Mechanisms Regulating Neuromuscular Junction Development and Function and Causes of Muscle Wasting

The neuromuscular junction is the chemical synapse between motor neurons and skeletal muscle fibers. It is designed to reliably convert the action potential from the presynaptic motor neuron into the contraction of the postsynaptic muscle fiber. Diseases that affect the neuromuscular junction may cause failure of this conversion and result in loss of ambulation and respiration. The loss of motor input also causes muscle wasting as muscle mass is constantly adapted to contractile needs by the balancing of protein synthesis and protein degradation. Finally, neuromuscular activity and muscle mass have a major impact on metabolic properties of the organisms. This review discusses the mechanisms involved in the development and maintenance of the neuromuscular junction, the consequences of and the mechanisms involved in its dysfunction, and its role in maintaining muscle mass during aging. As life expectancy is increasing, loss of muscle mass during aging, called sarcopenia, has emerged as a field of high medical need. Interestingly, aging is also accompanied by structural changes at the neuromuscular junction, suggesting that the mechanisms involved in neuromuscular junction maintenance might be disturbed during aging. In addition, there is now evidence that behavioral paradigms and signaling pathways that are involved in longevity also affect neuromuscular junction stability and sarcopenia.

Acetylcholine receptor (AChR) clustering is regulated both by glycogen synthase kinase 3β (GSK3β)-dependent phosphorylation and the level of CLIP-associated protein 2 (CLASP2) mediating the capture of microtubule plus-ends

The postsynaptic apparatus of the neuromuscular junction (NMJ) traps and anchors acetylcholine receptors (AChRs) at high density at the synapse. We have previously shown that microtubule (MT) capture by CLASP2, a MT plus-end-tracking protein (+TIP), increases the size and receptor density of AChR clusters at the NMJ through the delivery of AChRs and that this is regulated by a pathway involving neuronal agrin and several postsynaptic kinases, including GSK3. Phosphorylation by GSK3 has been shown to cause CLASP2 dissociation from MT ends, and nine potential phosphorylation sites for GSK3 have been mapped on CLASP2. How CLASP2 phosphorylation regulates MT capture at the NMJ and how this controls the size of AChR clusters are not yet understood. To examine this, we used myotubes cultured on agrin patches that induce AChR clustering in a two-dimensional manner. We show that expression of a CLASP2 mutant, in which the nine GSK3 target serines are mutated to alanine (CLASP2-9XS/9XA) and are resistant to GSK3β-dependent phosphorylation, promotes MT capture at clusters and increases AChR cluster size, compared with myotubes that express similar levels of wild type CLASP2 or that are noninfected. Conversely, myotubes expressing a phosphomimetic form of CLASP2 (CLASP2-8XS/D) show enrichment of immobile mutant CLASP2 in clusters, but MT capture and AChR cluster size are reduced. Taken together, our data suggest that both GSK3β-dependent phosphorylation and the level of CLASP2 play a role in the maintenance of AChR cluster size through the regulated capture and release of MT plus-ends.

Accumulation of Nav1 mRNAs at differentiating postsynaptic sites in rat soleus muscles

Acetylcholine receptors (AChRs) and voltage-gated sodium channels (Na(V)1s) accumulate at different times in the development of the murine neuromuscular junction (NMJ). We used in situ hybridization to study the relationship of Na(V)1 mRNA accumulation to this difference. mRNAs encoding both muscle Na(V)1 isoforms, Na(v)1.4 and Na(v)1.5, were first concentrated at NMJs at birth, when the proteins start to accumulate. Within 4 weeks, Na(v)1.4 mRNA increased 5-fold at the NMJ while Na(v)1.5 mRNA became undetectable. Na(V)1 mRNA accumulation occurred even if the nerve was cut at birth. Like AChR mRNA, Na(V)1 mRNA accumulated at denervated synaptic sites on regenerating muscles and in response to ectopically expressed neural agrin. Clustering of Na(V)1 at the NMJ follows that of its mRNA while AChR clustering precedes its mRNA clustering by several days. This suggests that factors other than local mRNA upregulation determine the timing of clustering of these two important postsynaptic ion channels.

Synapses form in skeletal muscles lacking neuregulin receptors

The formation of the neuromuscular junction (NMJ) is directed by reciprocal interactions between motor neurons and muscle fibers. Neuregulin (NRG) and Agrin from motor nerve terminals are both implicated. Here, we demonstrate that NMJs can form in the absence of the NRG receptors ErbB2 and ErbB4 in mouse muscle. Postsynaptic differentiation is, however, induced by Agrin. We therefore conclude that NRG signaling to muscle is not required for NMJ formation. The effects of NRG signaling to muscle may be mediated indirectly through Schwann cells.

Induction of multiple signaling loops by MuSK during neuromuscular synapse formation

At the neuromuscular junction, two motor neuron-derived signals have been implicated in the regulation of synaptogenesis. Neuregulin-1 is thought to induce transcription of acetylcholine receptor (AChR) genes in subsynaptic muscle nuclei by activating ErbB receptors. Neural agrin aggregates AChRs by activating the receptor tyrosine kinase MuSK. Here, we show that these two signals act sequentially. Agrin, by activating MuSK, induces the synthesis and aggregation of both MuSK and ErbB receptors. ErbB acts downstream of MuSK in synapse formation. In this way, MuSK activation leads to the establishment of a neuregulin-1-dependent signaling complex that maintains MuSK, ErbB, and AChR expression at the synapse of electrically active muscle fibers.

Electrical activity and postsynapse formation in adult muscle: gamma-AChRs are not required

Skeletal muscle fibers will not accept hyperinnervation by foreign motor axons unless they are paralyzed, suggesting that paralysis makes them receptive to innervation, e.g., by upregulating extrasynaptic expression of gamma-AChRs and/or of the agrin receptor MuSK. To examine the involvement of these parameters in paralysis-mediated synapse induction, ectopic expression of agrin, a factor from motor neurons controlling neuromuscular synapse formation, was made dependent on the administration of doxycycline in innervated adult muscle fibers. In response to doxycycline-induced agrin secretion, adult fibers did form ectopic postsynaptic specializations, even when they were electrically active, lacked fetal AChRs, and expressed normal low levels of MuSK. These data demonstrate that paralysis and changes associated with it are not required for agrin-induced postsynapse formation. They suggest that paralyzed muscle induces synapse formation via the release of factors that make motor neurites contact muscle fibers and secrete agrin.

Gene transfer into individual muscle fibers and conditional gene expression in living animals

Pressure injection of DNA directly into individual fibers of surgically exposed soleus muscle leads to efficient and reliable expression of the transgene. Conditionally regulated gene expression in a single muscle fiber was analyzed in vivo by co-injecting a tetracycline-regulated lacZ reporter construct and a transactivator (rtTA) expression vector. The tetracycline-responsive element revealed significant basal transcriptional activity that was further increased by rtTA even in the absence of the effector doxycycline (dox). The high basal activity of the simple two-component system precludes tight gene regulation in muscle. Concomitant expression of the silencer tTS(Kid), however, reduced the basal activity to low or undetectable levels. This allowed the specific activation of the tetracycline-responsive element by the application of dox. Direct gene transfer can thus be employed to express transgenic proteins in distinct muscle fibers at spatially defined regions and to regulate gene expression conditionally.

Constitutively active MuSK is clustered in the absence of agrin and induces ectopic postsynaptic-like membranes in skeletal muscle fibers

In skeletal muscle fibers, neural agrin can direct the accumulation of acetylcholine receptors (AChR) and transcription of AChR subunit genes from the subsynaptic nuclei. Although the receptor tyrosine kinase MuSK is required for AChR clustering, it is less clear whether MuSK regulates gene transcription. To elucidate the role of MuSK in these processes, we constructed a constitutively active MuSK receptor, MuSKneuTMuSK, taking advantage of the spontaneous homodimerization of the transmembrane domain of neuT, an oncogenic variant of the neu/erbB2 receptor. In the extrasynaptic region of innervated muscle fibers, MuSKneuTMuSK formed highly concentrated aggregates that colocalized with AChR clusters. Associated with MuSK-induced AChR clusters was a normal complement of synaptic proteins. Moreover, transcription of the AChR-epsilon subunit gene was increased, albeit via an indirect mechanism by MuSK-induced aggregation of erbB receptors and neuregulin. Although neural agrin was not required, the activity of MuSKneuTMuSK was nevertheless potentiated by ectopic expression of a muscle agrin isoform inactive in AChR clustering. To define the role of the kinase domain in the formation of a postsynaptic-like membrane, a second fusion receptor, neuneuTMuSK, which included the MuSK kinase but not the MuSK extracellular domain, was expressed. Significantly, neuneuTMuSK induced AChR clusters that colocalized with aggregates of endogenous MuSK. Taken together, it was concluded that the MuSK kinase domain is sufficient to initiate the recruitment of additional MuSK receptors, which then develop into highly concentrated aggregates by means of a positive feedback loop to induce a postsynaptic membrane in the absence of neural agrin.

A minigene of neural agrin encoding the laminin-binding and acetylcholine receptor-aggregating domains is sufficient to induce postsynaptic differentiation in muscle fibres

The extracellular matrix molecule agrin is both necessary and sufficient for inducing the formation of postsynaptic specializations at the neuromuscular junction (NMJ). At the mature NMJ, agrin is stably incorporated in synaptic basal lamina. The postsynapse-inducing activity of chick agrin, as assayed by its capability of causing aggregation of acetylcholine receptors (AChRs) on cultured muscle cells, maps to a 21 kDa, C-terminal domain. Binding of chick agrin to muscle basal lamina is mediated by the laminins and maps to a 25 kDa, N-terminal fragment of agrin. Here we show that an expression construct encoding a 'mini'-agrin, in which the laminin-binding fragment was fused to the AChR-clustering domain, is sufficient to induce postsynaptic differentiation in vivo when injected into non-synaptic sites of rat soleus muscle. As shown for ectopic postsynaptic differentiation induced by full-length neural agrin, myonuclei underneath the ectopic sites expressed the gene for the AChR epsilon-subunit. Altogether, our data show that a 'mini'-agrin construct encoding only a small fraction of the entire agrin protein is sufficient to induce postsynapse-like structures that are reminiscent of those induced by full-length neural agrin or innervation by motor neurons.

Agrin can mediate acetylcholine receptor gene expression in muscle by aggregation of muscle-derived neuregulins

The neural isoforms of agrin can stimulate transcription of the acetylcholine receptor (AChR) epsilon subunit gene in electrically active muscle fibers, as does the motor neuron upon the formation of a neuromuscular junction. It is not clear, however, whether this induction involves neuregulins (NRGs), which stimulate AChR subunit gene transcription in vitro by activating ErbB receptors. In this study, we show that agrin- induced induction of AChR epsilon subunit gene transcription is inhibited in cultured myotubes overexpressing an inactive mutant of the ErbB2 receptor, demonstrating involvement of the NRG/ErbB pathway in agrin- induced AChR expression. Furthermore, salt extracts from the surface of cultured myotubes induce tyrosine phosphorylation of ErbB2 receptors, indicating that muscle cells express biological NRG-like activity on their surface. We further demonstrate by RT-PCR analysis that muscle NRGs have Ig-like domains required for their immobilization at heparan sulfate proteoglycans (HSPGs) of the extracellular matrix. In extrasynaptic regions of innervated muscle fibers in vivo, ectopically expressed neural agrin induces the colocalized accumulation of AChRs, muscle-derived NRGs, and HSPGs. By using overlay and radioligand-binding assays we show that the Ig domain of NRGs bind to the HSPGs agrin and perlecan. These findings show that neural agrin can induce AChR subunit gene transcription by aggregating muscle HSPGs on the muscle fiber surface that then serve as a local sink for focal binding of muscle-derived NRGs to regulate AChR gene expression at the neuromuscular junction.

Neural agrin induces ectopic postsynaptic specializations in innervated muscle fibers

Neural agrin, in the absence of a nerve terminal, can induce the activity-resistant expression of acetylcholine receptor (AChR) subunit genes and the clustering of synapse-specific adult-type AChR channels in nonsynaptic regions of adult skeletal muscle fibers. Here we show that, when expression plasmids for neural agrin are injected into the extrasynaptic region of innervated muscle fibers, the following components of the postsynaptic apparatus are aggregated and colocalized with ectopic agrin-induced AChR clusters: laminin-beta2, MuSK, phosphotyrosine-containing proteins, beta-dystroglycan, utrophin, and rapsyn. These components have been implicated to play a role in the differentiation of neuromuscular junctions. Furthermore, ErbB2 and ErbB3, which are thought to be involved in the regulation of neurally induced AChR subunit gene expression, were colocalized with agrin-induced AChR aggregates at ectopic nerve-free sites. The postsynaptic muscle membrane also contained a high concentration of voltage-gated Na+ channels as well as deep, basal lamina-containing invaginations comparable to the secondary synaptic folds of normal endplates. The ability to induce AChR aggregation in vivo was not observed in experiments with a muscle-specific agrin isoform. Thus, a motor neuron-specific agrin isoform is sufficient to induce a full ectopic postsynaptic apparatus in muscle fibers kept electrically active at their original endplate sites.

Rapid drug application resolves two types of nicotinic receptors on rat sympathetic ganglion cells

The properties of nicotinic acetylcholine receptors (AChRs) on cultured rat superior cervical ganglion (SCG) neurons were analysed. AChR agonists [1,1-dimethyl-4-phenylpiperazinium iodide (DMPP), cytisine] were applied to whole cells within 70ms. The desensitization rate of whole-cell currents during constant application of DMPP varied between neurons. The time course of desensitization was fitted by double exponentials with time constants kfast, of between 0.35 and 0.55s, and kslow, of 3-5s. By exchanging intracellular chloride for caesium methanesulphonate, the possibility of interference by a calcium-activated chloride current was excluded. In cells that exhibited a slowly desensitizing current during the application 20 microM DMPP, equimolar cytisine induced a larger peak current compared to the response to DMPP, while in cells with rapidly desensitizing DMPP-induced currents the response to equimolar cytisine was smaller. The differences in desensitization rates and agonist potencies are due to different functional properties of AChR subtypes, as indicated by currents recorded from outside-out patches upon rapid agonist application and removal (2ms each). The results indicate the presence of two distinct AChR subtypes on SCG neurons: one with a fast and one with a slow activation/desensitization rate, but both with similar single-channel conductances. Slow activation/desensitization was found to be associated with a high potency of cytisine/low potency of DMPP. For AChRs with rapid activation/desensitization kinetics the agonist potencies were reversed.

Induction by agrin of ectopic and functional postsynaptic-like membrane in innervated muscle

Two factors secreted from the nerve terminal, agrin and neuregulin, have been postulated to induce localization of the acetylcholine receptors (AChRs) to the subsynaptic membrane in skeletal muscle fibers. The principal function ascribed to neuregulin is induction of AChR subunit gene expression and to agrin is the aggregation of AChRs. Here we report that when myoblasts engineered to secrete an agrin fragment were placed into the nerve-free region of denervated rodent muscle, the host muscle fibers expressed AChR epsilon-subunit gene transcripts, characteristic of the neuromuscular synapse in adult muscle. Transcripts were colocalized with agrin deposits and AChR clusters that were resistant to electrical muscle activity. More directly, single innervated muscle fibers injected intracellularly with agrin expression plasmids in their extrasynaptic region developed a functional ectopic postsynaptic membrane with clusters of adult-type AChR channels and acetylcholinesterase and accumulation of myonuclei. The results demonstrate that agrin is the principal neural signal that induces the formation of the subsynaptic apparatus in the muscle fiber and controls locally, either indirectly or directly, the transcription of AChR subunit genes and the aggregation of AChRs.

Acetylcholine receptor epsilon-subunit deletion causes muscle weakness and atrophy in juvenile and adult mice

In mammalian muscle a postnatal switch in functional properties of neuromuscular transmission occurs when miniature end plate currents become shorter and the conductance and Ca2+ permeability of end plate channels increases. These changes are due to replacement during early neonatal development of the gamma-subunit of the fetal acetylcholine receptor (AChR) by the epsilon-subunit. The long-term functional consequences of this switch for neuromuscular transmission and motor behavior of the animal remained elusive. We report that deletion of the epsilon-subunit gene caused in homozygous mutant mice the persistence of gamma-subunit gene expression in juvenile and adult animals. Neuromuscular transmission in these animals is based on fetal type AChRs present in the end plate at reduced density. Impaired neuromuscular transmission, progressive muscle weakness, and atrophy caused premature death 2 to 3 months after birth. The results demonstrate that postnatal incorporation into the end plate of epsilon-subunit containing AChRs is essential for normal development of skeletal muscle.

Substrate-bound agrin induces expression of acetylcholine receptor epsilon-subunit gene in cultured mammalian muscle cells

Expression of the epsilon-subunit gene of the acetylcholine receptor (AChR) by myonuclei located at the neuromuscular junction is precisely regulated during development. A key role in this regulation is played by the synaptic portion of the basal lamina, a structure that is also known to contain agrin, a component responsible for the formation of postsynaptic specializations. We tested whether agrin has a function in synaptic AChR gene expression. Synaptic basal lamina from native adult muscle and recombinant agrin bound to various substrates induced in cultured rat myotubes AChR clusters that were colocalized with epsilon-subunit mRNA. Estimation of transcript levels by Northern hybridization analysis of total RNA showed a significant increase when myotubes were grown on substrate impregnated with agrin, but were unchanged when agrin was applied in the medium. The effect was independent of the receptor aggregating activity of the agrin isoform used, and agrin acted, at least in part, at the level of epsilon-subunit gene transcription. These findings are consistent with a role of agrin in the regulation of AChR subunit gene expression at the neuromuscular junction, which would depend on its binding to the synaptic basal lamina.

Overexpression of the neural growth-associated protein GAP-43 induces nerve sprouting in the adult nervous system of transgenic mice

Regulation of neurite outgrowth and structural plasticity may involve the expression of intrinsic determinants controlling growth competence. We have tested this concept by targeting constitutive expression of the growth-associated protein GAP-43 to the neurons of adult transgenic mice. Such mice showed striking spontaneous nerve sprouting at the neuromuscular junction and in the terminal field of hippocampal mossy fibers. In control mice, these nerve fibers did not express GAP-43, and did not sprout spontaneously. Lesion-induced nerve sprouting and terminal arborization during reinnervation were greatly potentiated in GAP-43-overexpressing mice. A mutant GAP-43 that cannot be phosphorylated by PKC had reduced sprout-promoting activity. The results establish GAP-43 as an intrinsic presynaptic determinant for neurite outgrowth and plasticity.

Local neurotrophic repression of gene transcripts encoding fetal AChRs at rat neuromuscular synapses

The spatio-temporal expression patterns of mRNA transcripts coding for acetylcholine receptor (AChR) subunits and myogenic factors were measured in denervated rat soleus muscle and in soleus muscle chronically paralyzed for up to 12 d by conduction block of the sciatic nerve by tetrodotoxin (TTX). In denervated muscle the AChR alpha-, beta-, gamma-, and delta-subunit mRNAs were elevated with highest expression levels in the former synaptic and the perisynaptic region and with lower levels in the extrasynaptic fiber segments. In muscle paralyzed by nerve conduction block the alpha-, beta-, gamma-, and delta-subunit mRNA levels increased only in extrasynaptic fiber segments. Surprisingly, in the synaptic region the gamma-subunit mRNA that specifies the fetal-type AChR, and alpha-, beta-, delta-subunit mRNAs were not elevated. The expression of the gene encoding the epsilon-subunit, which specifies the adult-type AChR, was always restricted to synaptic nuclei. The mRNA for the regulatory factor myogenin showed after denervation similar changes as the subunit transcripts of the fetal AChR. When the muscle was paralyzed by nerve conduction block the increase of myogenin transcripts was also less pronounced in synaptic regions compared to extrasynaptic fiber segments. The results suggest that in normal soleus muscle a neurotrophic signal from the nerve locally down-regulates the expression of fetal-type AChR channel in the synaptic and perisynaptic muscle membrane by inhibiting the expression of the gamma-subunit gene and that inhibition of the myogenin gene expression may contribute to this down-regulation.

Involvement of extracellular matrix in acetylcholine receptor epsilon-subunit gene expression at the rat neuromuscular junction

During neuromuscular development, the nerve induces the expression of acetylcholine receptor (AChR) epsilon-subunit gene selectively in synaptic myonuclei. Here we show that even after elimination of neural effects by denervation, synaptic expression of epsilon-subunit transcripts is maintained for > 4 months. In contrast, after damage of the extracellular matrix (ECM) by treatment with proteolytic enzymes, epsilon-subunit mRNA is significantly reduced within less than 1 day, indicating a role of ECM in the regulation of AChR subunit transcripts at the synapse.

Nerve-dependent induction of AChR epsilon-subunit gene expression in muscle is independent of state of differentiation

To determine if the expression of the epsilon-subunit of the acetylcholine receptor by the subsynaptic nuclei in skeletal muscle is dependent on the state of differentiation of the muscle, we have compared the spatiotemporal distribution of epsilon-subunit transcripts during synapse formation in fetal and adult muscle. Both during "ontogenic" synaptogenesis in the fetus and during "ectopic" synaptogenesis in the adult animal the motor nerve induced focally the expression of the epsilon-subunit mRNA in subsynaptic nuclei. The temporal expression patterns at both types of developing synapses were similar. The results support the view that in muscle developing in vivo epsilon-subunit gene transcription and its stabilization in subsynaptic nuclei is exclusively controlled by the motor neuron, independently of the developmental state of the muscle nuclei. Thus, both nerve and muscle remain plastic in their respective abilities to induce and express the synapse-specific combination of AChR subunit genes.

Calcium influx and protein phosphorylation mediate the metabolic stabilization of synaptic acetylcholine receptors in muscle

During neuromuscular synapse development, the degradation rate of ACh receptors (AChRs) accumulated in the synaptic portion of the muscle membrane is drastically reduced under neural control, their half-life t1/2 increasing from 1 d to about 12 d. Recent evidence suggests that the metabolic stability of synaptic AChRs is mediated by the muscle activity induced by the nerve. We have now investigated the pathway linking muscle activity and metabolic stabilization of synaptic AChRs in organ cultured rat muscle. Soleus and diaphragm muscles were denervated for 14-40 d, a procedure leading to the destabilization of synaptic AChRs, and conditions required to restabilize synaptic AChRs in the denervated muscle were analyzed. The activity-dependent stabilization of synaptic AChRs in chronically denervated endplates required calcium entry through dihydropyridine-sensitive Ca2+ channels activated by high-frequency stimulation for approximately 6 hr and was specific for synaptic AChRs. As in vivo, extrasynaptic AChRs were not stabilized, and their t1/2 remained 1 d. The stabilization process was not dependent on de novo protein synthesis, and it could also be brought about by elevated cAMP levels. Furthermore, it required shorter stimulation periods in the presence of the phosphatase inhibitors okadaic acid and calyculin A, whereas blockade of protein kinases with high doses of staurosporine blocked the stabilization. Activity-dependent, dihydropyridine-sensitive as well as cAMP-dependent phosphorylation of myosin light chain was observed. These findings are consistent with the notion that muscle activity initiates AChR stabilization via the activation of calcium-dependent protein phosphorylation reactions.

Normal development of nerve-muscle synapses in mice lacking the prion protein gene

The expression of acetylcholine receptors (AChR) at neuromuscular synapses in skeletal muscle is regulated by innervation. Recent evidence suggests that the neurotrophic factors involved in the expression of AChR subunit genes may be related to the prion protein (PrPc), a protein of unknown function expressed primarily in neurons which, in its modified form, PrPSc, is thought to have a role in the pathogenesis of transmissible spongiform encephalopathies. We have tested for an involvement of PrPc in the neurotrophic regulation of synaptic AChRs in muscle by comparing the contents of AChR epsilon- and gamma-subunit mRNAs by Northern blot analysis and by in situ hybridization in mice with normal and with deleted PrP genes. At the protein level, AChR expression was assessed electrophysiologically. No difference was found between muscles from the two types of animals, suggesting that the neural regulation of AChR subunit expression in skeletal muscle can be mediated by factors that are not derived from the PrP gene.

Synapse-specific expression of acetylcholine receptor genes and their products at original synaptic sites in rat soleus muscle fibres regenerating in the absence of innervation

To test the hypothesis that synaptic basal lamina can induce synapse-specific expression of acetylcholine receptor (AChR) genes, we examined the levels mRNA for the alpha- and epsilon-subunits of the AChR in regenerating rat soleus muscles up to 17 days of regeneration. Following destruction of all muscle fibres and their nuclei by exposure to venom of the Australian tiger snake, new fibres regenerated within the original basal lamina sheaths. Northern blots showed that original mRNA was lost during degeneration. Early in regeneration, both alpha- and epsilon-subunit mRNAs were present throughout the muscle fibres but in situ hybridization showed them to be concentrated primarily at original synaptic sites, even when the nerve was absent during regeneration. A similar concentration was seen in denervated regenerating muscles kept active by electrical stimulation and in muscles frozen 41–44 hours after venom injection to destroy all cells in the synaptic region of the muscle. Acetylcholine-gated ion channels with properties similar to those at normal neuromuscular junctions were concentrated at original synaptic sites on denervated stimulated muscles. Taken together, these findings provide strong evidence that factors that induce the synapse-specific expression of AChR genes are stably bound to synaptic basal lamina.

The MyoD family of myogenic factors is regulated by electrical activity: isolation and characterization of a mouse Myf-5 cDNA

A full-length cDNA coding for a homolog of the human Myf-5 was isolated from a BC3H-1 mouse library and characterized. The clone codes for a protein of 255 amino acids that is 89%, 88% and 68% identical to the human, bovine and Xenopus myf-5, respectively. The mouse Myf-5 cDNA (mmyf-5), as well as sequences coding for MyoD, myogenin and Mrf-4, were used to probe Northern blots to analyze the effects of innervation on the expression of the MyoD family of myogenic factors. Mouse myf-5, MyoD and myogenin mRNAs levels were found to decline in hind limb muscles of mice between embryonic day 15 (E15) and the first postnatal week, a period that coincides with innervation. In contrast, Mrf-4 transcripts increase during this period and reach steady-state levels by 1-week after birth. To distinguish if the changes in myogenic factor expression are due to a developmental program or to innervation, mRNA levels were analyzed at different times after muscle denervation. Mmyf-5 transcripts begin to accumulate 2 days postdenervation; after 1 week levels are 7-fold higher than in innervated muscle. Mrf-4, MyoD and myogenin transcripts begin to accumulate as soon as 8h after denervation, and attain levels that are 8-, 15- and 40-fold higher than found in innervated skeletal muscle, respectively. The accumulation of these three mRNAs precedes the increase of nicotinic acetylcholine receptor alpha subunit transcripts, a gene that is transcriptionally regulated by MyoD-related factors in vitro. Using extracellular electrodes to directly stimulate in situ the soleus muscle of rats, we found that 'electrical activity' per se, in absence of the nerve, represses the increases of myogenic factor mRNAs associated with denervation.

How the Motoneuron Regulates Acetylcholine Receptor Channel Function in Muscle

Distribution and ion-conduction properties of acetylcholine receptors (AChR) in muscle change under neural control. The switch of AChR types at the synapse is regulated by neurotrophic signals. Muscle activity may support sufficient numbers of AChRs for synaptic transmission and downregulate them in nonsynaptic fiber segments.

Neural factors regulate AChR subunit mRNAs at rat neuromuscular synapses

To elucidate the nature of signals that control the level and spatial distribution of mRNAs encoding acetylcholine receptor (AChR), alpha-, beta-, gamma-, delta- and epsilon-subunits in muscle fibers chronic paralysis was induced in rat leg muscles either by surgical denervation or by different neurotoxins that cause disuse of the muscle or selectively block neuromuscular transmission pre- or postsynaptically and cause an increase of AChRs in muscle membrane. After paralysis, the levels and the spatial distributions of the different subunit-specific mRNAs change discoordinately and seem to follow one of three different patterns depending on the subunit mRNA examined. The level of epsilon-subunit mRNA and its accumulation at the end-plate are largely independent on the presence of the nerve or electrical muscle activity. In contrast, the gamma-subunit mRNA level is tightly coupled to innervation. It is undetectable or low in innervated normally active muscle and in innervated but disused muscle, whereas it is abundant along the whole fiber length in denervated muscle or in muscle in which the neuromuscular contact is intact but the release of transmitter is blocked. The alpha-, beta-, and delta-subunit mRNA levels show a different pattern. Highest amounts are always found at end-plate nuclei irrespective of whether the muscle is innervated, denervated, active, or inactive, whereas in extrasynaptic regions they are tightly controlled by innervation partially through electrical muscle activity. The changes in the levels and distribution of gamma- and epsilon-subunit-specific mRNAs in toxin-paralyzed muscle correlate well with the spatial appearance of functional fetal and adult AChR channel subtypes along the muscle fiber. The results suggest that the focal accumulation at the synaptic region of mRNAs encoding the alpha-, beta-, delta-, and epsilon-subunits, which constitute the adult type end-plate channel, is largely determined by at least two different neural factors that act on AChR subunit gene expression of subsynaptic nuclei.

Myogenin and MyoD join a family of skeletal muscle genes regulated by electrical activity

Myogenin and MyoD are proteins that bind to the regulatory regions of a battery of skeletal muscle genes and can activate their transcription during muscle differentiation. We have recently found that both proteins interact with the enhancer of the nicotinic acetylcholine receptor (nAChR) alpha subunit, a gene that is regulated by innervation. This observation prompted us to study if myogenin and MyoD transcript levels are also regulated by skeletal muscle innervation. Using Northern blot analysis, we found that MyoD and myogenin mRNA levels begin to decline at embryonic day 17 and attain adult levels in muscle of newborn and 3-week-old mice, respectively. In contrast, nAChR mRNAs are highest in newborn and 1-week-old mouse muscle and decline thereafter to reach adult levels in 3-week-old mice. To determine if the down-regulation of myogenin and MyoD mRNA levels during development is due to innervation, we quantitated message levels in adult calf muscles after denervation. We found that in denervated muscle myogenin and MyoD mRNAs reach levels that are approximately 40- and 15-fold higher than those found in innervated muscle. Myogenin mRNAs begin to accumulate rapidly between 8 and 16 hr after denervation, and MyoD transcripts levels begin to increase sharply between 16 hr and 1 day after denervation. The increases in myogenin and MyoD mRNA levels precede the rapid accumulation of nAChR alpha-subunit transcripts; receptor mRNAs begin to accumulate significantly after 1 day of denervation. The effects of denervation are specific because skeletal alpha-actin mRNA levels are not affected by denervation. In addition, we found that the repression of myogenin and MyoD expression by innervation is due, at least in part, to "electrical activity." Direct stimulation of soleus muscle with extracellular electrodes repressed the increase of myogenin and MyoD transcripts after denervation by 4- to 3-fold, respectively. In view of these results, it is interesting to speculate that myogenin and/or MyoD may regulate a repertoire of skeletal muscle genes that are down-regulated by electrical activity.

Metabolic stabilization of endplate acetylcholine receptors regulated by Ca2+ influx associated with muscle activity

During formation of the neuromuscular junction, acetylcholine receptors in the endplate membrane become metabolically stabilized under neural control, their half-life increasing from about 1 day to about 10 days. The metabolic stability of the receptors is regulated by the electrical activity induced in the muscle by innervation. We report here that metabolic stabilization of endplate receptors but not of extrajunctional receptors can be induced in the absence of muscle activity if muscles are treated with the calcium ionophore A23187. Acetylcholine receptor stabilization was also induced by culturing non-stimulated muscle in elevated K+ with the Ca2+ channel activator (+)-SDZ202-791. Conversely, activity-dependent receptor stabilization is prevented in muscle stimulated in the presence of the Ca2+ channel blockers (+)-PN200-110 or D-600. Treatment of muscles with ryanodine, which induces Ca2+ release from the sarcoplasmic reticulum in the absence of activity, does not cause stabilization of junctional receptors. Evidently, muscle activity induces metabolic acetylcholine receptor stabilization by way of an influx of Ca2+ ions through dihydropyridine-sensitive Ca2+ channels in the endplate membrane, whereas Ca2+ released from the sarcoplasmic reticulum is ineffective in this developmental process.

Metabolic stabilization of acetylcholine receptors in vertebrate neuromuscular junction by muscle activity

The effects of muscle activity on the growth of synaptic acetylcholine receptor (AChR) accumulations and on the metabolic AChR stability were investigated in rat skeletal muscle. Ectopic end plates induced surgically in adult soleus muscle were denervated early during development when junctional AChR number and stability were still low and, subsequently, muscles were either left inactive or they were kept active by chronic exogenous stimulation. AChR numbers per ectopic AChR cluster and AChR stabilities were estimated from the radioactivity and its decay with time, respectively, of end plate sites whose AChRs had been labeled with 125I-alpha-bungarotoxin (alpha-butx). The results show that the metabolic stability of the AChRs in ectopic clusters is reversibly increased by muscle activity even when innervation is eliminated very early in development. 1 d of stimulation is sufficient to stabilize the AChRs in ectopic AChR clusters. Muscle stimulation also produced an increase in the number of AChRs at early denervated end plates. Activity-induced cluster growth occurs mainly by an increase in area rather than in AChR density, and for at least 10 d after denervation is comparable to that in normally developing ectopic end plates. The possible involvement of AChR stabilization in end plate growth is discussed.

Imprinting of acetylcholine receptor messenger RNA accumulation in mammalian neuromuscular synapses

IN mammalian muscle, the subunit composition of the nicotinic acetylcholine receptor (AChR) and the distribution of AChRs along the fibre are developmentally regulated. In fetal muscle, AChRs are distributed over the entire fibre length whereas in adult fibres they are concentrated at the end-plate. We have used in situ hybridization techniques to measure the development of the synaptic localization of the messenger RNAs (mRNAs) encoding the alpha-subunit and the epsilon-subunit of the rat muscle AChR. The alpha-subunit is present in both fetal and adult muscle, whereas the epsilon-subunit appears postnatally and specifies the mature AChR subtype. The synaptic localization of alpha-subunit mRNA in adult fibres may arise from the selective down-regulation of constitutively expressed mRNA from extrasynaptic fibre segments. In contrast, epsilon-subunit mRNA appears locally at the site of neuromuscular contact and its accumulation at the end-plate is not dependent on the continued presence of the nerve terminal very early during synapse formation. This suggests that epsilon-subunit mRNA expression is induced locally via a signal which is restricted to the end-plate region and is dependent on the presence of the nerve only during a short period of early neuromuscular contact. Evidently, several mechanisms operate to confine AChR mRNAs to the adult end-plate region, and the levels of alpha-subunit and epsilon-subunit mRNAs depend on these mechanisms to differing degrees.

On the effect of muscle activity on the end-plate membrane in denervated mouse muscle

1. Mouse soleus muscles were denervated and some of them were chronically stimulated. Sixteen to twenty-one days later, the number of junctional acetylcholine receptors (AChR) and their metabolic stability were examined by measuring binding of 125I-alpha-bungarotoxin, their gating properties by analysis of acetylcholine-induced current fluctuations and the ultrastructure of the end-plate membrane by electron microscopy. 2. In agreement with other studies on inactive muscles, no effect of denervation on junctional AChR number could be resolved. However, some of the fast-gating 'adult' AChR channels had been replaced by slowly gating fetal AChRs, their half-life was lowered to 38 h and the folding of the end-plate membrane was reduced. 3. These changes were prevented in denervated but stimulated active muscles: the junctional AChR population remained homogeneously 'adult', the half-life of junctional AChRs was 13 days and folding of the end-plate membrane remained comparable to that in control muscles. 4. The significance of these results is discussed with respect to the role of muscle activity in end-plate development.

Acetylcholine receptor alpha-, beta-, gamma-, and delta-subunit mRNA levels are regulated by muscle activity

Denervation of adult skeletal muscle results in increased sensitivity to acetylcholine in extrajunctional regions of the muscle fiber. This increase in acetylcholine sensitivity is accompanied by a large increase in the level of mRNAs coding for the alpha-, beta-, gamma-, and delta-subunits of the acetylcholine receptor. To determine whether muscle activity is sufficient to regulate expression of extrajunctional acetylcholine receptor mRNA levels, denervated muscles were stimulated with extracellular electrodes. Direct stimulation of denervated muscle suppresses both the increase in extrajunctional acetylcholine sensitivity and the expression of mRNA encoding the alpha-, beta-, gamma-, and delta-subunits of the acetylcholine receptor. These results show that muscle activity regulates the level of extrajunctional acetylcholine receptors by regulating the expression of their mRNAs.

Dependence of acetylcholine receptor channel conversion on muscle activity at denervated neonatal rat endplates

During the development of the motor endplate, the apparent mean open time of the junctional acetylcholine (AChR) channels decreases during the first 3 weeks of postnatal life from about 4 to about 1 ms. This decrease is prevented by early denervation of the muscle, suggesting a neural control of subsynaptic AChR channel properties. To further examine the nature of this neural influence, neonatal rat soleus muscles were now denervated at an early stage of endplate development and the muscles were kept active by chronic stimulations in vivo for 4 days. The gating properties of AChR channels at the denervated endplates and at control endplates of similar age were then examined by analysis of acetylcholine-induced endplate current fluctuations and of the time course of miniature endplate currents, respectively. The results indicate, that stimulation restores the maturation of 'adult' AChR channel properties even in the absence of the nerve, suggesting an important role of muscle activity in synapse development.

Control of end-plate channel properties by neurotrophic effects and by muscle activity in rat

1. The formation of ectopic neuromuscular synapses was induced in rat soleus muscle by implantation of the fibular nerve into the proximal part of the muscle and subsequent sectioning of the soleus nerve. The gating properties of acetylcholine (ACh) receptors at the newly formed end-plates were examined by analysis of acetylcholine-induced membrane current fluctuations. 2. In agreement with earlier studies, the apparent mean open time of end-plate channels decreased during synaptic development from about 4 ms to about 1 ms (-60 mV membrane potential, 22 degrees C) within 7-18 days after the soleus nerve had been cut. 3. When the fibular nerve was cut at an early stage of end-plate development, fast-gating channels with apparent mean open times of 1 ms characteristic of mature end-plates did not develop within the next 10-14 days. 4. When the fibular nerve was cut at an early stage of end-plate development and the soleus muscle was then stimulated chronically via implanted electrodes, fast-gating channels did develop in the absence of the nerve terminals within 4-6 days. 5. When impulse conduction in the transplanted fibular nerve was blocked chronically at the time of soleus nerve section such that ectopic end-plates formed in inactive muscle, fast-gating channels developed within 12-14 days. 6. The results show that motoneurones control the conversion from slow-gating fetal to fast-gating adult-type ACh receptor channels at ectopic end-plates in rat soleus muscles. The conversion occurs in the absence of impulse activity provided the nerve continues to be present. However, it also occurs in the absence of the nerve provided the muscle is active and had received an early priming influence from the nerve. Thus, nerve-evoked muscle activity and nerve-released trophic influences complement each other in controlling the gating properties of junctional ACh receptor channels.

On the neurotrophic control of acetylcholine receptors at frog end-plates reinnervated by the vagus nerve

To test whether the properties of subsynaptic acetylcholine (ACh) receptors in skeletal muscle fibre are influenced by the type of the innervating neurone some pharmacological properties of ACh receptor in normal end-plates and in denervated end-plates reinnervated by the vagus nerve in the frog were compared. Blockade of nerve-evoked synaptic currents by 200 microM-hexamethonium was stronger at vagus-reinnervated than at normal end-plates. Blockade at both types of junctions was voltage dependent. The effect of hexamethonium on equilibrium currents induced by bath-applied ACh and carbamylcholine was similar at the two types of junctions. At both normal and vagus-reinnervated junctions, decamethonium had similar partial agonist properties. Following a step in membrane potential, the relaxations of ACh-induced conductance changes at the two types of junctions were affected in a similar fashion by hexamethonium: hyperpolarization first produced a fast decrease and then a slow exponential increase in conductance. Upon depolarization, a fast increase was followed by an exponential decline to its original level. The time constant of the slow relaxation was slightly prolonged compared to control. These findings are consistent with a fast blocking action of open channels by hexamethonium. The effectiveness of hexamethonium in blocking end-plate currents was reduced in the presence of (+)-tubocurarine, indicating that hexamethonium has a competitive blocking action on the receptors. These results do not indicate that the pharmacological properties of the ACh receptors are changed after an end-plate is reinnervated by a preganglionic neurone. The differential effect of hexamethonium on transmission at normal and vagus-reinnervated end-plates is discussed as a consequence of different transmitter release characteristics at the two types of junctions.

Synthesis and properties of NBD-n-acylcholines, fluorescent analogs of acetylcholine

We have synthesized a homologous series of fluorescent analogs of acetylcholine, N-7-(4-nitrobenzo-2-oxa-1,3-diazolyl)-omega-amino-n-alkanoic acid beta (N,N,N-trialkylammonium) ethylesters (NBD-n-acylcholines) and report here on their physiological and biochemical properties. All NBD-n-acylcholines trimethylated at the cholinergic nitrogen are agonists of acetylcholine at the frog neuromuscular junction. Their potencies in depolarizing frog muscle cells decrease with decreasing chain length. The affinities of binding to the purified receptor from Electrophorus electricus also decrease with decreasing chain length with a large drop in affinity for the derivatives n = 4 and n = 3. The rate constants of association to acetylcholine receptor and to acetylcholine esterase are of the order of 10(8) M-1 S-1 and do not vary significantly with the chain length of the NBD-n-acylcholines. In contrast, the dissociation rate constants decrease with increasing chain length. The quenching of fluorescence of NBD-n-acylcholines accompanying binding to purified receptor and esterase from E. electricus appears to be due to the formation of a hydrogen bond between the omega-amino group as donor and an unidentified acceptor group in a hydrophobic pocket of the protein. With their advantageous fluorescence properties, their simple pharmacology, and their clear structure-function relationships, these compounds are useful tools for the study of cholinergic mechanisms.

Early action of nerve determines motor endplate differentiation in rat muscle

The formation of a motor endplate is characterized by a complex series of changes in the properties of the subsynaptic acetylcholine receptors (AChRs). Among the last changes to occur are the shortening of the apparent mean open time of their ion channels from about 4 to 1 ms and an increase in the single-channel conductance. This conversion of channel gating at the endplate seems to be induced by the motor neurone. We report here that fast channel gating also develops at nerve-free endplate sites of fibres that had been denervated while gating was still slow. At such sites, junctional folds will develop in the absence of the nerve terminal. Although the conversion of channel gating and the formation of junctional folds are late events in endplate development, the neural signals inducing these changes must therefore act at the earliest stages of junctional development.

Neurotrophic control of channel properties at neuromuscular synapses of rat muscle

1. Ectopic neuromuscular synapses formed when the fibular nerve was implanted into the proximal part of rat soleus muscle and the soleus nerve was cut. The gating properties of acetylcholine (ACh) receptor channels in the newly formed ectopic and in the denervated original end-plates were examined at various stages of ectopic synapse formation.2. At ectopic end-plates the apparent mean open time of ACh receptor channels changes during synaptic development. Channels in immature ectopic end-plates, examined 1 week after cutting the soleus nerve, have apparent mean open times of approximately 4 ms (at -70 mV, 22 degrees C), similar to those of the extrasynaptic ACh receptor channels of completely denervated fibres. The channel gating of mature ectopic end-plates, examined 3-7 weeks after nerve section, is characterized by a mean open time of approximately 1 ms and resembles that found in normal end-plates of adult fibres.3. The conversion of end-plate channel gating occurs during the second and third week of synapse formation. During this period two discrete classes of channels with different gating behaviour are present in the ectopic end-plate.4. Examination of ectopic end-plates in the electron microscope reveals that junctional folds begin to appear in the subsynaptic membrane during the period of channel conversion.5. At the denervated original end-plates of ectopically innervated fibres the apparent mean open time of ACh receptor channels remains similar to that of normally innervated end-plates. Original end-plates retain the normal synaptic class of channel for at least 42 days after denervation. At this time, most of the ACh receptors present originally in the membrane have been replaced by newly inserted receptors.6. At former end-plates of completely denervated fibres ACh activates two classes of channels, even when most of the ACh receptors originally present in the end-plate have been replaced by new receptors.7. The results show that during synapse formation a neurally controlled conversion of ACh receptor channels occurs about 2-3 weeks after establishment of the nerve muscle contact. Thereafter end-plate channel properties are independent of neural influences. These observations are consistent with a mechanism of channel conversion whereby the nerve modifies not the ACh receptor channel itself, but another constituent of the end-plate membrane which determines the gating properties of end-plate channels.

Channel gating at frog neuromuscular junctions formed by different cholinergic neurones

1. Drug-induced membrane current fluctuations were analysed at frog ectopic neuromuscular junctions formed de novo by somatic motoneurones and by preganglionic autonomic neurones of the vagus nerve, and at denervated end-plates reinnervated by the vagus nerve. 2. At ectopic motor end-plates, the mean open time of the ion channels activated by ACh is tau ACh = 1.8 +/- 0.1 msec (S.E.) at -70 to -90 mV and 15-18 degrees C. Carbachol- and suberyldicholine-induced channels have average open times tau Carb = 1.0 +/- 0.1 msec (-80 mV, 6-8 degrees C) and tau Sub = 3.3 +/- 0.1 msec (-80 mV, 16-18 degrees C). 3. The conductances gamma of single channels induced by ACh, carbachol and suberyldicholine are: gamma ACh = 21.0 +/- 1.1 pS (+/- S.E.), gamma Carb = 14.6 +/- 1.2 pS and gamma Sub = 22.1 +/- 1.2 pS. 4. The mean open times tau of the channels is prolonged as the membrane is hyperpolarized. Their voltage dependence is similar to that of normal end-plate channels. 5. The average open time of ACh-induced channels at ectopic vagus junctions is tau = 1.6 +/- 0.2 msec (S.E.) at -70 to -80 mV and 14-15 degrees C. At denervated motor end-plates reinnervated by vagal neurones, the mean channel open time is tau = 1.5 +/- 0.1 msec at -80 mV and 14-18 degrees C. 6. At all vagus junctions, the synaptic currents are blocked by alpha-bungarotoxin. 7. Somatic motoneurons and vagal neurones induce junctional folds in the muscle membrane where they contact it to form an ectopic end-plate. Staining the ACh receptors of the motor end-plates with horseradish peroxidase-alpha-bungarotoxin conjugate shows that the receptors are restricted to the junctional region of the muscle fibre membrane.

Reduction in acetylcholine sensitivity of axotomized ciliary ganglion cells

1. Isolated cell clusters from ciliary ganglia of 3- to 4-day-old chickens were used to examine the electrical characteristics and sensitivity to iontophoretically applied acetylcholine (ACh) of normal cells and cells that had been axotomized on the day of hatching. 2. Resting potentials, input resistances and capacitances were the same in axotomized cells as in normal cells. These averaged about 70 mV, 165 Momega and 35 pF respectively. 3. Sensitivity to iontophoretically applied ACh was lower in axotomized cells than in normal cells by a factor of about 8. The rise times of the ACh potentials were the same in the two groups; indicating that the reduced sensitivity was not due to a diffusion barrier. 4. The slopes of the dose-reponse curves, plotted on a double-logarithmic scale, suggested that the co-operative action of two ACh molecules was involved in activating a post-synaptic conductance channel. This relation was unaltered by axotomy. 5. The estimated reversal potential for the action of ACh was unchanged after axotomy. 6. Cells in isolated clusters were similar to those in intact ganlia with respect to threshold depolarization, amplitude and time course of action potentials and ability to generate repetitive action potentials. There were no differences in these characteristics between normal and axotomized cells. 7. Cells in the isolated clusters had input resistances which were larger by a factor of 2-3 and capacitances that were smaller by a factor of about 2 than those of cells in intact ganglia. It is suggested that these differences were due to loss of initial segments of axons from the isolated cells. 8. Normal cells in the isolated clusters displayed spontaneous miniature synaptic potentials, indicating that synaptic integrity was maintained during the isolation procedure. As in intact ganglia, no spontaneous activity was observed in axotomized cells.

Physiological and morphological effects of post-ganglionic axotomy on presynaptic nerve terminals

1. Electrophysiological and electron microscope studies were done on cells in the ciliary ganglion of chickens which had been axotomized on the day of hatching. 2. By the third day after post-ganglionic axotomy both electrical and chemical transmission through the ganglion were severely depressed; by the fifth day ganglionic transmission had disappeared. 3. Action potential initiation and conduction in axotomized cells and in their associated presynaptic nerve terminals were unimpaired 3-4 days after axotomy. 4. Depression of ganglionic transmission in 3-4 day axotomized preparations was due to a reduction in amplitude of both the excitatory post-synaptic potential (e.p.s.p.) and the electrical coupling potential in individual ganglion cells. 5. In addition to being reduced in amplitude, e.p.s.p.s in axotomized cells were more subject to fatigue during low frequency (1/sec) stimulation. 6. The reduction in e.p.s.p. amplitude was due to a reduction in both the mean quantal content of the e.p.s.p.s and the calculated depolarization produced by an individual quantum of transmitter. On the average the e.p.s.p. was reduced by a factor of about 4, the mean quantum content to about two thirds normal and the quantal size to about a third normal, compared with responses in unaxotomized cells of the same age. 7. Ultrastructural studies revealed a progressive maturation of pre-synaptic terminals in normal ganglia between 0 and 9 days after hatching. Over this period the content of synaptic vesicles and mitochondria in the terminals increased and the background matrix became more dense. 8. After axotomy these signs of maturation was abolished or reversed, particularly from the third day onward. In addition there was an increase in the number of cell sections in which no synaptic terminals were observed. 9. It was concluded that loss of synaptic transmission was due to at least three factors: a reduction in release of transmitter from presynaptic terminals, a reduction in quantal size, probably due to a loss of post-synaptic sensitivity, and a partial loss of presynaptic contact.

The quantal nature of synaptic transmission at the neuromuscular junction of a spider

Spontaneous and evoked release of transmitter at neuromuscular junctions in three different leg muscles of a tarantula (Dugesiella hentzi) was investigated. In most cases the spontaneous miniature potentials were released independently, although bursts from single synaptic junctions occasionally occurred. In contrast to recent findings in other arthropod muscles, focal extracellular recording from junctional areas revealed that the evoked release of transmitter quanta followed Poisson's theorem at low quantal content synaptic junctions in arachnid muscles.