Terminal sprouting in rat sternocostalis muscle following partial denervation

Summary The sternocostalis muscle of the rat was examined at one to five days after partial denervation and levels of terminal sprouting were assessed.The removal of one intercostal nerve caused localised degeneration which did not extend more than a few muscle fibres deep into the field of distribution of the adjacent nerve. Terminal sprouting was clearly seen at 24 h after operation and did not appear to develop further up to five days.There was no difference in the sprouting responses to section of either intercostal nerve 2, 4 or 5. There was, however, a decrease in the response with increasing distance from the cut nerve. No sprouting response was observed in the contralateral muscle.Comparison of sprouting levels of B and C type end plates revealed a greater percentage of C type end plates with sprouts. However, the response of B type end plates, considered in relation to the levels of spontaneous sprouting, was greater than that of C type end plates.     

Activity alters muscle reinnervation and terminal sprouting by reducing the number of Schwann cell pathways that grow to link synaptic sites

In partially denervated rodent muscle, terminal Schwann cells (TSCs) located at denervated end plates grow processes, some of which contact neighboring innervated end plates. Those processes that contact neighboring synapses (termed "bridges") appear to initiate nerve terminal sprouting and to guide the growth of the sprouts so that they reach and reinnervate denervated end plates. Studies conducted prior to knowledge of this potential involvement of Schwann cells showed that direct muscle stimulation inhibits terminal sprouting following partial denervation (Brown and Holland, 1979). We have investigated the possibility this inhibition results from an alteration in the growth of TSC processes. We find that stimulation of partially denervated rat soleus muscle does not alter the length or number of TSC processes but does reduce the number of TSC bridges. Stimulation also reduces the number of TSC bridges that form between end plates during reinnervation of a completely denervated muscle. The nerve processes ("escaped fibers") that normally grow onto TSC processes during reinnervation are also reduced in length. Therefore, stimulation alters at least two responses to denervation in muscles: (1) the ability of TSC processes to form or maintain bridges with innervated synaptic sites, and (2) the growth of axons along processes extended by TSCs.     

Nerve sprouting in innervated adult skeletal muscle induced by exposure to elevated levels of insulin-like growth factors

Partial denervation or paralysis of adult skeletal muscle is followed by nerve sprouting, probably due to release of diffusible sprout-inducing activity by inactive muscle. Insulin-like growth factors (IGF1 and IFG2) are candidates for muscle-derived sprouting activity, because (a) they induce neurite growth from peripheral neurons in vitro; and (b) their mRNA levels in adult skeletal muscle increase severalfold after denervation or paralysis. We sought to determine whether the presence of elevated levels of IGFs in innervated adult skeletal muscle was sufficient to produce intramuscular nerve growth. Low concentrations of IGFs induced massive neurite growth from enriched embryonic chick motoneurons in vitro. Half-maximal responses required 0.2 nM IGF2 or IGF1, or 20 nM insulin. Similar hormone binding properties of motoneuron processes in vitro were observed. Exposure of adult rat or mouse gluteus muscle in vivo to low quantities of exogenous IGF2 or IGF1 led to intramuscular nerve sprouting. Numbers of sprouts in IGF-exposed muscles were 10-fold higher than in vehicle-exposed or untreated muscles, and 12.2% of the end plates in IGF-exposed muscle (control: 2.7%) had sprouts growing from them. The nerve growth reaction was accompanied by elevated levels of intramuscular nerve-specific growth-associated protein GAP43. Additional properties of IGF-exposed muscle included modest proliferation of interstitial cells and elevated interstitial J1 immunoreactivity. These results suggest that elevated levels of IGFs in denervated or paralyzed muscle might trigger coordinate regenerative reactions, including nerve sprouting and expression of nerve growth-supporting substrate molecules by activated interstitial cells.     

Inhibition of parasympathetic axonal sprouting in the cat submandibular gland by sympathetic axons

Summary The sprouting of parasympathetic axons into the submandibular sympathetic nerve trunk following sympathetic denervation has been investigated. It was found that a permanent sympathetic denervation was necessary in order for the sprouting to develop and be maintained: if reinnervation by adrenergic nerves was delayed, the sprouting developed but was reduced at longer survival times when the original innervation was reestablished. The evidence for suppression of the cholinergic sprouting by the adrenergic axons is discussed, as is the evidence that these sprouts arise from the submandibular gland.     

Topological differences along mammalian motor nerve terminals for spontaneous and alpha-bungarotoxin-induced sprouting

Spontaneous sproutings can be observed in end plates from normal adult vertebrate muscles and motor end plates develop increased growth signs and sprouts when target muscle cells become less active or paralysed. Nevertheless, very little is known about where in the motor nerve terminal arborization spontaneous and experimentally induced sprouts originate, their similarities and differences and also about their final maturation or elimination. In this study we investigate the topological properties of both spontaneous and alpha-bungarotoxin-induced sprouts (during different periods of intoxication and after recovery) along the motor nerve terminal branches of the Levator auris longus muscle of Swiss mice (between 48-169 day old). Muscles were processed for immunocytochemistry to simultaneously detect postsynaptic AChRs and axons. This procedure permits us to make an accurate identification of the fine sprouts and a morphometric study of the presynaptic branching pattern profile in control muscles, during the toxin action and after recovery from paralysis. The results show that in normal muscles, the initial and trunk segments (those between branch points) of the terminal arborization sprouted proportionally more branches when taking their relative lengths into account than the distal free-end segments. In contrast, every micrometer of alpha-bungarotoxin-treated muscles throughout the full terminal arborization have the same probability of generating a sprout. Moreover, the toxin-induced sprouts can consolidate as new branches once recovered from the paralysis without changing the total length of the nerve terminal arborization.     

A scanning electron microscope study of the development of free axonal sprouts at the cut ends of dorsal spinal nerve roots in the rat

Summary Rat dorsal spinal nerve roots were cut and the tip on the ganglionic side of the cut was examined by scanning electron microscopy at 0, 7, 20 and 48 h after operation. Seven hours after cutting, free axonal sprouts had started to protrude from the cut end of the nerve. After 20 h the free sprouts were more profuse than at 7 h but were smaller and had a rougher surface. At both 7 and 20 h many of the sprouts consisted of a stalk 2–7 m in diameter with a bulbous end 5–20 m in diameter. A few branching sprouts were seen. At 48 h the sprouts were shrunken with a deeply furrowed surface. The significance of the surface structure of the sprouts is discussed.I.R.D. is supported by the Medical Research Council; P.K. thanks the Mental Health Trust for a project grant     

End plate classification and spontaneous sprouting in the sternocostalis muscle of the rat: A new whole mount preparation

Summary The sternocostalis muscle of the rat provides an ideal preparation for examination of neuromuscular junctions in a whole mount. It contains all three morphological end plate types (A, B and C), and its segmental innervation allows ease of experiment, such as partial denervation.The ratio of end plate types remains constant in all individuals of the same age, and there is no variation in this ratio over different regions of the same muscle. Spontaneous sprouting was observed from end plates of all the animals examined: again the ratio of sprouting end plate types remained constant over all muscles examined, and over all regions of the same muscle.     

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.     

Botulinum neurotoxins: from paralysis to recovery of functional neuromuscular transmission.

The neuromuscular junction is one of the most accessible mammalian synapses which offers a useful model to study long-term synaptic modifications occurring throughout life. It is also the natural target of botulinum neurotoxins (BoNTs) causing a selective blockade of the regulated exocytosis of acetylcholine thereby triggering a profound albeit transitory muscular paralysis. The scope of this review is to describe the principal steps implicated in botulinum toxin intoxication from the early events leading to a paralysis to the cellular response implementing an impressive synaptic remodelling culminating in the functional recovery of neuromuscular transmission. BoNT/A treatment promotes extensive sprouting emanating from intoxicated motor nerve terminals and the distal portion of motor axons. The current view is that sprouts have the ability to form functional synapses as they display a number of key proteins required for exocytosis: SNAP-25, VAMP/synaptobrevin, syntaxin-I, synaptotagmin-II, synaptophysin, and voltage-activated Na+, Ca2+ and Ca2+-activated K+ channels. Exo-endocytosis was demonstrated (using the styryl dye FM1-43) to occur only in the sprouts in vivo, at the time of functional recovery emphasising the direct role of nerve terminal outgrowth in implementing the restoration of functional neurotransmitter release (at a time when nerve stimulation again elicited muscle contraction). Interestingly, sprouts are only transitory since a second distinct phase of the rehabilitation process occurs with a return of synaptic activity to the original nerve terminals. This is accompanied by the elimination of the dispensable sprouts. The growth or elimination of these nerve processes appears to be strongly correlated with the level of synaptic activity at the parent terminal. The BoNT/A-induced extension and later removal of "functional" sprouts indicate their fundamental importance in the rehabilitation of paralysed endplates, a finding with ramifications for the vital process of nerve regeneration.     

Suppression of terminal axonal sprouting at the neuromuscular junction by monoclonal antibodies against a muscle-derived antigen of 56,000 daltons

After the partial denervation or paralysis of a muscle, the remaining motor axon terminals may sprout fine, neuritic processes (terminal sprouts) which escape the endplate region of the neuromuscular junction. We previously identified a muscle-derived, protein antigen of 56,000 daltons (56 kD) which plays a necessary role in terminal sprouting. A panel of monoclonal antibodies have been produced against the 56-kD antigen, some of which also partially suppress motor axon terminal sprouting. These monoclonal antibodies define at least two different epitopes upon the surface of the antigen, one of which is necessary for it to effect its biological role in vivo.     

Sprouting and regeneration of frog motoneurons during synapse elimination

The ability of frog axons to sprout and reinnervate during the period of synapse elimination was examined in the cutaneous pectoris muscle from young postmetamorphic frogs using histological staining of nerve terminals and postsynaptic acetylcholinesterase. Partial denervation of the cutaneous pectoris muscle during the period of synapse elimination produced rapid sprouting of the intact axons. The majority of denervated endplates were being reinnervated by sprouts within 3 days. In addition, total denervation performed by either sectioning or crushing the nerve was followed by functional reinnervation. Approximately 98% of the endplates were being reinnervated within 7 days after a nerve crush and 10 days after sectioning the nerve.     

Juvenile sprouting ability of the endangered maple, <Emphasis Type="Italic">Acer pycnanthum</Emphasis>

Japanese red maple, Acer pycnanthum, is an endangered species having a limited distribution of central Honshu, Japan. Sprouting is an important part of its natural history, and many remnant populations contain high number of multiple-stem clones. However, knowledge of sprout formation and growth is lacking, which has hampered understanding of the reestablishment process after major disturbance. My research objectives were to characterize the formation and growth of basal sprouts in the juvenile stage and determine the effects of light intensity and stump diameter on these characteristics. Twenty sprouting clones were investigated at a natural site in Nagano Prefecture during a four-year period after cutting. Japanese red maple exhibited abundant and vigorous sprouting from the root collar of cut trees. Many sprouts arose immediately after cutting. Average number of sprouts per stump was 12.2. Number of sprouts per stump was negatively correlated with relative light intensity. The two dominant sprouts (sprouts 1 and 2) of each clone were selected to analyze their growth. The average extension growth of sprout 1 (i.e., the tallest and most vigorous) was 173.3 cm at the end of first growing season. At the end of fourth growing season, average height and diameter at breast height (dbh) of sprout 1 were 377 and 2.1 cm, respectively. Relative light intensity and stump diameter significantly and positively affected D²H (diameter at breast height squared × height) of sprout 1. Because the growth rate of sprouts is much faster than that of seedlings, regeneration by sprouting is more significant than seedling regeneration to maintain populations after disturbances.     

Ultrastructure of the new neuromuscular junctions formed during reinnervation of rat soleus muscle by a “foreign” nerve

Summary In rats the fast fibular nerve was transposed to the slow soleus muscle outside the original innervation band. Formation of new neuromuscular junctions was induced by cutting the soleus nerve after different periods of time. The morphological maturation of these junctions was studied by electron microscopy.New neuromuscular junctions do not form when the original innervation is left intact.Three to five days after denervation, vesicle-laden terminal boutons contact muscle fibers with only the basal lamina of the latter intervening. Three weeks after denervation, most boutons are larger and postsynaptic folds are present, although younger stages are also seen. Sixteen weeks after denervation, the neuromuscular junctions appear mature. This corresponds well with electrophysiological findings in the same material.The fully developed neuromuscular junctions sixteen weeks after denervation possess postsynaptic folds similar to those of normal fast muscle fibers. This suggests that the fast fibular nerve rather than the slow soleus muscle fibers determines the morphology of the postsynaptic folds.Possible trophic neuromuscular interactions are discussed.The authors are indebted to Mrs. Jorunn Line Vaaland, Miss Bjørg Riber, and Miss Berit Branil for technical assistance. Dr. T. Lømo and Dr. C. Slater have contributed constructive criticism and advice     

Perisynaptic Schwann cells at neuromuscular junctions revealed by a novel monoclonal antibody

This study aimed to generate a probe for perisynaptic Schwann cells (PSCs) to investigate the emerging role of these synapse-associated glial cells in the formation and maintenance of the neuromuscular junction (NMJ). We have obtained a novel monoclonal antibody, 2A12, which labels the external surface of PSC membranes at the frog NMJ. The antibody reveals PSC fine processes or “fingers” that are interposed between nerve terminal and muscle membrane, interdigitating with bands of acetylcholine receptors. This antibody also labels PSCs at the avian neuromuscular junction and recognizes a 200 kDa protein in Torpedo electric organs. In frog muscles, axotomy induces sprouting of PSC processes beyond clusters of acetylcholine receptors and acetylcholinesterase at denervated junctional branches. PSC branches often extend across several muscle fibers. At some junctions, PSC sprouts join the tips of neighboring branches. The average length of PSC sprouts is approximately 156 µ at 3-week denervated NMJs. PSC sprouting is accompanied by a significant increase in the number of Schwann cell bodies per NMJ. Following nerve regeneration, nerve terminals reinnervate the junction along the PSC processes. In vivo observations of normal frog muscles also show PSC processes longer than nerve terminals at some junctional branches. The results suggest that nerve injury induces profuse PSC sprouting that may play a role in guiding nerve terminal regeneration at frog NMJs. In addition, antibody 2A12 reveals the fine morphology of PSCs in relation to other synaptic elements and is a useful probe in elucidating the function of these synapse-associated glial cells in vivo.     

Reciprocal interactions between perisynaptic Schwann cells and regenerating nerve terminals at the frog neuromuscular junction

The perisynaptic Schwann cell (PSC) has gained recent attention with respect to its roles in synaptic function, remodeling, and regeneration at the vertebrate neuromuscular junction (NMJ). Here we test the hypothesis that, following nerve injury, processes extended by PSCs guide regenerating nerve terminals (NTs) in vivo, and that the extension of sprouts by PSCs is triggered by the arrival of regenerating NTs. Frog NMJs were double-stained with a fluorescent dye, FM4-64, for NTs, and fluorescein isothiocyanate (FITC)-tagged peanut agglutinin (PNA) for PSCs. Identified NMJs were imaged in vivo repeatedly for several months after nerve injury. PSCs sprouted profusely beginning 3-4 weeks after nerve transection and, as reinnervation progressed, regenerating NTs closely followed the preceding PSC sprouts, which could extend tens to hundreds of microns beyond the original synaptic site. The pattern of reinnervation was dictated by PSC sprouts, which could form novel routes joining neighboring junctions or develop into new myelinated axonal pathways. In contrast to mammals, profuse PSC sprouting in frog muscles was not seen in response to axotomy alone, and did not occur at chronically denervated NMJs. Instead, sprouting coincided with the arrival of regenerating NTs. Immunofluorescent staining revealed that in muscle undergoing reinnervation 4 weeks after axotomy, 91% of NMJs bore PSC sprouts, compared to only 6% of NMJs in muscle that was chronically denervated for 4 weeks. These results suggest that reciprocal interactions between regenerating NTs and PSCs govern the process of reinnervation at frog NMJs: regenerating NTs induce PSCs to sprout, and PSC sprouts, in turn, lead and guide the elaboration of NTs.     

In vivo observations of terminal Schwann cells at normal, denervated, and reinnervated mouse neuromuscular junctions

We found a low-molecular-mass, fluorescent dye, Calcein blue am ester (CB), that labels terminal Schwann cells at neuromuscular junctions in vivo without damaging them. This dye was used to follow terminal Schwann cells at neuromuscular junctions in the mouse sternomastoid muscle over periods of days to months. Terminal Schwann cell bodies and processes were stable in their spatial distribution over these intervals, with processes that in most junctions were precisely aligned with motor nerve terminal branches. Three days after nerve cut, the extensive processes elaborated by terminal Schwann cells in denervated muscle were labeled by CB. The number and length of CB-labeled terminal Schwann cell processes decreased between 3 days and 1 month after denervation, suggesting that terminal Schwann cell processes are only transiently maintained in the absence of innervation. During reinnervation after nerve crush, however, terminal Schwann cell processes were extended in advance of axon sprouts, and these processes persisted until reinnervation was completed. By viewing the same junctions twice during reinnervation, we directly observed that axon sprouts used existing Schwann cell processes and chains of cell bodies as substrates for outgrowth. Thus, CB can be used to monitor the dynamic behavior of terminal Schwann cells, whose interactions with motor axons and their terminals are important for junction homeostasis and repair.     

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.     

The three-dimensional structure of motor endplates in different fiber types of rat intercostal muscle

Summary The three-dimensional organization of the motor end plates in the red, white and intermediate striated muscle fibers of the rat intercostal muscle was observed under a field-emission type scanning electron microscope after removal of connective tissue components by HCl hydrolysis.The motor endplate of the white fiber had terminal branches (or axon terminals), which were large, long and thin, and small but numerous nerve swellings (or terminal boutons). The motor endplate of the red fiber had terminal branches, which were small, short and thick, and had large but fewer nerve swellings. The motor endplate of the intermediate fiber was intermediate in size and structure between these two. In detached nerve-ending preparations, primary synaptic grooves with slit-like openings of the junctional folds appeared on the surface of the muscle fibers. The primary synaptic grooves were more developed in the white fiber than in the red fiber, and they were intermediate in the intermediate fiber. The numerical ratio of slit-like openings was 11.83.5 in the red, intermediate and white fiber, respectively.The Schwann cells and their processes were observed on the surface of the motor endplate, with the processes covering the upper orifices of the primary synaptic grooves and sealing the terminal branches. The number of Schwann cells was usually three in the white fiber, two in the intermediate fiber and one in the red fiber.     

The effects of electrical inactivity and denervation on the distribution of acetylcholine receptors in developing rat muscle

Explants of thoracic body wall from rat embryos, including intercostal muscles, ribs, and the adjacent segments of spinal cord, were maintained in organ culture. Nerve-muscle differentiation proceeded in culture with a pattern and time course similar to that of the same synapses developing in utero. To understand further the factors that regulate acetylcholine sensitivity in developing rat myotubes, we studied the effects of electrical inactivity and denervation on the distribution of acetylcholine receptors. When muscle and spinal cord were explanted at 15 days of gestation, prior to the appearance of junctional receptor clusters, intact nerve terminals were required to initiate receptor aggregation at the site of nerve-muscle junction. Electrical activity was not necessary for induction of these primary junctional clusters. Inactivity resulted, however, in the appearance of secondary multiple receptor clusters at random sites along the fibers. In the presence of tetrodotoxin, the electrically inactive nerve terminals sprouted; this was accompanied by the enlargement of the junctional receptor clusters, at the end plate, but there was no correlation between nerve sprouting and the location of extrajunctional receptor aggregates. Later in development, at a time when the junctional receptors are metabolically more stable, terminal sprouting failed to induce the increase in size of junctional receptor aggregates.     

Pericyte involvement in capillary sprouting during angiogenesis in situ

Summary To investigate the participation of microvascular pericytes in the process of capillary sprouting, we examined whole-mount preparations of the rat mesentery by use of a double immunofluorescence approach. Angiogenesis was induced by intraperitoneal injections of either the mast cell-degranulating substance compound 48/80 or tumor cell-conditioned medium. Capillary sprouts were visualized by staining with rhodaminconjugated phalloidin and pericytes were simultaneosly stained by an antibody to the intermediate filament protein desmin. Developing pericytes were negative for the smooth-muscle isoform of -actin, bbut were clearly reactive for desmin. Pericytes appear to be involved in the carliest stages of capillary sprouting. Pericytes were regularly found lying at and in front of the advancing tips of endothelial sprouts. At many sites pericytes were seen to bridge the gap between the leading edges of opposing endothelial sprouts, which were apparently preparing to merge, suggesting that pericytic processes may serve as guiding structures aiding outgrowth of endothelial cells.