The Effect of Inhibiting the Calcium Activated Neutral Protease,on Motor Unit Size after Partial Denervation of the Rat Soleus Muscle

Rat soleus muscles were partially denervated by removal of the L5 ventral ramus at either 4 - 6 days or 17 - 19 days. Local application of leupeptin, a potent inhibitor of the calcium activated neutral protease to these operated muscles, resulted in a significantly greater maximal tetanic tension and motor unit size, when compared to untreated partially denervated muscles. This was achieved in the 4 - 6 day operated animals by an increased number of terminals and in the 17 - 19 day old animals by increased number of axonal sprouts that maintain contact with muscle fibres. In both groups of operated animals in the leupeptin treated muscles large numbers of motor units were able to maintain or achieve an expanded territory, whilst the size of the largest motor unit did not appear to be increased. It is proposed that leupeptin exerts its effect by inhibiting the degradative action of the neuronal calcium activated neutral protease on the axonal cytoskeleton. Such inhibition may act to prevent or decrease the degradation of cytoskeletal structures in the nerve terminal, and so provide protection for weak terminals at a synapse and growth cones of sprouting axons following partial denervation.     

Factors affecting denervation-like changes at the neuromuscular junction during aging

The ability to sustain synaptic transmission diminishes with aging. To determine whether this is accompanied by alterations in the structure of the synapse, end-plate architecture was examined in EDL muscles from 10- to 25-month rats. There was a significant age-related increase in end-plate area and a decrease in the number of nerve terminals per end plate. Furthermore, the percentage of end plates with ultraterminal sprouts increased dramatically with age. To compare the morphological changes associated with aging to the changes in response to denervation, EDL muscles from 10- and 25-month animals were partially denervated. Both end-plate area and ultraterminal sprouting increased, while terminal number decreased following denervation in the 10-month muscles. To determine whether the age- and denervation-associated changes were accompanied by alterations in muscle-derived nerve-outgrowth factors, in vitro assays were performed. Neurite outgrowth was quantified from embryonic motoneurons incubated with muscle extract, or grown on cryostat-cut muscle cross sections from 10- and 25-month innervated and denervated EDL muscles. Both aged and denervated muscles induced greater degrees of neurite outgrowth compared with younger innervated muscles. Innervation to the EDL was then examined, and signs of axonal degeneration were observed. It is suggested that aging is associated with alterations in the motor axon to the EDL muscle. These changes are manifest at the neuromuscular junction. In turn, the muscle responds as if it were in a state of functional denervation.     

A specific force deficit exists in skeletal muscle after partial denervation.

Skeletal muscle demonstrates a specific force deficit after repair of injured peripheral nerves, microneurovascular muscle transfer, and normal aging. Because atrophy cannot account for deficits in specific force, other, unknown, mechanisms are responsible for the resulting muscle contractile dysfunction under these circumstances. We tested the hypothesis that a subpopulation of denervated fibers is partially or completely responsible for the specific force deficit after partial denervation of the rat extensor digitorum longus muscle (EDL). Adult Fisher rats underwent either sham exposure or partial transection of 80% of the cross-sectional area of the left deep peroneal nerve. After a 2-week recovery period, maximum isometric force (F(0)) was measured in situ and maximum specific force (sF(0)) was calculated for EDL from both control (n = 8) and partial denervation (n = 7) groups. Innervated fiber cross-sectional area (CSA(inn)) was measured directly from whole EDL cross sections after immunohistochemical labeling for neural cell adhesion molecule (NCAM), a marker of muscle fiber denervation. A corrected specific force value (sF(0-inn)) was calculated by normalizing F(0) to CSA(inn). Partial skeletal muscle denervation resulted in significant reductions in muscle mass, F(0), and sF(0). The percentage of muscle fibers expressing NCAM in the extrajunctional sarcolemma increased from 1.0 +/- 0.8% in control to 49 +/- 15% in partially denervated EDL muscles. A 62.7% deficit in EDL specific force was observed after partial denervation. Denervated muscle fibers accounted for 59.3% of this deficit, but sF(0-inn) still differed significantly between control and partially denervated muscles, with a 25.5% difference between groups. In partially denervated muscles, the specific force deficit is partially but not fully explained by a subpopulation of noncontractile, denervated fibers.     

Org.2766 stimulates collateral sprouting in the soleus muscle of the rat following partial denervation

The influence of melanocortins on the process of collateral sprouting has been investigated in rat soleus muscle. The soleus muscle was partially denervated by transecting and ligating the L5 mixed nerve. Collateral sprouting was assessed by means of isometric twitch tension measurements of soleus motor units that remained following L5 transection. The smaller the number of remaining soleus motor units, the larger the extent of collateral sprouting. Seven days following partial denervation, the index of sprouting (ratio between twitch tension of motor units in partly denervated muscles and in normal muscles) was significantly increased by treatment with the ACTH4-9 analog Org.2766 (1 microgram/48 hours). This increase appeared to be present also 28 days following partial denervation. The electrophysiological results were confirmed by histological investigations. The results provide evidence that Org.2766 increases the motor neuron collateral sprouting capacity of peripheral nerve. Org.2766 did not induce muscle fiber hypertrophy.     

Differential effects of NT-3 on reinnervation of the fast extensor digitorum longus (EDL) and the slow soleus muscle of rat

Previous studies of gastrocnemius muscle reinnervation showed specific normalization of the proportion and diameter of fast type 2b muscle fibres following NT-3 delivery to the proximal stump of the cut sciatic nerve. Here, we investigate if normalization was related to greater improvement of muscle reinnervation of fast (extensor digitorum longus; EDL) than slow (soleus) motor units. NT-3-impregnated (NT-3 group) or plain fibronectin (FN group) mats were inserted into a sciatic nerve gap. Neuromuscular junctions (NMJs) labelled with TRITC-alpha-bungarotoxin were colabelled with calcitonin gene-related peptide (CGRP) or 4E2 antisera and imaged using confocal microscopy. CGRP and 4E2 were used as markers for newly reinnervated and structurally mature NMJs, respectively. At 40 days postsurgery, denervated NMJs in EDL and soleus muscles of both groups presented a 50% decrease of surface area due to decreased width. At day 80 in EDL, more NMJs were reinnervated by CGRP-immunoreactive terminals in the NT-3 (7.1%) than in the FN group (4.2%); there was no difference between groups for soleus. At 120 days, 4E2-immunoreactive NMJs were more numerous in EDL of the NT-3 (40.0%) than in the FN group (7.3%), unlike in soleus (NT-3, 1. 6%; FN, 1.8%), and presented a partial size recovery. These results indicate that NT-3 preferentially improves reinnervation of fast muscles over slow muscle, although the mechanism of this improvement is still unclear.     

Glycosaminoglycans treatment increases IGF-I muscle levels and counteracts motor neuron death: A novel nonanticoagulant action

The present study shows that sciatic nerve crush in 2-day-old rats causes extensor digitorum longus (EDL) muscle atrophy and motor neuron loss and that treatment with glycosaminoglycans (GAGs) promotes muscle reinnervation, motor neuron survival, and markedly increases insulin-like growth factor-I (IGF-I) content in the denervated muscles. EDL muscle denervation-induced atrophy in saline-treated rats is progressive and reaches the greatest extent at 42 days after birth, which correlates with reduced EDL weight growth. There is also a partial reinnervation as shown by the number of reinnervated EDL muscle fibers (65.4% of control) and by the poor restoration of the indirect isometric twitch tension (62% of control) that is further reduced under tetanic stimulation (34% of control). The number of surviving motor neurons that innervate EDL muscle drops from 55 +/- 3 to 29 +/- 8. In GAGs-treated 42-day-old rats, the effects of neonatal nerve lesioning on EDL muscle atrophy and denervation are successfully reversed, and the isometric twitch tension and the capacity to hold tetanic stimulation are restored to almost control levels. The number of surviving EDL motor neurons is also increased to 43 +/- 4. Treatment with GAGs selectively affects IGF-I content in denervated hindlimb muscles, which is augmented from 7.02 +/- 0.71 ng/mg tissue to 25.72 +/- 0.7 in the EDL and from 3.2 +/- 0.18 to a robust 211 +/- 9.6 in the soleus.     

Choline acetyltransferase activity in muscles of old rats

The total activity of choline acetyltransferase (ChAc) in the rat extensor digitorum longus (EDL) and soleus muscles increased by 50 and 55%, respectively, between 3 and 9 months of age. In rats 28 to 29 months old, the activity of ChAc in EDL and soleus diminished to 41 and 40%, respectively, of the activity observed in 9-month-old animals. Age changes of ChAc activity in the diaphragm were not significant. The number of muscle fibers in EDL and soleus muscles of rats 28 to 29 months old decreased by 44 and 38% respectively, in comparison with younger animals. Mean muscle fiber diameters did not change between 3 and 9 months of age and decreased by 24, 35 and 9% in the EDL, soleus and diaphragm, respectively, in the 28- to 29-month-old rats. The activity of ChAc expressed in relation to one muscle fiber was about the same in the EDL and soleus muscles. It increased between 3 and 9 months and decreased between 9 and 28 to 29 months of age. The observation that ChAc activity per muscle fiber was identical in the fast EDL and slow soleus muscle suggests that the physiological differences between the two muscles are not caused by a difference in the capacity of their motor nerves to synthesize ACh. In the diaphragm the activity of ChAc per muscle fiber apparently did not diminish in old age. The decrease in the total ChAc activity in the limb muscles of old animals seems due both to a decrease in the number of nerve terminals in the muscles and to a decrease in the amount of enzyme present in individual terminals. We suggest that the maintenance of ChAc activity in the motor nerve terminals in the diaphragm of old rats is due to the continuous activity of this muscle and its motor nerves.     

Putative effects of nerve extract on carbonic anhydrase III expression in rat muscles

Carbonic anhydrase III (CA III), the predominant CA isoform in skeletal muscle is very sensitive to neuronal influences. We aimed to determine whether CA III expression could be influenced by neurotrophic factor(s) present in sciatic nerve extract (SNE). Intact muscles were thus compared with denervated soleus (SOL), extensor digitorum longus (EDL), and tibialis anterior (TA) muscles injected daily for 7 days with saline solution (SS) or with SNE. CA III activity was significantly increased in SS-treated EDL and TA muscles compared to control (CTR), while SNE injections partially prevented this increase. There was no significant difference for CA III activity in the SOL between CTR, SS, and SNE groups. The CA III mRNA increase observed in response to denervation was reduced by 40% in SNE-treated EDL and TA muscles. While SOL CA III mRNA level was not affected by denervation, a 52% decrease was observed with SNE. We concluded that neuronal modulation of CA III expression in type II fibers may involve a neurotrophic component. © 1994 John Wiley & Sons, Inc.     

Effect of electrotherapy on denervated muscles in rabbits: An electrophysiological and morphological study

The effects of electrotherapy on muscles denervated by crushing the sciatic nerve were studied in rabbits using electrophysiologic and morphologic techniques. The sciatic nerve was crushed in the thigh, just above its division into the lateral and medial popliteal nerves and the completeness of denervation was ascertained by EMG tests. Electrotherapy was carried out in six animals and six others were denervated controls; the contralateral leg of each animal was used as the normal control. The first appearance of signs of reinnervation was detected by means of EMG tests and the “reinnervation time” established. The animals were killed at the 50th day after nerve crush; the length of nerves below the crushed point was measured; soleus and extensor digitorum longus (EDL) muscles were removed and weighed. The percentages and the mean diameter of different muscle-fiber types in normal, control-denervated, and treated soleus and EDL muscles were calculated. No statistically significant difference was observed between electrophysiologic findings in control-denervated and treated rabbits. Electrotherapy was found to antagonize the weight loss of EDL muscles and the reduction of type 2b fiber diameters induced by denervation, but significantly accentuated the reduction of the mean diameter of type 1 fibers in EDL and soleus and increased the weight loss of denervated soleus muscles. The results obtained raise further doubts about the clinical utility of electrotherapy.     

Dynamics of nuclei of muscle fibers and connective tissue cells in normal and denervated rat muscles

The mitotic activity in muscles of growing rats and the effect of denervation were studied by means of continuous infusion of 5-bromo-2-deoxyuridine (BRDU). Denervated muscles after 10 weeks contained 20 to 60% fewer muscle nuclei than normal; BRDU labeled about 25% of the nuclei of normal soleus and extensor digitorum longus (EDL) and of denervated EDL muscles but only 5% in the denervated soleus muscle. Labeled nuclei persisted in denervated but not in normal muscles. After the main growth period, the turnover of myonuclei was at most 1 to 2% per week. The behavior of connective tissue nuclei was similar to that in muscle fibers. Infusion of BRDU had no effect on contractile properties. It is suggested that the exceptionally rapid atrophy of the denervated rat soleus associated with loss of satellite cells was due to loss of myonuclei and differentiation and fusion of satellite cells. The cause may possibly be that the phase of postdenervation fibrillation is shorter than in other muscles.     

Reinnervation of long-term denervated rat muscle freely grafted into an innervated limb

This experiment was designed to test the hypothesis that in the presence of regenerating nerve fibers long-term denervated skeletal muscle does not become reinnervated. This hypothesis was tested in rats by the transplantation of 22-month denervated extensor digitorum longus (EDL) muscles into the sites of EDL muscles in the contralateral, normally innervated legs. Two months after transplantation, the muscles contracted when stimulated via the motor nerve, and based on silver-acetylcholinesterase staining, all grafts possessed innervated motor end plates. Compared to values for control EDL muscles in old rats, the maximum force developed by standard free grafts in old rats was 19% and that of long-term denervated grafts was 7%. For standard free grafts, nerve stimulation produced a maximum force that was 81% of that produced by direct stimulation, and for control EDL muscles in young and old rats, the values were 96 and 90%, respectively. These results show that after long-term denervation rat muscles are capable of becoming functionally reinnervated, even though by the time of reinnervation the animals have attained an advanced age of 26 months.     

Effect of vinblastine on neural regulation of metabolism in rat skeletal muscle.

Chronic application of vinblastine, a substance known to disrupt axoplasmic flow, to nerves innervating the fast extensor digitorum longus and slow soleus muscles of the rat, produces electrophysiological signs of denervation (depolarization and extrajunctional acetylcholine sensitivity), but does not alter motor activity. We therefore examined the effects of vinblastine treatment on those metabolites and enzymes that are known to change after denervation of fast and slow skeletal muscle. A silastic cuff containing 0.1% vinblastine was placed around sciatic nerves of adult rats for 5 days. Glucose-6-P decreased 68% in the extensor, but did not change in soleus muscles. Phosphocreatine also decreased slightly, but significantly, in the extensor. Thus, intracellular levels of glucose-6-P and phosphocreatine in the extensor may be controlled, in part, by a factor (s) transported to the muscle by axoplasmic flow. Other metabolites known to change 5 days after denervation, namely glucose, glycogen, lactate, and α-ketoglutarate, were not altered in extensor and soleus muscles innervated by vinblastine-treated nerves. The activities of glucose-6-phosphate dehydrogenase and hexokinase increased in denervated extensor muscles, but not in denervated soleus muscles. Thus, metabolism in extensor muscles may be more readily altered after disruption of neural influences than is metabolism in soleus muscles. In contrast to denervation, exposure of sciatic nerves to vinblastine did not alter enzyme activities. These results provide evidence that certain metabolic processes, as well as membrane properties in skeletal muscle, are influenced by separate and distinct neural factors.     

The role of Ca2+ in the elimination of polyneuronal innervation of rat soleus muscle fibres

The mechanism by which nerve - muscle contacts are reduced during postnatal development of the rat soleus muscle was investigated using electrophysiological methods. Between days 7 and 9 after birth, soleus muscle fibres lose 0.19–0.24 terminals per muscle fibre within 24 h. A much more rapid loss of contacts is seen when muscles are exposed in vitro to acetylcholine (10⁻³ g/ml). In this case 0.67–0.87 terminals per muscle fibre lose contact within 2 h. The loss of neuromuscular contacts induced by acetylcholine can be reduced by preincubating the muscles in solutions containing acetoxymethyl ester of 1,2-bis(2-amino-phenoxylethane-N,N₁;N₁-tetraacetic acid (BAPTA-AM), a Ca²⁺ chelating agent that enters cells and reduces the Ca²⁺ transients inside the cell. Treatment of muscles with nifedipine, which blocks dihydropyridine-sensitive (L-type) Ca²⁺ channels, also reduced the acetylcholinesterase-induced loss of neuromuscular contacts. The results indicate that transient increases in Ca²⁺ inside nerve terminals contribute to loss of neuromuscular contacts, and that these increases occur by Ca²⁺ entry through L-type channels.     

Biochemical,morphological, and functional changes during peripheral nerve regeneration

The success of axon regeneration after nerve injury should be judged by the extent to which the target organs regain their function. Recovery of muscle contraction involves axon regeneration, reestablishment of nerve-muscle connections, recovery of transmission, and muscle force. All these processes were investigated under the same experimental conditions and correlated in order to better understand their time-course and interdependence. The sciatic nerve of a rat was crushed in the thigh. The ingrowth of regenerating motor axons into the soleus (SOL) and extensor digitorum longus (EDL) muscles was monitored by measuring the activity of choline acetyltransferase (ChAT), a marker enzyme for cholinergic nerve terminals, in the muscles. The electron microscopic cytochemistry of acetylcholine esterase (AChE) was used to estimate the reestablishment of neuromuscular junctions in these two muscles. The recovery of muscle contraction was followed by measuring the force of isometric contraction in the triceps surae muscle in vivo. The pattern of ChAT recovery during reinnervation was similar in the EDL and SOL. The statistically significant increase of ChAT activity in these muscles, 14 d after the nerve crush, signified the entry of regenerating axons into the calf muscles. Electron microscopic cytochemistry revealed the first small nerve endings in contact with the denervated end plates 12 d after denervation. Subsequently, the number of reinnervated motor end plates and the surface area of the neuromuscular junctions steadily increased. The recovery of muscle force started between d 14 and 21 after the nerve crush. Thirty-five days after denervation, the difference between the muscle force of the reinnervated muscle and the control became statistically insignificant. Morphological normalization of the motor end plates was practically complete 33 d after denervation, concomitant with the normalization of the muscle force. At that time, however, ChAT activity in both muscles was still clearly subnormal (33.5% in EDL and 45% of the control in SOL) and therefore does not reflect the true extent of muscle force recovery. Yet, it seems that in spite of this, the regenerated nerve terminals contained sufficient amounts of acetylcholine (ACh) to trigger normal muscle contractions.     

Biometrical and histochemical comparison between extra- and intra-fusal muscle fibres in denervated and re-innervated rat muscle

Summary Biometrical and histochemical changes in extra- and intrafusal muscle fibres were determined in twenty adult rats during denervation and re-innervation. The right sciatic nerve was severed and at regular intervals the denervated gastrocnemius, soleus and peroneal muscles were examined and compared with the corresponding muscles of the non denervated limb.Although the extra- and intra-fusal muscle fibres show the same histochemical changes, the atrophy of the intra-fusal muscle fibres is insignificant compared with the atrophy of the extra-fusal muscle fibres in the denervation phase. This could be explained by the small size of the intra-fusal fibres and the increased fluid resorption of the spindle.In the re-innervation phase the same histochemical changes occur in both types of muscle fibres.     

Effects of steroid hormones on muscle reinnervation after nerve crush in rabbit

The ability of an association of three steroid hormones to influence the reinnervation process and the trophism of rabbit muscles denervated by crush of the sciatic nerve was investigated. The beginning of reinnervation was established with electromyographic recordings from the tibialis anterior muscle. The distance from the site of crushing to the point where the motor nerve enters the tibialis anterior muscle was then measured in each animal, and the nerve regeneration velocity (mm/day) was calculated: a slightly but significantly higher (P less than 0.001) mean value was found in treated animals compared with untreated ones. When soleus and extensor digitorum longus (EDL) muscles were histochemically examined 50 days after lesion, a larger mean diameter of type 2c fibers was found in treated than in untreated animals, pointing out a possible useful effect of the treatment. On the contrary, the size reduction of EDL type 2b fibers was more pronounced in treated rabbits, indicating a catabolic influence of the drugs on this fiber type.     

Effect of nerve extract on atrophy of denervated or immobilized muscles

Changes in denervated muscles are due to disuse caused by paralysis of the muscle and the loss of special neurotrophic substances. We determined the relative roles of these two factors in the production of atrophy in denervated rats' extensor digitorum longus (EDL) muscles. Muscles were denervated and/or immobilized (by fixation of the ankle) for 7 days. Some rats also received daily intramuscular injections of a saline extract of rats' sciatic nerves (2.0 mg protein/ml). Atrophy was assessed by measurement of wet weight, total protein, and cross-sectional areas of types IIA and IIB fibers (in sections stained for ATPase). Both denervation and immobilization produced significant decreases in weight, protein, and areas of fiber. The group of rats with denervated EDL muscles had significantly greater atrophy than the group with immobilized muscles. In another group, denervated EDL muscles had significantly greater atrophy than contralateral muscles which were immobilized. However, when denervated muscles were injected with nerve extract, they did not differ significantly from contralateral, noninjected, immobilized muscles. Comparisons of the group of rats in which one EDL was denervated with groups in which one muscle was immobilized or was denervated and injected with nerve extract, indicated that loss of trophic influence was responsible for about 40% of the decreases in wet weight, total protein, and cross-sectional area of type IIB fibers, and the remaining 60% was due to disuse. Loss of trophic influence was responsible for only about 5% of the atrophy of denervated type IIA fibers. Therefore, inactivity and loss of neurotrophic influence were responsible for the atrophy which occurred in denervated skeletal muscles, and these two factors influenced the two types of fiber differently. The component of denervation atrophy due to loss of trophic influence could be completely prevented by injection of substances extracted from peripheral nerves.     

Neurotrophic effects of sciatic nerve extract on denervated extensor digitorum longus muscle in the rat

The trophic action of nerves upon muscles may be mediated by substances secreted by the terminals of the nerves. Several investigators showed that peripheral nerves contain a protein with trophic actions on denervated muscle maintained in tissue culture. This study was undertaken to determine whether or not the neurotrophic properties of proteins extracted from nerves are also demonstrable Pitin vivo. The right extensor digitorum longus (EDL) was denervated in 42 rats. For the following 7 days the denervated EDL was injected daily with a saline extract of rats' sciatic nerves (protein content 2.0 mg/ml). Control groups received injections of saline or of heat-inactivated nerve extract into the denervated EDL, or received no treatment. In denervated EDL muscles injected with nerve extract, there were significantly smaller mean decreases in wet weight (P < 0.05) and total protein (P < 0.05) than in the denervated controls. The mean reduction in cross-sectional area of type IIB muscle fibers (in sections stained for ATPase) was 16 ± 2% less (P < 0.005) than in the control animals. There were no significant differences in the cross-sectional area of IIA fibers or in the content of acetylcholinesterase. Thus, a substance present in a peripheral nerve is able in vivo to ameliorate some of the consequences of denervation of a striated skeletal muscle.     

Carnitine and acyltransferase in experimental neurogenic atrophies: changes with treatment

Summary Carnitine level and carnitine palmityl transferase (CPT) activity were investigated in muscles of patients with infantile and juvenile spinal muscular atrophy and polyneuropathies. A significant decrease of both carnitine and CPT was found in the infantile spinal muscular atrophy, but not in the other neurogenic muscle atrophies. These findings were compared with the experimental effect of denervation and reinnervation upon the lipid metabolism in soleus and extensor digitorum longus (EDL) of adult and newborn rats. Twenty-one days after denervation free and total carnitine decreased significantly in both EDL (P<0.001) and soleus (P<0.05) of adult animals. CPT activity was significantly decreased in the soleus 50 days after denervation (P<0.005). Long-term reinnervation restored the level of carnitine fraction and CPT activity. l-carnitine treatment for 21 days restored the level of free carnitine to normal in the soleus of denervated adult animals. Denervation in newborn rats influenced carnitine concentration in soleus and EDL to a lesser extent; the treatment with l-carnitine raised short-chain acylcarnitines in denervated muscles, while reinnervation restored carnitine level within 50 days.Presented as a preliminary report at the Fifth International Congress on Neuromuscular Diseases, Marseille, France, September 1982     

Acetylcholinesterase activity in motor nerve fibres in correlation to muscle fibre types in rat

Rat muscle nerves were examined histochemically for their activity of acetylcholinesterase (AChE). The corresponding muscles were stained for myofibrillar ATPase and for NADH diaphorase. The nerves to the extensor digitorum longus (EDL) muscle and to the medial head of the gastrocnemius (MG) muscle consist of a motor axons of high AChE activity. Both muscles are characterized by the prevalence of type II muscle fibres. On the other hand, the soleus muscle and the quandratus femoris muscle, both mainly composed of type I muscle fibres, are innervated by a motor axons of low AChE activity. Since it is well established that EDL and MG are typical fast-twitch muscles and that the soleus, and probably also the auadratus femoris, is a typical slow-twitch muscle, it is suggested that, in rat, fast muscles are innervated by motor nerve fibres of high AChE activity and slow muscles are innervated by motor axons of low AChE activity.