Axonin-1, Nr-CAM, and Ng-CAM play different roles in the in vivo guidance of chick commissural neurons.

Immunoglobulin/fibronectin type III-like cell adhesion molecules have been implicated in axon pathfinding based on their expression pattern in the developing nervous system and on their complex interactions described in vitro. The present in vivo study demonstrates that interactions by two of these molecules, axonin-1 on commissural growth cones and Nr-CAM on floor plate cells, are required for accurate pathfinding at the midline. When axonin-1 or Nr-CAM interactions were perturbed, many commissural axons failed to cross the midline and turned instead along the ipsilateral floor plate border. In contrast, though perturbation of Ng-CAM produced a defasciculation of the commissural neurites, it did not affect their guidance across the floor plate.

Alterations in transmission, vesicle dynamics, and transmitter release machinery at NCAM-deficient neuromuscular junctions.

Although functional neuromuscular junctions (NMJs) form in NCAM-deficient mice, they exhibit multiple alterations in presynaptic organization and function. Profound depression and unusual periodic total transmission failures with repetitive stimulation point to a defect in vesicle mobilization/cycling, and these defects were mimicked in (+/+) NMJs by inhibitors of myosin light chain kinase, known to affect vesicle mobilization. Two separate release mechanisms, utilizing different endocytic machinery and Ca(2+) channels, were shown to coexist in (-/-) terminals, with the mature process targeted to presynaptic membrane opposed to muscle, and an abnormally retained immature process targeted to the remainder of the presynaptic terminal and axon. Thus, NCAM plays a critical and heretofore unsuspected role in the molecular organization of the presynaptic NMJ.

Interference with axonin-1 and NrCAM interactions unmasks a floor-plate activity inhibitory for commissural axons.

Axonin-1 and NrCAM were previously shown to be involved in the in vivo guidance of commissural growth cones across the floor plate of the embryonic chicken spinal cord. To further characterize their role in axon pathfinding, we developed a two-dimensional coculture system of commissural and floor-plate explants in which it was possible to study the behavior of growth cones upon floor-plate contact. Although commissural axons readily entered the floor plate under control conditions, perturbations of either axonin-1 or NrCAM interactions prevented the growth cones from entering the floor-plate explants. The presence of antiaxonin-1 resulted in the collapse of commissural growth cones upon contact with the floor plate. The perturbation of NrCAM interactions also resulted in an avoidance of the floor plate, but without inducing growth-cone collapse. Therefore, axonin-1 and NrCAM are crucial for the contact-mediated interaction between commissural growth cones and the floor plate, which in turn is required for the proper guidance of the axons across the ventral midline and their subsequent rostral turn into the longitudinal axis.

Synaptic plasticity: keeping synapses under control.

Recent studies have confirmed that a retrograde signal is produced at the neuromuscular junction that can adjust the efficacy of transmission to meet long-term changing needs. Genetic manipulations in Drosophila have begun to define the circumstances in which such signals are generated and how they act.

Site-directed antibodies to low-voltage-activated calcium channel CaV3.3 (alpha1I) subunit also target neural cell adhesion molecule-180.

Synthetic peptides of defined amino acid sequence are commonly used as unique antigens for production of antibodies to more complex target proteins. We previously showed that an affinity-purified, site-directed polyclonal antibody (CW90) raised against a peptide antigen (CNGRMPNIAKDVFTKM) anticipated to be specific to a T-type voltage-dependent Ca(2+) channel subunit identified recombinant rat alpha1I/Ca(V)3.3 and two endogenous mouse proteins distinct in their developmental expression and apparent molecular mass (neonatal form 260 kDa, mature form 190 kDa) [Yunker AM, Sharp AH, Sundarraj S, Ranganathan V, Copeland TD, McEnery MW (2003) Immunological characterization of T-type voltage-dependent calcium channel Ca(V)3.1 (alpha 1G) and Ca(V)3.3 (alpha 1I) isoforms reveal differences in their localization, expression, and neural development. Neuroscience 117:321-335]. In the present study, we further characterize the biochemical properties of the CW90 antigens. We show for the first time that recombinant alpha1I/Ca(V)3.3 is modified by N-glycosylation. Using peptide:N-glycosidase F (PNGase F), an enzyme that removes polysaccharides attached at Asn residues, and endoneuraminidase-N (Endo-N), which specifically removes polysialic acid modifications, we reveal that differential glycosylation fully accounts for the large difference in apparent molecular mass between neonatal and adult CW90 antigens and that the neonatal form is polysialylated. As very few proteins are substrates for Endo-N, we carried out extensive analyses and herein present evidence that CW90 reacts with recombinant alpha1I/Ca(V)3.3 as well as endogenous neural cell adhesion molecule-180 (NCAM-180). We demonstrate the basis for CW90 cross-reactivity is a five amino acid epitope (AKDVF) present in both alpha1I/Ca(V)3.3 and NCAM-180. To extend these findings, we introduce a novel polyclonal anti-peptide antibody (CW678) that uniquely recognizes NCAM-180 and a new antibody (CW109) against alpha1I/Ca(V)3.3. Western blot analyses obtained with CW678, CW109 and CW90 on a variety of samples confirm that the endogenous CW90 signals are fully attributed to the two developmental forms of NCAM-180. Using CW678, we present novel data on differentiation-dependent NCAM-180 expression in human neuroblastoma IMR32 cells. These results strongly suggest the need for careful analyses to validate anti-peptide antibodies when targeting membrane proteins of low abundance.

Axon guidance at choice points.

The common theme in many recent axonal pathfinding studies, both in vertebrates and invertebrates, is the demonstration of the importance of a balance between positive and negative cues. The integration of multiple and often opposing molecular interactions at each site along the axon's trajectory, especially at choice points, helps to fine tune the directional response of its growth cone, which continuously samples its environment for guidance cues. The dynamic regulation of the receptors for such cues, in response to extrinsic signals, also enhances the behavioral repertoire of growth cones at different points along their trajectory. Some of the molecules identified as being important for axon guidance at choice points are conserved between invertebrates and vertebrates (e.g. Robo and netrin), whereas other molecules have been identified, so far, only in invertebrates (e.g. Comm) or vertebrates (e.g. axonin-1 and NrCAM).

The pattern of avian intramuscular nerve branching is determined by the innervating motoneuron and its level of polysialic acid.

Most skeletal muscles are composed of a heterogeneous population of fast and slow muscle fibers that are selectively innervated during development by fast and slow motoneurons, respectively. It is well recognized that, in both birds and mammals, fast and slow motoneurons have substantially different intramuscular branching patterns, a difference critical for proper motor function. However, the cellular mechanisms regulating these differences in motoneuron branching are unknown. In a previous study, we showed that the fast and slow pattern of intramuscular branching, in a chick muscle containing distinct fast and slow muscle regions, was remarkably similar to normal when formed by foreign motoneurons. Whether this was attributable to some property of the innervating "fast" or "slow" motoneurons or to some property of the developing fast-slow muscle fibers was not determined. To distinguish between these two possibilities, we performed chick-quail hindlimb chimeras to force slow chick plantaris motoneurons to innervate a fast quail plantaris muscle. The pattern of intramuscular nerve branching in the fast plantaris of these chimeras closely resembled the slow branching pattern normally observed in chick slow plantaris muscles. Enzymatic removal of polysialic acid (PSA) from nerve and muscle during normal quail plantaris development dramatically changed the normal fast pattern to more closely resemble a slow pattern. In contrast, removal of PSA from chick plantaris motoneurons and muscle fibers had little effect on the pattern of nerve branching. Together, these results indicate that the pattern of intramuscular nerve branching is determined by the level of PSA on the innervating motoneurons.

Neuromuscular activity blockade induced by muscimol and d-tubocurarine differentially affects the survival of embryonic chick motoneurons.

To understand better how spontaneous motoneuron activity and intramuscular nerve branching influence motoneuron survival, we chronically treated chicken embryos in ovo with either d-tubocurarine (dTC) or muscimol during the naturally occurring cell death period, assessing their effects on activity by in ovo motility measurement and muscle nerve recordings from isolated spinal cord preparations. Because muscimol, a GABA(A) agonist, blocked both spontaneous motoneuron bursting and that elicited by descending input but did not rescue motoneurons, we conclude that spontaneous bursting activity is not required for the process of normal motoneuron cell death. dTC, which rescues motoneurons and blocks neuromuscular transmission, blocked neither spontaneous nor descending input-elicited bursting and early in the cell death period actually increased burst amplitude. These changes in motoneuron activation could alter the uptake of trophic molecules or gene transcription via altered patterns of [Ca(2+)](i), which in turn could affect motoneuron survival directly or indirectly by altering intramuscular nerve branching. A good correlation was found between nerve branching and motoneuron survival under various experimental conditions: (1) dTC, but not muscimol, greatly increased branching; (2) the removal of PSA from NCAM partially reversed the effects of dTC on both branching and survival, indicating that branching is a critical variable influencing motoneuron survival; (3) muscimol, applied with dTC, prevented the effect of dTC on survival and motoneuron bursting and, to a large extent, its effect on branching. However, the central effects of dTC also appear to be important, because muscimol, which prevented motoneuron activity in the presence of dTC, also prevented the dTC-induced rescue of motoneurons.

Neurites and growth cones in the chick embryo. Enhanced tissue preservation and visualization of HRP-labeled subpopulations in serial 25-microns plastic sections cut on a rotary microtome.

Study of axonal guidance in developing vertebrates has been hindered by an inability to readily visualize individual growth cones, determine the neuronal population from which they originate, trace their trajectories, and discern their interactions with their embryonic environment. We report a method that combines plastic embedding and serial sectioning with horseradish peroxidase labeling of subpopulations of neurons in the chick embryo. This method labels individual neurites from the soma to the tip of the growth cones, allowing their trajectory to be inferred and their identity to be determined by the position of the somata. As sections are up to 25 micron thick, entire growth cones can often be visualized without laborious reconstruction. Tissue preservation is much better than with similar material embedded in paraffin. Sections are cut relatively quickly using a steel knife on a standard rotary microtome and are suitable for subsequent electron microscopy.

The acquisition of motoneuron subtype identity and motor circuit formation.

Experiments in chick embryos using classical transplantation techniques introduced by Viktor Hamburger are reviewed; these demonstrated that chick-limb innervating motoneurons become specified by extrinsic signals prior to axon outgrowth and that they selectively grow to appropriate muscles by actively responding to guidance cues within the limb. More recent experiments reveal that fast/slow and flexor/extensor subclasses of motoneurons are distinct by E4-5 and that they exhibit patterned spontaneous activity while still growing to their targets. These observations are then related to the combinatorial code of LIM transcription factor expression, which has been hypothesized to specify motoneuron subtypes.

Interspecies selective motoneuron projection patterns in chick-quail chimeras.

During normal development chick motoneurons have been shown to project selectively to appropriate muscles by responding to a series of cues, both specific and nonspecific, within the limb. We tested the ability of motoneurons from another avian species, the Japanese quail, to respond to these cues by transplanting chick limb buds onto quail embryos and quail limb buds onto chick embryos between stages 17 1/2 and 19. Feulgen staining, which distinguishes chick from quail cells on the basis of nuclear chromatin, revealed that all limb tissue, including muscle, was of donor origin, indicating that the migration of somite-derived muscle precursor cells had been completed by the time of transplantation. Normal quail motoneuron pools for most muscles were located in the same relative positions as homologous chick pools. In chick-quail chimeras we found that the motoneuron pools of one species selectively innervated the homologous muscles in the limb of opposite species with considerable precision. This was determined by defining the segmental innervation pattern of the muscles electrophysiologically and by retrogradely labeling motoneuron pools with HRP. Selective innervation was confirmed by using the functional activation patterns of the motoneuron pools as an additional means of identifying motoneurons. We conclude that any limb-derived cues required by motoneurons to project to their appropriate muscles must be similar in chick and quail and that the growth cones of both species must have similar detector systems for responding to these cues. Only 7 spinal segments were found to innervate the quail limb (versus 8 for the chick), resulting in an anterior shift in the spinal segments innervating several posterior quail muscles.(ABSTRACT TRUNCATED AT 250 WORDS)

Development of the major pathways for neurite outgrowth in the chick hindlimb.

To elucidate mechanisms that may control development of the gross anatomical nerve pattern, motoneuron outgrowth into the chick hindlimb was examined using orthograde labeling, scanning and transmission electron microscopy, and Alcian blue staining. Results show that growth cones are not guided by contact with oriented extracellular fibrils, aligned mesenchyme cells, the myotome, or the vasculature. Pathways are not delineated by cell-free space or channels of lower cell density; however, densely packed mesenchyme may form barriers that channel outgrowth. In addition, abundant mesenchymal cell death was seen at the nerve front. This cell death may provide space that encourages growth cone advancement. Pathways often lie along interfaces between areas that stain darkly and lightly with Alcian blue, which specifically stains glycosaminoglycans, and growth cones never penetrate areas that stain intensely, such as the pelvic girdle, which is known to be a barrier to outgrowth. Leading growth cones form specialized contacts with mesenchyme cells, but the predominant contacts are interneuronal. It is proposed that the anatomical pattern of outgrowth is determined by the distribution of preferred substrata, the most preferred substratum being other neurites. Further, neurites tend to prefer loose mesenchyme to dense mesenchyme or areas rich in glycosaminoglycans.

Specificity of early motoneuron growth cone outgrowth in the chick embryo.

During development, chick lumbosacral motoneurons have been reported to form precise topographic projections within the limb from the time of initial outgrowth. This observation implies, first, that motoneurons select the appropriate muscle nerve pathway and, second, that they restrict their ramification within the primary uncleaved muscle masses to appropriate regions. Several reports based on electrophysiology and orthograde horseradish peroxidase (HRP) labeling have shown muscle nerve pathway selection to be fairly precise. However, studies based on retrograde labeling with HRP have produced conflicting reports on the extent to which vertebrate motoneurons make projection errors. Since it is difficult to distinguish between true projection errors and HRP leakage when using retrograde labeling, we decided to assess the distribution of labeled growth cones in 25-micron serial plastic sections, following orthograde labeling of identifiable subpopulations of motoneurons during the period of initial axon outgrowth. Examination of a large number of muscle nerves revealed no segmentally inappropriate axons, confirming earlier reports that muscle nerve pathway selection is very accurate. In addition, we observed that growth cones take widely divergent trajectories into the same muscle nerve, suggesting that growth cones are responding independently to some specific environmental cue rather than being passively channeled at this point. The distribution of labeled growth cones within the muscle masses provided direct evidence that motoneurons did not at any time project to obviously inappropriate muscle regions.(ABSTRACT TRUNCATED AT 250 WORDS)

Pattern and specificity of axonal outgrowth following varying degrees of chick limb bud ablation.

Motoneurons grow into the chick hindlimb via consistent pathways, within which they make specific decisions leading to their correct targets. To determine which axonal guidance features dictate the position of the pathways and to examine the distribution of specific cues, we totally or partially ablated the early hindlimb bud and determined how the subsequent pattern of nerve outgrowth related to the distribution of tissue remnants. Our results suggest that local elements determine the gross anatomical pattern of outgrowth. First, determinants of individual pathways could be selectively removed without altering the pattern in other regions. Second, neurites were restricted to the plexus region at the base of the leg (within which, for unknown reasons, they proceeded posteriorly) unless distal permissive pathways or nearby target remnants were present. Finally, we found that the central region of the pelvic girdle, adjacent to the plexus region, determines the position where the major nerve trunks enter the leg. When gaps were introduced in this region of the girdle, nerves traversed the gaps and directly innervated adjacent muscle. The developing girdle is probably a nonpermissive environment for axon elongation, and axons enter the leg only where it is locally absent. Our results also support the concept that the specific cues that neurites use to reach their appropriate muscles are local. We find that neurites could make correct and specific decisions in the plexus region in the absence of all tissues distal to the pelvic girdle. This shows that the cues for these decisions are independent of the target and must reside in the local mesenchyme. In addition, when muscle remnants were present they were correctly innervated.(ABSTRACT TRUNCATED AT 250 WORDS)

Growth cone morphology and trajectory in the lumbosacral region of the chick embryo.

We quantitatively analyzed several features of orthogradely labeled peripheral growth cones in the lumbosacral region of the chick embryo. We compared motoneuron growth cones in regions where they appear to express specific directional preferences (the plexus region and regions where muscle nerves diverge from main nerve trunks), which we operationally defined as "decision regions," to motoneuron growth cones in other pathway regions (the spinal nerve, nerve trunk, and muscle nerve pathways) which we termed, for contrast, "non-decision region." We found that motoneuron growth cones are larger, more lamellepodial, and have more complex trajectories in decision regions. Sensory growth cone populations, which are thought to be dependent upon motoneurons for outgrowth (Landmesser, L., and M. Honig (1982) Soc. Neurosci. Abstr. 8: 929), do not enlarge or become more lamellepodial in motoneuron decision regions, suggesting that this local environment does not affect all species of growth cones equally and that the alterations in motoneuron growth cones in these regions may be relevant to their specific guidance. In addition, the resemblance between the sensory population and other closely fasciculating growth cones lends support to the suggestion that sensory neurons utilize motoneuron neurites as a substratum. We suggest that the convoluted trajectories, enlarged size, and more lamellepodial morphology of motoneuron growth cones in decision regions is either related directly to the presence of specific cues that guide motoneurons or to some aspect of this environment that allows them to respond to specific cues.

Cell death of lumbosacral motoneurons in chick, quail, and chick-quail chimera embryos: a test of the quantitative matching hypothesis of neuronal cell death.

The quantitative matching hypothesis of neuronal cell death was tested for the chick hindlimb by determining the relationship between myotube number at the onset of motoneuron cell death and the number of motoneurons that survive in chicks, quail, and chick-quail chimeras. Hindlimb buds, which differ in size between the 2 species, were exchanged at stages 16 1/2-19, myosin ATPase-stained myotubes in selected thigh muscles were counted during the cell death period (stages 30-34), and lumbosacral motoneurons were counted following the cell death period (stage 38). No quail motoneurons were rescued when quail cords innervated chick limbs. When chick cords innervated quail limbs, the number of surviving motoneurons was significantly decreased but not to quail values. We consider that this occurred because chicks develop more slowly than quail, and we found that transplanted chick limbs were developmentally younger than the contralateral quail limb at the onset of motoneuron cell death and contained fewer myotubes. Similarly, transplanted quail limbs contained more myotubes at the onset of cell death than normal stage 30 quail limbs. An excellent correlation was obtained during normal development of both species between the number of myotube clusters at the onset of cell death and the number of surviving motoneurons. This correlation was also observed for chick-quail chimeras, and when the data points were plotted for control chick, control quail, chick host-quail limb, and quail host-chick limb, the correlation coefficient was 0.996. This strongly suggests that some parameter closely related to myotube number limits the number of motoneurons that will survive. A proposal consistent with our observations is that motoneuron survival is dependent on the uptake of a myotube-derived trophic factor that can only be taken up at synaptic sites and that the number of such sites is limited and directly related to myotube number. In conclusion, our observations strongly support a quantitative-matching component in the process of neuronal cell death. However, since we were unable to rescue any neurons, we cannot exclude the possibility that some proportion of neurons normally dies for reasons other than peripheral competition.

Activation patterns of embryonic chick hind-limb muscles following blockade of activity and motoneurone cell death.

Motoneurone cell death and spontaneous embryonic motility were blocked in chick embryos by daily in ovo injections of d-tubocurarine from stage 28-36 (E5-10). Isolated spinal cord-hind-limb preparations were prepared from these embryos and movement sequences in response to electrical stimulation of the thoracic cord were assessed, after drug wash-out, by electromyogram (e.m.g.) or muscle-nerve recordings. In embryos in which complete blockade of lumbar motoneurone cell death was later confirmed histologically, flexor and extensor motoneurone pools were found to be activated in alternating bursts as occurs in control embryos. Thus the development of the basic cord circuits responsible for these patterns of motoneurone activation does not require motoneurone cell death. Partial blockade of motoneurone cell death by guanosine 3',5'-phosphate (cyclic GMP) was also without effect on muscle activation patterns. In ovo injection of d-tubocurarine or alpha-bungarotoxin in doses sufficient to block embryonic motility was found to have a direct effect on the spinal cord, preventing the patterned activation of motoneurone pools in alternating bursts. Cords removed from treated embryos behaved similarly to cords in which these drugs were applied acutely in the bath. Minor changes in muscle activation patterns that occurred with chronic drug treatment were also observed in acutely treated cords and appear to be a direct and persistent effect of the drugs on cord circuits. It is possible to conclude that cholinergic circuits within the chick lumbar cord play a role in the normal patterned activation of flexor and extensor motoneurone pools. Systemically applied drugs can have access to these circuits, indicating a need for caution when interpreting the results of drugs applied in this manner to developing embryos. We also conclude that neither the activation of motoneurones in patterned bursts, nor the afferent feed-back from the movements that result, are required to form the basic spinal cord circuits responsible for the activation of extensor and flexor motoneurone pools in alternating bursts.

The regulation of synaptogenesis during normal development and following activity blockade.

The mature neuromuscular junction is characterized by the tight spatial colocalization of synaptic vesicles and acetylcholine receptor (AChR) clusters. Although a large body of work exists on the interactions between motoneurons and myotubes leading to synaptogenesis in tissue culture, how the neuromuscular junction acquires its highly specialized structure in vivo is not well understood, particularly during the earliest period of synaptogenesis. In this study, the development of the neuromuscular synapse in chick hindlimb muscles was examined and quantified by simultaneously labeling the pre- and postsynaptic elements from the time the main nerve trunks leave the lumbosacral plexus region to enter the developing limb (St 24) through the end of the motoneuron cell death period (St 36). Based on these results, synaptogenesis can be divided into several distinct stages that are intimately connected to the innervation sequence described in a previous paper (Dahm and Landmesser, 1988). Briefly, as large nerve trunks approach the developing muscles and the first AChR clusters are induced to form on nearby myotubes, none of these initial receptor clusters are in direct contact with a nerve profile. The first appearance of nerve-contacted clusters (synapses) is coincident with the growth of large, unbranched nerve trunks into the muscles. The next step is initiated by the formation of small nerve side branches that grow out from the larger intramuscular nerve trunks to bring most axons and myotubes into contact for the first time. As side branches form, synapses appear around them, and non-nerve-contacted receptor clusters disappear from around the main intramuscular nerve trunks. The next step in synaptogenesis is the restriction of synaptic vesicle antigen to sites of synaptic contact. These early stages of synaptogenesis are also characterized by the growth of the presynaptic terminal to match the length of the postsynaptic receptor cluster. This study showed that AChR cluster formation during early in vivo neuromuscular development does not require close anatomical nerve contact, but that the presence of the nerves is necessary for AChR clusters to form. This suggests that the nerves normally induce AChR clustering via the release of a diffusible substance, a suggestion substantiated by the observation that AChR clusters do not form on aneural myotubes in vivo. In order to assess the role of synapse formation in the regulation of motoneuron number, synaptogenesis was quantitatively examined after chronic neuromuscular blockade, which prevents motoneuron cell death.(ABSTRACT TRUNCATED AT 400 WORDS)

Relationship of primary and secondary myogenesis to fiber type development in embryonic chick muscle.

The formation of fast and slow myotubes was investigated in embryonic chick muscle during primary and secondary myogenesis by immunocytochemistry for myosin heavy chain and Ca2(+)-ATPase. When antibodies to fast or slow isoforms of these two molecules were used to visualize myotubes in the posterior iliotibialis and iliofibularis muscles, one of the isoforms was observed in all primary and secondary myotubes until very late in development. In the case of myosin, the fast antibody stained virtually all myotubes until after stage 40, when fast myosin expression was lost in the slow myotubes of the iliofibularis. In the case of Ca2(+)-ATPase, the slow antibody also stained all myotubes until after stage 40, when staining was lost in secondary myotubes and in the fast primary myotubes of the posterior iliotibialis and the fast region of the iliofibularis. In contrast, the antibodies against slow muscle myosin heavy chain and fast muscle Ca2(+)-ATPase stained mutually exclusive populations of myotubes at all developmental stages investigated. During primary myogenesis, fast Ca2(+)-ATPase staining was restricted to the primary myotubes of the posterior iliotibialis and the fast region of the iliofibularis, whereas slow myosin heavy chain staining was confined to all of the primary myotubes of the slow region of the iliofibularis. During secondary myogenesis, the fast Ca2(+)-ATPase antibody stained nearly all secondary myotubes, while primaries in the slow region of the iliofibularis remained negative. Thus, in the slow region of the iliofibularis muscle, these two antibodies could be used in combination to distinguish primary and secondary myotubes. EM analysis of staining with the fast Ca2(+)-ATPase antibody confirmed that it recognizes only secondary myotubes in this region. This study establishes that antibodies to slow myosin heavy chain and fast Ca2(+)-ATPase are suitable markers for selective labeling of primary and secondary myotubes in the iliofibularis; these markers are used in the following article to describe and quantify the effects that chronic blockade of neuromuscular activity or denervation has on these populations of myotubes.