Early endplate remodeling and skeletal muscle signaling events following rat hindlimb suspension.

Motor endplates naturally undergo continual morphological changes that are altered in response to changes in neuromuscular activity. This study examines the consequences of acute (6-12 hr) disuse following hindlimb suspension on rat soleus muscle endplate structural stability. We identify early changes in several key signaling events including markers of protein kinase activation, AMPK phosphorylation and autophagy markers which may play a role in endplate remodeling. Acute disuse does not change endplate fragmentation, however, it decreases both the individual fragments and the total endplate area. This decrease was accompanied by an increase in the mean fluorescence intensity from the nicotinic acetylcholine receptors which compensate the endplate area loss. Muscle disuse decreased phosphorylation of AMPK and its substrate ACC, and stimulated mTOR controlled protein synthesis pathway and stimulated autophagy. Our findings provide evidence that changes in endplate stability are accompanied by reduced AMPK phosphorylation and an increase in autophagy markers, and these changes are evident within hours of onset of skeletal muscle disuse.

Loss of glial neurofascin155 delays developmental synapse elimination at the neuromuscular junction.

Postnatal synapse elimination plays a critical role in sculpting and refining neural connectivity throughout the central and peripheral nervous systems, including the removal of supernumerary axonal inputs from neuromuscular junctions (NMJs). Here, we reveal a novel and important role for myelinating glia in regulating synapse elimination at the mouse NMJ, where loss of a single glial cell protein, the glial isoform of neurofascin (Nfasc155), was sufficient to disrupt postnatal remodeling of synaptic circuitry. Neuromuscular synapses were formed normally in mice lacking Nfasc155, including the establishment of robust neuromuscular synaptic transmission. However, loss of Nfasc155 was sufficient to cause a robust delay in postnatal synapse elimination at the NMJ across all muscle groups examined. Nfasc155 regulated neuronal remodeling independently of its canonical role in forming paranodal axo-glial junctions, as synapse elimination occurred normally in mice lacking the axonal paranodal protein Caspr. Rather, high-resolution proteomic screens revealed that loss of Nfasc155 from glial cells was sufficient to disrupt neuronal cytoskeletal organization and trafficking pathways, resulting in reduced levels of neurofilament light (NF-L) protein in distal axons and motor nerve terminals. Mice lacking NF-L recapitulated the delayed synapse elimination phenotype observed in mice lacking Nfasc155, suggesting that glial cells regulate synapse elimination, at least in part, through modulation of the axonal cytoskeleton. Together, our study reveals a glial cell-dependent pathway regulating the sculpting of neuronal connectivity and synaptic circuitry in the peripheral nervous system.

Involvement of neurotrophin-3 (NT-3) in the functional elimination of synaptic contacts during neuromuscular development.

Confocal immunohistochemistry shows that neurotrophin-3 (NT-3) and its receptor tropomyosin-related tyrosin kinase C (trkC) are present in both neonatal (P6) and adult (P45) mouse motor nerve terminals in neuromuscular junctions (NMJ) colocalized with several synaptic proteins. NT-3 incubation (1-3h, in the range 10-200ng/ml) does not change the size of the evoked and spontaneous endplate potentials at P45. However, NT-3 (1h, 100ng/ml) strongly potentiates evoked ACh release from the weak (70%) and the strong (50%) axonal inputs on dually innervated postnatal endplates (P6) but not in the most developed postnatal singly innervated synapses at P6. The present results indicate that NT-3 has a role in the developmental mechanism that eliminates redundant synapses though it cannot modulate synaptic transmission locally as the NMJ matures.

Influence of location, fluid flow direction, and tissue maturity on the macroscopic permeability of vertebral end plates.

STUDY DESIGN: We implemented a pilot study in a growing animal model. The macroscopic permeability of the vertebral endplates was measured. The influence of location, tissue maturity, and fluid flow direction was quantified. OBJECTIVE: We hypothesized that the macroscopic permeability of vertebral endplate may decrease with maturity of the vertebral segment. SUMMARY OF BACKGROUND DATA: The alternation of loading induced by the diurnal cycle generates convective flux into the vertebral segment with the dominant flow path through the vertebral endplates. The alteration of mass transport at the disc-vertebrae interface may interrupt the mechanobiologic balance, and have an effect such as degenerative changes or scoliosis. METHODS: A previously validated method for measuring permeability, based on the relaxation pressure caused by a transient-flow rate was used. Three specimens were extracted from each L1 to L5 endplate. Seventy-one specimens were frozen, and 64 were stored fresh in a standard culture media. A microscopic analysis completed the biomechanical analysis. RESULTS: At 2, 4, and 6 months, the mean permeability (10(-14) m/N x s, flow-in/flow-out) of the central zone was respectively: 1.23/1.66, 1.03/1.29, and 0.792/1.00. Laterally, it was 1.03/1.19, 1.094/1.001, and 0.765/0.863. For all groups, cartilage endplate and growth plate were both thinner in the center of the plate. Weak differences of the vascular network were detected, except for a small increase of vascular density in the central zone. CONCLUSION: The results from this animal study showed that the central zone of the vertebral endplate was more permeable than the periphery and the flow-out permeability was up to 35% greater than the flow-in permeability. Increase of permeability with decrease of cartilage thickness was noticed within the same age group. We also found a statistically significant decrease of the macroscopic permeability correlated with the tissue maturity.

Muscle-specific calpain is localized in regions near motor endplates in differentiating lobster claw muscles.

Calpains are Ca2+-dependent proteinases that mediate protein turnover in crustacean skeletal muscles. We used an antibody directed against lobster muscle-specific calpain (Ha-CalpM) to examine its distribution in differentiating juvenile lobster claw muscles. These muscles are comprised of both fast and slow fibers early in development, but become specialized into predominantly fast or exclusively slow muscles in adults. The transition into adult muscle types requires that myofibrillar proteins specific for fast or slow muscles to be selectively removed and replaced by the appropriate proteins. Using immunohistochemistry, we observed a distinct staining pattern where staining was preferentially localized in the fiber periphery along one side of the fiber. Immunolabeling with an antibody directed against synaptotagmin revealed that the calpain staining was greatest in the cytoplasm adjacent to synaptic terminals. In complementary analyses, we used sequence-specific primers with real-time PCR to quantify the levels of Ha-CalpM in whole juvenile claw muscles. These expression levels were not significantly different between cutter and crusher claws, but were positively correlated with the expression of fast myosin heavy chain. The anatomical localization of Ha-CalpM near motor endplates, coupled with the correlation with fast myofibrillar gene expression, suggests a role for this intracellular proteinase in fiber type switching.

Muscarinic autoreceptors related with calcium channels in the strong and weak inputs at polyinnervated developing rat neuromuscular junctions.

Using intracellular recording, we studied how several muscarinic antagonists affected the evoked endplate potentials in singly and dually innervated endplates of the levator auris longus muscle from 3 to 6-day-old rats. In dually innervated fibers, a second endplate potential (EPP) may appear after the first one when we increase the stimulation intensity. The lowest and highest EPP amplitudes are designated "small-EPP" and "large-EPP," respectively. In singly innervated endplates and large-EPP, we found an inhibition of acetylcholine release by M1-receptor antagonists pirenzepine and MT-7 (more than 30%) and M2-receptor antagonists methoctramine and AF-DX 116 (more than 40%). The small-EPP was also inhibited by both M2-receptor antagonists methoctramine (approximately 70%) and AF-DX 116 (approximately 40%). However, the small-EPP was enhanced by M1-receptor antagonists pirenzepine (approximately 90%) and MT-7 (approximately 50%). The M4-receptor selective antagonists tropicamide and MT-3 can also increase the small-EPP amplitude (75% and 120%, respectively). We observed a graded change from a multichannel involvement (P/Q- N- and L-type voltage-dependent calcium channels) of all muscarinic responses (M1-, M2- and M4-mediated) in the small-EPP to the single channel (P/Q-type) involvement of the M1 and M2 responses in the singly innervated endplates. This indicates the existence of a progressive calcium channels shutoff in parallel with the specialization of the adult type P/Q channel. In conclusion, muscarinic autoreceptors can directly modulate large-EPP generating ending potentiation, and small-EPP generating ending depression through their association with the calcium channels during development.

Quantal endplate currents from newborn to adult mice and the switch from embryonic to adult channel type.

Quantal endplate currents (qEPCs) were recorded extracellularly by a macropatch electrode from excised diaphragms of mice. During the first 3 days after birth, the mean rise time t(r) was 0.5 ms (0.1-0.9 peak, 20 degrees C). Double-exponential, amplitude-weighted fits of the decay discerned almost equally abundant components tau(1)' approximately equal to 6 ms and tau(2)' approximately equal to 9 ms. Beginning on day 3, on days 4 and 5 after birth both t(r) and the tau' dropped. Further decreasing slowly, adult values were reached at day 8, with t(r) approximately equal to 0.3 ms, tau(1)' approximately equal to 2 ms and a very weak tau(2)' approximately equal to 6 ms component. When compared to the kinetics of fetal channels, the tau(1)' and tau(2)' of up to 3 day qEPCs could correspond to the short and long splice variants of the fetal channel type. The tau(1)' of adult muscles of 2 ms agrees well with the burst durations of adult channels while a weak longer tau(2)' component may represent 'extrasynaptic' channels. The long t(r) of very young mice may correspond to the relatively slow rise of channel currents elicited by ACh pulses in mouse myoballs.

Morphological features of nerve terminal degeneration as part of the remodeling process in the motor endplate in adult muscles.

With the exception of signs of retraction and withdrawal, there have been few morphological data concerning degenerated neural profiles in adult motor endplates. Here, investigation into the ultrastructure of the soleus motor endplates of adult rats (4 months old) turned up particular axonal degeneration in approximately 3% of the subjects. These axons occur as synaptic debris in the synaptic matrix of the motor endplate, adjacent to thin processes of the perisynaptic cells occupying the outermost layer of the motor endplate and were devoid of basal lamina. They often possessed dense-cored vesicles (50-80 nm). Axonal debris released from Schwann cell processes occurred during the period of acute sciatic neurectomy, when nerve terminals progressively disrupted within the motor endplate-associated Schwann cells. Finally, immunohistochemical staining for antibodies to label macrophages (ED1 or ED2) has shown that nerve fiber-associated macrophages are located near the motor endplate. The results suggest that during the course of endplate remodeling, a few parts of the terminal branches are disposed of through spontaneous collapse, subsequent release from the Schwann cell investment, and eventual ingestion by macrophages in the perisynaptic space.

Effects of hindlimb unloading on neuromuscular development of neonatal rats.

We hypothesized that hindlimb suspension unloading of 8-day-old neonatal rats would disrupt the normal development of muscle fiber types and the motor innervation of the antigravity (weightbearing) soleus muscles but not extensor digitorum longus (EDL) muscles. Five rats were suspended 4.5 h and returned 1.5 h to the dam for nursing on a 24 h cycle for 9 days. To control for isolation from the dam, the remaining five littermates were removed on the same schedule but not suspended. Another litter of 10 rats housed in the same room provided a vivarium control. Fibers were typed by myofibrillar ATPase histochemistry and immunostaining for embryonic, slow, fast IIA and fast IIB isomyosins. The percentage of multiple innervation and the complexity of singly-innervated motor terminal endings were assessed in silver/cholinesterase stained sections. Unique to the soleus, unloading accelerated production of fast IIA myosin, delayed expression of slow myosin and retarded increases in standardized muscle weight and fiber size. Loss of multiple innervation was not delayed. However, fewer than normal motor nerve endings achieved complexity. Suspended rats continued unloaded hindlimb movements. These findings suggest that motor neurons resolve multiple innervation through nerve impulse activity, whereas the postsynaptic element (muscle fiber) controls endplate size, which regulates motor terminal arborization. Unexpectedly, in the EDL of unloaded rats, transition from embryonic to fast myosin expression was retarded. Suspension-related foot drop, which stretches and chronically loads EDL, may have prevented fast fiber differentiation. These results demonstrate that neuromuscular development of both weightbearing and non-weightbearing muscles in rats is dependent upon and modulated by hindlimb loading.

Maturation of neuromuscular transmission during early development in zebrafish.

We have examined the rapid development of synaptic transmission at the neuromuscular junction (NMJ) in zebrafish embryos and larvae by patch-clamp recording of spontaneous miniature endplate currents (mEPCs) and single acetylcholine receptor (AChR) channels. Embryonic (24-36 h) mEPCs recorded in vivo were small in amplitude (<50 pA). The rate of mEPCs increased in larvae (3.5-fold increase measured by 6 days), and these mEPCs were mostly of larger amplitude (10-fold on average) with (

Deficient development and maintenance of postsynaptic specializations in mutant mice lacking an 'adult' acetylcholine receptor subunit.

At many synapses, 'fetal' neurotransmitter receptor subunits are replaced by 'adult' subunits as development proceeds. To assess the significance of such transitions, we deleted the gene encoding the adult acetylcholine receptor (AChR) epsilon subunit, which replaces its fetal counterpart, the gamma subunit, at the skeletal neuromuscular junction during early postnatal life. Several aspects of postnatal maturation, including synapse elimination, proceeded normally in the absence of the adult AChR, but structural development of the endplate was compromised. Later, inadequate compensation by the gamma subunit led to severely reduced AChR density in mutant endplates relative to controls. This decreased density led to a profound reorganization of AChR-associated components of the postsynaptic membrane and cytoskeleton. Together, these results suggest novel roles for AChRs in assembly of the postsynaptic apparatus.

Motor nerve transplantation.

The motor nerve transplantation (MNT) technique is used to transfer an intact nerve into a denervated muscle by harvesting a neurovascular pedicle of muscle containing motor endplates from the motor endplate zone of a donor muscle and implanting it into a denervated muscle. Thirty-six adult New Zealand White rabbits underwent reinnervation of the left long peroneal (LP) muscle (fast twitch) with a motor nerve graft from the soleus muscle (slow twitch). The right LP muscle served as a control. Reinnervation was assessed using microstimulatory single-fiber electromyography (SFEMG), alterations in muscle fiber typing and grouping, and isometric response curves. Neurofilament antibody was used for axon staining. The neurofilament studies provided direct evidence of nerve growth from the motor nerve graft into the adjacent denervated muscle. Median motor endplate jitter was 13 microsec preoperatively, and 26 microsec at 2 months, 29.5 microsec at 4 months, and 14 microsec at 6 months postoperatively (p < 0.001). Isometric tetanic tension studies showed a progressive functional recovery in the reinnervated muscle over 6 months. There was no histological evidence of aberrant reinnervation from any source outside the nerve pedicle. Isometric twitch responses and adenosine triphosphatase studies confirmed the conversion of the reinnervated LP muscle to a slow-type muscle. Acetylcholinesterase studies confirmed the presence of functioning motor endplates beneath the insertion of the motor nerve graft. It is concluded that the MNT technique achieves motor reinnervation by growth of new nerve fibers across the pedicle graft into the recipient muscle.

Regression of polyneural innervation in the human psoas muscle.

During the early stages of mammalian ontogeny muscle fibres are innervated by more than one axon. This polyneural innervation is replaced by mononeural innervation in the course of development. The regression of polyneural innervation in the psoas muscle in the human is the topic of the present study. Innervation patterns were studied in fetuses from 15 1/2 weeks of post menstrual age (PMA) and in babies until 80 weeks PMA (40 weeks after term age) and compared to data from two adults. Motor endplates were stained by a combined acetylcholinesterase stain. Innervation patterns and motor endplate morphology were studied and the sizes of endplates were measured. As a main result of our study polyneural innervation of the psoas muscle remains at a level of about 2 endings per endplate (range 1-5 terminals) until 18-25 weeks PMA and decreases thereafter. From 52 weeks PMA (12 weeks post term) onwards, muscle fibres are predominantly mononeurally innervated. During development the morphology of the terminal patterns of the nerve endings becomes more complex and the size of endplates increases, implying that the adult pattern of muscle innervation is reached at the age at which a major functional transformation in the neurobehavioural repertoire occurs (i.e. the end of the second and the beginning of the third month.

[Changes in the shape and growth of motor endplates of mm. fibularis longus, semitendinosus and longissimus in pigs]. / Zu den Formveränderungen und zum Wachstum der motorischen Endplatten der Mm. fibularis longus, semitendinosus et longissimus bei Schweinen.

Age-related changes in motor endplates were studied in the fibularis longus, semitendinosus and longissimus muscles in pigs. They develop from small, compact AChE-active figures in fetuses to typical myoneuronal synapses with a branched subsynaptical structure of AChE-active units. High correlations were found between size of endplates and both myofibre diameter and body mass. Growth analyses with respect to age, as well as allometrical approaches, showed that endplate growth slightly precedes that of myofibres, with both having similar growth patterns. The morphological changes, however, imply that the increment of synaptical area could lag behind that of myofibres.

Ciliary neurotrophic factor may act in target musculature to regulate developmental synapse elimination.

During development of mammalian skeletal muscles, synaptic contacts from different motoneurons are made on to individual muscle fibers but then are progressively lost until the adult pattern of single innervation is established. Although this process of synapse elimination occurs throughout the developing nervous system, little is known about the underlying mechanisms that drive this process. Competition for target-derived trophic substances has been proposed as one mechanism whereby synapses are selectively maintained or eliminated. To directly test whether exogenous trophic substance could alter neuromuscular synapse elimination, levator ani (LA) muscles of male rats were treated during the period of synapse elimination with either human recombinant ciliary neurotrophic factor (CNTF-a putative motoneuronal survival factor), or vehicle. LA muscles were stained with tetranitroblue tetrazolium at the end of treatment and the number of axonal inputs per muscle fiber was quantified. Effects of CNTF on other parameters such as body weight, axonal sprouting, muscle fiber and motoneuronal growth were also assessed. CNTF-treated muscles contained 3 times more multiple innervation than did vehicle-treated muscles, suggesting that CNTF can regulate synapse elimination in the LA. Moreover, CNTF delivered near the LA was more potent in blocking synapse elimination than the same dose of CNTF delivered at a site distant from the LA, suggesting that the target muscle is an important site, either for direct CNTF action on synapse elimination, and/or for directed transport of CNTF to motoneuronal cell bodies.

Both basic fibroblast growth factor and ciliary neurotrophic factor promote the retention of polyneuronal innervation of developing skeletal muscle fibers.

At birth, nearly all rat muscle fibers receive synaptic inputs from more than one motoneuron at a single end-plate site. By the end of the third postnatal week all but one of these inputs has been eliminated. During this loss of polyneuronal innervation, developing neuromuscular synapses compete with one another. Although the nature of this competition is not known, it is commonly assumed that it is mediated through differential activity of the competing inputs. One means by which such differential activity might be translated into a biological signal would be if the synapses compete in an activity-dependent manner for a scarce supply of neurotrophic molecules. A prediction of this hypothesis is that excess quantities of such trophic molecules will reduce competition and thereby slow down or abolish the normal loss of polyneuronal innervation. In newborn rats, the effects of injection of either basic fibroblast growth factor (bFGF) or ciliary neurotrophic factor (CNTF) on the outcome of neuromuscular synapse elimination were investigated. Daily injections of either bFGF or CNTF were made for 1 week into the lateral gastrocnemius muscle beginning at the postnatal age of 2 days. The amount of polyneuronal innervation of fibers in trophic molecule-injected muscles and saline-injected contralateral muscles was assayed using intracellular recording methods. For both bFGF- and CNTF-injected muscles, an increase in the percentage of polyneuronally innervated fibers relative to saline-injected muscles was noted. For bFGF-injected muscles, the amount of polyneuronal innervation remained at nearly 60% as late as the postnatal age of 14 days (P14). This is the amount of polyneuronal innervation found at age 6 days in normal animals. Nearly 40% of the fibers of CNTF-injected muscles remained polyneuronally innervated at age P14, the amount expected at age 9 days. These results indicate that both bFGF and CNTF exert powerful and long-lasting effects on developing neuromuscular synapses.

Developmental changes in rat diaphragm endplate response to repetitive stimulation.

Endplate potentials (epps) were recorded intracellularly from single diaphragm fibers, in vitro, of newborn (< or = 10 days, n = 10) and older (18-29 days, n = 5) rats with glass microelectrodes. The muscle was stimulated via the phrenic nerve for 1 s at 10, 20 or 50 Hz. Muscle action potentials were blocked by mu conotoxin GIIIA, a specific muscle Na+ channel blocker. In diaphragms from older animals, epps followed nerve stimulation at the 3 frequencies, with a gradual decrement in amplitude to 70% of the first epp at 50 Hz. The younger age group showed an initial enhancement of epp amplitude, followed by large variability in amplitude. These data suggest that neuromuscular transmission failure in the newborn diaphragm is secondary to variability in neurotransmitter release as compared to the more mature diaphragm.

Effects of muscle electrical activity on the transmission of developing neuromuscular junction.

Miniature endplate potentials (MEPPS) caused by the spontaneous release of ACh from the growth cone of cholinergic neurons, are recorded by the whole-cell patch-clamp technique on a large number of 1-day cultured myoballs which have contact neurites of co-cultured neurons. Both muscle cell and neuron are dissociated from the 1-day-old (about stage 20) Xenopus embryo. Frequency and/or amplitude of MEPPs can obviously increase after the repetitive high-level depolarization caused by the stimuli on muscle cells. No detectable changes of single ACh receptor channel property are observed by using the single-channel recording technique. These results suggest that the mechanism of the increase of MEPPs after electrical activity of postsynaptic muscle cells probably involve some alteration of presynaptic membrane.