Effects of denervation and immobilisation during development upon [3H]ouabain binding by slow- and fast-twitch muscle of the rat

The effect of innervation and of muscle inactivity upon the normal production of Na+-K+-ATPase sites, assayed by [3H]ouabain binding, in muscle surface membranes has been determined for the rat. In both slow-twitch soleus (SOL) and fast-twitch extensor digitorum longus (EDL) muscles a large increase was found to occur in [3H]ouabain binding per unit weight of muscle over the first 3 weeks of life. Interruptions of development, brought about by fixation of muscles at different lengths at 5 days of age, had no significant effect upon [3H]ouabain binding by EDL. In contrast, fixation led to a decrease in binding in SOL. When fixed in a shortened position profound morphological changes occurred, although these were not apparent when SOL was fixed in a stretched position. Denervation of SOL at 5 days of age significantly reduced the age related increase in the density of [3H]ouabain binding, whilst denervation of EDL had little effect. It was concluded that normal development of SOL is dependent upon innervation and possibly the resulting muscle activity, whereas development of EDL was relatively independent of innervation.     

Ouabain binding sites in skeletal muscle from normal and dystrophic mice.

The specific binding of tritiated ouabain was used to estimate the density of Na+-K+-ATPase sites ("Na+-pump" sites) in segments of skeletal muscle from normal and dystrophic mice. Ouabain binding was approximately 4 times greater in red (soleus) muscle than in white (superficial gastrocnemius) muscle from normal animals. In dystrophic soleus muscles, ouabain binding was decreased by nearly one-half. Because Na+-K+-ATPase activity is associated with plasma membranes, these observations constitute further evidence for a sarcolemmal abnormality in dystrophic mice.     

Analysis of dystrophin in fast- and slow-twitch skeletal muscles from mdx and dy2J mice at different ages

Muscles from mdx, control, and dy2J/dy2J mice at different ages were analyzed for dystrophin in an attempt to relate the chronology of the protein expression with the final phenotypes in regenerated, normal, and dystrophic muscle, respectively. Immunostaining and gold staining of electrophoresis gels were carried out in the investigation. At 5, 25, and 219 days of age, control muscles exhibited dystrophin bands in both the fast-twitch extensor digitorum longus (EDL) and the slow-twitch soleus (SOL) muscles. Muscles from the mdx mice at comparable ages (8, 28, and 217 days) never exhibited bands for dystrophin, although titin, nebulin, myosin, and other protein bands were present at intensities comparable to those in control muscles. The dystrophin band was present in both the EDL and SOL from dy2J/dy2J dystrophic mice. As indicated by the present study, the dystrophin deficiency from mdx tissue is not transient. This suggests that dystrophin is not necessary for the success of mdx muscle regeneration.     

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.     

Abnormal distribution of proteins in the soleus and extensor digitorum longus of dystrophic mice

Proteins of the whole muscle homogenates of the slow-twitch soleus (SOL) and fast-twitch extensor digitorum longus (EDL) of normal and dystrophic C57BL/6J mice at 4, 8, 12, and 32 weeks of age were resolved on polyacrylamide isoelectric focusing gels. Gels of the normal SOL proteins at all ages contained two bands specific to SOL and not represented in EDL. Gels of normal EDL contained three bands highly amplified in EDL but barely detectable in SOL. The distribution of proteins in dystrophic SOL was abnormal at all age groups studied due, in part, to a decrease in the proportion of SOL-specific proteins relative to other proteins in the muscle. The distribution of proteins in dystrophic EDL appeared abnormal first at 12 weeks due to a decrease in the relative proportion of EDL-amplified proteins. Due to these and other changes, at 32 weeks the dystrophic SOL and EDL were almost indistinguishable on the basis of their proteins' distributions.     

Intracellular sodium-activity at rest and after tetanic stimulation in muscles of normal and dystrophic (dy2J/dy2J) C57BL/6J mice

Intrafiber Na+-activity, (aNa)i, was measured in vivo in single muscle fibers in the gastrocnemius and soleus muscles of normal and dystrophic (dy2J/dy2J) C57BL/6J mice by means of double-barrel Na+-selective microelectrodes. Values of (aNa)i in normal gastrocnemius and soleus muscles were 9.8 +/- 1.0 mM (means +/- SE; N = 15) and 13.7 +/- 1 mM (N = 19), respectively. Values of (aNa)i in dystrophic gastrocnemius and soleus muscles were 18.7 +/- 1.3 mM (N = 10) and 26.2 +/- 3.3 mM (N = 15), respectively. The soleus muscle of both normal and dystrophic mice was "Na+ loaded" by an intermittent tetanus delivered via the sciatic nerve. Muscles from both normal and dystrophic mice could extrude the Na+ load at similar rates. The results suggest that in the dystrophic mice the elevated (aNa)i is not due to inability of the Na+ pump to respond to a Na+ load; rather, it may be due to an alteration in the affinity of the pump for Na+, resulting in a different "set point" for (aNa)i.     

Fatiguability and oxidative capacity of forelimb and hind limb muscles of dystrophic mice

Fatigue indices and succinic dehydrogenase (SDH) activities were determined in the extensor digitorum longus (EDL) and soleus muscles of the hind limb and the extensor carpi radialis longus of the forelimb in control and dystrophic mice aged 4 to 26 weeks. A good correlation was found between SDH activities and fatigue indices in muscles from normal mice. In the dystrophic (dy2J) mice, however, this correlation was not present. The EDL muscles from 26-week-old dy2J mice showed a much higher resistance to fatigue than age-matched controls but this was not accompanied by a significant change in SDH. The increased fatigue resistance in dy2J EDL appeared between 8 and 12 weeks of age and was temporally correlated with the onset of fused bursts of spontaneous activity in the hind limb muscles. Nevertheless, there was no conclusive evidence for a link among this spontaneous activity, oxidative enzyme capacity, and fatigue resistance.     

Developmental changes in fiber type-related proteins in soleus, rectus femoris, and heart muscles of normal and dystrophic mice

By using sensitive enzyme immunoassay methods, several isoenzymes or isoproteins related to muscle fiber types were determined in the soleus (SOL), rectus femoris (RFM), and heart muscles of normal and dystrophic (dy/dy) mice of various ages. In normal adult mice, the S-100 protein alpha subunit (S-100 alpha) and creatine kinase B subunit (CK-B), which are known to be distributed predominantly in type I muscle fibers as S-100a0 (alpha alpha form of the S-100 protein) and the MB form of CK, respectively, were enhanced several-fold in the "aerobic" SOL muscle as compared with the "anaerobic" RFM muscle. The enolase beta subunit (beta-enolase) and the M subunit of CK (CK-M) were present in the RFM at levels increased several-fold compared to levels in the SOL of the same mice. In age-matched dystrophic adult mice, however, the compositions of these muscle-related proteins in the RFM muscle shifted to those of the SOL muscle: S-100 alpha and CK-B increased several-fold, beta-enolase and CK-M decreased markedly as compared with the normal RFM. On the other hand, the SOL and heart muscles of dystrophic mice showed only a slight increase of CK-B or decrease of CK-M. In the RFM of 3-week-old dystrophic mice, S-100 alpha and beta-enolase levels were similar to those in the RFM of control littermates, but a significant increase of CK-B and a decrease of CK-M were already observed in this early stage of dystrophy. These results indicate that changes in muscle-related proteins in the dystrophic muscles are apparently displayed mainly in the anaerobic muscles and feature a decrease in type II fiber-related proteins and a relative increase in type I fiber-related proteins. The mechanism of these changes in dystrophic mice is discussed.     

IGF-I treatment improves the functional properties of fast- and slow-twitch skeletal muscles from dystrophic mice

Although insulin-like growth factor-I (IGF-I) has been proposed for use by patients suffering from muscle wasting conditions, few studies have investigated the functional properties of dystrophic skeletal muscle following IGF-I treatment. 129P1 ReJ-Lama2(dy) (129 ReJ dy/dy) dystrophic mice suffer from a deficiency in the structural protein, laminin, and exhibit severe muscle wasting and weakness. We tested the hypothesis that 4 weeks of IGF-I treatment ( approximately 2 mg/kg body mass, 50 g/h via mini-osmotic pump, subcutaneously) would increase the mass and force producing capacity of skeletal muscles from dystrophic mice. IGF-I treatment increased the mass of the extensor digitorum longus (EDL) and soleus muscles of dystrophic mice by 20 and 29%, respectively, compared with untreated dystrophic mice (administered saline-vehicle only). Absolute maximum force (P(o)) of the EDL and soleus muscle was increased by 40 and 32%, respectively, following IGF-I treatment. Specific P(o) (sP(o)) was increased by 23% in the EDL muscles of treated compared with untreated mice, but in the soleus muscle sP(o) was unchanged. IGF-I treatment increased the proportion of type IIB and type IIA fibres and decreased the proportion of type I fibres in the EDL muscles of dystrophic mice. In the soleus muscles of dystrophic mice, IGF-I treatment increased the proportion of type IIA fibres and decreased the proportion of type I fibres. Average fibre cross-sectional area was increased in the EDL and soleus muscles of treated compared with untreated mice. We conclude that IGF-I treatment ameliorates muscle wasting and improves the functional properties of skeletal muscles of dystrophic mice. The findings have important implications for the role of IGF-I in ameliorating muscle wasting associated with the muscular dystrophies.     

Potassium and caffeine contractures in limb muscles of normal and dystrophic (C57 BL/6J dy2J/dy2J) mice

The strength of contractures, produced by 15 to 146 mM [K]0 (as L-glutamate), was measured in isolated small bundles of muscle fibers from the fast-twitch extensor digitorum longus and from the slow-twitch soleus of normal and dystrophic (C57 BL/6J dy2J/dy2J) mice. The analysis of the relation between the maximal amplitude of the contracture vs the membrane potential and the time constant of relaxation of the K-contractures has shown that dystrophy induced an attenuation of the differences between fast- and slow-twitch muscles. The repriming of K-contractures was more affected by changes in [Ca]0 in normal soleus than in normal extensor digitorum longus and this difference was unaffected by dystrophy. For both types of muscles, the ability of caffeine to produce contractures was reduced in dystrophic muscle and this modification was not related to a change in the fiber typing.     

Effect of neonatal denervation-reinnervation on the functional capacity of a 129ReJ dy/dy murine dystrophic muscle

The sciatic nerves of 14-day-old 129 ReJ normal (++) and dystrophic (dy/dy) mice were transected in the mid-thigh region. The cut ends of the nerves were approximated to facilitate regeneration. One hundred days after denervation, contractile properties of denervated-reinnervated, normal and dystrophic extensor digitorum longus (EDL) muscles were compared to age-matched normal and dystrophic muscles. In dystrophic muscle, in vitro twitch and tetanic tensions were reduced, compared to those of normal muscle. The denervation-reinnervation procedure resulted in an increase in these parameters as compared to unoperated dy muscle. These data correlated with increases in total myofiber cross-sectional areas. Twitch contraction time was not significantly affected by the dystrophic condition or by the denervation-reinnervation protocol. Whereas dystrophic muscle had a longer half-relaxation time than normal muscle, denervation-reinnervation of the dystrophic EDL resulted in a significantly faster half-relaxation time. While fatigue resistance was greater in dystrophic muscles than in normal muscle, there was a significant decrease in fatigue resistance in the denervated-reinnervated dystrophic muscle. Transient neonatal denervation results in modification of both the morphological and physiological characteristics of murine dystrophy.     

Effects of insulin on protein synthesis in muscles from normal and dystrophic mice

Protein synthesis in soleus and extensor digitorum longus (EDL) muscles was measured in vitro to test the hypothesis that the lack of muscle protein accumulation in dystrophic conditions could be caused by a reduced sensitivity to insulin. We demonstrate that physiological insulin concentrations stimulate protein synthesis in soleus muscles from normal mice but not from muscles obtained from dystrophic (dy) animals. The difference is lost at very high insulin concentrations (1 microM) and could not be shown at any concentration with EDL muscles. These results, together with the reported reduced inhibitory effect of insulin on protein synthesis in dystrophic hamsters and on protein breakdown in dystrophic mice, suggest that protein metabolism in certain muscles from dystrophic animals may be less responsive to the anabolic effects of insulin.     

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.     

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.     

Identification of regenerated dystrophic minced muscle transplanted in normal mice

The origin of the reconstituted normal and dystrophic transplants in normal mice of the Bar Harbor 129 ReJ strain was investigated by transplanting [³H]thymidine-labelled minced tibialis anterior muscles into the legs of unlabelled hosts. After 20 days the transplants were processed for autoradiography and histology. At varying time intervals between 0 and 50 days radioactivity counts were made on the transplants and compared with those from the adjacent EDL and contralateral tibialis anterior muscles of the hosts.Both autoradiography and radioactivity counts showed that the transplanted muscles were formed from muscle cells derived from within the donor tissue. Moreover, normal and dystrophic transplants from normal hosts were histologically similar.     

Muscular transverse relaxation time measurement by magnetic resonance imaging at 4 Tesla in normal and dystrophic dy/dy and dy(2j)/dy(2j) mice

Muscular transverse relaxation times values were measured in vivo in normal mice (strain C57BL6/J, n=14) and in murine models of human congenital muscular dystrophy (dy/dy, n=9; dy(2j)/dy(2j), n=8). A single-slice multi-echo sequence was used. Gastrocnemius/soleus complex, thigh and buttock muscles were studied. Muscular transverse relaxation times values were compared between different muscle groups in each type of animal and between animal groups. Differences were observed between normal and dy(2j)/dy(2j) mice from 3 to 12 weeks of age, and between normal and dy/dy mice at 6 weeks. In specific age ranges, the values of muscular transverse relaxation times in two dystrophic models are different from those in normal mice, and could thus be used as an index of modifications in dystrophic muscle to evaluate therapies.     

Effect of low Ca2+ solution on muscle contraction of developing, preclinical dystrophic (dy2j) mice.

EDL muscles from normal and dystrophic (dy2j) mice aged 7 to 21 days of postnatal life were examined. Muscles were divided into 2 groups according to age, 7 to 14 days and 16 to 21 days postnatal, so as to assess age- and/or phenotype-related differences in the muscle response to low Ca2+ solution. Tension production was already much impaired in "predystrophic" muscles. At this stage, however, there was essentially no difference in twitch kinetics between normal and dystrophic muscles. Upon exposure to low Ca2+ solution, twitch responses of both normal and dystrophic muscles declined in a similar manner. In the youngest animals studied (7 to 14 days), the tetanic responses of both normal and dystrophic muscles to low Ca2+ solution were also similar. In animals 15 to 21 days old, however, the tetanic tension developed in low Ca2+ solution by dystrophic muscles, was significantly less than that of normal. Moreover, under these conditions (i.e., in low Ca2+ solution), and following tetanic stimulation, the membrane potential of dystrophic muscles in this age group was significantly more depolarized than that of normal muscles. Our results suggest that the ability of the cell to deal with extracellular Ca2+ is normal in predystrophic muscles up to 21 days of postnatal life. The results also clearly point to the fragility of the membrane in these muscles.     

A maturational defect in passive membrane properties of dystrophic mouse muscle

Electrical properties, component ionic conductances, and histochemical characteristics of normal and dystrophic (dy^2J/dy^2J) mouse extensor digitorum longus (EDL) and soleus (SOL) muscles were studied between 1 and 6 months of age. Normal EDL and SOL membrane electrical parameters were indistinguishable at 1 month. Between 1 and 3 months, membrane resistance (R_m) in normal EDL decreased progressively to a mature value one-half that found in SOL muscles. Measurements of component conductances indicated that this decrease in R_m was due to a specific increase in membrane chloride conductance (G_C1) in EDL fibers. During the same time membrane capacitance increased slightly in both EDL and SOL. Dystrophic EDL failed to develop fully the changes in membrane resistance seen in controls, showing significant deviation at all time points beyond 1 month. An abnormal high-resistance subpopulation was evident in R_m histograms of mature dystrophic EDL. Average membrane properties of dystrophic SOL appeared normal during the 6-month interval studied but significant changes in R_m histograms were found. Histochemical analysis of normal and dystrophic EDL showed that both contained almost exclusively type II fibers (> 95%); normal and dystrophic SOL contained a nearly equal mixture of type I and type II fibers. Progressive degenerative changes were seen in both dystrophic muscles with age but were more severe in the SOL. The depressed average G_C1 in the dystrophic EDL was due to a subpopulation of fibers (30% of total) having a high membrane resistance. Denervation was ruled out as a cause for this subpopulation by a lack of correlation between membrane resistance and resting potential. Histochemical evidence eliminated the possibility that this subpopulation was composed of slow-twitch fibers. Data are presented indicating that the subpopulation represents a group of dystrophic EDL fibers which fail to undergo normal maturation.     

Developmental changes in succinate dehydrogenase activity in muscle fibers from normal and dystrophic mice

The question of whether or not the development of dystrophic muscles is similar to that of normal muscles, prior to the manifestations of the symptoms of the disease, is investigated here. The developmental change in the activity of succinate dehydrogenase was therefore measured in individual fibers of prospectively dystrophic muscles from 10- to 28-day-old mice (strain C57Bl/6J dy2j) and compared with that of muscles from normal mice of the same age. It was found that up to 10 days of age, muscle fibers from normal and prospective dystrophic animals had low succinate dehydrogenase activities, and were all more or less uniform. Thereafter in the normal muscle the overall activity of the enzyme increased and the fibers became more heterogeneous with age. By 21 days the extensor digitorum longus muscle resembled that of the adult. At that time, fibers from prospectively dystrophic muscles had lower succinate dehydrogenase activities and were more homogeneous. Thus fibers from prospectively dystrophic muscles fail to achieve their adult characteristics by 21 days. On the basis of these results, it is suggested that muscle maturation is retarded in dystrophic animals.     

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.