Ultrastructure of sites of cholinesterase activity on amphibian embryonic muscle cells cultured without nerve

Roles of tyrosine kinases and phosphatases in the formation and dispersal of acetylcholine receptor clusters

The formation of acetylcholine receptor (AChR) clusters at the postsynaptic muscle membrane in response to motor innervation is a key event in the development of the neuromuscular junction. The synaptic AChR clustering process is initiated by motor axon-released agrin, which activates a tyrosine kinase-based signaling pathway to cause AChR aggregation. In cultured muscle cells, AChR clustering is elicited by diverse nonneural signals, and this process is also mediated by tyrosine kinases. Conversely, the formation of new AChR clusters induced by innervation or nonneural stimuli is unfailingly associated with the dispersal of pre-existing AChR clusters, and this process is mediated by tyrosine phosphatases. In this review, we address how local kinase activation leads to global phosphatase action in muscle. More specifically, we discuss the roles of Src kinase and the SH2 domain-containing tyrosine phosphatase Shp-2 in establishing a regenerative mechanism to propagate the AChR cluster dispersing signal extrasynaptically and in defining the boundary of cluster formation subsynaptically.

A role of tyrosine phosphatase in acetylcholine receptor cluster dispersal and formation

Innervation of the skeletal muscle involves local signaling, leading to acetylcholine receptor (AChR) clustering, and global signaling, manifested by the dispersal of preexisting AChR clusters (hot spots). Receptor tyrosine kinase (RTK) activation has been shown to mediate AChR clustering. In this study, the role of tyrosine phosphatase (PTPase) in the dispersal of hot spots was examined. Hot spot dispersal in cultured Xenopus muscle cells was initiated immediately upon the presentation of growth factor-coated beads that induce both AChR cluster formation and dispersal. Whereas the density of AChRs decreased with time, the fine structure of the hot spot remained relatively constant. Although AChR, rapsyn, and phosphotyrosine disappeared, a large part of the original hot spot-associated cytoskeleton remained. This suggests that the dispersal involves the removal of a key linkage between the receptor and its cytoskeletal infrastructure. The rate of hot spot dispersal is inversely related to its distance from the site of synaptic stimulation, implicating the diffusible nature of the signal. PTPase inhibitors, such as pervanadate or phenylarsine oxide, inhibited hot spot dispersal. In addition, they also affected the formation of new clusters in such a way that AChR microclusters extended beyond the boundary set by the clustering stimuli. Furthermore, by introducing a constitutively active PTPase into cultured muscle cells, hot spots were dispersed in a stimulus- independent fashion. This effect of exogenous PTPase was also blocked by pervanadate. These results implicate a role of PTPase in AChR cluster dispersal and formation. In addition to RTK activation, synaptic stimulation may also activate PTPase which acts globally to destabilize preexisting AChR hot spots and locally to facilitate AChR clustering in a spatially discrete manner by countering the action of RTKs.

Potassium inward rectifier and acetylcholine receptor channels in embryonic Xenopus muscle cells in culture

Embryonic muscle cells of the frog Xenopus laevis were isolated and grown in culture and single-channel recordings of potassium inward rectifier and acetylcholine (ACh) receptor currents were obtained from cell-attached membrane patches. Two classes of inward rectifier channels, which differed in conductance, were apparent. With 140 mM potassium chloride in the electrode, one channel class had a conductance of 28.8 +/- 3.4 pS (n = 21), and, much more infrequently, a smaller channel class with a conductance of 8.6 +/- 3.6 pS (n = 7) was recorded. Both channel classes had relatively long mean channel open times, which decreased with membrane hyperpolarization. The probability of finding a patch of membrane with an inward rectifier channel was high (66%) and many membrane patches contained more than one inward rectifier channel. The open state probability (with no applied potential) was high for both inward rectifier channel classes so that 70% of the time there was a channel open. Seventy-three percent of the membrane patches with ACh receptor channels (n = 11) also had at least one inward rectifier channel present when the patch electrode contained 0.1 mu M ACh. Inward rectifier channels were also found at 71% of the sites of high ACh receptor density (n = 14), which were identified with rhodamine-conjugated alpha-bungarotoxin. The results indicate that the density of inward rectifier channels in this embryonic skeletal muscle membrane was relatively high and includes sites of membrane that have synaptic specializations.

Sixth Annual Stuart Reiner Memorial Lecture: embryonic development of nerve and muscle

This article provides a basic scheme of sequential anatomic and some physiologic events occurring during the course of embryonic development of motor neurons and muscles, leading to the establishment of mature nerve-muscle relationships. Motor neurons and muscles begin their development independently and during embryogenesis they become dependent on each other for further development and survival. Aspects of development which occur independently and those requiring mutual interactions are identified. The development of motor neurons is discussed with respect to their production, projection, neuromuscular transmission, myelination, sprouting, survival, and death. The development of muscles is discussed with respect to the origin, differentiation, and muscle fiber types. Discussion on the development of neuromuscular junction includes differentiation of presynaptic nerve terminal, postsynaptic components, and elimination of multiple axons.

Development of acetylcholinesterase induced by basic polypeptide-coated latex beads in cultured Xenopus muscle cells

The formation of acetylcholine receptor (AChR) clusters can be induced by basic polypeptide-coated latex beads in cultured Xenopus muscle cells. Here we investigated the development of acetylcholinesterase (AChE) at the bead-induced AChR clusters. AChE activity began to appear at the clusters after 1 day of bead-muscle coculture and was present at all of the bead-induced clusters within 4-7 days. Electron microscopy revealed that AChE reaction products were discretely localized within the cleft and the membrane invaginations at the bead-muscle contacts. Thus, the beads can mimic the nerve in inducing a local accumulation of both the AChRs and AChE, suggesting that the development of both specializations can be effected by a common stimulus.

Two types of focal accumulations of acetylcholinesterase appear in noninnervated regenerating skeletal muscles of the rat

Muscle fibers in the soleus muscle of the rat, injured by bupivacaine and free autografting, were allowed to regenerate within their old basal laminae. Histochemical and cytochemical analysis of newly synthesized acetylcholinesterase (AChE) revealed that two kinds of focal accumulations of AChE appeared in regenerating myotubes. First, AChE gets concentrated at the sites of the former motor endplates. Accumulation of AChE starts in places where a tight contact between the remnants of the old junctional basal lamina and the budding surface of the myotube engulf the extracellular material. Appearance of these AChE accumulations can be prevented by papain treatment of the soleus muscle before autografting but not by predenervating it for 1 month. Focalization of AChE is probably induced by a component of the junctional basal lamina, possibly a protein, the existence of which is not dependent upon continuous presence of the motor nerve and may be produced by the muscle. This view is corroborated by the fact that an additional kind of AChE accumulation appeared in regenerating muscles in regions remote from the sites where motor endplates were located in the muscles of origin. Although differing in localization, size, and appearance, both kinds of AChE accumulations ultrastructurally resemble the postsynaptic specialization of the motor endplate: they consist of tubelike sarcolemmal invaginations containing AChE. The extrajunctional AChE accumulations seem to arise spontaneously and are usually located more than 750 micron away from the junctional ones as if some local inhibitory mechanism prevents their formation in the immediate vicinity.

Development of postsynaptic-like specializations of the neuromuscular synapse in the absence of motor nerve

It was previously reported that the acetylcholine receptor clusters and acetylcholinesterase appear on embryonic superior oblique muscle cells developing in vivo without motor nerve contacts. The objective of this study was to examine whether some other components of neuromuscular junction also form on muscle cells developing in vivo in the absence of motor neurons. In the present study, postsynaptic specializations such as junctional folds, postsynaptic density and basal lamina were studied in normal and aneural muscles. The superior oblique muscle of duck embryos was made aneural by permanent destruction of trochlear motor neurons by cauterizing midbrain on embryonic day 7; 3 days before the motor neurons normally project their axons into the muscle. Normal and aneural muscles from embryonic days 10 to 25 were processed for electron microscopy. The results indicate that morphological specializations such as junction-like folds, postsynaptic-like density, and basal lamina also develop in the absence of motor neuron contacts. Whether the differentiation of specialized synaptic basal lamina is dependent on the presence of motor neurons was examined by utilizing a monoclonal antibody against heparan sulfate proteoglycan. Immunohistochemical studies indicate that specialized synaptic basal lamina differentiates in the absence of motor neurons. Thus, the mechanism of development of postsynaptic components of neuromuscular junction in this muscle is not dependent on motor neuron contacts. These results also suggest that the postsynaptic cell plays a more active role in synapse formation than previously realized. The results are discussed in relation to the control of synapse numbers by the postsynaptic cell.

Molecular forms of acetylcholinesterase in Xenopus muscle

Xenopus adult muscle, whole Xenopus embryos, and cultured embryonic myocytes together contain five acetylcholinesterase forms which can be resolved by sucrose density gradient centrifugation. These are identified as the collagenase-sensitive asymmetric forms A12 and A8, and the globular forms G4, G2, and G1. Asymmetric forms rise in whole embryos during the period of neuromuscular synapse formation, but their rise is not prevented by tricaine methanesulfonate, which abolishes motor activity. Aneural myocyte cultures synthesize primarily asymmetric acetylcholinesterase, much of which is extracellular. Prior nerve contact is not required for its expression. The proportion of asymmetric forms is neither decreased by tetrodotoxin, nor enhanced by veratridine and aconitine. We conclude that muscle activity does not modulate the expression of asymmetric acetylcholinesterase in Xenopus.

The location of neuromuscular junctions on regenerating adult mouse muscle in culture

The location of neuromuscular junctions which form in vitro between regenerating adult mouse muscle fibres and sections of embryonic mouse spinal cord was examined. The position of the original motor end-plates on the explanted muscle fibres was determined by using either rhodamine-labelled alpha-bungarotoxin (R alpha BT) binding to the acetylcholine receptors, or by stains to demonstrate acetylcholinesterase (AChE) also located at the end-plate. In this culture system, the explanted muscle fibres degenerate and regenerate to form new myotubes which develop cross-striations and contractions. The location of the newly-formed neuromuscular junctions in these mature cultures was then demonstrated using R alpha BT-binding to acetylcholine receptors, silver impregnation and cholinesterase techniques. Less than half the new neuromuscular junctions were at the original end-plate areas indicating that, at least in this system, junctions can form at sites other than those of the original end-plate.

Appearance of high-molecular-weight acetylcholinesterase in aneural muscle developing in vivo

Acetylcholinesterase was studied in the superior oblique muscle of the duck embryo during the course of in vivo development. Normally developing, paralyzed, and uninnervated muscles were studied using velocity sedimentation for separation of various forms and biochemical determination of enzyme activity, and light and electron microscopy for histochemical and cytochemical localization of enzyme. Results indicate that neither muscle activity nor contact by the motor neurons is essential for the appearance of high-molecular-weight form of acetylcholinesterase on muscle cells developing in vivo. Acetylcholinesterase activity per muscle was considerably lower in the paralyzed and aneural muscles than the normal muscle. The absolute loss of acetylcholinesterase parallels loss of muscle protein in paralyzed and aneural muscles and may be secondary. Paralysis or absence of innervation had no significant effect on the specific activity of acetylcholinesterase.

Clonal myoblasts and myotubes show differences in lectin-binding patterns

To determine changes in distribution or mobility of cell-surface glycoconjugates during myogenesis the binding of fluorescein-conjugated plant lectins to myoblasts and myotubes of the L6 rat skeletal muscle cell line has been studied. Binding has been carried out at 4 degrees C on either live or glutaraldehyde-fixed cells. Fluorescein conjugates of soybean agglutinin (Fl-SBA), wheat germ agglutinin (Fl-WGA), concanavalin A (Fl-conA) and Lens culinaris agglutinin (Fl-LCA) produced predominantly uniform fluorescence on both live and fixed myoblasts. On fixed myotubes, Fl-LCA, Fl-conA and Fl-SBA again produced predominantly uniform fluorescence, whereas Fl-WGA showed a pattern of diffuse, irregular spots in addition to uniform fluorescence. Fl-conA, Fl-LCA and Fl-WGA binding to live myotubes resulted in patterns quite similar to those on fixed myotubes; the only differences being the presence of weak patterns of diffuse spots with Fl-LCA and Fl-conA and an enhanced pattern of diffuse spots with Fl-WGA. Fl-SBA, however, showed a unique pattern on live myotubes which consisted of discrete, round spots and minimal uniform fluorescence. With shorter labeling times, Fl-SBA produced relatively more prominent uniform fluorescence on live myotubes. It appears, therefore, that the native distribution of SBA, conA and LCA-binding sites is similar and predominantly random on L6 myoblasts and myotubes, whereas some WGA-binding sites may be aggregated on myotubes. The results also suggest that SBA-binding sites readily cluster at 4 degrees C on myotubes but not myoblasts, whereas the other lectin sites undergo little or no redistribution on either cell type. Thus the mobility of SBA-binding sites may increase with differentiation.

Cholinesterase localization at sites of nerve contact on embryonic amphibian muscle cells in culture

Cholinesterase (ChE), detected histochemically, was found to be localized at many sites of nerve-muscle contact in cultures of spinal cord and muscle cells derived from Xenopus laevis embryos. Such contacts were often characterized by a corresponding localization of acetylcholine receptors and by synaptic ultrastructure, including aggregates of clear vesicles in the nerve fibre and an 80-100 nm wide intercellular cleft. The ChE reaction product was localized in the cleft. When cultures were grown in the presence of curare many of the nerve-contacted muscle cells still exhibited ChE at the sites of contact. It is concluded that ChE accumulates at synaptic contacts in these cultures even in the absence of muscle action potentials and contraction.

Association of the synaptic form of acetylcholinesterase with extracellular matrix in cultured mouse muscle cells

Myotubes of a mouse muscle-cell line (C2) synthesize in culture a 16S form of acetylcholinesterase that is normally found only in regions of adult mouse muscle that contain endplates. The 16S enzyme in C2 cell extracts has the properties expected of acetylcholinesterase forms that have a collagen-like tail. In intact cells, the active site of the 16S acetylcholinesterase is protected by a membrane-impermeable inhibitor, and this form of the enzyme can be removed by treatment of the cells with collagenase. Thus the enzyme is extracellular. Its extraction by high ionic strength solutions lacking detergent suggests that the 16S form is associated with the extracellular matrix by ionic interactions. Histochemical staining shows focal patches of acetylcholinesterase activity on the cell surface. Collagenase treatment, which removes only the 16S form, abolishes this staining pattern, indicating that the patches consist of the 16S enzyme. We conclude that the 16S enzyme in C2 myotubes occurs in focal patches on the cell surface, where it is associated with the extracellular matrix.

Ubiquitous presence of the tailed, asymmetric forms of acetylcholinesterase in the peripheral and central nervous systems of the frog (Rana temporaria)

Five molecular forms of acetylcholinesterase can be solubilized from the peripheral and central nervous systems of the frog: they will be referred to as the 3.6, 6, 10.5, 14 and 18 S forms. They seem to be analogous to the forms present in endplate-rich and endplate-free regions of frog skeletal muscle. In particular the 18 and 14 S forms represent the collagen-tailed forms of frog acetylcholinesterase. These heavy forms are found in all peripheral and central tissues examined, including whole brain or regions of brain: cerebellum, telencephalon, optic tectum, spinal cord, spinal ventral and dorsal roots and sciatic nerve, as well as in glial or Schwann cellrich tissues devoid of neuronal elements, such as the filum terminale or the severed stump of the nerve, several weeks after section. The 18 S form may represent up to 30% of total acetylcholinesterase activity. It thus seems that the 14 S and 18 S forms are very widely distributed throughout most neuronal and non-neuronal tissues in amphibians.