at less accessible synapses in the central nervous system in vivo.     

Acetylcholinesterase mobility and stability at the neuromuscular junction of living mice

Acetylcholinesterase (AChE) is an enzyme that terminates acetylcholine neurotransmitter function at the synaptic cleft of cholinergic synapses. However, the mechanism by which AChE number and density are maintained at the synaptic cleft is poorly understood. In this work, we used fluorescence recovery after photobleaching, photo-unbinding, and quantitative fluorescence imaging to investigate the surface mobility and stability of AChE at the adult innervated neuromuscular junction of living mice. In wild-type synapses, we found that nonsynaptic (perisynaptic and extrasynaptic) AChEs are mobile and gradually recruited into synaptic sites and that most of the trapped AChEs come from the perijunctional pool. Selective labeling of a subset of synaptic AChEs within the synapse by using sequential unbinding and relabeling with different colors of streptavidin followed by time-lapse imaging showed that synaptic AChEs are nearly immobile. At neuromuscular junctions of mice deficient in alpha-dystrobrevin, a component of the dystrophin glycoprotein complex, we found that the density and distribution of synaptic AChEs are profoundly altered and that the loss rate of AChE significantly increased. These results demonstrate that nonsynaptic AChEs are mobile, whereas synaptic AChEs are more stable, and that alpha-dystrobrevin is important for controlling the density and stability of AChEs at neuromuscular synapses.     

Fasciculin II,a protein inhibitor of acetylcholinesterase,tested on central synapses ofAplysia

Fasciculin II, a potential inhibitor of acetylcholinesterase (AChE), was tested on two types of Aplysia cholinergic receptors: H type, opening Cl- channels; and D type, opening cationic channels. Evoked postsynaptic inhibitory responses and responses to ionophoretic application of acetylcholine (ACh) or carbachol onto H-type receptors were potentiated in the presence of fasciculin II at 10(-9) M, whereas the same concentration of this drug was without effect on the evoked postsynaptic excitatory responses or on the application of ACh or carbachol on D-type receptors. The observed effects of fasciculin II were identical to those obtained with other inhibitors of AChE on the same preparation. The facilitatory effect on the carbachol response in H-type cells indicates that fasciculin II, as other AChE inhibitors, does not act on H-type synapses solely by blocking the hydrolysis of ACh. We concluded that fasciculin II was a good inhibitor of acetylcholinesterase on neuronal preparations in vivo. The results are further discussed as a new element in favor of a previously proposed hypothesis of a molecular interaction between AChE and ACh H-type receptors.     

Transmembrane mechanisms in the assembly of the postsynaptic apparatus at the neuromuscular junction

The vertebrate neuromuscular junction (NMJ) is marked by molecular specializations that include postsynaptic clusters of acetylcholine receptor (AChR) and acetylcholinesterase (AChE). Whereas AChRs are aggregated in the postsynaptic muscle membrane to a density of 10,000/mum(2), AChE is concentrated, also to a high density, in the synaptic basement membrane (BM). In recent years considerable progress has been made in understanding the cellular and molecular mechanisms of AChR clustering. It is known that during the early stages of motoneuron-muscle interaction, the nerve-secreted proteoglycan agrin activates the muscle-specific kinase MuSK, which leads to the formation of a postsynaptic cytoskeletal scaffold that immobilizes and concentrates AChRs through a process generally accepted to involve diffusion-mediated trapping of the receptors. We have recently tested this diffusion-trap model at the single molecule level for the first time by using quantum-dot labeling to track individual AChRs during NMJ development. Our results showed that single AChRs exhibit Brownian-type movement, with diffusion coefficients of 10(-11) to 10(-9)cm(2)/s, until they become immobilized at "traps" assembled in response to synaptogenic stimuli. Thus, free diffusion of AChRs is an integral part of their clustering mechanism. What is the mechanism for AChE clustering? We previously showed that the A(12) asymmetric form of AChE binds to perlecan, a heparan-sulfate proteoglycan which in turn interacts with the transmembrane dystroglycan complex. Through this linkage AChE becomes bound to the muscle membrane and, like AChRs, may exhibit lateral mobility along the membrane. Consistent with this idea, pre-existent AChE at the cell surface becomes clustered together with AChRs following synaptogenic stimulation. Future studies testing diffusion-mediated trapping of AChE should provide insights into the synaptic localization of BM-bound molecules at the NMJ.     

The fasciculin-acetylcholinesterase interaction

Acetylcholinesterase (AChE) terminates the action of the neurotransmitter acetylcholine at cholinergic synapses in the central and peripheral nervous systems. Fasciculins, which belong to the family of "three-fingered" snake toxins, selectively inhibit mammalian AChEs with Ki values in the picomolar range. In solution, the cationic fasciculin appears to bind to the enzyme's peripheral anionic site, located near the mouth of the gorge leading to the active center, to inhibit catalysis either allosterically or by creating an electrostatic barrier at the gorge entry (or both). Yet the crystal structure of the fasciculin-mouse AChE complex, which shows that the central loop of fasciculin fits snugly at the entrance of the gorge, suggests that the mode of action of fasciculin is steric occlusion of substrate access to the active center. Mutagenesis of the fasciculin molecule, undertaken to establish a functional map of the binding surfaces, identified determinants common to those identified by the structural approach and revealed that only a few of the many fasciculin residues residing at the complex interface provide the strong contacts required for high affinity binding and enzyme inhibition. However, it did not reconcile the disparity between the kinetic and structural data. Finally, the crystal structure of mouse AChE without bound fasciculin shows a tetrameric assembly of subunits; within the tetramer, a short loop at the surface of a subunit associates with the peripheral site of a facing subunit and sterically occludes the entrance of the active center gorge. The position and complementarity of the peripheral site-occluding loop mimic the characteristics of the central loop of fasciculin bound to AChE. This suggests not only that the peripheral site of AChE is a site for association of heterologous proteins with interactive surface loops, but also that endogenous peptidic ligands of AChE sharing structural features with the fasciculin molecule might exist.     

Aggregating factor from Torpedo electric organ induces patches containing acetylcholine receptors, acetylcholinesterase, and butyrylcholinesterase on cultured myotubes

A factor in extracts of the electric organ of Torpedo californica causes the formation of clusters of acetylcholine receptors (AChRs) and aggregates of acetylcholinesterase (AChE) on myotubes in culture. In vivo, AChRs and AChE accumulate at the same locations on myofibers, as components of the postsynaptic apparatus at neuromuscular junctions. The aim of this study was to compare the distribution of AChRs, AChE, and butyrylcholinesterase (BuChE), a third component of the postsynaptic apparatus, on control and extract-treated myotubes. Electric organ extracts induced the formation of patches that contained high concentrations of all three molecules. The extract-induced aggregation of AChRs, AChE, and BuChE occurred in defined medium, and these components accumulated in patches simultaneously. Three lines of evidence indicate that a single factor in the extracts induced the aggregation of all three components: the dose dependence for the formation of patches of AChRs was the same as that for patches of AChE and BuChE; the AChE- and BuChE-aggregating activities co-purified with the AChR-aggregating activity; and all three aggregating activities were immunoprecipitated at the same titer by a monoclonal antibody against the AChR-aggregating factor. We have shown previously that this monoclonal antibody binds to molecules concentrated in the synaptic cleft at neuromuscular junctions. Taken together, these results suggest that during development and regeneration of myofibers in vivo, the accumulation at synaptic sites of at least three components of the postsynaptic apparatus, AChRs, AChE, and BuChE, are all triggered by the same molecule, a molecule similar if not identical to the electric organ aggregating factor.     

Developmental increase in the amount of rapsyn per acetylcholine receptor promotes postsynaptic receptor packing and stability

Neuromuscular synaptic transmission depends upon tight packing of acetylcholine receptors (AChRs) into postsynaptic AChR aggregates, but not all postsynaptic AChRs are aggregated. Here we describe a new confocal Fluorescence Resonance Energy Transfer (FRET) assay for semi-quantitative comparison of the degree to which AChRs are aggregated at synapses. During the first month of postnatal life the mouse tibialis anterior muscle showed increases both in the number of postsynaptic AChRs and the efficiency with which AChR was aggregated (by FRET). There was a concurrent two-fold increase in immunofluorescent labeling for the AChR-associated cytoplasmic protein, rapsyn. When 1-month old muscle was denervated, postsynaptic rapsyn immunostaining was reduced, as was the efficiency of AChR aggregation. In vivo electroporation of rapsyn-EGFP into muscle fibers increased postsynaptic rapsyn levels. Those synapses with higher ratios of rapsyn-EGFP to AChR displayed a slower metabolic turnover of AChR. Conversely, the reduction of postsynaptic rapsyn after denervation was accompanied by an acceleration of AChR turnover. Thus, a developmental increase in the amount of rapsyn targeted to the postsynaptic membrane may drive enhanced postsynaptic AChRs aggregation and AChR stability within the postsynaptic membrane.     

The signaling pathways mediated by P2Y nucleotide receptors in the formation and maintenance of the skeletal neuromuscular junction

The motor neuron, the Schwann cell and the muscle cell are highly specialized at the vertebrate skeletal neuromuscular junction (NMJ). The muscle cell surface contains a high local density of acetylcholine (ACh) receptors (AChRs), acetylcholinesterase (AChE) and their interacting macromolecules at the NMJ, forming the postsynaptic specializations. During the early stages of development, the incoming nerve terminal induces the formation of these postsynaptic specializations; the nerve secretes agrin and neuregulin (NRG), which are known to aggregate existing AChRs and to increase the expression of AChR at the synaptic region, respectively. In addition, adenosine 5'-triphosphate (ATP) is stored at the motor nerve terminals and is coreleased with ACh during muscle contraction. Recent evidence suggests that ATP can play a role in forming and maintaining the postsynaptic specializations by activating its corresponding receptors. In particular, one of the nucleotide receptor subtypes, the P2Y(1) receptor, is specifically localized at the NMJs. The gene expression of AChR and AChE is upregulated after the activation of P2Y(1) receptors. Thus, the synaptic ATP together with agrin and NRG can act as a synapse-organizing factor to induce the expression of postsynaptic functional effectors.     

Acetylcholinesterase activity and type C synapses in the hypoglossal, facial and spinal-cord motor nuclei of rats. An electron-microscope study

Using the electron-microscope technique of Lewis and Shute, we studied the localization of the acetylcholinesterase (AChE) activity in the hypoglossal, facial and spinal-cord motor nuclei of rats. The technique used selectively detects synapses with subsynaptic cisterns (type C synapses) as well as heavy deposits of reaction products in the rough endoplasmic reticulum, in fragments of the nuclear envelope, in some Golgi zones and on parts of the pericaryal plasma membrane, the axolemma and the dendritic membrane. In C synapses, AChE activity was located in the synaptic cleft and on the membrane of presynaptic boutons. Some C synapses exhibited distinct synaptic specialization in the form of multiple 'active zones'. These zones were characterized by dense presynaptic projections, short dilations of the synaptic cleft, and postsynaptic densities localized between the postsynaptic membrane and the outer membrane of the subsynaptic cistern. Within the postsynaptic densities, rows of rod- or channel-like structures were observed. The subsynaptic cisterns were continuous with the positive rough endoplasmic reticulum. The results are discussed in terms of the possible role of C synapses in the regulation of AChE synthesis in postsynaptic cholinergic neurons and/or in the regulation of AChE release into the extracellular space as well as in the establishment of new synaptic contacts.     

In vivo imaging of presynaptic terminals and postsynaptic sites in the mouse submandibular ganglion

Much of what is currently known about the behavior of synapses in vivo has been learned at the mammalian neuromuscular junction, because it is large and accessible and also its postsynaptic acetylcholine receptors (AChRs) are readily labeled with a specific, high-affinity probe, alpha-bungarotoxin (BTX). Neuron-neuron synapses have thus far been much less accessible. We therefore developed techniques for imaging interneuronal synapses in an accessible ganglion in the peripheral nervous system. In the submandibular ganglion, individual preganglionic axons establish large numbers of axo-somatic synapses with postganglionic neurons. To visualize these sites of synaptic contact, presynaptic axons were imaged by using transgenic mice that express fluorescent protein in preganglionic neurons. The postsynaptic sites were visualized by labeling the acetylcholine receptor (AChR) alpha7 subunit with fluorescently tagged BTX. We developed in vivo methods to acquire three-dimensional image stacks of the axons and postsynaptic sites and then follow them over time. The submandibular ganglion is an ideal site to study the formation, elimination, and maintenance of synaptic connections between neurons in vivo.     

PKC and PKA Regulate AChR Dynamics at the Neuromuscular Junction of Living Mice

The steady state of the acetylcholine receptor (AChR) density at the neuromuscular junction (NMJ) is critical for efficient and reliable synaptic transmission. However, little is known about signaling molecules involved in regulating the equilibrium between the removal and insertion of AChRs that establishes a stable postsynaptic receptor density over time. In this work, we tested the effect of activities of two serine/threonine kinases, PKC and PKA, on the removal rate of AChRs from and the re-insertion rate of internalized recycled AChRs into synaptic sites of innervated and denervated NMJs of living mice. Using an in vivo time-lapse imaging approach and various pharmacological agents, we showed that PKC and PKA activities have antagonistic effects on the removal and recycling of AChRs. Inhibition of PKC activity or activation of PKA largely prevents the removal of pre-existing AChRs and promotes the recycling of internalized AChRs into the postsynaptic membrane. In contrast, stimulation of PKC or inactivation of PKA significantly accelerates the removal of postsynaptic AChRs and depresses AChR recycling. These results indicate that a balance between PKA and PKC activities may be critical for the maintenance of the postsynaptic receptor density.     

Agrin and acetylcholine receptors are removed from abandoned synaptic sites at reinnervated frog neuromuscular junctions

Changes in the distribution of agrin and acetylcholine receptors (AChRs) were examined during reinnervation and following permanent denervation as a means of understanding mechanisms controlling the distribution of these molecules. Following nerve damage in the peripheral nervous system, regenerating nerve terminals preferentially return to previous synaptic sites leading to the restoration of synaptic activity. However, not all portions of original synaptic sites are reoccupied: Some of the synaptic sites are abandoned by both the nerve terminal and the Schwann cell. Abandoned synaptic sites contain agrin, AChRs, and acetylcholinesterase (AChE) without an overlying nerve terminal or Schwann cell providing a unique location to observe changes in the distribution of these synapse-specific molecules. The distribution of anti-agrin and AChR staining at abandoned synaptic sites was altered during the process of reinnervation, changing from a dense, wide distribution to a punctate, pale pattern, and finally becoming entirely absent. Agrin and AChRs were removed from abandoned synaptic sites in reinnervated frog neuromuscular junctions, while in contralateral muscles which were permanently denervated, anti-agrin and AChR staining remained at abandoned synaptic sites. Decreasing synaptic activity during reinnervation delayed the removal of agrin and AChRs from abandoned synaptic sites. Altogether, these results support the hypothesis that synaptic activity controls a cellular mechanism that directs the removal of agrin from synaptic basal lamina and the loss of agrin leads to the dispersal of AChRs. © 1997 John Wiley & Sons, Inc. J Neurobiol 33: 999–1018, 1997     

Synaptic transmission is impaired at neuronal autonomic synapses in agrin-null mice

Neuronal synapse formation is a multistep process regulated by several pre- and postsynaptic adhesion and signaling proteins. Recently, we found that agrin acts as one such synaptogenic factor at neuronal synapses in the PNS by demonstrating that structural synapse formation is impaired in the superior cervical ganglia (SCG) of z+ agrin-deficient mice and in SCG cultures derived from those animals. Here, we tested whether synaptic function is defective in agrin-null (AGD-/-) ganglia and began to define agrin's mechanism of action. Our electrophysiological recordings of compound action potentials showed that presynaptic stimulation evoked action potentials in approximately 40% of AGD-/- ganglionic neurons compared to 90% of wild-type neurons; moreover, transmission could not be potentiated as in wild-type or z+ agrin-deficient ganglia. Intracellular recordings also showed that nerve-evoked excitatory postsynaptic potentials in AGD-/- neurons were only 1/3 the size of those in wild-type neurons and mostly subthreshold. Consistent with these defects in transmission, we found an approximately 40-50% decrease in synapse number in AGD-/- ganglia and cultures, and decreased levels of differentiation at the residual synapses in culture. Furthermore, surface levels of acetylcholine receptors (AChRs) were equivalent in cultured AGD-/- and wild-type neurons, and depolarization reduced the synaptic localization of AChRs in AGD-/- but not wild-type neurons. These findings provide the first direct demonstration that agrin is required for proper structural and functional development of an interneuronal synapse in vivo. Moreover, they suggest a novel role for agrin, in stabilizing the postsynaptic density of nAChR at nascent neuronal synapses.     

Invertebrate acetylcholinesterases: Insights into their evolution and non-classical functions

Acetylcholinesterase (AChE) plays a pivotal role in synaptic transmission by hydrolyzing the neurotransmitter acetylcholine. In addition to the classical function of AChE in synaptic transmission, various non-classical functions have been elucidated. Unlike vertebrates possessing a single AChE gene (ace), invertebrates (nematodes, arachnids, and insects) have multiple ace loci, encoding diverse AChEs with a range of different functions. In the field of toxicology, AChE with synaptic function has long been exploited as the target of organophosphorus and cabarmate pesticides to control invertebrate pests for the past several decades. However, many aspects of the evolution and non-classical roles of invertebrate AChEs are still unclear. Although currently available information on invertebrate AChEs is fragmented, we reviewed the recent findings on their evolutionary status, molecular/biochemical properties, and deduced non-classical (non-neuronal) functions.     

Acetylcholinesterase activity and type C synapses in the hypoglossal,facial and spinal-cord motor nuclei of rats

Summary Using the electron-microscope technique of Lewis and Shute, we studied the localization of the acetylcholinesterase (AChE) activity in the hypoglossal, facial and spinal-cord motor nuclei of rats. The technique used selectively detects synapses with subsynaptic cisterns (type C synapses) as well as heavy deposits of reaction products in the rough endoplasmic reticulum, in fragments of the nuclear envelope, in some Golgi zones and on parts of the pericaryal plasma membrane, the axolemma and the dendritic membrane. In C synapses, AChE activity was located in the synaptie cleft and on the membrane of presynaptic boutons. Some C synapses exhibited distinct synaptic specialization in the form of multiple active zones. These zones were characterized by dense presynaptic projections, short dilations of the synaptic cleft, and postsynaptic densities localized between the postsynaptic membrane and the outer membrane of the subsynaptic cistern. Within the postsynaptic densities, rows of rod- or channel-like structures were observed. The subsynaptic cisterns were continuous with the positive rough endoplasmic reticulum. The results are discussed in terms of the possible role of C synapses in the regulation of AChE synthesis in postsynaptic cholinergic neurons and/or in the regulation of AChE release into the extracellular space as well as in the establishment of new synaptic contacts.In honour of Prof. P. van Duijn     

Biochemical characterization of two distinct acetylcholinesterases possessing almost identical catalytic activity in the damselfly Vestalis gracilis

Most insects possess two different acetylcholinesterases (AChEs) (i.e., AChE1 and AChE2). It has been recently reported that only one AChE (either AChE1 or AChE2) has been selected as the main synaptic enzyme and it varies with different insect lineages (Kim et al., 2012, Kim and Lee, 2013). Interestingly, however, both AChE1 and AChE2 are almost equally active in a damselfly species, providing a unique example of the incomplete specialization of one AChE function after duplication, where, consequently, both AChE1 and AChE2 likely play a similar role in synaptic transmission. In this study, therefore, we investigated the tissue distribution patterns and the molecular and inhibitory properties of two AChEs (i.e., VgAChE1 and VgAChE2) from the Vestalis gracilis damselfly as a model species possessing two AChEs that are equally active. VgAChEs exhibited almost identical catalytic activity and were expressed in the central nervous system (CNS). The most predominant molecular form of both VgAChEs was a disulfide-bridged dimer, which is associated with the cell membrane via a glycosylphosphatidylinositol anchor. In an inhibition assay, however, VgAChE1 and VgAChE2 exhibited different sensitivities to organophosphate and carbamate insecticides depending on the structure of the inhibitors. These findings suggest that both VgAChEs have neuronal functions. In addition, soluble monomeric and cleaved molecular forms were detected in both the CNS and peripheral nervous system tissues by an AChE2-specific antibody, implying that VgAChE2 probably shares both neuronal and non-neuronal physiological functions in V. gracilis. Our results support the notion that both VgAChEs, paralogous of each other, are involved in synaptic transmission, with VgAChE2 being in the early stage of acquiring non-neuronal functions.     

Anti-agrin staining is absent at abandoned synaptic sites of frog neuromuscular junctions

The neuromuscular junction is a plastic structure and is constantly undergoing changes as the nerve terminals that innervate the muscle fiber extend and retract their processes. In vivo observations on developing mouse neuromuscular junctions revealed that prior to the retraction of a nerve terminal the acetylcholine receptors (AChRs) under that nerve terminal disperse. Agrin is a protein released by nerve terminals that binds to synaptic basal lamina and directs the aggregation of AChRs and acetylcholinesterase (AChE) in and on the surface of the myotube. Thus, if the AChRs under a nerve terminal disperse, then the cellular signaling mechanism by which agrin maintains the aggregation of those AChRs must have been disrupted. Two possibilities that could lead to the disruption of the agrin induced aggregation are that agrin is present at the synaptic basal lamina but is unable to direct the aggregation of AChRs, or that agrin has been removed from the synaptic basal lamina. Thus, if agrin were blocked, one would expect to see anti-agrin staining at abandoned synaptic sites; whereas if agrin were removed, anti-agrin staining would be absent at abandoned synaptic sites. We find that anti-agrin staining and α-bungarotoxin staining are absent at abandoned synaptic sites. Further, in vivo observations of retracting nerve terminals confirm that agrin is removed from the synaptic basal lamina within 7 days. Thus, while agrin will remain bound to synaptic basal lamina for months following denervation, it is removed within days following synaptic retraction. © 1996 John Wiley & Sons, Inc.     

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

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

Isolated primary osteocytes express functional gap junctions in vitro

The differentiation of the neuromuscular junction is a multistep process requiring coordinated interactions between nerve terminals and muscle. Although innervation is not needed for muscle production, the formation of nerve-muscle contacts, intramuscular nerve branching, and neuronal survival require reciprocal signals from nerve and muscle to regulate the formation of synapses. Following the production of muscle fibers, clusters of acetylcholine receptors (AChRs) are concentrated in the central regions of the myofibers via a process termed “prepatterning”. The postsynaptic protein MuSK is essential for this process activating possibly its own expression, in addition to the expression of AChR. AChR complexes (aggregated and stabilized by rapsyn) are thus prepatterned independently of neuronal signals in developing myofibers. ACh released by branching motor nerves causes AChR-induced postsynaptic potentials and positively regulates the localization and stabilization of developing synaptic contacts. These “active” contact sites may prevent AChRs clustering in non-contacted regions and counteract the establishment of additional contacts. ACh-induced signals also cause the dispersion of non-synaptic AChR clusters and possibly the removal of excess AChR. A further neuronal factor, agrin, stabilizes the accumulation of AChR at synaptic sites. Agrin released from the branching motor nerve may form a structural link specifically to the ACh-activated endplates, thereby enhancing MuSK kinase activity and AChR accumulation and preventing dispersion of postsynaptic specializations. The successful stabilization of prepatterned AChR clusters by agrin and the generation of singly innervated myofibers appear to require AChR-mediated postsynaptic potentials indicating that the differentiation of the nerve terminal proceeds only after postsynaptic specializations have formed.