Muscle fiber type differentiation and satellite cell populations in normally grown and neonatally denervated muscles in the rat

Summary To examine the neural influence upon fiber type differentiation in developing muscles, newborn rats were subjected to sciatic nerve dissection, and the denervated extensor digitorum longus (EDL) (white) and soleus (red) muscles were examined in chronologic sequence by means of histochemistry and electron microscopy. The skeletal muscles in the newborn rats were undifferentiated (type 2C fibers seen on ATPase staining) and contained numerous myotubes. In the controls, the type 2C fibers started to differentiate at around 5 days and had almost completed type differentiation by 30 days in EDL and by 90 days in soleus muscles. On the other hand, none of the fibers in the neonatally denervated muscles developed into well differentiated type 1 and 2A fibers, but both the EDL and soleus showed longlasting type 2C and 2B populations. The satellite cells in the denervated EDL and soleus muscles decreased in number at the same rate as in the control muscles with maturation. The absence of a neural supply in the developing muscles induced a delay in muscle fiber type differentiation but did not influence the satellite cell populations in either EDL or soleus muscles.     

Factors affecting muscle fiber transformation in cross. Reinnervated muscle

Nerves of two fast muscles [peroneus longus (PL) and extensor digitorum longus (EDL)], having different type 2 muscle fiber compositions, were used to cross-reinnervate the slow soleus muscle in the rat. Contraction characteristics, histochemical muscle fiber type compsotions and myosin heavy chain (MHC) isoform compositions were determined for the reinnervated muscles. Shortening velocity increased in soleus muscles crossreinnervated with EDL nerve [X-SOL(EDL)] but not in muscles cross-reinnervated with PL nerve [X-SOL(PL)]. Type 2A MHC isoform content was increased in X-SOL(EDL) but not in X-SOL(PL), where MHC isoform composition remained similar to normal soleus. The complement of type 1 (slow) muscle fibers was reduced and that of type 2 (fast) fibers increased in both types of X-SOL muscle, but this change was significantly greater in X-SOL(EDL); the majority of the type 2 fibers in X-SOL muscles were of type 2A. Results show that “the type 2 composition” of the reinnervating motoneuron pool is an important factor in determining the transformation of a target slow muscle after cross-reinnervation. © 1993 John Wiley & Sons, Inc.     

Effects of tenotomy on muscles reinnervated by a foreign nerve

Tenotomy of the rat soleus (SOL) and gastrocnemius (MG) muscles produces a central degeneration in slow fatigue-resistant fibers, but not in similar fibers of muscles in the extensor and peroneal compartments. To investigate the part that innervation plays in rendering a particular fiber type in a particular muscle susceptible to this degeneration, the SOL, extensor digitorum longus (EDL), and MG muscles were experimentally reinnervated by foreign nerves and tenotomized. When the SOL was reinnervated by the common peroneal nerve, slow fatigue-resistant fibers showed lesions, but when the EDL was reinnervated by the nerve to the SOL, no lesions were found after tenotomy. When the MG was reinnervated by the nerve to the SOL, slow fatigue-resistant fibers that had differentiated in regions normally occupied almost entirely by fast fatigable fibers showed characteristic lesions. These results show that the failure of tenotomy to produce lesions in the EDL is not due to the nature of its innervation and that a fiber type not normally susceptible to the degenerative change will become susceptible when transformed to the slow fatigueresistant type.     

Effect of hind-limb suspension on young and adult skeletal muscle. II. Dystrophic mice

Disuse atrophy induced by limb immobilization reportedly protects dystrophic mouse muscle from histopathological changes. This study was conducted to determine whether disuse atrophy induced by hind-limb suspension (HS) limits the histopathology and contractile abnormalities typically observed in the dystrophic mouse. Two weeks of hind-limb suspension were applied to dystrophic mice (line 129B6F1) at two ages, 4 weeks (6 mice) and 12 weeks (8 mice). Thirty-one untreated dystrophics served as controls. In general, HS exaggerated the dystrophic signs, especially in the younger mice; it reduced animal weight, muscle weight, maximum tetanic and twitch tensions, and rates of tetanic and twitch tension development. HS further slowed the contractile properties of soleus (SOL) and extensor digitorum longus (EDL) muscles, and increased their fatigue resistance. HS reduced the size of type I and IIA fibers in the 6-week SOL and EDL, but not in the 14-week muscles. HS produced a preferential atrophy of SOL type I fibers, with a parallel increase in type IIA fibers. However, it did not alleviate the fiber size variability, degree of necrosis, central nucleation, inflammation, or muscle fibrosis in dystrophic muscles. These data demonstrate that disuse by hind-limb suspension does not prevent the histopathological deterioration or loss of muscle function in 6- and 14-week dystrophic mice.     

Changes in number and distribution of orthogonal arrays during postnatal muscle development

Quantitative freeze-fracture electron microscopy was utilized to study the changes in number and distribution of orthogonal arrays (aggregates of 6-7 nm particles) of the sarcolemmas of the fast twitch extensor digitorum longus (EDL) and slow twitch soleus muscles during the first few weeks of postnatal development in the rat. In the adult rat, orthogonal arrays are present in high densities in the fast twitch type II fibers but only in low densities in slow twitch type I fibers. In this study, the changing histochemical profiles of fiber types in the EDL and soleus muscles were also determined for the first month of postnatal development and correlated with the changing number and distribution of orthogonal arrays during the same time frame. At day 3 postpartum, EDL and soleus fibers possessed few orthogonal arrays. The developing EDL fibers rapidly acquired additional orthogonal arrays until the approximate adult number and distribution were attained at postpartum day 25. In contrast, the slow twitch soleus fibers rapidly acquired orthogonal arrays and type IIA fibers until day 35 when both were in excess of adult values. Subsequently, the number of arrays and type IIA fibers declined to normal adult ranges. We suggest that the patterns of development of orthogonal arrays and fiber types are different in the EDL and soleus because the types of innervating motor units are different in the two muscles. The EDL is innervated almost entirely by fast motor units throughout early development and maturity. The soleus, however, is initially innervated by a more heterogeneous population of motor neurons. Thus, during the period of polyneuronal innervation which occurs normally during the first weeks of postnatal development, many individual soleus fibers may possess simultaneous innervation by axons from different motor neuron types. These dual influences may be responsible for the irregular pattern of development of orthogonal arrays and type IIA fibers in developing soleus fibers. Later, as the adult pattern of monosynaptic innervation is developed, expected adult values of orthogonal arrays and fiber types are attained.     

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.     

Changes in the cholinergic system of rat sciatic nerve and skeletal muscle following suspension-induced disuse

Muscle disuse-induced changes in the cholinergic system of sciatic nerve, slow-twitch soleus (SOL), and fast-twitch extensor digitorum longus (EDL) muscles were studied in rats. Rats with hind limbs suspended for 2 to 3 weeks showed marked elevation in the activity of choline acetyltransferase in sciatic nerve (38%), in the SOL (108%), and in the EDL (67%). Acetylcholinesterase (AChE) activity in the SOL increased 163% without changing the molecular forms pattern of 4S, 10S, 12S, and 16S. No significant (P greater than 0.05) changes in the activity and molecular forms pattern of AChE were seen in the EDL or in AChE activity of sciatic nerve. Nicotinic receptor binding of [3H]acetylcholine was increased in both muscles. When measured after 3 weeks of hind limb suspension the normal distribution of type I fibers in the SOL (87%) was reduced (to 58%) and a corresponding increase in types IIa and IIb fibers occurred. In the EDL no significant change in fiber proportion was observed. Muscle activity, such as loadbearing, appeared to have a greater controlling influence on the characteristics of the slow-twitch SOL muscle than on the fast-twitch EDL muscle.     

Failure of neuromuscular transmission and contractility during muscle fatigue

In previous studies of muscle fatigue, tension was monitored from whole muscle, while action potentials were recorded from a few muscle fibers. To compare more accurately changes in these responses, an in vitro fluid electrode technique was employed to record the action potential of whole muscle simultaneously with tension during fatigue induced by nerve stimulation in the rat extensor digitorum longus (EDL), soleus, and diaphragm muscles. In each muscle, tension declined from the start of stimulation, while action potential amplitude initially increased slightly and then declined most rapidly in EDL, more slowly in diaphragm, and most slowly in soleus. Direct stimulation of the fatigued muscle produced the greatest increase in tension in EDL, next in diaphragm, and least in soleus. These results indicate that while failure of excitation-contraction coupling or of the contractile mechanism is the initial cause of fatigue in all the muscles studied, and remains the predominant cause throughout in the soleus muscle, failure of neuromuscular transmission plays an important role in fatigue after the first 15 seconds in EDL, and to a lesser extent, after the first 90 seconds in diaphragm.     

Repeated injury to the sciatic nerve in immature rats causes motoneuron death and impairs muscle recovery

Injury to the sciatic nerve of newborn rats causes motoneuron death, while the same insult inflicted 5 days later does not. In this study the effects of prolonging the period of target deprivation and axonal regeneration were investigated by inflicting a second nerve crush 6 days after the first, just before reinnervation of the muscle occurred. Two to 4 months later the number of motoneurons supplying soleus, tibialis anterior, and extensor digitorum longus muscles was established by retrograde labeling with horseradish peroxidase injected into the muscle. After nerve injury at 5 days there was no significant loss of motoneurons to any muscle. However, when the injury was repeated, the number of labeled motoneurons was reduced, suggesting that a significant proportion had died. Motoneurons to soleus were affected more than those to the fast muscles, reflecting their lesser maturity. Moreover, motoneurons to soleus that survived both injuries to their axon failed to grow to their full size. The relative impairment of recovery of the muscles, indicated by weight and maximal tetanic tension, mirrored the loss of motoneurons in each case. Previous studies have suggested that repeated nerve injuries in adult animals can enhance reinnervation. However, the present results along with those of other recent studies suggest that immature motoneurons that are repeatedly induced to support growth of their axons are at greater risk of death and can result in poorer reinnervation of the muscles.     

Effect of hind-limb suspension on young and adult skeletal muscle. I. Normal mice

The purpose of this study was to determine the effect of hind-limb suspension (HS) on morphometric, histologic, and contractile characteristics of fast extensor digitorum longus (EDL) and slow soleus (SOL) twitch muscles in adult and immature mice. Hind-limb suspension for 2 weeks was used to produce atrophy in two groups of mice, ages 4 and 12 weeks, with nonsuspended animals serving as controls. Young HS mice exhibited marked decreases in SOL weight, length, cross-sectional area (CSA), twitch and tetanic tensions, and rates of tension development and relaxation, with increases in fatigue resistance. HS reduced the diameter of both type I and IIA fibers, increased the percentage of type I fibers, and decreased the percentage of type IIA fibers in both young and adult SOL. Muscle weight, length, CSA, IIA and IIB fiber areas, and maximum rate of tetanic tension development were decreased in EDL of young HS mice; fatigue resistance and EDL half-relaxation times were increased. For most parameters evaluated, slow twitch muscle was more affected than fast twitch. HS affected contractile characteristics less than morphometric or histologic parameters. Rates of tension development and relaxation were the contractile parameters most affected by HS, and the time parameters of contraction were least affected. For all measurements young mice were more affected than adult mice.     

Absence of Nerve - muscle Interaction Influences the Survival of Developing Motoneurons

Following sciatic nerve crush at birth, approximately 70% of motoneurons to the soleus and 60% of motoneurons to the tibialis anterior (TA) and to the extensor digitorum longus (EDL) die. However, following nerve injury at 5 days, there is negligible motoneuron death. We investigated whether the interaction between the nerve and its target during these 5 days is an important factor for the ability of the motoneuron to survive injury. Nerve - muscle interaction was blocked shortly after birth by alpha-bungarotoxin (BTX) and the effect on motoneuron survival after subsequent injury was examined. It was confirmed that sciatic nerve crush at 5 days produced no significant reduction in motoneuron numbers. However, if nerve crush was preceded by paralysis with alpha-bungarotoxin, the number of surviving motoneurons after nerve injury at 5 days was substantially reduced. On the operated side only 43 +/- 6.68% of the motoneurons of the soleus pool survived and even fewer, 14 +/- 5.0%, in the TA and EDL pool. In a control group of animals paralysed with alpha-bungarotoxin at birth but receiving no nerve crush, there was no appreciable reduction in the motoneuron numbers at 28 days in either motor pool. It is concluded that blocking of nerve - muscle interaction by paralysis in early postnatal life reduces the motoneurons' ability to survive nerve injury later in life, and that this effect is more severe for the motoneurons to the TA and EDL than to the soleus.     

Fiber type susceptibility in the dystrophic mouse

Slow-twitch soleus (SOL) and fast-twitch extensor digitorum longus (EDL) muscles from young normal and dystrophic ( ) mice were examined histochemically. Counts were made of total fiber content and of the proportions of various fiber types in whole cross sections. By 3 weeks of age the number of fibers in the SOL of dystrophic mice decreased by 16%. The proportions of both type I and type II_ox fibers decreased approximately equal amounts. Even at this relatively early stage of the disease process, almost 20% of the fibers appeared abnormal and could not be clearly identified as belonging to a specific fiber type. Very few type I fibers with dystrophic characteristics were seen. However, this may simply reflect an alteration in staining characteristics which preceded structural changes in involved fibers. In 6- to 7-week-old EDL muscles the most marked change occurred in the proportion of type II_glyc fibers. The percentage of these fibers in dy^2J mice was 8.4% compared with 57.3% in control animals. At this stage the total number of fibers in dy^2J EDL had decreased by 30%, although the number of type II_ox fibers remained virtually constant. Various explanations for these findings are considered.     

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.     

Neural regulation of muscle acetylcholinsterase: effects of batrachotoxin and 6-aminonicotinamide.

Batrachotoxin (BTX), which causes increased Na+ permeability and blocks axoplasmic transport, or 6-aminonicotinamide (6-AN), which causes neuronal damage, was injected into the subarachnoid space of rat lumbar spinal cord. The activity of acetylcholinesterase (AChE) was measured in homogenates of the fast-twitch extensor digitorum longus (EDL) muscle and the slow-twitch soleus (SOL) muscle 10 days after injection. Both drug treatments significantly decreased AChE in EDL and SOL. Correlative electrophysiological measurements were made in intact EDL and SOL after injection of BTX or 6-AN. The results support the hypothesis that AChE in muscle is neurotrophically controlled.     

Experimental corticosteroid myopathy

Summary The steroids triamcinolone, dexamethasone, beta-methasone, and cortisone were administered i.p. to adult rats for 14–63 days. The extensor digitorum longus (EDL, white muscle) and soleus (SOL, red muscle) muscles were examined histologically and histochemically. Triamcinolone was the most potent lesion-producing drug. Selective involvement of muscles, and of the fiber types within them was observed: Neerotic changes were seen only in the type 1 fibers of the SOL; atrophic fibers were observed in the type 2 fibers of both the SOL and the EDL.     

Effect of NT-4 and BDNF delivery to damaged sciatic nerves on phenotypic recovery of fast and slow muscles fibres

We investigated whether neurotrophin-4 (NT-4) and brain-derived neurotrophic factor (BDNF) affected the reinnervation of slow and fast motor units. Neurotrophin-impregnated or plain fibronectin (FN) conduits were inserted into a sciatic nerve gap. Fast extensor digitorum longus (EDL) and slow soleus muscles were collected 4 months postsurgery. Muscles were weighed and fibre type proportion and mean fibre diameters were derived from muscle cross-sections. All fibre types in muscles from FN animals were severely atrophied and this correlated well with type 1 fibre loss and atrophy in soleus and type 2b loss and atrophy in EDL. Treatment with NT-4 reversed soleus but not EDL mass loss above the FN group by significantly restoring type 1 muscle fibre proportion and diameters towards those of normal unoperated animals. BDNF did not increase muscle mass but did have minor effects on fibre type and diameter. Thus, NT-4 significantly improved slow motor unit recovery, and provides a basis for therapies intended to aid the functional recovery of muscles after denervating injury.     

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.     

Cordotomy-denervation interactions on contractile and myofibrillar properties of fast and slow muscles in the rat

Cordotomy-denervation interactions were studied on contractile and myofibrillar properties of slow (soleus) and fast (extensor digitorum longus) muscles of the rat. The spinal cord was transected midthoracically in neonatal (2-day-old) animals. Two months after birth, a unilateral transection of the sciatic nerve was carried out in both cordotomized and control animals. Five weeks after denervation, contractile properties were tested isometrically in vitro; myofibrillar properties were assessed by histochemical staining of the muscle fibers and by electrophoretic analysis of the myosin heavy chain composition. The following results were obtained: (i) In cordotomized animals the contraction time of the soleus was significantly shorter (-23.3% on average) than that in the control animals and this shortening was accompanied by a proportional slow-to-fast shift in myofibrillar properties. (ii) The extensor digitorum longus properties were not significantly different in the control and cordotomized animals. (iii) Denervation in control animals was followed by a marked increase of contraction and half-relaxation times in the extensor digitorum longus, whereas in the soleus only the half-relaxation time was significantly increased; myofibrillar properties in the soleus showed an appreciable slow-to-fast shift, whereas in the fast muscle the main change was an increase in type 2A fibers to the detriment of type 2B. (iv) In cordotomized animals, denervation caused the soleus contraction time to increase to control values, whereas myofibrillar properties shifted to an even faster pattern; in the extensor digitorum longus denervation caused the same changes seen in the control animals. The results showed that cordotomy at birth caused the soleus to develop as a faster muscle than in the control animals. The concurrent effects of cordotomy and denervation on the myofibrillar properties of the soleus suggest that the slow-to-fast change in these properties is a common consequence of the reduction in the level of motor activity. The opposite effects of the two experimental conditions in the soleus contraction time support the view that the contractile alterations that follow denervation mainly reflect alterations in the muscle activation process.     

Effects of hind limb suspension on the development of dystrophic hamster muscle

The effects of hind limb suspension on the development of dystrophic muscles was studied in five dystrophic hamsters (CHF 147, formally UMX 7.1) from age 20 days for 5 months. Their histochemical and contractile properties were compared to five aged-matched controls. Twitch and tetanic tensions (Po) were reduced in treated soleus by 22% and 32% and in plantaris by 29% and 39%, respectively; these reductions were proportional to their smaller cross-sectional areas. Twitch duration and half-relaxation times were not altered in experimental soleus muscle but the mean time to 50% of Po was 19 ms faster than the controls. Experimental soleus and plantaris had higher percentages of type II fibers, i.e., 63% and 97% compared with 37% and 93% in controls, respectively. A similar trend was seen in gastrocnemius and extensor digitorum longus muscles. Areas of both fiber types were reduced in all muscles, but only statistically significant differences in type I areas were seen in soleus and type II areas in the other three muscles. The percentages of fibers with centronuclei in whole cross sections, determined at different positions along the muscle lengths, were reduced by 30% in soleus and extensor digitorum longus. The areas of fiber necrosis were also reduced in experimental extensor digitorum longus and plantaris. These changes in nonweight-bearing muscles support the hypothesis that contractile activity can influence the development of dystrophic properties.