Influence of temperature on isometric tension development in mouse fast- and slow-twitch skeletal muscles

The influence of temperature (range 35 to 20°C) on the isometric contractile properties of fast-twitch extensor digitorum longus (EDL) and slow-twitch soleus (SOL) muscles of the male C57 mice was studied in vitro, with direct stimulation. Cooling from 35 to 25°C resulted in an average twitch tension potentiation of 42% in EDL and 13% in SOL muscles. Further cooling to 20°C did not produce further potentiation in EDL muscles. The time-to-peak tension and the time to half-relaxation increased 2.4 to 3.2 times for a 10°C cooling in both muscles. The maximum tetanic tension was little changed in cooling from 35 to 30°C, but was depressed 16 to 19% in cooling to 20°C in both muscles. These results from mouse fast and slow muscles were compared with previously published data from muscles of the rat and the cat. The behaviors of the slow SOL muscles in the three species were found to be significantly different, but they could be explained on the basis of their muscle fiber-type composition.     

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.     

Changes in isometric contractile properties of fast-twitch and slow-twitch skeletal muscle of C57BL/6J dy2J/dy2J dystrophic mice during postnatal development

Our primary aim was to determine if there exists a preferential involvement of the fast-twitch or slow-twitch skeletal muscle fibers in the dy2J/dy2J strain of murine dystrophy. The changes in the contractile properties of the slow-twitch soleus (SOL) and the fast-twitch extensor digitorum longus (EDL) muscles of normal and dystrophic mice were studied at 4, 8, 12, and 32 weeks of age. Isometric twitch and tetanus tension were decreased in the 4- and 8-week-old dystrophic EDL compared with controls, this situation being reversed in the older animals. At 12 weeks, the dystrophic EDL generated 15% more tetanic tension than normal EDL and by 32 weeks no significant difference was seen between normal and dystrophic EDL twitch or tetanus tension. By 8 weeks, dystrophic EDL exhibited a prolonged time-to-peak twitch tension (TTP) and half-relaxation time (1/2RT) of the isometric twitch which continued to 32 weeks. For the dystrophic SOL, decreased twitch and tetanus tension was observed from 4 to 32 weeks. At 8 and 12 weeks, TTP and 1/2RT of dystrophic SOL were prolonged. However, by 32 weeks there was no longer a significant difference seen in TTP or 1/2RT between normal and dystrophic SOL. Our results appear to indicate that a loss of the primary control which is determining the fiber composition of the individual muscles is occurring as the dystrophic process advances.     

Contractile and fatigue properties of thyrotoxic rat skeletal muscle

The effects of thyrotoxicosis on the contractile properties and development of muscle fatigue in the slow soleus (SOL) and fast extensor digitorum longus (EDL) muscles were examined in rats given 3 mg of L-thyroxine and 1 mg of L-triiodothyronine per kilogram of diet for 6 weeks. The hormone treatment produced significant decreases in the contraction time, one-half relaxation time, and twitch tension in the SOL, while the peak rate of tension development (+ dP/dt) and decline (? dP/dt) in this muscle were elevated. Additionally, the forcefrequency curve was shifted to the right and, thus, resembled the curve of a normal fast-twitch muscle. In contrast, the contractile properties of the fast EDL were relatively unaltered by the hormone administration. Thyrotoxicosis also changed the SOL response to contractile activity as twitch tension, + dP/dt, and ? dP/dt remained high, and a faster decline in muscle glycogen and an increase in lactate occurred compared to control muscles. These results clearly demonstrate a preferential effect of thyroid hormone on slow compared to fast skeletal muscle.     

Control of contractile properties within adaptive ranges by patterns of impulse activity in the rat

These experiments explore the relationship between patterned impulse activity and contractile properties of skeletal muscles. Soleus (SOL) and extensor digitorum longus (EDL) muscles of adult rats were denervated and stimulated directly from 4 to 15 weeks with the same number of pulse trains at different intratrain pulse frequencies (1-500 Hz), with different numbers of pulse trains (864-4,320,000 pulses/d) at the same intratrain pulse frequencies, or with different combinations of pulse trains at 10 and 100 Hz. Chronic stimulation of the denervated SOL resulted in twitch times-to-peak and half-relaxation times that varied in a graded manner between values longer than those in the normal SOL to values as fast as those in the normal EDL, depending upon the pattern used. Increasing pulse frequencies (constant number) resulted in faster twitches, lower twitch/tetanus ratios, increasing post-tetanic potentiations, and larger tetanic tensions. Increasing pulse numbers (constant frequencies) resulted in slower twitches, lower twitch/tetanus ratios, post-tetanic depressions, and higher fatigue indices. The effect of varying the pulse number on twitch parameters was greater at low frequencies (10-20 Hz) than at high frequencies (100 Hz). SOL muscles receiving pulse trains at both 10 and 100 Hz became much faster than muscles receiving pulse trains at 10 Hz only, even in the experiments where the stimulation pattern contained 9 times as many pulses at 10 as at 100 Hz. Chronic stimulation of both the denervated and the innervated EDL with large numbers of pulses at 10 or 15 Hz resulted in twitches that were only half as slow as those induced in the SOL by the same "slow" patterns. In addition, these patterns led to a marked decrease in maximum tetanic tension and a marked increase in twitch/tetanus ratio. During stimulation with a small number of pulses at 150 Hz, on the other hand, twitch speed, twitch/tetanus ratio, and maximum tetanic tension remained normal or almost normal. We conclude that the isometric twitch and related properties of the rat SOL muscle can be graded within wide "adaptive ranges" by varying either the number or the frequency of pulses. In the EDL, the corresponding adaptive ranges appear much narrower, suggesting that the EDL and the SOL contain intrinsically different muscle fibers.     

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.     

Long-term effects of estrogen on rat skeletal muscle

The long-term effects of estrogen on the development of rat extensor digitorum longus (EDL) and soleus (SOL) muscles were examined using physiological and histochemical methods. The rats were in three groups: group 1, ovariectomized; group 2, sham-operated; and group 3, ovariectomized followed by estradiol administration. Isometric twitch and tetanic tensions of both the EDL and SOL obtained from 10-week-old rats were evoked by electrical stimulation. The isometric twitch tensions of the EDL in groups 2 and 3 were significantly lower than in group 1, however, there was no significant differences in isometric twitch tensions of the SOL among the three groups. The isometric tetanic tensions of the EDL in groups 2 and 3 were also significantly lower than in group 1, and the isometric tetanic tension of the SOL in group 3 was significantly lower than in group 1. There were no changes in the total number of muscle fibers or in the ratios of fiber types. But the mean fiber diameter of all fiber types (particularly in types IIA and IIB) was significantly lower in group 3 than in groups 1 and 2. Therefore, the possibility that estrogen may play an inhibitory role in the development of skeletal muscle fibers has to be considered.     

Isometric contractile properties of fast- and slow-twitch muscles in normal and spastic mice

Isometric contractile properties of the fast-twitch extensor digitorum longus (EDL) and slow-twitch soleus (SOL) muscles of 24 male C57 mice were studied in vitro at 35°C. Ten animals exhibited the hereditary movement disorder known as spasticity. EDL muscles of spastic and normal mice developed similar specific tensions and they had similar twitch tension:tetanic tension ratios. The time-to-peak tension and the time to half relaxation in the twitch of spastic EDL muscles were, on average, slightly longer. SOL muscles of spastic and normal mice also developed similar specific tensions and their twitch contractions had similar times to half-relaxation. The time-to-peak tension in the twitch and the twitch tension: tetanic tension ratio of spastic SOL muscles were, on average, higher than in normal SOL. The significance of our findings remains somewhat uncertain.     

Temperature sensitivity of tension development in a fast-twitch muscle of the rat

Isometric contractions of the biceps brachii (short head) muscle in the rat were recorded in vitro with direct stimulation and at different temperatures (range, 35 degrees C-10 degrees C). In confirmation of our previous findings from fast extensor digitorum longus and slow soleus muscles, the time and rate parameters of the twitch and the tetanus showed an increased temperature sensitivity below 20 degrees C. The dependence on the initial muscle length of the rate of rise of tetanic tension was examined at 27 degrees C and at 15 degrees C. When represented as a percentage of the tetanic tension at each length, the rate of rise was independent of muscle length at both temperatures. Our interpretation of this particular observation is that the increased cooling depression of the rate of tension rise below 20 degrees C is not associated with a qualitative change in its underlying basis.     

Effect of precocious locomotor activity on the development of motoneurones and motor units of slow and fast muscles in rat

We have investigated the effect of precociously increasing locomotor activity during early postnatal development by daily treatment with the monoaminergic precursor L-DOPA on the survival of motoneurones supplying the slow soleus (SOL) muscle and the fast, tibialis anterior (TA) and extensor digitorum longus (EDL) muscles as well as the contractile and histochemical properties of these muscles. L-DOPA treatment resulted in a significant loss of motoneurones to the slow SOL muscle, but not to the fast TA and EDL muscles. Moreover, motoneurones to fast muscles also die as when exposed to increased activity in early life, if their axons are repeatedly injured. The loss of normal soleus motoneurones was accompanied by an increase in force of the remaining motor units and sprouting of the surviving axons suggesting a remodelling of motor unit organisation. The time to peak contraction of both SOL and EDL muscles from L-DOPA treated rats was prolonged at 8 weeks of age. At 4 weeks the soleus muscles of the L-DOPA treated animal developed more tension than the saline treated one. This difference between the two groups did not persist and by 8 weeks of age the muscle weight and tetanic tension from either group were not significantly different from control animals. The present study shows that early transient, precocious locomotor activity induced by L-DOPA is damaging to normal soleus but not to normal EDL/TA motoneurones.     

Slowing of fast-twitch muscle in the dystrophic mouse

Isometric twitch tension was measured in fast-twitch and slow-twitch muscles of normal and dystrophic ( ) mice in vivo. In dystrophic mice more than 6 months old the fast-twitch extensor digitorum longus (EDL) showed a prolongation of the time to peak tension as well as the time to relax to one-half peak tension ( ) compared with age-matched controls. In younger dystrophic mice (4 to 6 weeks) the time to peak tension was prolonged but not significantly so. This apparent “slowing” of dystrophic fast-twitch muscle was accompanied by a reduction in both cooling potentiation and post-tetanic potentiation toward values typical of slow-twitch muscle. Slow-twitch soleus muscle (SOL) of old mice was almost unaffected by the dystrophic process with regared to its contractile characteristics. However, there appeared to be a slight, but significant “speeding” of young dystrophic SOL compared with age-matched control muscles. This was apparent in reduced times to peak tension and half-relaxation as well as an enhanced cooling potentiation. We suggest that the altered contractile characteristics result from a change in some intrinsic property of the muscle fibers rather than from extrinsic factors such as the additional perimysial connective tissue seen in these muscles.     

3H]Ouabain binding in normal and dystrophic mouse skeletal muscles and the effect of age

The numbers of Na+-K+ ATPase sites in skeletal muscles of normal and dystrophic mice between 3 and 17 months of age have been estimated using [3H]ouabain binding assays. In normal mice, at all ages, slow twitch muscle, soleus (SOL), bound significantly more [3H]ouabain than fast-twitch muscle, extensor digitorum longus (EDL). [3H]Ouabain binding did not alter in either SOL or EDL from normal mice over the age range studied. The numbers of Na+-K+ ATPase sites did alter in muscles taken from dystrophic mice (C57BL/6J dy2J/dy2J). In EDL there was an increase and in SOL a decrease in [3H]ouabain binding. This may be related to a change in muscle fibre metabolism from glycolytic to oxidative or to an altered activity pattern. Increasing age resulted in a progressive reduction in [3H]ouabain binding of both SOL and EDL from dystrophic mice. Part of this reduction may be only apparent and due to an increase in connective tissue composition of dystrophic muscles. A limited study of muscles from neonate dystrophic mice indicated that abnormal [3H]ouabain binding was not present in EDL before two weeks of age.     

Core myofibers and related alterations induced in rats' soleus muscle by immobilization in shortened position

Experimental induction of core myofibers by tenotomy or local tetanus suggests that mechanical factors such as muscle tension loss, shortening or immobilization may play a role in core fiber formation. To test this hypothesis, we investigated the morphologic alterations induced in soleus (SOL) and extensor digitorum longus (EDL) muscles following immobilization of rats' hindlimb in various positions. The SOL and EDL muscles were immobilized in either shortened or lengthened state by applying wire-meshed plaster cast for 1, 2 and 3 weeks. The muscles were dissected out, measured, weighed and examined by histochemistry and electron microscopy. Gross atrophy was noted in all muscles but was greatest in shortened SOL. The SOL atrophy was diffuse and associated with relative increase in type 2 fibers. In EDL, the atrophy selectively involved fibers with low oxidative enzyme activity. Core myofibers were seen mainly in shortened SOL and consisted of myofibrillar derangement, loss of myofilaments and streaming of Z bands. The preferential involvement of shortened SOL (tonic, fatigue-resistant, slow-twitch muscle) suggests that the functional length, loss of tension subsequent to shortening and intrinsic biochemical properties of the muscle are important in core fiber formation.     

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.     

Satellite cells in slow and fast rat muscles differ in respect to acetylcholinesterase regulation mechanisms they convey to their descendant myofibers during regeneration

The hypothesis of satellite cell diversity in slow and fast mammalian muscles was tested by examining acetylcholinesterase (AChE) regulation in muscles regenerating (1) under conditions of muscle disuse (tenotomy, leg immobilization) in which the pattern of neural stimulation is changed, and (2) after cross-transplantation when the regenerating muscle develops under a foreign neural stimulation pattern. Soleus (SOL) and extensor digitorum longus (EDL) muscles of the rat were allowed to regenerate after ischemic-toxic injury either in their own sites or had been cross-transplanted to the site of the other muscle. Molecular forms of AChE in regenerating muscles were analyzed by velocity sedimentation in linear sucrose gradients. Neither tenotomy nor limb immobilization significantly affected the characteristic pattern of AChE molecular forms in regenerating SOL muscles, suggesting that the neural stimulation pattern is probably not decisive for its induction. During an early phase of regeneration, the general pattern of AChE molecular forms in the cross-transplanted regenerating muscle was predominantly determined by the type of its muscle of origin, and much less by the innervating nerve which exerted only a modest modifying effect. However, alkali-resistant myofibrillar ATPase activity on which the separation of muscle fibers into type I and type II is based, was determined predominantly by the motor nerve innervating the regenerating muscle. Mature regenerated EDL muscles (13 weeks after injury) which had been innervated by the SOL nerve became virtually indistinguishable from the SOL muscles in regard to their pattern of AChE molecular forms. However, AChE patterns of mature regenerated SOL muscles that had been innervated by the EDL nerve still displayed some features of the SOL pattern. In regard to AChE regulation, muscle satellite cells from slow or fast rat muscles convey to their descendant myotubes the information shifting their initial development in the direction of either slow or fast muscle, respectively. The satellite cells in fast or slow muscles are, therefore, intrinsically different. Intrinsic information is expressed mostly during an early phase of regeneration whereas later on the regulatory influence of the motor nerve more or less predominates. © 1994 Wiley-Liss, Inc.     

Neural regulation of muscle activation

The effects of temperature and repetitive stimulation on isometric twitch contractions of normal, self-innervated and cross-innervated fast extensor digitorum longus and slow soleus muscles of the rat were studied in situ. Normal and self-innervated extensor digitorum longus showed a 2-fold increase in twitch tension following either a train of 200 stimuli at 35 C (post-tetanic potentiation) or lowering of temperature from 35 C to 20 C (cooling potentiation), while under these conditions the twitch tensions of normal and self-innervated slow soleus fell by about 15%. Post-tetanic and cooling potentiation were virtually abolished in cross-innervated extensor digitorum longus but appeared in cross-innervated soleus. The degree of potentiation in these and control muscles was inversely proportional to contraction time. These experiments suggest that mammalian motor nerves exert a controlling influence on the degree of activation of skeletal muscle during a twitch. An hypothesis of the molecular mechanism of post-titanic and cooling potentiation is proposed. According to this hypothesis, neural regulation of muscle activation results from the transformation of myosin after nerve cross-union.     

A distinct difference between slow and fast muscle in acetylcholinesterase recovery after reinnervation in the rat

The changes in acetylcholinesterase (AChE) and choline acetyltransferase (CAT) activity in nerve proximal and distal to the crush site as well as in fast extensor digitorum longus (EDL) and slow soleus (SOL) muscle were studied during denervation and reinnervation in rat. Within 24 h after nerve crush, conduction in the distal nerve and neuromuscular transmission was lost. In the distal nerve segment, AChE and CAT activity showed no initial increase and was reduced to 25% 14 days after crush. During the reinnervation period, AChE and CAT activity recovered to 50% (AChE) and 80% (CAT) of control values and CAT activity in the EDL and SOL muscles followed closely the changes in distal nerve. In muscle, AChE activity was reduced to 15% by 2 weeks postoperatively. Enzyme activity in EDL recovered to 50% of control activity in 5 weeks after crush. In the SOL, end-plate and non-end-plate regions' AChE activity recovered at a faster rate, resulting in a temporary increase in AChE activity to more than control values during the third and fourth week. By the end of the fifth week, AChE activity had returned to control activity. Turnover values for AChE based on the reinnervation data showed a half-life value for AChE in proximal nerve of 32 days, in distal nerve 42 days, in EDL 23 days, and for SOL 5.1 days. The half-life for AChE in both muscles was significantly shorter than that of the nerve, indicating that the nerve did not supply AChE to the muscles. Half-lives for CAT calculated on the basis of the reinnervation data were 11.6 days for proximal nerve, 18.4 days for distal nerve, and 30 days for SOL and EDL muscles. It is concluded that the ability to synthesize AChE in end-plate and non-end-plate regions of muscle is an endogenously programmed event in the development of both fast and slow muscles. The nerve initiates and maintains the synthesis and can modify the rate of synthesis in individual muscle fibers. The mechanism by which the nerve stimulates and maintains AChE synthesis in muscle may be related to the release of trophic factors muscle activity or to a combination of these and other factors still to be investigated.     

Muscle-specific beta-enolase concentrations after cross- and random innervation of soleus and extensor digitorum longus in rats

The concentration of beta-enolase, a highly specific marker of the skeletal muscle of rats, was determined in a slow-twitch muscle, the soleus (SOL) and a fast-twitch muscle, the extensor digitorum longus (EDL) after cross-innervation, random reinnervation, or denervation. The beta-enolase concentration is normally high in EDL and low in SOL. When the nerves entering into these muscles were cross-sutured, the beta-enolase concentration in EDL decreased and that in SOL increased to reach an almost equal value in 20 weeks and by the 35th week the SOL ultimately had a higher beta-enolase concentration than the EDL. When the sciatic nerve trunk was completely transected and sutured immediately, the beta-enolase concentration in EDL decreased and that of SOL increased; in 20 weeks SOL had a beta-enolase concentration similar to that of the EDL. When these muscles were denervated by cutting the sciatic nerve trunk, their beta-enolase concentrations were markedly lowered, but EDL still retained on the 12th week a beta-enolase value comparable to the normal SOL. Possible mechanisms behind the observed changes in beta-enolase concentration are discussed.     

Influence of temperature on the characteristics of summation of isometric mechanical responses of mammalian skeletal muscle

Characteristics of summation of isometric mechanical responses elicited by two supramaximal nerve stimuli were examined at different temperatures (18 to 38°C) in a fast twitch (flexor digitorum longus) and a slow twitch (soleus) muscle, in situ, in the cat hind leg. At 37 to 38°C, both muscles developed a peak tension that was more than twice the twitch tension when a second stimulus was applied shortly after the first. The rate of rise of tension in such a summated response was also about, or more than, twice that of the twitch tension, and the time to peak tension was about 1.5 times the time to peak of the twitch. The peak tension in summated responses decreased with increasing the stimulus interval so that, when the interval was equal to the time to peak twitch, the tension developed was significantly less. Cooling significantly alters these characteristics in the fast twitch muscle, so that, at 20 to 22°C, the tension, the rate of rise of tension, and the time to peak tension enhancement produced by a second stimulus are markedly reduced; little or no change in the characteristics is seen with cooling of the slow twitch muscle. These results are examined in the light of some observations made on the pattern of summation in frog sartorius muscle at different temperatures (2 to 28°C). Cooling significantly increases the degree of activation occurring during the twitch in the fast twitch muscle fibers, whereas it has little or no effect on the degree of mechanical activation in the slow twitch muscle fibers. Furthermore, the results suggest that the tension, the rate of rise of tension, and, perhaps the time to peak tension of the isometric twitch in both the fast twitch and the slow twitch muscle fibers at 37 to 38°C are limited by the degree of mechanical activation and that a second stimulus applied shortly after the first can greatly overcome the effect of that limitation.     

Effects of ageing on the total number of muscle fibers and motoneurons of the tibialis anterior and soleus muscles in the rat

The age-related changes in the total number of muscle fibers and motoneurons of the tibialis anterior and soleus muscles were studied using 10-, 65-, and 135-week-old rats. The number of fast twitch muscle fibers was decreased at age 65 weeks, while the numbers of slow twitch fibers and of alpha motoneurons were decreased only later, at age 135 weeks. Therefore, the degenerative process of muscle fibers differs with the fiber type.