Differentiation of chick embryo myoblasts is transiently sensitive to functional denervation

Clonal analysis of myoblast differentiation has been used to assess effects of denervation on developing skeletal muscle: chick embryo legs denervated by spinal cord cautery yield reduced proportions of clonable myoblasts (P. H. Bonner, 1978, Develop. Biol., 66, 207–219). The present work examines the effects on clonable myoblasts of functional denervation by d-tubocurarine. Curare treatment during the third or fourth days of embryonic development had no effect on clonable myoblasts later in development, treatment during the fifth or sixth days resulted in reduced proportions of clonable myoblasts, and treatment during the eighth or ninth days again had no effect. Clonal analysis of treated and control embryo leg muscle cells was performed between Days 10 and 18. Embryos were also permanently denervated by spinal cord cautery late in the sixth day. These embryos showed no effect of denervation on clonable myoblast proportion. It is concluded that the differentiation of skeletal muscle myoblasts is affected by interference with normal nerve-muscle relationships only during a “window” of sensitivity and that this “window” extends approximately from Hamburger and Hamilton stage 27 to stage 30.     

Clonal analysis of vertebrate myogenesis. I. Early developmental events in the chick limb

Early developmental events occurring in the prospective muscle tissue region of chick embryo leg buds have been subjected to an in vitro clonal analysis. Colony-forming cells are present at stage 20 (72 hr incubation), but none of the colonies exhibit morphological signs of muscle differentiation. After an additional 8 hr of incubation (stage 21), approximately 10% of the colony-forming cells have acquired the capacity to form multinucleated cells in vitro, and the percentage of clonable myoblasts increases to a level of approximately 60% during the next 3 days of incubation. Clonal analysis of myoblast populations within regions of the developing limb have indicated that, between stages 21 and 27, the dorsal and ventral segments of the myogenic region contain appreciably more clonable muscle cells than the anterior and posterior segments. In addition, during stages 21 and 22 there is a 3-fold difference in muscle-colony-forming cells between the proximal and distal halves of the dorsal-ventral segments, as well as between the proximal and distal halves of the anterior-posterior segments. Thus at least two temporal and regional gradients—proximal to distal and medial to lateral—of clonable myoblast content can be delineated within the developing chick limb. In addition to changes in the proportions of muscle-colony-forming cells, the extent of multinuclearity within individual muscle colonies increases with the developmental age of the embryo from which the clonable myoblasts are derived. The progressive changes in the relative proportions of muscle-colony-forming cells and in clonal morphology are discussed in terms of their possible cell lineage implications.     

Nerve-dependent changes in clonable myoblast populations

Between the 3rd and 12th days of development at least four distinct classes of clonable myoblast are present in chick embryo leg skeletal muscle (N. K. White, P. H. Bonner, D. R. Nelson, and S. D. Hauschka, 1975, Develop. Biol.44, 346–361). In the present study, the behavior of each class has been examined quantitatively by clonal growth and differentiation of cells derived from denervated and normal embryos. Embryos functionally denervated by cauterization of the posterior spinal cord or by injection of the neuromuscular blocking agent d-tubocurarine exhibit changes in the two broad categories of clonable myoblast—fresh medium-sufficient (FMS) and conditioned medium-requiring (CMR) muscle cells. Clonal analysis of cells derived from leg muscle tissue of 10- to 12-day-old embryos denervated early in development (Days 3 to 6) has shown that the proportion of FMS clonable myoblasts is reduced to about 60% of the level found in normally innervated leg muscle. The CMR class is composed of three subclasses: CMR-I, CMR-II, and CMR-III (White et al., 1975). Clonal analysis of cells from denervated muscle has shown that, while the total CMR clone proportion is unchanged, the three subclasses are rearranged. The proportions of CMR-I and CMR-II muscle clones are greatly increased and the CMR-III subclass is severely reduced or absent when compared to clones derived from normally innervated leg muscle tissue.     

Clonal analysis of vertebrate myogenesis. 3. Developmental changes in the muscle-colony-forming cells of the human fetal limb

The cell lineage of developing human limb muscle has been investigated by means of an in vitro clonal assay. Single cells capable of forming differentiated muscle colonies have been detected within the prospective leg muscle region as early as the 36th day of human development (Streeter's Horizon XVI). At this stage clonable myoblasts account for 14% of the total colony-forming cells. The relative proportion of clonable myoblasts increases rapidly during subsequent fetal development and attains a plateau level of approximately 90% by the 100th day of development. The 90% plateau level persists at least until day 172. By correlating the percent muscle colony differentiation with clonal plating efficiency and with the number of single cells derived from the total limb muscle region of fetuses of different ages, an estimate of the actual number of clonable myoblasts within the developing limb musculature is obtained.Sequential changes within the muscle cell lineage have been further dissected by the temporal analysis of age-dependent medium effects on muscle colony differentiation. The analysis indicates that clonable myoblasts derived from early fetuses are sensitive to medium conditions to which older muscle-colony-forming cells are relatively insensitive. In addition, fusing and nonfusing colonies have been classified into recognizable morphological types whose relative proportions are observed to change during limb development. The results are correlated with human limb morphogenesis and skeletal muscle histogenesis and an operational model of muscle cell lineage is proposed.     

A comparative study of myogenic cell invasion of the avian wing and leg bud.

The borders of myogenic cell invasion of avian wing and leg buds were determined using the interspecific grafting technique between quail and chick embryos. Distal parts of quail limb buds were grafted ectopically into the coelomic cavity of chick embryos. The presence or absence of skeletal muscle was investigated in histological sections of the reincubated grafts. A comparison between the borders of myogenic cell invasion of the wing and leg buds showed that the differences in the position of the distal most muscles in the adult avian limbs could be a consequence of the cranio-caudal sequence of development.     

Spatial analysis of limb bud myogenesis: A proximodistal gradient of muscle colony-forming cells in chick embryo leg buds

The regional distribution of myogenic cells in developing chick leg buds has been investigated using an in vitro clonal assay. Leg buds were embedded in gelatin and sectioned at intervals of 100–300 μm utilizing a vibratome, and cells dissected from prospective myogenic areas were analyzed for their ability to form colonies containing multinucleated myotubes. The results show that muscle colony-forming (MCF) cells from stage 23 ( to 4-day incubation) are exclusively of the early morphological type, and are found in the proximal two-thirds of the bud. Late-type MCF cells are first obtained from the proximal sections of stage 24–25 (4- to day) buds; in succeeding stages (26–29), late MCF cells supercede the early MCF cell type in the proximal regions, and extend into progressively more distal sections in a graded fashion. Results from sequential sections suggest that early and late MCF cells are located within the same muscle groups. The proportion of late MCF cells continues to increase throughout this period, until by stage 31 (7 days) only the most distal myogenic regions (the toe muscle regions) have an appreciable proportion of early MCF cells. Clonal plating efficiencies increase throughout the period of analysis, and by stage 31 precisely dissected myogenic regions yield plating efficiencies as high as 36% with greater than 95% of these colonies differentiating as muscle.     

Position-related capacity for differentiation of limb mesenchyme in cell culture.

A quantitative comparison (i.e., number of cartilage nodules) of cartilage differentiation was made between micromass cell cultures prepared with cells from different locations (core vs periphery) within prechondrogenic chick wing buds. Wing bud core cells in micromass culture exhibit a greater developmental bias toward cartilage differentiation than periphery cells from the same limbs. In addition, myogenic cells appear more frequently in cultures prepared from wing bud periphery than in those prepared from core tissue. Therefore a stage 23–24 wing bud is not a homogeneous population of multipotential mesenchymal cells. Instead, a stage 23–24 wing bud contains two classes of cells, each characterized by a bias for either cartilage or muscle differentiation, and a third class of uncharacterized mesenchymal cells.     

Changes in the pericellular matrix during differentiation of limb bud mesoderm

Mesodermal cells in the developing chick embryo limb bud appear morphologically homogeneous until stage 21. At stage 22 the prechondrogenic and premyogenic areas begin to condense, culminating in the appearance of cartilage and muscle by stage 25-26. We have examined changes in the hyaluronate-dependent pericellular matrices elaborated by mesodermal cells of the limb bud from different developmental stages and the corresponding changes in production of cell surface-associated and secreted glycosaminoglycans. When placed in culture, most early mesodermal cells (stage 17 lateral plate and stage 19 limb bud) exhibited pericellular coats as visualized by the exclusion of particles. These coats were removed by treatment of the cultures with Streptomyces hyaluronidase. Cells from stage 20-21 limb buds (precondensation) had smaller coats, whereas cells derived from stage 22, 24, and 26 limb buds (condensed chondrogenic and myogenic regions) lacked coats. However, coats were reformed during subsequent cytodifferentiation of chondrocytes; chondrocytes from stage 28 and 30 limb buds, and more mature chondrocytes from stage 38 tibiae, had pericellular coats. Thus, cytodifferentiation of cartilage is accompanied by extensive intercellular matrix accumulation in vivo and reacquisition of pericellular coats in vitro. Although their structure was still dependent on hyaluronate, chondrocyte coats were associated with increased proteoglycan content compared to the coats of early mesodermal cells. The amount of incorporation of [3H]acetate into cell surface hyaluronate remained relatively constant from stages 17 to 38, whereas in the medium compartment, incorporation into hyaluronate was more than 4-fold greater by stage 17 and 19 mesodermal cells than by cells from stages between 20 and 38. However, there was a progressive increase in incorporation into cell surface and medium chondroitin sulfate throughout these developmental stages. Thus, at the time of cellular condensation in the limb bud in vivo, we have observed a reduction in size of hyaluronate-dependent pericellular coats and a dramatic change in the relative proportion of hyaluronate and chondroitin sulfate produced by the mesodermal cells in vitro.     

Factors released by ciliary neurons and spinal cord explants induce acetylcholine receptor mRNA expression in cultured muscle cells

The nuclei of cultured noninnervated muscle cells are heterogeneous with respect to production of mRNA for the nicotinic acetylcholine receptor (AChR). Some nuclei actively express AChR mRNA while others have a low level of activity or are inactive. To determine if innervation, or a factor released by neurons, influences nuclear expression of AChR mRNA, we examined mRNA at a single cell level via in situ hybridization and autoradiography with an alpha-subunit AChR genomic probe. Four days after plating, we co-cultured chicken primary muscle cells with spinal cord explants, ciliary neurons, or dorsal root ganglia (DRG) cells. In situ hybridization of the spinal-cord and muscle-cell co-cultures with the AChR alpha-subunit probe revealed a high density of silver grains on muscle cells, which were within two explant diameters of the spinal cord explant, and a graded decrease in silver grain density as the distance from the explant increased, as well as the appearance of a strikingly nonhomogenous distribution of active and inactive muscle cell nuclei. When ciliary neurons were uniformly distributed over the muscle cells, a high level of AChR mRNA was induced, but no gradients appeared. Neither an increased mRNA level nor a gradient was observed when DRG cells were co-cultured with muscle cells. When ciliary neurons are cultured within Costar permeable inserts, which prevent any contact between the neurons and the underlying muscle cells, AChR messenger RNA is still induced, showing that diffusible factors are responsible. Our results indicate that molecules released by cholinergic neurons regulate the expression of AChR mRNA in the myotubes and raise the possibility that AChR expression depends on both neuronal signals and on intracellular information from the muscle cell.     

Reinnervation of adult muscle in organ culture restores tetrodotoxin sensitivity in the absence of electrical activity.

Strips of denervated adult mouse diaphragm muscle maintained in organ culture were reinnervated by nerve processes growing out from explants of embryonic mouse spinal cord. In vivo, following denervation, the action potential loses its sensitivity to tetrodotoxin; this sensitivity is regained upon reinnervation. Similarly, action potentials in cultured muscle fibres were insensitive to tetrodotoxin, and sensitivity was restored in muscle fibres that became reinnervated in vitro. Tetrodotoxin sensitivity was also restored in cultured muscle fibres reinnervated in the continuous presence of d-tubocurarine, but it was not induced by 4 days of direct electrical stimulation of noninnervated muscles. We conclude that developing nerve terminals can exert a trophic action on adult muscle fibres that is independent of electrical activity in the muscle.     

Expression of muscle-gene-specific isozymes of phosphorylase and creatine kinase in innervated cultured human muscle

Isozymes of creatine kinase and glycogen phosphorylase are excellent markers of skeletal muscle maturation. In adult innervated muscle only the muscle-gene-specific isozymes are present, whereas aneurally cultured human muscle has predominantly the fetal pattern of isozymes. We have studied the isozyme pattern of human muscle cultured in monolayer and innervated by rat embryo spinal cord explants for 20-42 d. In this culture system, large groups of innervated muscle fibers close to the ventral part of the spinal cord explant continuously contracted. The contractions were reversibly blocked by 1 mM d-tubocurarine. In those innervated fibers, the total activity and the muscle-gene-specific isozymes of both enzymes increased significantly. The amount of muscle-gene-specific isozymes directly correlated with the duration of innervation. Control noninnervated muscle fibers from the same dishes as the innervated fibers remained biochemically immature. This study demonstrated that de novo innervation of human muscle cultured in monolayer exerts a time-related maturational influence that is not mediated by a diffusable neural factor.     

Ethanol influences on the chick embryo spinal cord motor system. II. Effects of neuromuscular blockade and period of exposure

The study described below was performed as a continuation of a previous study in which we found reduced motoneuron number in lumbar spinal cord of the chick embryo following chronic ethanol administration from embryonic day 4 (E4) to E11. We sought to determine whether this reduction was due to primary ethanol toxicity or to enhancement of naturally occurring cell death (NOCD) and to determine whether administration of ethanol at a later period of development could also reduce motoneuron number. Earlier studies have shown that curare suspends NOCD in the chick embryo. By administering both ethanol and curare to these embryos from E4 to E11 and examining the lumbar spinal cord on E12, we determined that ethanol was directly toxic to motoneurons and reduced motoneuron number in the absence of NOCD. By administering ethanol from E10 to E15 and examining the lumbar spinal cord on E16, we determined that ethanol can reduce motoneuron number without altering spinal cord length during more than one stage of chick embryo development, and that ethanol toxicity is not dependent on NOCD. In addition, we demonstrated that ethanol does not affect the neurotrophic content of chick muscle when it is administered from E10 to E15. © 1997 John Wiley & Sons, Inc. J Neurobiol 32 : 684–694, 1997     

Repair of spinal cord transection and its effects on muscle mass and myosin heavy chain isoform phenotype.

A number of significant advances have been developed for treating spinal cord injury during the past two decades. The combination of peripheral nerve grafts and acidic fibroblast growth factor (hereafter referred to as PNG) has been shown to partially restore hindlimb function. However, very little is known about the effects of such treatments in restoring normal muscle phenotype. The primary goal of the current study was to test the hypothesis that PNG would completely or partially restore 1) muscle mass and muscle fiber cross-sectional area and 2) the slow myosin heavy chain phenotype of the soleus muscle. To test this hypothesis, we assigned female Sprague-Dawley rats to three groups: 1) sham control, 2) spinal cord transection (Tx), and 3) spinal cord transection plus PNG (Tx+PNG). Six months following spinal cord transection, the open-field test was performed to assess locomotor function, and then the soleus muscles were harvested and analyzed. SDS-PAGE for single muscle fiber was used to evaluate the myosin heavy chain (MHC) isoform expression pattern following the injury and treatment. Immunohistochemistry was used to identify serotonin (5-HT) fibers in the spinal cord. Compared with the Tx group, the Tx+PNG group showed 1) significantly improved Basso, Beattie, and Bresnahan scores (hindlimb locomotion test), 2) less muscle atrophy, 3) a higher percentage of slow type I fibers, and 4) 5-HT fibers distal to the lesion site. We conclude that the combined treatment of PNG is partially effective in restoring the muscle mass and slow phenotype of the soleus muscle in a T-8 spinal cord-transected rat model.     

Development of the myotomal neuromuscular junction in Xenopus laevis: An electrophysiological and fine-structural study

The normal development of the myotomal neuromuscular junction in Xenopus embryos and tadpoles was investigated electrophysiologically as well as electron microscopically. Spontaneous potentials, considered to be miniature end-plate potentials (MEPPs), were detected by intracellular recording as early as stage 21 and by stage 24 they were observed in every embryo tested. Like MEPPS at later stages they were blocked by curare but not by tetrodotoxin. End-plate potentials (EPPs), subject to block by tetrodotoxin, were evoked by electrical stimulation of the spinal cord in embryos as young as stage 24 and occurred spontaneously as early as stage 22. The durations of MEPPs and EPPs were initially relatively long. Focal external recordings revealed an eightfold decrease in duration during the course of development. Nerve processes emerged from the spinal cord and contacted developing muscle cells as early as stage 21, but junctional specializations were not apparent and vesicles were rare even in stage 24 embryos. During the next 24 hr, between stages 25 and 36, vesicles increased in number and became localized toward the junctional surface of the nerve ending. Basement lamina developed in the cleft and postjunctional ridges and densities were observed. Individual muscle cells also became contacted by several nerve processes. By stages 48–52 there were fewer contacts on individual muscle cells and Schwann cell processes partially covered the nerve endings. Gap junctions were observed between the muscle cells throughout development but occurred less frequently at the later stages. It is concluded that by the time they reach the muscle cells, or very shortly thereafter, at least some of the growing nerve processes can release transmitter, and some of the muscle cells are sufficiently sensitive to acetylcholine in the region of contact to respond with millivolt depolarizations. These earliest functional contacts, however, are morphologically undifferentiated.     

Immune cells exploit a neural circuit to enter the CNS

Multiple sclerosis (MS) is associated with the appearance of autoreactive T?cells in the central nervous system. Using a mouse model of MS, Arima et?al. now show that this attack begins at a specific spinal cord location. T?cell entry into the CNS is regulated by a reflex neural circuit originating from leg muscle contractions.     

Interactions between spinal cord stimulation and activity blockade in the regulation of synaptogenesis and motoneuron survival in the chick embryo

The present study investigated the effects of spinal cord stimulation, neuromuscular blockade, or a combination of the two on neuromuscular development both during and after the period of naturally occurring motoneuron death in the chick embryo. Electrical stimulation of the spinal cord was without effect on motoneuron survival, synaptogenesis, or muscle properties. By contrast, activity blockade rescued motoneurons from cell death and altered synaptogenesis. A combination of spinal cord stimulation and activity blockade resulted in a marked increase in motoneuron death, and also altered synaptogenesis similar to that seen with activity blockade alone. Perturbation of normal nerve–muscle interactions by activity blockade may increase the vulnerability of developing motoneurons to excessive excitatory afferent input (spinal cord stimulation) resulting in excitotoxic-induced cell death. © 1993 John Wiley & Sons, Inc.     

Effect of Microcirculation Reserves on Spinal Cord Recovery after Injury

Local capillary blood flow was studied in and around the spinal cord compression focus in humans with spinal injuries in the acute and early periods of the trauma. The effect of the capillary blood flow in the perimedullary network in the region of spinal cord compression on the degree of motor and sensory disturbances was analyzed. The relationship of the increase in capillary blood flow after spinal cord decompression with increases in leg muscle strength and pain threshold was determined.     

Spatial analysis of limb bud myogenesis: Elaboration of the proximodistal gradient of myoblasts requires the continuing presence of apical ectodermal ridge

Myogenic tissue from embryonic chick wing and leg buds is composed of several subpopulations of myoblasts. These clonally distinct subpopulations first appear at different developmental stages, and are distributed differently along the proximo-distal axis of the buds, giving the appearance of a gradient of myoblast cell types. This myoblast distribution pattern has been utilized to investigate the dependence of muscle tissue outgrowth and development on the presence of the apical ectodermal ridge (AER). Wing buds which have had the AER removed at stages 17–18 (2 days) subsequently develop normal proximal regions, but fail to elaborate skeletal structures distal to the humerus. The myoblast pattern of operated buds is also normal proximally, but distal portions of the pattern are not observed. Removal of the AER at stage 20 (3 days) results in buds which develop slightly more distal skeletal structures and the coinciding portions of the myoblast pattern, but in which the more distal portions of the normal myoblast gradient are truncated. These data suggest that elaboration of the myogenic pattern in early limb buds is dependent on the continuing presence of the AER, and that early removal of the AER leads to the subsequent cessation of myoblast pattern specification.     

Time-related changes of motor unit properties in the rat medial gastrocnemius muscle after spinal cord injury. I. Effects of total spinal cord transection

The contractile properties of motor units (MUs) were electrophysiologically investigated in the medial gastrocnemius (MG) muscle in 17 Wistar three-month-old female rats: 14, 30, 90 and 180 days after the total transection of the thoracic spinal cord and compared to those in intact (control) rats. A sag phenomenon, regularly observed in unfused tetani of fast units in intact animals at 40 Hz stimulation, almost completely disappeared in spinal rats. Therefore, the MUs of intact and spinal rats were classified as fast or slow types basing on 20 Hz tetanus index, the value of which was lower or equal 2.0 for fast and higher than 2.0 for slow MUs. The MUs composition of MG muscle changed with time after the spinal cord transection: an increasing proportion of fast fatigable (FF) units starting one month after injury and a disappearance of slow (S) units within the three months were observed. In all MUs investigated the twitch contraction and half-relaxation time were significantly prolonged after injury (p < 0.01, Mann–Whitney U-test). Moreover, a decrease of the fatigue index for fast resistant (FR) and slow MUs was observed in subsequent groups of spinal rats. No significant changes were found between twitch forces in all MU types of spinal animals (p > 0.05). However, due to a decrease of the maximal tetanic force, a significant rise of the twitch-to-tetanus ratio of all MUs in spinal rats was detected (p < 0.01). The considerable reduction of ability to potentiate the force was noticed for fast, especially FF type MUs. In conclusion, the spinal cord transection leads to changes in the proportion of the three MU types in rat MG muscle. The majority of changes in MUs’ contractile properties were developed progressively with time after the spinal cord injury. However, the most intensive alterations of twitch-time parameters were observed in rats one month after the transection.