Acetylcholine receptor aggregation parallels the deposition of a basal lamina proteoglycan during development of the neuromuscular junction

To determine the time course of synaptic differentiation, we made successive observations on identified, nerve-contacted muscle cells developing in culture. The cultures had either been stained with fluorescent alpha-bungarotoxin, or were maintained in the presence of a fluorescent monoclonal antibody. These probes are directed at acetylcholine receptors (AChR) and a basal lamina proteoglycan, substances that show nearly congruent surface organizations at the adult neuromuscular junction. In other experiments individual muscle cells developing in culture were selected at different stages of AChR accumulation and examined in the electron microscope after serial sectioning along the entire path of nerve-muscle contact. The results indicate that the nerve-induced formation of AChR aggregates and adjacent plaques of proteoglycan is closely coupled throughout early stages of synapse formation. Developing junctional accumulations of AChR and proteoglycan appeared and grew progressively, throughout a perineural zone that extended along the muscle surface for several micrometers on either side of the nerve process. Unlike junctional AChR accumulations, which disappeared within a day of denervation, both junctional and extrajunctional proteoglycan deposits were stable in size and morphology. Junctional proteoglycan deposits appeared to correspond to discrete ultrastructural plaques of basal lamina, which were initially separated by broad expanses of lamina-free muscle surface. The extent of this basal lamina, and a corresponding thickening of the postsynaptic membrane, also increased during the accumulation of AChR and proteoglycan along the path of nerve contact. Presynaptic differentiation of synaptic vesicle clusters became detectable at the developing neuromuscular junction only after the formation of postsynaptic plaques containing both AChR and proteoglycan. It is concluded that motor nerves induce a gradual formation and growth of AChR aggregates and stable basal lamina proteoglycan deposits on the muscle surface during development of the neuromuscular junction.     

DEVELOPMENT OF THE NEUROMUSCULAR JUNCTION : I. Cytological and Cytochemical Studies on the Neuromuscular Junction of Differentiating Muscle in the Regenerating Limb of the Newt Triturus

Development of the neuromuscular junction on differentiating muscle was investigated in the regenerating limb of the newt Triturus. Motor end-plate formation begins when vesicle-filled axon terminations approach differentiating muscle cells that have reached the stage of a multinucleate cell containing myofibrils. Slight ridges or elevations occur on the muscle surface, and there is an increase in density of the cytoplasm immediately beneath the plasma membrane of the elevation. The axon becomes more closely approximated to the muscle cell and comes to lie in a shallow depression or gutter on the surface of the muscle. The surface ridges increase in length and constrict at their bases to form junctional folds. In the axon terminal, focal accumulations of vesicles are found where the axon contour projects slightly opposite the secondary synaptic clefts. Cholinesterase activity in the developing junctions was demonstrated by the thiolacetic acid-lead nitrate method. Enzymatic activity is not found on intercellular nerve fibers or the muscle surface prior to close approximation of axon endings and muscle. Eserine- and DFP-sensitive activity appears concurrently with morphological differentiation. Activity occurs in membranous tubulovesicles in the sarcoplasm subjacent to the neuromuscular junction and in association with the sarcolemma. The largest reaction deposits occur at the tips of the emerging junctional folds. Smaller and less numerous localizations occur on the axon membrane and within the axoplasm. It is concluded from these studies that the nerve endings have an inductive effect on both the morphological and chemical specializations of the neuromuscular junction.     

Effects of vinblastine and colchicine on the postsynaptic membrane at the frog neuromuscular junction

The possible effects of the alkaloids vinblastine and colchicine on the postsynaptic membrane of the frog neuromuscular junction were investigated using voltage-clamp techniques. Concentrations of vinblastine and colchicine which had been shown to exert no effect on the amplitude and duration of miniature endplate currents (MEPC) and the current-voltage relationship of low-quantal endplate currents (EPC) together with the coefficient of voltage-dependent EPC decay did produce a considerable rise in the amplitude of response to iontophoretically applied acetylcholine (ACh). In addition, vinblastine and colchicine accelerate MEPC and EPC during acetylcholine esterase inhibition while further depressing the amplitude of multi-quantal EPC succeeding at the rate of 10 Hz as well as response to regular (5–10 Hz) application of ACh from a micropipet. The dosage-frequency effects of vinblastine and colchicine on the postsynaptic membrane (as described) are presumed to be unconnected with the action of these agents on muscle fiber cytoskeleton but the results of accelerated desensitization of cholinoreceptors.S. V. Kurashov Medical Institute, Kazan. Translated from Neirofiziologiya, Vol. 20, No. 1, pp. 75–81, January–February, 1988.     

Morphological differences between excitatory and inhibitory nerve terminals in cockroach coxal muscles

Two morphologically distinct types of neuromuscular junction on the coxal leg muscles of the cockroach, Periplaneta americana, which have been physiologically described as innervated by fast, slow and inhibitory nerve fibers, have been found. In one type of neuromuscular junction the axon terminal contains many round clear synaptic vesicles and contacts several sarcoplasmic extensions from the muscle fiber. The muscle processes adhere to the axon terminal for a short distance (short contact or SC type). The axon terminal of the other type of neuromuscular junction directly contacts the muscle fiber and no extensions of the muscle fiber are formed. The contact region is comparatively long (long contact or LC type). The nerve terminal contains many polymorphic synaptic vesicles. From a correlation of the present morphological findings and the previous physiological results, it may be suggested that the SC type of nerve terminal represents both fast and slow nerve terminals and the inhibitory terminal is of the LC type.     

Intense ultraterminal sprouting from motor nerves and ultrastructural aspects of the neuromuscular junction and non-junctional sarcolemma of the soleus (slow-twitch) muscle in motor endplate disease in the mouse

Motor end-plate disease (med) in the mouse is an hereditary defect of the neuromuscular system, with partial functional denervation and muscle inactivity in late stages of the disease. Motor end-plate disease is characterized by an intense ultraterminal sprouting of the motor nerves from swollen nerve terminal branches in the soleus muscle. At the ultrastructural level, the neuromuscular junctions extend to very wide territories, often outside the original motor end-plate, in regions where the nerve sprouts are in simple apposition to the muscle fiber, with no secondary synaptic folds. The nerve terminals are rich in neurofilaments and poor in synaptic vesicles.Freeze fracture analysis of the pre-synaptic and post-synaptic membrane specializations fails to reveal any important structural alteration which could suggest a defect in acetylcholine release or in muscle membrane excitability. However, the non-junctional sarcolemmal specializations (the so-called ‘square arrays’) arc found with a frequency slightly higher than in normal muscle.The nerve abnormalities at the neuromuscular junction may be either a consequence of muscle inactivity or the morphological expression of some primary nerve abnormality. Further studies of the soleus muscle at early stages of the disease may provide evidence in favor of either possibility.     

DEVELOPMENT OF THE NEUROMUSCULAR JUNCTION : II. Cytological and Cytochemical Studies on the Neuromuscular Junction of Dedifferentiating Muscle in the Regenerating Limb of the Newt Triturus

Following amputation of the limb of the newt, Triturus viridescens, muscle fibers dedifferentiate giving rise to mesenchymal cells. The earliest changes detected in neuromuscular junctions of dedifferentiating muscle fibers are the appearance of a few vacuoles and decrease in density of the terminal axoplasm. Later, synaptic vesicles become tightly clustered in the axon termination, and their content appears denser than normal. Then, vesicles diminish in number until few are seen in the ending. While these changes are occurring, the area of contact of nerve with muscle becomes smaller. Junctional folds persist only where the nerve maintains contact with muscle, but these are shorter than normal and appear as slight ridges on the muscle surface. Subsequently, the nerve withdraws from the muscle cell and is completely invested by Schwann cell cytoplasm, and all traces of junctional folds are lost at the former region of contact. Cholinesterase activity was localized with the thiolacetic acid-lead nitrate method. Even before marked morphological changes occur in the junction, DFP- and physostigmine-sensitive activity in the cleft between nerve and muscle is decreased in intensity. Activity continues to decrease as the area of nerve-muscle contact diminishes and junctional folds disappear. When the nerve has withdrawn from the muscle surface, only a few small deposits of lead are left in the intervening region. These results show that as muscle becomes less specialized during dedifferentiation, the neuromuscular junction also loses the cytological and cytochemical specializations associated with synaptic function.     

Nonquantal acetylcholine release from motor nerve endings and denervation changes in rat muscle fiber membranes after axonal transport blockade

Microelectrode experiments on the rat diaphragm showed that application of colchicine, which disturbs axonal transport, to the motor nerve leads after 5 days to a decrease in resting potential and an increase in input resistance of the electrogenic membrane, disappearance of differences of input resistance between the postsynaptic and extrasynaptic membranes, the appearance of extrasynaptic sensitivity to acetylcholine, and the appearance of anode-break action potentials resistant to tetrodotoxin. Similar changes develop in the muscle membrane after division of the motor nerve. Application of colchicine to the nerve, unlike its division, does not cause cessation of contractile activity of the muscle or disturbance of quantal and reduction of nonquantal acetylcholine secretion in motor nerve endings, as reflected in the degree of hyperpolarization of the postsynaptic membrane (H effect) in response to the action of D-tubocurarine chloride on the muscle after inhibition of acetylcholinesterase. The results confirmed the view that neurotrophic control of the mammalian muscle fiber membrane is effected mainly by means of substances carried to the muscle by axonal transport. Synaptic acetylcholine, secreted from nerve endings in nonquantal form, does not play a leading role in neurotrophic control of the muscle membrane.S. V. Kurashov Medical Institute, Ministry of Health of the RSFSR, Kazan'. Translated from Neirofiziologiya, Vol. 16, No. 2, pp. 231–238, March–April, 1984.     

Receptors to agglutinin fromDolichus biflorus (DBA) at the synaptic basal lamina of rat neuromuscular junction

Summary The binding of agglutinin fromDolichus biflorus (DBA) and other lectins (Concanavalin A, agglutinin from wheat germ and lectin fromBandeiraea simplicifolid) to synaptic and extrasynaptic portions of the basal lamina of muscle fibers, was studied with histochemical methods. In rat muscle, DBA-binding is specifically detected at the basal lamina of neuromuscular junction. However, long-term (6 months) denervated end-plate in adult rat muscle failed to bind DBA. During normal development, synaptic DBA receptors appear later than acetylcholine receptors or acetylcholinesterase at the rat neuromuscular junction. Generalized DBA-binding to motor end-plates is first visualized in 3-day-old rats, but section of sciatic nerve in 1-day-old rats prevents the appearence of synaptic DBA-binding on the leg end-plates. It is suggested, therefore, that the synaptic DBA receptors could be related to the postnatal stabilization of rat neuromuscular synapses.     

Aggregates of acetylcholine receptors are associated with plaques of a basal lamina heparan sulfate proteoglycan on the surface of skeletal muscle fibers

Hybridoma techniques have been used to generate monoclonal antibodies to an antigen concentrated in the basal lamina at the Xenopus laevis neuromuscular junction. The antibodies selectively precipitate a high molecular weight heparan sulfate proteoglycan from conditioned medium of muscle cultures grown in the presence of [35S]methionine or [35S]sulfate. Electron microscope autoradiography of adult X. laevis muscle fibers exposed to 125I-labeled antibody confirms that the antigen is localized within the basal lamina of skeletal muscle fibers and is concentrated at least fivefold within the specialized basal lamina at the neuromuscular junction. Fluorescence immunocytochemical experiments suggest that a similar proteoglycan is also present in other basement membranes, including those associated with blood vessels, myelinated axons, nerve sheath, and notochord. During development in culture, the surface of embryonic muscle cells displays a conspicuously non-uniform distribution of this basal lamina proteoglycan, consisting of large areas with a low antigen site-density and a variety of discrete plaques and fibrils. Clusters of acetylcholine receptors that form on muscle cells cultured without nerve are invariably associated with adjacent, congruent plaques containing basal lamina proteoglycan. This is also true for clusters of junctional receptors formed during synaptogenesis in vitro. This correlation indicates that the spatial organization of receptor and proteoglycan is coordinately regulated, and suggests that interactions between these two species may contribute to the localization of acetylcholine receptors at the neuromuscular junction.     

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.     

Effects of berberine,glaucine, stephaglabrine,and sanguirythrine on neuromuscular transmission

The effects of certain alkaloid (glaucine, stephaglabrine, and sanguirythrine) on parameters of neuromuscular transmission follow a complex pattern and are thought likely to operate via two or more different mechanisms. These alkaloids, in common with berberine, reduced the amplitude of miniature potentials at the frog neuromuscular junction. All four concentrations reduced and raised miniature potential rate at low and high concentrations respectively — a very marked action in the case of sanguirythrine, producing virtually a 100-fold increase, probably due to its uncoupling effect on oxidative phosphorylation at the mitochondria of the nerve endings. Sanguirythrine and stephaglabrine both gave rise to repeated muscular contraction which matches their anticholinesterase activity. High glaucine concentrations also induced contraction of the muscles.Institute for Hydrobiontic Substance Research, Soviet Ministry of Health, Moscow. Translated from Neirofiziologiya, Vol. 23, No. 2, pp. 131–135, March–April, 1991.     

OBSERVATIONS ON THE FINE STRUCTURE AND CYTOCHEMISTRY OF MOUSE AND HUMAN INTERCOSTAL NEUROMUSCULAR JUNCTIONS

The fine structure of the mouse and human intercostal muscle neuromuscular junction was studied after brief fixation in a new formol-sucrose fixative. This primary formalin fixation was followed by brief postosmication in buffered 1 per cent osmium tetroxide. Muscle blocks were embedded in methacrylate or Epon 812 epoxy resin. Marked similarities between mouse and human motor end-plates were observed. Neuromuscular junctions from both mouse and human intercostal muscle showed synaptic vesicles, primary and secondary synaptic clefts, and layered differentiation of the amorphous surface material (ASM) present on the surface of the Schwann cell plasma membrane and on the muscle surface membrane in the region of the neuromuscular junction. An attempt to stain the ASM with lead was unsuccessful. Observations on thick and thin plastic-embedded sections stained by PAS after diastase digestion showed that the ASM within the subneural apparatus is PAS positive. Alcian blue stained the endoneurium and perineurium of peripheral nerve bundles and portions of the end-plates. The similarity of the PAS-positive ASM to other basement membranes described in other sites is discussed and its possible physiologic significance within the subsynaptic apparatus is considered.     

Antibodies that bind specifically to synaptic sites on muscle fiber basal lamina

Basal lamina (BL) ensheathes each skeletal muscle fiber and passes through the synaptic cleft at the neuromuscular junction. Synaptic portions of the BL are known to play important roles in the formation, function, and maintenance of the neuromuscular junction. Here we demonstrate molecular differences between synaptic and extrasynaptic BL. We obtained antisera to immunogens that might be derived from or share determinants with muscle fiber BL, and used immunohistochemical techniques to study the binding of antibodies to rat skeletal muscle. Four antisera contained antibodies that distinguished synaptic from extrasynaptic portions of the muscle fiber's surface. They were anti- anterior lens capsule, anti-acetylcholinesterase, anti-lens capsule collagen, and anti-muscle basement membrane collagen; the last two sera were selective only after antibodies binding to extrasynaptic areas had been removed by adsorption with connective tissue from endplate-free regions of muscle. Synaptic antigens revealed by each of the four sera were present on the external cell surface and persisted after removal of nerve terminal. Schwann cell, and postsynaptic plasma membrane. Thus, the antigens are contained in or connected to BL of the synaptic cleft. Details of staining patterns, differential susceptibility of antigens to proteolysis, and adsorption experiments showed that the antibodies define at least three different determinants that are present in synaptic but not extrasynaptic BL.     

Evidence for a peripheral mechanism of esophagocrural diaphragm inhibitory reflex in cats

The esophagogastric junction (EGJ) is guarded by two sphincters, a smooth muscle lower esophageal sphincter (LES) and a skeletal muscle crural diaphragm. These two sphincters relax simultaneously under certain physiological conditions, i.e., swallowing, belching, vomiting, transient LES relaxation, and esophageal distension. Esophageal distension-induced crural diaphragm relaxation is mediated through vagal afferents that are thought to exert inhibitory influence on the central mechanism (brain stem) of crural diaphragm contraction. We conducted studies in 10 cats to determine whether a mechanism of crural diaphragm relaxation was located at the level of the neuromuscular junction and/or muscle. Stimulation of the crural diaphragm neuromuscular junction through 1) the electrodes implanted in the muscle and 2) the bilateral phrenic nerve resulted in an increase in EGJ pressure. Nicotinic receptor blockade (pancuronium, 0.2 mg/kg) abolished the EGJ pressure increase caused by electrical stimulation of the neuromuscular junction. Esophageal distension and bolus-induced secondary esophageal peristalsis caused relaxation of the EGJ during the stimulation of the neuromuscular junction. Bilateral phrenicotomy and vagotomy had no influence on this relaxation. These data suggest the existence of a peripheral mechanism of crural diaphragm inhibition. This peripheral inhibitory mechanism may reside at the level of either the neuromuscular junction or the skeletal muscle.     

Expression of cytotactin in the normal and regenerating neuromuscular system

Cytotactin is an extracellular glycoprotein found in a highly specialized distribution during embryonic development. In the brain, it is synthesized by glia, not neurons. It is involved in neuron-glia adhesion in vitro and affects neuronal migration in the developing cerebellum. In an attempt to extend these observations to the peripheral nervous system, we have examined the distribution and localization of cytotactin in different parts of the normal and regenerating neuromuscular system. In the normal neuromuscular system, cytotactin accumulated at critical sites of cell-cell interactions, specifically at the neuromuscular junction and the myotendinous junction, as well at the node of Ranvier (Rieger, F., J. K. Daniloff, M. Pincon-Raymond, K. L. Crossin, M. Grumet, and G. M. Edelman. 1986. J. Cell Biol. 103:379-391). At the neuromuscular junction, cytotactin was located in terminal nonmyelinating Schwann cells. Cytotactin was also detected near the insertion points of the muscle fibers to tendinous structures in both the proximal and distal endomysial regions of the myotendinous junctions. This was in striking contrast to staining for the neural cell adhesion molecule, N-CAM, which was accumulated near the extreme ends of the muscle fiber. Peripheral nerve damage resulted in modulation of expression of cytotactin in both nerve and muscle, particularly among the interacting tissues during regeneration and reinnervation. In denervated muscle, cytotactin accumulated in interstitial spaces and near the previous synaptic sites. Cytotactin levels were elevated and remained high along the endoneurial tubes and in the perineurium as long as muscle remained denervated. Reinnervation led to a return to normal levels of cytotactin both in inner surfaces of the nerve fascicles and in the perineurium. In dorsal root ganglia, the processes surrounding ganglionic neurons became intensely stained by anticytotactin antibodies after the nerve was cut, and returned to normal by 30 d after injury. These data suggest that local signals between neurons, glia, and supporting cells may regulate cytotactin expression in the neuromuscular system in a fashion coordinate with other cell adhesion molecules. Moreover, innervation may regulate the relative amount and distribution of cytotactin both in muscle and in Schwann cells.     

Localization of acetylcholine receptors by means of horseradish peroxidase-alpha-bungarotoxin during formation and development of the neuromuscular junction in the chick embryo

The localization of acetylcholine receptors (AChR) in the surface of developing myogenic cells of the chick embryo anterior and posterior latissimus dorsi muscles in relation to the process of innervation has been studied at the ultrastructural level utilizing a horseradish peroxidase-alpha-bungarotoxin conjugate. Localized concentrations of AChR were found in small regions 0.1-0.4 micron in width on the surface of myogenic cells of 10- to 14-d-old muscles. Surface specializations consisting of an external coating of extraneous material and an internal accumulation of dense material are associated with the plasma membrane in the regions of AChR concentration. As the muscle fibers are innervated, reactive surface patches are found at the region of contact of the growing nerve fiber and the surface of myotubes or their fusing myoblasts. After the establishment of contact, the patches of reaction product become more numerous and coextensive within the region of the neuromuscular junction and its immediate surroundings forming a dense continuous deposit on the postsynaptic sarcolemma. Activity becomes increasingly restricted to the site of the neuromuscular junction as the embryos approach hatching. At all stages, specializations external and internal to the plasmalemma are found at regions of high density of AChR, suggesting that they play a role in the maintenance of a higher concentration of receptors at these sites. These specializations also occur at the region of initial synaptic contact, indicating that they might be recognized by the nerve and represent preferred sites of innervation. Innervation appears to exert a stabilizing influence on the area of high AChR concentration in contact with the nerve and to induce a further increase in the AChR density of this site while the number of AChR in the remaining portions of the muscle surface declines.     

Agrin-like molecules at synaptic sites in normal, denervated, and damaged skeletal muscles

Several lines of evidence have led to the hypothesis that agrin, a protein extracted from the electric organ of Torpedo, is similar to the molecules in the synaptic cleft basal lamina at the neuromuscular junction that direct the formation of acetylcholine receptor and acetylcholinesterase aggregates on regenerating myofibers. One such finding is that monoclonal antibodies against agrin stain molecules concentrated in the synaptic cleft of neuromuscular junctions in rays. In the studies described here we made additional monoclonal antibodies against agrin and used them to extend our knowledge of agrin-like molecules at the neuromuscular junction. We found that anti-agrin antibodies intensely stained the synaptic cleft of frog and chicken as well as that of rays, that denervation of frog muscle resulted in a reduction in staining at the neuromuscular junction, and that the synaptic basal lamina in frog could be stained weeks after degeneration of all cellular components of the neuromuscular junction. We also describe anti-agrin staining in nonjunctional regions of muscle. We conclude the following: (a) agrin-like molecules are likely to be common to all vertebrate neuromuscular junctions; (b) the long-term maintenance of such molecules at the junction is nerve dependent; (c) the molecules are, indeed, a component of the synaptic basal lamina; and (d) they, like the molecules that direct the formation of receptor and esterase aggregates on regenerating myofibers, remain associated with the synaptic basal lamina after muscle damage.     

Electrical and acetylcholine-receptive properties of the muscle fiber membrane after axoplasmic transport blockade by colchicine

Electrical properties of the membrane and sensitivity of the fibers to acetylcholine were investigated in the frog sartorius muscle after denervation and a single application of colchicine to the nerve. After both types of procedure the electrical properties showed similar changes and extrasynaptic sensitivity to acetylcholine appeared. No such changes took place in the fibers of the contralateral muscle. Injection of colchicine into the lymphatic sac did not affect the electrical properties of the membrane, but widened the zone of sensitivity to acetylcholine. The results are regarded as further evidence in support of the view that denervation-like changes after application of colchicine to the motor nerve, when the transmission of excitation of nerve to muscle is preserved, are the result of a disturbance of the supply of neurotrophic substances along the axon by means of axoplasmic transport.Kazan' Medical Institute. I. M. Sechenov Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 12, No. 5, pp. 550–557, September–October, 1980.     

Axonal transport blockade and denervation have qualitatively different effects upon skeletal muscle metabolism

The activity and isoenzyme pattern of muscle lactic dehydrogenase (LDH) was measured at different times after axonal transport blockade by colchicine or after denervation. After denervation, total LDH activity decreased and the isoenzyme pattern was altered, LDH-1 being the most affected form. In contrast, after axonal transport blockade there was a decrease in LDH activity but the isoenzyme pattern was not modified. Denervation abolishes both nerve-evoked muscle activity and the release of neuro trophic substances from the nerve whereas colchicine blocks axonal transport without affecting the nerve capacity to conduct action potentials or neuromuscular transmission. It is then concluded that nerve-evoked muscle activity is the most important factor in the regulation of muscle LDH isoenzyme distribution. On the other hand, muscle metabolism can also be regulated by axonally transported molecules. The results presented here show that there is a qualitative difference between the effects of denervation and those of axonal transport blockade upon the muscle, since only denervation altered the isoenzyme pattern of muscle LDH.     

Nonacceptance of innervation by innervated neonatal rat muscle

Denervated adult muscle accepts innervation and has high levels of extrajunctional acetylcholine (ACh) receptor, compared to innervated adult muscle. If the high receptor density or any externally oriented part of the receptor molecule permitted or triggered functional synaptogenesis, then innervated neonatal muscle, with its known high extrajunctional sensitivity, should also accept extra synapses from implanted motor nerves. This prediction was tested by implanting the common peroneal nerve into innervated lateral gastrocnemius muscle in 25 neonatal rats and studying the innervation achieved 1–8 weeks later. With one exception, zero or negligible twitch tensions were obtained when the implanted nerve was stimulated. Intracellular recording in two cases showed no evidence of subthresholdevoked potentials in surface muscle fibers. In contrast, when the original motor nerve was cut at the time of common peroneal nerve implantation, reinnervation occurred as soon as 4 days later, and substantial indirect twitches (most observed qualitatively) were invariably found 6–7 days after operation. Four to eight weeks after nerve implantation into denervated muscle, substantial twitch tensions were obtained upon stimulation of the implanted nerve. α-Bungarotoxin binding to extrajunctional ACh receptors per unit surface area was similar in innervated neonatal and denervated adult muscle. Therefore, nonacceptance of additional functional innervation in neonatal muscle implies that a high average density of extrajunctional ACh receptor is not sufficient to permit or trigger functional neuromuscular junction formation.