Effects of innervation on the distribution of acetylcholine receptors in regenerating skeletal muscles of adult chickens

Cloning and characterization of nicotinic acetylcholine receptor γ-like gene in adult transparent Pristella maxillaris

Nicotinic acetylcholine receptors (nAChRs) play an important role in regulating the development and function of nervous system. The muscle AChR is composed of four homologous glycoprotein subunits with a stoichiometry α₂βγδ in fetal or α₂βεδ in adult. But the mechanism controlling the transition of fetal AChR γ-subunit to adult AChR ε is still unknown. Here a gene annoted AChR γ-like in Pristella maxillaris was first cloned by rapid amplification of cDNA ends (RACE) based on a transcriptome of dorsal fins. The full length of AChR γ-like was 1984 bp and it encoded 518 amino acids from 100 bp to 1653 bp. The multiple alignment analysis showed that AChR γ-like had 98% protein identity to AChR γ-like in Astyanax mexicanus. Then an 11647 bp DNA from 5'-UTR to 3'-UTR was cloned based on gene structure of AChR γ-like in A.mexicanus. Additionally a 2768 bp DNA upstream 5'-UTR was cloned by chromosome walking method. Furthermore, the results from semi-quantitative PCR showed that AChR γ-like was highly expressed in embryo and adult tissues, such as the muscle, eye, heart and intestine. While it showed low expression in the brain and gill. Significantly, the results of in situ hybridization showed strong diffused expression of AChR γ-like in the muscle of 1 dpf (day post-fertilization) embryo. And weak signal was observed in the muscle of 2-4 dpf embryos. All these data indicated that AChR γ-like could be one subunit of AChRs in the muscle and it could be used to study the development of the neuromuscular junction in adult transparent Pristella maxillaris. Thus our work will lay the foundation for using Pristella maxillaris to analyze the in vivo function of the nAChRs in adult vertebrate.

The spatiotemporal relationship among Schwann cells, axons and postsynaptic acetylcholine receptor regions during muscle reinnervation in aged rats

To morphologically define the aging-related features during muscle reinnervation the spatiotemporal relationships among the major components of the neuromuscular junctions (NMJs) were investigated. A total of 64 rats, 30 adults (4 months old) and 34 aged adults (24 months old), were used. Between 1 and 12 weeks after sciatic nerve-crushing injury, cryosections of skeletal muscle were single or double labeled for S100, a marker of Schwann cells (SCs), for protein gene product 9.5, a neuronal marker, and for alpha-bungarotoxin (alpha-BT), a marker of the acetylcholine receptor site (AChR site), and then observed by confocal laser microscopy. The most obvious age changes were noted: (1) the regenerating SCs and axons were delayed in their arrival at the NMJ, (2) the dimensions of terminal SCs and AChR sites displayed a drastic and long-lasting drop (for terminal SCs, during 1-8 weeks; for AChR sites, during 1-12 weeks); (3) the degree of spatial overlap between AChR sites and terminal SCs was markedly low until 8 weeks post-crush; (4) damage and poor formation in the SCs, terminal axons and AChR sites, together with poor process extension from the terminal SC or terminal axon, were pronounced; (5) persistent aberrant changes, such as multiple innervation and terminal axon sprouting, together with poorly formed collateral innervation, nerve bundles, and NMJs, more frequently occurred in the later reinnervation period. Thus, with aging, regeneration is impaired during the period in which regenerating SC strands and axons extend into NMJs and the subsequent establishment of nerve-muscle contact is in progress. A complex set of morphological abnormalities between or among the TSCs, terminal axons, and AChR sites may be important in slowing of regeneration and reinnervation in aged motor endplates.

Neurotrophins regulate agrin-induced postsynaptic differentiation

The precise orchestration of synaptic differentiation is critical for efficient information exchange in the nervous system. The nerve-muscle synapse forms in response to agrin, which is secreted from the motor nerve terminal and induces the clustering of acetylcholine receptors (AChRs) and other elements of the postsynaptic apparatus on the subjacent muscle cell surface. In view of the highly restricted spatial localization and the plasticity of neuromuscular junctions, it seems likely that synapse formation and maintenance are regulated by additional, as-yet-unidentified factors. Here, we tested whether neurotrophins modulate the agrin-induced differentiation of postsynaptic specializations. We show that both brain-derived neurotrophic factor (BDNF) and neurotrophin-4 (NT-4) inhibit agrin-induced AChR clustering on cultured myotubes. Nerve growth factor and NT-3 are without effect. Muscle cells express full-length TrkB, the cognate receptor for BDNF and NT-4. Direct activation of this receptor by anti-TrkB antibodies mimicked the BDNF/NT-4 inhibition of agrin-induced AChR clustering. This BDNF/NT-4 inhibition is likely to be an intrinsic mechanism for regulating AChR clustering, because neutralization of endogenous TrkB ligands resulted in elevated levels of AChR clustering even in the absence of added agrin. Finally, high concentrations of agrin can occlude the BDNF/NT-4 inhibition of AChR clustering. These results indicate that an interplay between agrin and neurotrophins can regulate the formation of postsynaptic specializations. They also suggest a mechanism for the suppression of postsynaptic specializations at nonjunctional regions.

Neural activity affects distribution of glutamate receptors during neuromuscular junction formation in Drosophila embryos

Changes in the distribution and density of transmitter receptors in the postsynaptic cell are required steps for functional synapse formation. We raised antibodies against Drosophila glutamate receptors (DGluR-II) and visualized the distribution of receptors during neuromuscular junction formation in embryos. In wild-type embryos, embryonic development is complete within 22 hr after egg lying (AEL) and neuromuscular junction (NMJ) formation begins at 13 hr AEL. At the time of initial synapse formation, DGluR-IIs appeared as clusters closely associated with some muscle nuclei. Subsequently, these nonjunctional clusters dispersed while DGluR-IIs accumulated at the junctional region. In a paralytic temperature-sensitive mutant, para(ts1), neural activity decreases drastically at restrictive temperatures. When neural activity was blocked throughout synaptogenesis by rearing embryos at a restrictive temperature prior to the beginning of synaptogenesis, 12 hr AEL, the dispersal of extrajunctional clusters was significantly suppressed and no accumulation of receptors at the junction was observed at 22 hr AEL. However, when neural activity was blocked later, by rearing embryos at a restrictive temperature from 13 hr AEL, DGluR-IIs did not accumulate at the NMJ, although extrajunctional clusters dispersed normally. These findings suggest that the neural activity differentially regulates dissipation of receptor clusters in the nonjunctional region and accumulation of receptors at the junctional region.

A specific effect of muscle cells on the distribution of presynaptic proteins in neurites and its absence in a C2 muscle cell variant

The distribution of neurofilament (NF) and synaptic vesicle (SV) proteins in neurites cultured in vitro was visualized with immunocytochemical methods. NF and SV proteins were detected in neurites from both embryonic mouse spinal cord and chick ciliary ganglion neurons. NF proteins generally occupied more proximal, unbranched neurite segments while SV proteins were most often found in highly branched terminal segments. Neurites from mouse spinal cord cells showed a striking segregation of the NF and SV proteins into distinct domains; neurites from chick ciliary ganglion cells exhibited a similar, though less pronounced segregation. In cocultures of neurons and muscle cells, the neurite segments in contact with myotubes more often stained for SV than for NF while the opposite was true for neurites not in contact with myotubes. The preferential association of SV neurites with myotubes was also observed when the myotubes were previously fixed with paraformaldehyde. This association was absent in neurites growing over Chinese hamster ovary cells, suggesting that the effect is specific for muscle cells. Coculture of neurons with variant strains of C2 myotubes that are deficient in AChR (1R-) or proteoglycans (S27) revealed a preferential association of SV neurites with 1R- myotubes but not with S27 myotubes. Thus, proteoglycans on the surface of C2 myotubes may influence the growth and/or differentiation of presynaptic neurons.

Activity-dependent regulation of gene expression in muscle and neuronal cells

In both the central and the peripheral nervous systems, impulse activity regulates the expression of a vast number of genes that code for synaptic proteins, including neuropeptides, enzymes involved in neurotransmitter biosynthesis and degradation, and membrane receptors. In recent years, the mechanisms involved in these regulations became amenable to investigation by the methods of recombinant DNA technology. The first part of this review focuses on the activity-dependent control of nicotinic acetylcholine receptor biosynthesis in vertebrate muscle, a model case for the regulation of synaptic protein biosynthesis at the postsynaptic level. The second part summarizes some examples of neuronal proteins whose biosynthesis is under the control of transsynaptic impulse activity. The first, second, and third intracellular messengers involved in membrane-to-gene signaling are discussed, as are possible posttranscriptional control mechanisms. Finally, models are proposed for a role of neuronal activity in the genesis and stabilization of the synapse.

Denervation alters the size, number, and distribution of clusters of acetylcholine receptor-like molecules on frog cardiac ganglion neurons

Acetylcholine receptor (AChR)-like molecules are found in clusters on the surface of parasympathetic neurons in the frog cardiac ganglion. Electron microscopy of immunoperoxidase-stained tissue reveals that in normally innervated ganglia most of these clusters are located at synaptic sites. Denervation for 2-3 weeks results in a 64% reduction in the total surface area occupied by AChR-like clusters; this change is brought about by the combined effects of a 4-fold decrease in cluster size and a 30% increase in cluster number. Denervation also changes the distribution of AChR-like clusters: clusters, normally restricted to portions of the cell surface, are more widely distributed following denervation. Denervation of amphibian skeletal muscle for a comparable period of time has no effect on the size or the number of synaptic clusters of AChRs. These results suggest that AChRs in nerve and in muscle are regulated differently by innervation.