Differential delay of reinnervating axons alters specificity in the rat serratus anterior muscle

Previous studies have shown remarkable rostrocaudal selectivity by regenerating motoneurons to the rat serratus anterior (SA) muscle after freezing, crushing, or sectioning the long thoracic (LT) nerve. The LT nerve contains motoneurons from both the sixth and seventh cervical spinal nerves (C6 and C7), with C6 motoneurons as the major source of innervation throughout the muscle, and with C7 motoneurons innervating a larger percentage of muscle fibers caudally than rostrally. To determine if synaptic competition can play a role in neuromuscular topography, both the LT nerve and the branch carrying C6 (rostral) motoneurons to the LT nerve were crushed in newborn rats. This approach provides a temporal advantage to regenerating C7 (caudal) motoneurons. After an initial period during which C7 motoneurons reinnervated a larger proportion of muscle fibers than normal in all SA muscle sectors, C6 motoneurons regained their original proportion of rostral muscle fibers. Caudally, however, C7 motoneurons maintained an expanded territory. With this two-site crush method, the number of C6 motoneurons that reinnervate the SA muscle was significantly decreased from normal, whereas the number of C7 motoneurons remained the same. It is concluded that when C7 motoneurons are given a temporal advantage, synaptic specificity can be altered transiently in rostral muscle sectors and permanently in caudal sectors, and this is correlated with a disproportionate loss of C6 motoneurons. Moreover, this may be an important model for studies of synaptic competition, where terminals destined to be eliminated can be identified beforehand. © 1995 John Wiley & Sons, Inc.     

Retrograde effects on synaptic transmission at the Ia/motoneuron connection.

The fidelity of impulse propagation through the complex axonal tree en route to the various target cells of that fiber is an important question in neurobiology. Anatomists can trace pathways, but if impulses fail to propagate down to the terminals to release transmitter onto the target cell, there is a significant 'disconnect' between anatomy and physiology. These issues have been studied at length in the spinal cord of the cat where it has proven possible to examine the connections made by afferent fibers on motoneurons under different stimulus conditions. EPSP amplitude varies systematically during high frequency stimulation of the afferents according to the identity of the target motoneuron. This variation is a function of the state of the motoneuron's relation to its peripheral target. It changes after motoneuron axotomy and recovers with reinnervation of the periphery. Neurotrophins delivered to the axotomized motor axons fail to induce recovery. Chronic stimulation of the motor nerve alters muscle properties with coordinated changes in properties of the synapses on motoneurons innervating the stimulated muscle. We cannot yet definitively establish the mechanisms determining synaptic behavior during high frequency stimulation. However, the retrograde regulation of these properties suggests that it is an important variable and thus is worthy of intensive further study.     

Reinnervation of the rat levator ani muscle after neonatal denervation

After axonal injury on postnatal day 14 (P14), but not P21, motoneurons in the spinal nucleus of the bulbocavernosus (SNB) do not display their normal response to circulating testosterone levels. This could result from a permanent disruption of communication between motoneurons and their testosterone-sensitive target muscles. We assessed the extent of reinnervation of one of these target muscles, the levator ani (LA) muscle, 5 months after the pudendal nerve was cut either on P14 or P21. The number of motoneurons innervating the LA in control and nerve cut animals was determined using retrograde labeling procedures. Functional recovery of the LA muscle was determined via the testing of its in situ contractile properties. Compared to control muscles, reinnervated LA muscles were smaller, had fewer muscle fibers, generated a lower maximum tetanic tension, and were more fatigable. In spite of the fact that fewer motoneurons reinnervated the LA muscle after nerve cut on P14 than on P21, there were no differences in the weight or contractile properties of the LA muscle between these two groups. These data suggest that motoneurons that survived injury on P14 innervated more muscle fibers than normal and exhibited a similar ability to functionally reinnervate the target muscle as those motoneurons that survived injury on P21.     

Structure of allotransplanted ganglia and regenerated neuromuscular connections in crayfish

In adult crayfish, Procambarus clarkii, motoneurons to a denervated abdominal superficial flexor muscle regenerate long-lasting and highly specific synaptic connections as seen from recordings of excitatory postsynaptic potentials, even when they arise from the ganglion of another crayfish. To confirm the morphological origins of these physiological connections we examined the fine structure of the allotransplanted tissue that consisted of the third abdominal ganglion and the nerve to the superficial flexor muscle (the fourth ganglion and the connecting ventral nerve cord were also included). Although there is considerable degeneration, the allotransplanted ganglia display intact areas of axon tracts, neuropil, and somata. Thus in both short (6–8 weeks) and long (24–30 weeks) term transplants approximately 20 healthy somata are present and this is more than the five axons regenerated to the host muscle. The principal neurite and dendrites of these somata receive both excitatory and inhibitory synaptic inputs, and these types of synaptic contacts also occur among the dendritic profiles of the neuropil. Axon tracts in the allotransplanted ganglia and ventral nerve cord consist largely of small diameter axons; most of the large axons including the medial and lateral giant axons are lost. The transplanted ganglia have many blood vessels and blood lacunae ensuring long-term survival. The transplanted superficial flexor nerve regenerates from the ventral to the dorsal surface of the muscle where it has five axons, each consisting of many profiles rather than a single profile. This indicates sprouting of the individual axons and accounts for the enlarged size of the regenerated nerve. The regenerated axons give rise to normal-looking synaptic terminals with well-defined synaptic contacts and presynaptic dense bars or active zones. Some of these synaptic terminals lie in close proximity to degenerating terminals, suggesting that they may inhabit old sites and in this way ensure target specificity. The presence of intact somata, neuropil, and axon tracts are factors that would contribute to the spontaneous firing of the transplanted motoneurons. © 1996 John Wiley & Sons, Inc.     

Cerebral motoneurons mediating tentacle retraction in the land slug Ariolimax columbianus

(1) Tentacle retraction in the land slug Ariolimax columbianus can be elicited by stimulation of all nerves and connectives of the ipsi- and contralateral cerebral ganglia. (2) Six neurons in the left cerebral ganglion were classified as tentacle retraction motoneurons because their action potentials are followed one-for-one with constant delay by action potentials in the left tentacle retractor nerve and their depolarization causes retraction of the ipsilateral tentacle. The motoneurons can be identified by size, pattern of pigmentation, position, and physiological characteristics. (3) Each retractor motoneuron discharges at a rather constant rate and has more than one source of excitatory input, but no IPSPs were observed. No synaptic connections between the six retractor motoneurons were found. The nerve action potentials that correspond to each motoneurons are distinguishable by waveform and size rank. (4) Each motoneuron elicits visible contractions in a particular region of the ipsilateral retractor muscle, but the motor fields of some motoneurons overlap. Some motoneurons mediate relatively rapid contractions while others cause slower responses. (5) There is one-for-one correspondence between action potentials of the largest unit recorded extracellularly in the retractor nerve and exciatory junction potentials recorded from the retractor muscle. No evidence of a peripheral neural plexus was found in serial sections of the retractor muscle.     

Evolution of the arthropod neuromuscular system. 1. Arrangement of muscles and innervation in the walking legs of a scorpion: Vaejovis spinigerus (Wood, 1863) Vaejovidae, Scorpiones, Arachnida

(1) The musculature of the walking legs is analysed with regard to both morphology and function in the scorpion, Vaejovis spinigerus (Wood, 1863) (Vaejovidae, Scorpiones, Arachnida), and selected other species. Conspicuous features are multipartite muscles, muscles spanning two joints, and partial lack of antagonistic muscles. The muscle arrangement is compared to that in the walking limbs of other Arthropoda and possible phylogenetic implications are discussed. (2). Histochemical characterisation of selected leg muscles indicates that these are composed of layers of slow, intermediate and fast muscle fibres. Anti-GABA immunohistochemistry shows that mainly the intermediate fibres receive innervation from putative inhibitory motoneurons. (3). Intracellular recording from muscle fibres reveals both excitatory and inhibitory muscle innervation. Individual muscle fibres may receive input from more than one inhibitory motoneuron, as indicated by different IPSP amplitudes. (4). The motoneuron supply of the leg muscles is analysed by retrograde fills of motor nerves. The general arrangement of leg motoneurons in the central nervous system and motoneuron anatomy conforms to the situation in pterygote insects and decapod crustaceans. For example, there are an anterior and a posterior group of leg motoneurons in each hemineuromere, and two contralateral somata near the ganglion midline. Between 12 and 20 motoneurons are found to supply each muscle. Most motoneuron cell bodies supplying a given muscle are arranged in a single cluster with a specific location.     

The dorsal compartment locomotory control system in amphioxus larvae

Amphioxus myotomes consist of separate sets of superficial and deep muscle fibers, each with its own innervation, that are thought to be responsible for slow swimming and escape behavior, respectively. Tracings from serial EM sections of the anterior nerve cord in the larva show that the motoneurons and premotor interneurons controlling the superficial fibers (the dorsal compartment, or DC pathway) are linked by specialized junctions of a previously undescribed type, referred to here as juxta-reticular (JR) junctions for the characteristic presence of a cisterna of endoplasmic reticulum on each side. JR junctions link the DC motoneurons with each other, with the largest of the anterior paired neurons (LPN3s) and with one class of ipsilateral projection neurons (IPNs), but occur nowhere else. Because of the paucity of synaptic input to the DC system, larval behavior can only be explained if the JR junctions act as functional links between cells. An analysis of the pattern of cell contacts also suggests that the LPN3s are probably pacemakers for both slow and fast locomotion, but act through junctions in the former case and conventional synapses in the latter. The only major synaptic input to the DC system identified in somites 1 and 2 was from four neurons located in the cerebral vesicle, referred to here as Type 2 preinfundibular projection neurons (PPN2s). They have unusually large varicosities, arranged in series, that make periodic contacts with the DC motoneurons. More caudally, the DC motoneurons receive additional input via similar large varicosities from the receptor cells of the first dorsal ocellus, located in somite 5. The overall circuitry of the locomotory control system suggests that the PPN2s may be instrumental in sustaining slow swimming, whereas mechanical stimulation, especially of the rostrum, preferentially activates the fast mode.     

Synaptic processes in thoracic α-motoneurons evoked by segmental afferent stimulation

Synaptic processes in various functional groups of thoracic motoneurons (Th₉-Th₁₁) evoked by stimulation of segmental nerves were investigated in anesthetized and decerebrate cats. No reciprocal relations were found between these groups of motoneurons. Only excitatory mono- and polysynaptic responses were recorded in the motoneurons of the principal intercostal nerve following stimulation of the homonymous nerve. Activation of the afferents of the external intercostal muscle and dorsal branches does not cause noticeable synaptic processes in these motoneurons; much more rarely it is accompanied by the development of low-amplitude polysynaptic EPSP's. In motoneurons of the dorsal branches, stimulation of homonymous nerves leads to the appearance of simple, short-latent EPSP's. Late responses of the IPSP or EPSP - IPSP type with a predominance of the inhibitory component were observed in most motoneurons of this type following activation of the afferent fibers of the principal intercostal nerve. In other motoneurons of the dorsal muscles, stimulation of the main intercostal nerve (and nerve of the external intercostal muscle) did not evoke apparent synpatic processes. EPSP's (mono- and polysynaptic) appeared in the motoneurons of the external intercostal muscle following stimulation of the homonymous and main intercostal nerves. Activation of the afferents of the dorsal branches was ineffective. The character of the synaptic responses of the respiratory motoneurons to segmental afferent stimulation, investigated under conditions of spontaneous respiration, was different. The characteristics of synaptic activation of thoracic motoneurons by segmental afferents under conditions of hyperventilation apnea and during spontaneous breathing of the animals are discussed.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 2, No. 3, pp. 279–288, May–June, 1970.     

Distribution of neurotrophin receptors in the mouse neuromuscular system

The neurotrophins are a family of secreted proteins with critical roles in regulation of many aspects of neural development, survival and maintenance. Their actions on neural tissue are thought to be mediated by interaction with high affinity (trk family members) or low affinity (p75NTR) cell surface receptors. In general, neurotrophins are considered to be supplied in limiting quantity by cells of a target tissue or synaptic partner. To date, alpha motoneurons have been shown surprisingly indifferent to loss of neurotrophic factors. Direct evidence for supply of a critical motoneuron factor(s) by skeletal muscle and a specific uptake mechanism in vivo remains elusive. We wished to directly establish whether targets in the periphery might be potential sources of neurotrophic support for motoneurons by examining whether neurotrophin receptors are present on motoneuron nerve terminals. We have used immunofluorescence techniques with a panel of antibodies against known neurotrophin receptors (trk A, trk B, trk C, p75NTR) to map the locations of these receptors in the developing neuromuscular system of mice from our neurotrophin-3 (NT-3) knockout colony. To our surprise, we failed to locate immunoreactivity for any of these receptors in association with motor nerve endplates or terminal intramuscular axon branches, although they were found in association with a population of unidentified cells. We believe this result indicates that the neurotrophic relationship between alpha motoneurons and their target cells is not a simple one of neurotrophin supply by skeletal muscle cells and its uptake at the neuromuscular junction.     

Critical periods in rat motoneuron development

Reinnervation of rat internal intercostal muscles was examined 2 weeks after intramuscular axotomy in the period embryonic Day 17 (E17) to postnatal Day 2 (PN2). The efficiency of reinnervation depended on the day of denervation. Responses to nerve stimulation were common only in muscles denervated in the interval E19–E21. Functional reinnervation was seldom seen in muscles denervated earlier, and was absent in muscles denervated shortly after birth. We suggest that there are “critical periods” in the sequence of differentiation of motoneurons. At E17 these neurons are very susceptible to cell death and any that lose contact with their muscle will die. Motoneurons axotomized later, while motor unit size is still increasing, can regenerate some functional nerve-muscle junctions. Motor unit size reaches its maximum by E21 and if motoneurons are exotomized after that time, in neonates, they cannot form more synaptic terminals although they can still extend axons. During this early postnatal period motoneurons normally reduce their number of nerve-muscle contacts. Finally, at 3 weeks of age, motoneurons reach their adult state when they are capable of regeneration relatively unhindered by restrictions on the number and location of their peripheral connections.     

Transient inability of neonatal rat motoneurons to reinnervate muscle

We studied the reinnervation of internal intercostal muscles of newborn rats. The distal halves were denervated by nerve section at various ages between birth and 6 weeks. Regardless of the age at denervation, neither evoked nor spontaneous nerve-muscle transmission reappeared until the animals were at least 3 weeks old. Older rats recovered a substantial degree of function within 7 days of nerve section. Normally the motor units in this muscle are narrowly distributed, so most axotomized motoneurons lost their entire synaptic periphery. Reinnervation was by axons which had been sectioned, and regenerated motor units were of normal size and number. There was no collateral sprouting from end plates left intact. Motoneurons axotomized at birth did regenerate axons the full length of the muscle within 7 days of operation. Their failure to reinnervate the muscle was due to delay in forming functional end plates. Nerve section in animals aged 1 month or older resulted in an abnormal pattern of reinnervation; reinnervated motor units were diffusely spread through large portions of the muscle, although they still did not overlap with the region left intact. This indicates that thoracic motoneurons respond to axotomy differently in neonatal rats than they do in adults.     

Changing perspectives on the functional organization of the segmental motor system

Results from a wide variety of recent studies on the architecture and innervation of skeletal muscles, the neuromechanical characteristics of motor units, and the properties and spinal reflex actions of muscle proprioceptors present a number of challenges to conventional views of the functional organization of the segmental motor system. To illustrate the nature of these challenges, studies directed toward several specific issues are reviewed. These include the functional subdivision of single muscles into two or more neuromuscular compartments; the patterns of synaptic input from peripheral afferent fibers to motoneurons innervating muscle units of different "type;" and the convergence in the segmental reflex pathways from muscle spindles and tendon organs to motoneurons.     

Identification of the motoneurons innervating the stapedius muscle in Gallus gallus: a horseradish peroxidase study

The location of the stapedial motoneurons in Gallus gallus was investigated by means of the retrograde transport of HRP, injected into the stapedius muscle. The labeled neurons are located in both the ventral and dorsal divisions of the VII nerve nucleus, in a lateral and ventral position respectively, facing the superior olivary nucleus. The neurons are distributed in two size classes. The functional implications of these findings are discussed, in relation both to the absence of the acoustic stapedial reflex in birds and to the functional properties of the stapedius muscle.     

Retrograde transport of NGF by early chick embryo spinal cord motoneurons

Neuronal retrograde transport of nerve growth factor (NGF) was examined in chick embryos at 5, 6, and 7 days of incubation. Radiolabeled NGF was injected in the target limb muscle and the retrograde transport was viewed following processing for autoradiography. Silver grains were localized in the peripheral nerve, in the ventral root, in neuronal cell bodies within the dorsal root ganglion, and in motoneurons of the lateral motor column. Comparable injections of 125I-cytochrome c resulted in the presence of label at the peripheral injection site only. The possible developmental significance of these observations is discussed.     

Sensory and central nervous control of gill ventilation in Limulus.

The gills of Limulus are ventilated by a metachronal rhythm of movements of five pairs of gill plates. A gill plate is promoted and remoted by action of alternating nerve impulse bursts to antagonist promotor and remotor muscles. The motor output pattern is centrally generated, requiring no sensory feedback. Intracellularly recorded rhythmic activity of respiratory motoneurons consists of cyclic depolarization and spiking, and repolarization. The repolarizations have reversal potentials that indicate that motoneuron burst terminations result from synaptic inhibition. Intracellular and antidromic stimulation of motoneurons has little effect on other motoneurons. This apparent lack of interaction between motoneurons indicates that the central respiratory pattern is generated at interneuronal levels. Proprioceptive reflexes are present; they play little role in modulating the centrally generated motor pattern, but they are capable of partially entraining the rhythm when all gill plates are cycled at frequencies near the respiratory rate. Respiratory rate in intact animals is proportional to the ambient oxygen content, respiration ceasing in an anoxic environment. This oxygen dependence may result from sensory input from external oxygen receptors located in the cuticle between the coxae of the walking legs and within the lamellas of the book gills. The intercoxal units are inhibited by anoxia. Three classes of units are recorded from the gills: units excited by oxygen, units inhibited by oxygen, and units whose mechanosensitivity is oxygen dependent. These external oxygen receptors may modulate ventilation via command fibers present in the ventral nerve cord.     

Allotransplanted nerves regenerate inhibitory synapses on a crayfish muscle: Possible postsynaptic specification

Donor nerves of different origins, when transplanted onto a previously denervated adult crayfish abdominal superficial flexor muscle (SFM), regenerate excitatory synaptic connections. Here we report that an inhibitory axon in these nerves also regenerates synaptic connections based on observation of nerve terminals with irregular to elliptically shaped synaptic vesicles characteristic of the inhibitory axon in aldehyde fixed tissue. Inhibitory terminals were found at reinnervated sites in all 12 allotransplanted-SFMs, underscoring the fact that the inhibitory axon regenerates just as reliably as the excitatory axons. At sites with degenerating nerve terminals and at sparsely reinnervated sites, we observe densely stained membranes, reminiscent of postsynaptic membranes, but occurring as paired, opposing membranes, extending between extracellular channels of the subsynaptic reticulum. These structures are not found at richly innervated sites in allotransplanted SFMs, in control SFMs, or at several other crustacean muscles. Although their identity is unknown, they are likely to be remnant postsynaptic membranes that become paired with collapse of degenerated nerve terminals of excitatory and inhibitory axons. Because these two axons have uniquely different receptor channels and intramembrane structure, their remnant postsynaptic membranes may therefore attract regenerating nerve terminals to form synaptic contacts selectively by excitatory or inhibitory axons, resulting in postsynaptic specification.     

Retrograde Effect of Muscle on Forms of Acetylcholinesterase in Peripheral Nerves

In the peripheral nerves of birds and mammals, acetylcholinesterase (AChE) exists in four main molecular forms (G1, G2, G4, and A12). The two heaviest forms (G4 and A12) are carried by rapid axoplasmic transport, whereas the two lightest forms (G1 and G2) are probably much more slowly transported. Here we report that nerves innervating fast-twitch (F nerves) and slow-twitch (S nerves) muscles of the rabbit differ both in their AChE molecular form patterns and in their anterograde and retrograde axonal transport parameters. Since we had previously shown a selective regulation of this enzyme in fast and slow parts of rabbit semimembranosus muscle, we wondered whether the differences observed in the nerve could be affected by the twitch properties of muscle. The results reported here show that in F nerves that reinnervate slow-twitch muscles, both the AChE molecular form patterns and axonal transport parameters turn into those of the S nerve. These data suggest the existence of a retrograde specific effect exerted by the muscles on their respective motoneurons.     

Regenerated synaptic terminals on a crayfish slow muscle identify with transplanted phasic or tonic axons

Phasic or tonic nerves transplanted onto a denervated slow superficial flexor muscle in adult crayfish regenerated synaptic connections that displayed large or small excitatory postsynaptic potentials (EPSPs), respectively, suggesting that the neuron specifies the type of synapse that forms (Krause et al., J Neurophysiol 80:994-997, 1998). To test the hypothesis that such neuronal specification would extend to the synaptic structure as well, we examined the regenerated synaptic terminals with thin serial section electron microscopy. There are distinct differences in structure between regenerated phasic and tonic innervation. The phasic nerve provides more profuse innervation because innervation sites occurred more frequently and contained larger numbers of synaptic terminals than the tonic nerve. Preterminal axons of the phasic nerve also had many more sprouts than those of the tonic nerve. Phasic terminals were thinner and had a lower mitochondrial volume than their tonic counterparts. Phasic synapses were half the size of tonic ones, although their active zone-dense bars were similar in length. The density of active zones was higher in the phasic compared with the tonic innervation, based on estimates of the number of dense bars per synapse, per synaptic area, and per nerve terminal volume. Because these differences mirror those seen between phasic and tonic axons in crayfish muscle in situ, we conclude that the structure of the regenerated synaptic terminals identify with their transplanted axons rather than with their target muscle. Therefore, during neuromuscular regeneration in adult crayfish, the motoneuron appears to specify the identity of synaptic connections.     

Muscle Plasticity During Sprouting and Reinnervation

SYNOPSIS. When peripheral nerves are cut, the axotomized nervesand denervated muscles undergo atrophic changes which are reversedonly when functional connections are remade in the periphery.The restored interaction completely reverses the effects ofaxotomy and denervation and leads to rematching of the sizeof the motoneuron, muscle unit force, speed and histochemicalproperties, according to the size principle. Differences inunit force and fatigue characteristics between motor unit typesare not fully restored in reinnervated muscles but do not obscuresize relationships between the motoneurons and their muscleunits. Although intact motoneurons will supply increased numbers ofmuscle fibers after partial nerve injuries, regenerating axonsappear to be limited in their ability to enlarge their muscleunits. Increased motor unit force in reinnervated slow motorunits is accounted for primarily by an increase in fiber diameter;fast motor units do not increase their mean force output. As a result of the rematching of muscle unit properties withthe size of the motoneurons that reinnervate them, motor unitproperties are appropriate for fine control of movement aftercomplete or partial nerve injuries. However, regenerating axonsdo not reinnervate their original muscle fibers and unless thefibers are injured close to the muscles, they often fail toreinnervate their original muscles. The mismatching of motorpools with inappropriate target muscles is probably the mainfactor responsible for poor recovery of motor function aftercomplete nerve injuries.     

Properties of synaptic transmission at the neuromuscular junction of the squid, Loligo opalescens

1. Spontaneous and evoked synaptic activity were recorded from the muscles of squid fin and mantle. These spontaneous synaptic potentials were large (up to 30 mV) and pleomorphic. Their amplitudes were not normally distributed, nor did they appear to be clustered in integral multiples of some "unit" event size. 2. Electrical stimulation of the nerve resulted in muscle twitches when the bath calcium concentration was a third normal or higher. The frequency of spontaneous synaptic events was unaffected by low calcium. 3. The large size of spontaneous events may mean that the synchronized release of only a few such "quanta" are sufficient to cause muscle action potentials and contraction. 4. The shapes of spontaneous events correlated poorly with their amplitudes, which is consistent with release from multiple synaptic sites with distinct properties.