Increased susceptibility of EDL muscles from mdx mice to damage induced by contractions with stretch

Summary Absence of dystrophin in mdx muscles may render the muscle more susceptible to damage when submitted to high stress levels. To test this, typically slow (soleus) and fast (EDL) limb muscles of dystrophic (mdx) and normal (C57BL/10) mice were submitted (in vitro) to a series of isometric contractions, followed by a series of contractions with stretches. Muscle injury was assessed by monitoring the force signal. Membrane damage was evaluated by bathing the muscle in Procion Red, a dye that does not penetrate intact fibres, and subsequent analysis by light microscopy. After isometric contractions, only a very small force drop (<3% of maximal isometric force) was observed which indicated that no injury had occurred in soleus and EDL muscles in either mdx or C57 strains. After contractions with a stretch, a force drop of 10% was observed in soleus muscles from both strains and in EDL muscles from C57 mice. However, in mdx mice EDL muscles displayed an irreversible force drop of 40–60%. Histological analysis of the muscles indicates that force drop is associated with membrane damage. These results show that EDL muscles from mdx mice are more vulnerable than their controls, supporting the structural role hypothesis for dystrophin. Furthermore, they suggest that contractions with stretches may contribute to the muscle damage and degeneration observed in DMD-patients.     

Functional regeneration in the hindlimb skeletal muscle of the mdx mouse

Summary The pattern of spontaneous skeletal muscle degeneration and clinical recovery in hindlimb muscles of the mdx mutant mouse was examined for functional and metabolic confirmation of apparent structural regeneration. The contractile properties, histochemical staining and myosin light chain and parvalbumin contents of extensor digitorum longus (EDL) and soleus (Sol) muscles of mdx and age-matched control mice were studied at 3–4 and 32 weeks. Histochemical staining (myofibrillar ATPase and NADH-tetrazolium reductase) revealed no significant change in slow-twitch-oxidative (SO) or fast-twitch-oxidative-glycolytic (FOG) fibre type proportions in mdx Sol apart from the normal age-related increase in SO fibres. At 32 weeks mdx EDL, however, showed significantly smaller fast-twitch-glycolytic (FG) and larger FOG proportions than those in control EDL. These fibre type distributions were confirmed by differential staining with antibodies to myosin slow-twitch and fast-twitch heavy chain isozymes. Frequency distribution of cross-sectional area for each fibre type showed a wider than normal range of areas especially in FOG fibres of mdx Sol, and FG fibres of mdx EDL, supporting previous observations using autoradiography of myofibre regeneration. Isometric twitch and tetanic tensions in Sol were significantly less than in controls at 4 weeks, but by 32 weeks, values were not different from age-matched controls. In mdx EDL at 3 weeks, twitch and tetanus tensions were significantly less, and time-to-peak twitch tensions were significantly faster than in control EDL. By 32 weeks, mdx EDL twitch and tetanus tensions expressed relative to muscle weight continued to be significantly lower than in age-matched controls, despite normal absolute tensions. The maximum velocity of shortening in 32-week mdx EDL was significantly lower than in control EDL. Myosin light chain distribution in mdx Sol exhibited significantly less light chain 2-slow (LC2s) and more light chain 1b-slow(LC1bs) at 32 weeks than age-matched control Sol. Gels of EDL from 32-week-old mdx mice showed significantly less light chain 2-fast-phosphorylated (LC2f-P) and light chain 3-fast (LC3f) and significantly more light chain 1-fast (LC1f) and light chain 2-fast (LC2f), but normal parvalbumin content compared to age-matched controls. These observations suggest that mdx hindlimb muscles are differentially affected by the disease process as it occurs in murine models of dystrophy. However, the uniqueness of mdx Sol and to a lesser extent EDL is that they also undergo an important degree of functional regeneration which is able to compensate spontaneously for degenerative influences of genetic origin. The mdx mutant may therefore be an important model for the study of regeneration by skeletal muscle, and of the nerve-muscle interactions which enable or restrict that regeneration.     

Mechanical and energetic properties of dystrophic (mdx) mouse muscle

The mechanical and energetic properties of extensor digitorum longus (EDL) and soleus muscles of X chromosome-linked muscular dystrophic mutant (mdx) mice aged 4-6 weeks were studied and compared with those of the muscles of normal mice. Maximum tetanic tension, the speed of contraction of relaxation, and the heat production of mdx soleus muscles were not significantly different from those of the normal muscles. However, in mdx EDL muscles, the tension and heat production were significantly reduced, and relaxation was prolonged. To study the cause of these changes in mdx EDL muscles, tension and heat production were measured at various muscle lengths greater than optimum for tension. Both the amount of twitch heat and the heat rate for a tetanus were linearly related to the tension and had non-zero intercepts at zero tension, the activation heat. The twitch activation heat and the tension-related heat in tetani of mdx EDL muscles were not different from those in normal muscles. On the other hand, the tetanus activation heat of mdx EDL muscles was significantly smaller than that of normal muscles. Assuming that the degenerated fibers do not contribute to the active force produced, these results suggest that the amount of Ca2+ released in a contraction is not significantly different between normal and mdx muscles, but the Ca-ATPase activity of the salcoplasmic reticulum is reduced in mdx EDL, which could cause the slowing of relaxation.     

Modulation of insulin-like growth factor (IGF)-I and IGF-binding protein interactions enhances skeletal muscle regeneration and ameliorates the dystrophic pathology in mdx mice

Administration of recombinant human insulin-like growth factor-I (rhIGF-I) has beneficial effects in animal models of muscle injury and muscular dystrophy. However, the results of these studies may have been confounded by interactions of rhIGF-I with endogenous IGF-binding proteins (IGFBPs). To date, no study has examined whether inhibiting IGFBP interactions with endogenous IGF-I can improve muscle fiber regeneration or muscular pathologies. We tested the hypothesis that reducing IGFBP interactions with endogenous IGF-I would enhance muscle regeneration after myotoxic injury and improve the dystrophic pathology in mdx mice. We administered an IGF-I aptamer (NBI-31772; 6 mg/kg per day, continuous infusion) to C57BL/10 mice undergoing regeneration after myotoxic injury or to mdx dystrophic mice. NBI-31772 binds all six IGFBPs with high affinity and releases "free" endogenous IGF-I. NBI-31772 treatment increased the rate of functional repair in fast-twitch tibialis anterior muscles after notexin-induced injury as evidenced by an increase in maximum force producing capacity (P(o)) at 10 days after injury. In contrast, NBI-31772 administration for 28 days did not alter P(o) of extensor digitorum longus (EDL) and soleus muscles or normalized force of diaphragm muscle strips from mdx mice. Although IGFBP inhibition reduced the susceptibility of the fast-twitch EDL and the diaphragm muscle to contraction-mediated damage, it increased muscle fatigability during repeated maximal contractions. Although the results in the myotoxic injury model suggest IGF-I signaling is important in this model, the results in the mdx model are mixed.     

Effect of zinc-carnosine chelate compound on muscle function in mdx mouse

The effect of antioxidant Z-103, catena-(S)-[mu-[N(alpha)-(3-aminopropinyl)histidinnato-(2-)N(1),N(2),O:N(tau)]-zinc], on muscle function in the muscular dystrophy (mdx) mouse was examined by repetitive intraperitoneal administration in subjects aged 4 to 12 weeks. Z-103 administration at a dose of 150 mg/kg increased the load resistant time (LRT), during which the animal with a load holds itself upright on a wire net. The Z-103 administration reduced hypertrophy, the ratio of centronucleated myofibers, and the rate of decay for magnitude of twitch force elicited by 0.5 Hz of electricity to the extensor digitorum longus (EDL) muscle of 12-week-old mdx mice, with little effect on the magnitude of twitch force. The administration of Z-103 (100 mg/kg) had a lesser effect on LRT and the other characteristics examined for EDL muscles. The constituent of Z-103, Zn(2+) applied in the form of ZnSO(4) (5 mg/kg), carnosine (100 mg/kg), and the combination of the two had no beneficial effect on mdx mice. Z-103 (150 mg/kg) administered to normal mice increased LRT with little effect on the contractile properties of EDL muscles. These results suggest that the administration of Z-103 ameliorates muscle function in the mdx mouse.     

Reduced density of intramembranous particle clusters: freeze-fracture study of mdx mouse muscle plasma membrane

Our previous freeze-fracture study demonstrated the decreased density of intramembranous particles (IMPs) on the protoplasmic (P) face of muscle plasma membranes in mdx mice. However, the molecular mechanism is unknown. In the present freeze-fracture study, we examined whether the reduced P-face IMP density in mdx mice would be caused by depletion of the rosette-like IMP clusters, which are IMP aggregations differing from crystal-like orthogonal arrays (OAs). By comparison with control mice, the P-face plasma membranes of extensor digitorum longus (EDL) and soleus (SOL) muscles of mdx mice demonstrated the following findings: (1) decreased IMP density with subunit particles of OAs and IMP clusters, (2) decreased IMP density without subunit particles of OAs, (3) normal IMP density without subunit particles of OAs and IMP clusters, (4) decreased OA density in EDL muscles and normal OA density in SOL muscles, and (5) decreased IMP cluster densities in both muscles. Thus, the reduced IMP density of P-face muscle plasma membranes in mdx mice may result from the decreased IMP clusters, suggesting the relationship between IMP clusters and the integral membrane proteins is influenced by dystrophin deficiency such as that of dystrophin-associated glycoproteins or other membrane proteins.     

Electron microscopic and autoradiographic characterization of hindlimb muscle regeneration in the mdx mouse

The pattern of postnatal growth and development of skeletal muscle in mdx mice was studied by light and transmission electron microscopy and by autoradiography and was compared with that in their normal age-matched controls at 4 and 32 weeks of age. The muscle weights of both the extensor digitorum longus (EDL) and soleus muscles of mdx mice were significantly greater than those in control mice at both ages. Body weights of male and female mdx mice were also increased over controls up to 12 weeks of age. At 4 weeks, both the EDL and soleus muscles exhibited focal areas of degeneration, necrosis, and regeneration of centrally nucleated extrafusal fibers resulting in a wide range of fiber sizes. By 32 weeks, the majority of fibers in both muscles were centrally nucleated, and focal areas of recent regeneration were observed. By electron microscopy, the course of macrophage infiltration into areas of degenerating fibers and the ongoing regeneration of myofibers within redundant cylinders of external lamina were noted. This pattern was frequent in 4-week-old mdx muscles and was present to a lesser degree at 32 weeks. A notable lack of both adipose tissue infiltration and fibrotic change in the endomysium were observed in muscles at both ages. Autoradiograms of muscles from 4-week-old mdx mice injected with tritiated thymidine showed an increased proportion of labeled sublaminal nuclei at 24 and 48 hours after injection compared to controls. At 32 weeks of age, labeling of nuclei in muscles of mdx mice was also greater than in controls, but was reduced compared to muscle labeling in 4-week-old mdx mice. The observed features of mdx muscle tissue suggest that this animal model is more applicable to the study of regeneration dynamics than to Duchenne-type human muscular dystrophy.     

Effect of cyclopiazonic acid, an inhibitor of the sarcoplasmic reticulum Ca-ATPase, on skeletal muscles from normal and mdx mice

AIM: In this study, we investigated Ca2+ loading by the sarcoplasmic reticulum in skeletal muscle from mdx mice, an animal model of human Duchenne's muscular dystrophy, at two stages of development: 4 and 11 weeks. METHOD: Experiments were conducted on fast- (extensor digitorum longus, EDL) and slow- (soleus) twitch muscles expressing different isoforms of Ca2+-ATPase, which is responsible for the uptake of Ca2+ by the sarcoplasmic reticulum. RESULTS: In sarcoplasmic reticulum vesicles, the ATP-dependent activity and sensitivity to cyclopiazonic acid (CPA), an inhibitor of the sarcoplasmic reticulum Ca2+-ATPase, were similar in mdx and normal EDL muscle. Furthermore, in chemically-skinned fibres from both normal and mdx muscles, the presence of CPA induced a decrease in Ca2+ uptake by the sarcoplasmic reticulum. However, the sensitivity to CPA was lower in mdx EDL muscle than in normal muscle. In addition, in EDL muscle from 4-week-old mdx mice, the expression of the slow Ca2+-pump isoform (SERCA2a) was significantly increased, without any accompanying change in slow myosin expression. In contrast, the expression and function of the Ca2+-ATPase in mdx soleus muscles at 4- and 11-weeks of development did not differ from those in age-matched controls. CONCLUSION: These findings show that in dystrophic muscle, where the Ca2+ homeostasis was perturbed, the Ca2+ handling by the sarcoplasmic reticulum was altered in fast-twitch muscle, and this was associated with the expression of the slow isoform of SERCA. In these muscles, reduced Ca2+ uptake could then contribute to an elevated concentration of Ca2+ in the cytosol, and also to Ca2+ depletion of the sarcoplasmic reticulum.     

Rapid recovery following contraction-induced injury to in situ skeletal muscles in mdx mice

The muscles of mdx mice lack the subsarcolemmal protein dystrophin, and as a consequence may be more susceptible to damage induced by contractions. The purpose of this study was to characterize the response of muscles in mdx mice to contraction-induced injury in situ. The hypothesis tested was that following a protocol of repeated stretches of maximally activated muscles, the magnitude of the injury is greater for muscles in mdx mice than for muscles in C57BL/10 control mice, and consequently, the muscles in mdx mice recover more slowly. Each stretch was of 20% strain relative to muscle fibre length (Lf) at 0.5 Lf s-1 and was initiated from the force plateau of an isometric contraction. The protocol consisted of a total of ten contractions, with one contraction occurring every ten seconds. The time-course of injury and recovery was determined through measurements of in situ force production at 10, 30, 45 and 60 minutes, and either 12, 24, 48 or 72 hours after the contraction protocol. The initial injury, as assessed by the decrease in force production both immediately and 60 minutes after the contraction protocol, was significantly greater for the muscles in mdx mice compared with those in control mice. Over the next three days, a value for maximum isometric force of sim 80% of the pre-injury value was maintained for muscles in control mice, whereas within three days muscles in mdx mice showed complete recovery of force. For muscles in mdx mice, the greater decrease in force during the contraction protocol and the more rapid recovery indicates an increased susceptibility to contraction-induced injury but an enhanced rate of recovery. This revised version was published online in August 2006 with corrections to the Cover Date.     

Muscle injury induced by different types of contractions in dystrophic mdx mice

Studies on comparing the effect of lengthening, isometric and shortening contractions on dystrophin-deficient muscles are unavailable. We hypothesized that different types of contractions lead to different extents to which dystrophin-deficient muscles are injured. For this purpose, we developed protocols for different types of contraction-induced injury to mdx muscles in vitro. Force deficits and percentages of procion orange dye positive fibers were employed to assess the extent of injury to each muscle. Our results revealed that both the lengthening and isometric contractions resulted in significantly greater injury to extensor digitorum longus (EDL) muscles of mdx mice than to that of control (C57BL/6) mice. In contrast, the shortening contractions induced very mild and identical injury to EDL muscles of mdx and C57BL/6 mice. Then another protocol was carried out in vivo to ascertain the effect of shortening contractions on mdx muscles by achillotenotomy. Histological assessment revealed that the triceps surae muscles with excised Achilles tendon (EAT) displayed little and significantly milder injury than the normal ones did. In conclusions, the unloaded shortening contractions induce little injury to mdx muscles. The in vitro protocol for different types of contraction-induced injury is sensitive and reliable.     

Sarcoplasmic reticulum function in slow- and fast-twitch skeletal muscles from mdx mice

The aim of the present study was to establish whether alterations in sarcoplasmic reticulum function are involved in the abnormal Ca(2+) homeostasis of skeletal muscle in mice with muscular dystrophy ( mdx). The properties of the sarcoplasmic reticulum and contractile proteins of fast- and slow-twitch muscles were therefore investigated in chemically skinned fibres isolated from the extensor digitorum longus (EDL) and soleus muscles of normal (C57BL/10) and mdx mice at 4 and 11 weeks of development. Sarcoplasmic reticulum Ca(2+) uptake, estimated by the Ca(2+) release following exposure to caffeine, was significantly slower in mdx mice, while the maximal Ca(2+) quantity did not differ in either type of skeletal muscle at either stage of development. In 4-week-old mice spontaneous sarcoplasmic reticulum Ca(2+) leakage was observed in EDL and soleus fibres and this was more pronounced in mdx mice. In addition, the maximal Ca(2+)-activated tension was smaller in mdx than in normal fibres, while the Ca(2+) sensitivity of the contractile apparatus was not significantly different. These results indicate that mdx hindlimb muscles are affected differently by the disease process and suggest that a reduced ability of the Ca(2+)-ATPase to load Ca(2+) and a leaky sarcoplasmic reticulum membrane may be involved in the altered intracellular Ca(2+) homeostasis.     

Muscle Plasma Membrane Changes in Dystrophin Gene Exon 52 Knockout Mouse

Changes in muscle plasma membranes in mice lacking exon 52 of the dystrophin gene (mdx52 mouse) were studied using the freeze-fracture technique. The extensor digitorum longus (EDL) muscle plasma membrane of the mdx52 mouse at 8 weeks of age showed significantly increased caveola density (p < 0.05 by two-tailed t-test) and significantly decreased densities of intramembranous particles (IMPs), orthogonal arrays (OAs) and orthogonal array subunit particles (OASPs) (p < 0.05 by two-tailed t-test, p < 0.01 by Wilcoxon rank-sum test, p < 0.05 by two-tailed t-test, respectively) on the protoplasmic face when compared with those of control EDL muscles. These changes are more similar to those seen in DMD than those in the mdx mouse at the same age as reported previously. Thus, the gene abnormality in the different exon of the mouse dystrophin gene seems to induce somewhat different changes in the muscle plasma membrane.     

The physiological effects of IGF-1 (class 1:Ea transgene) over-expression on exercise-induced damage and adaptation in dystrophic muscles of mdx mice

Duchenne muscular dystrophy (DMD) is a genetic disorder in which muscle weakness and fragility contribute to ongoing muscle degeneration. Although exercise-induced muscle damage is associated with adaptation that protects normal muscle from further damage, exploiting this process to protect dystrophic muscle has been avoided for fear of inducing excessive muscle degeneration. However, muscle-specific over-expression of the class 1:Ea isoform of insulin-like growth factor-1 (IGF-1) reduces myofibre necrosis in dystrophic mdx mice (a model for DMD) and, therefore, may enhance the adaptation process in response to eccentric exercise. To test this hypothesis, we evaluated the effect of transgenic class 1:Ea IGF-1 over-expression on the susceptibility to muscle damage and subsequent adaptation in 12-week-old dystrophic mdx and non-dystrophic control mice. Experiments were conducted in vivo using a custom-built isokinetic mouse dynamometer to measure the deficit in joint torque (indicating muscle damage) after 20 maximal lengthening (eccentric) contractions. Adaptation to this damaging exercise was evaluated by repeating the protocol 7 days after the initial exercise. The over-expression of IGF-1 significantly increased the normalised joint torque in non-dystrophic mice and appeared to ameliorate the muscle weakness in dystrophic mice. All mice displayed a marked reduction in the susceptibility to muscle damage on day 7; however, this adaptation was unaffected by IGF-1, showing that IGF-1 does not protect the dystrophic muscles of adult mdx mice against damage resulting from maximal lengthening contractions.     

Akt activation prevents the force drop induced by eccentric contractions in dystrophin-deficient skeletal muscle

Skeletal muscles of the mdx mouse, a model of Duchenne Muscular Dystrophy, show an excessive reduction in the maximal tetanic force following eccentric contractions. This specific sign of the susceptibility of dystrophin-deficient muscles to mechanical stress can be used as a quantitative test to measure the efficacy of therapeutic interventions. Using inducible transgenesis in mice, we show that when Akt activity is increased the force drop induced by eccentric contractions in mdx mice becomes similar to that of wild-type mice. This effect is not correlated with muscle hypertrophy and is not blocked by rapamycin treatment. The force drop induced by eccentric contractions is similar in skinned muscle fibers from mdx and Akt-mdx mice when stretch is applied directly to skinned fibers. However, skinned fibers isolated from mdx muscles exposed to eccentric contractions in vivo develop less isometric force than wild-type fibers and this force depression is completely prevented by Akt activation. These experiments indicate that the myofibrillar-cytoskeletal system of dystrophin-deficient muscle is highly susceptible to a damage caused by eccentric contraction when elongation is applied in vivo, and this damage can be prevented by Akt activation. Microarray and PCR analyses indicate that Akt activation induces up-regulation of genes coding for proteins associated with Z-disks and costameres, and for proteins with anti-oxidant or chaperone function. The protein levels of utrophin and dysferlin are also increased by Akt activation.     

Effects of firing frequency on length-dependent myofascial force transmission between antagonistic and synergistic muscle groups

Effects of stimulation frequency on myofascial force transmission between rat peroneal and triceps surae and antagonistic anterior crural muscles, and between extensor digitorum longus (EDL) and tibialis anterior and extensor hallucis longus (TA + EHL) muscles were investigated for lengthening of all anterior crural muscles. Muscles contracted isometrically at firing rates of 10, 20, 30 and 100 Hz. EDL and TA + EHL were distally lengthened. Peroneal and triceps surae muscles attained a constant muscle-tendon complex length. Peroneal and triceps surae distal active force decreased significantly as a function of anterior crural muscle length, also at submaximal activation. The absolute decrease was highest for 100 Hz (peroneal muscles -0.87 N; triceps surae muscles -0.92 N), but the highest normalized decrease occurred at 10 Hz stimulation (peroneal muscles -34%; triceps surae muscles -18%). At all muscle lengths, a negative proximo-distal difference in EDL active force was present which decreased with lower firing frequencies (from -0.4 N at 100 Hz to -0.03 N at 10 Hz). The passive proximo-distal force difference attained positive values. EDL and TA + EHL length-force characteristics agree with effects of firing frequency, except for 10 Hz stimulation, where active force was higher than expected and optimum length shifted to lower muscle lengths. It is concluded that also at submaximal stimulation frequencies, extramuscular myofascial force transmission between peroneal and triceps surae muscles and antagonistic anterior crural muscles is substantial. Although lengthening of submaximally active anterior crural muscles decreases the net myofascially transmitted load on EDL, myofascial force transmission significantly alters effects of firing frequency on length-force characteristics.     

Clenbuterol treatment affects myosin heavy chain isoforms and MyoD content similarly in intact and regenerated soleus muscles

AIMS: Pharmacological treatment with the beta2-adrenoceptor agonist clenbuterol is known to induce a slow-to-fast fibre type and myosin heavy chain (MHC) isoform transition in intact muscle. This study examined the sensitivity of regenerated soleus muscle to 4 weeks of clenbuterol treatment (2 mg kg-1 day-1). METHODS: Female Wistar rats were divided into two groups: vehicle treated (n = 8) and clenbuterol treated (n = 8). The clenbuterol effects on MHC and MyoD expression were examined in soleus muscles either intact, or previously degenerated by venom of the Notechis scutatus scutatus snake. RESULTS: Post-treatment body weights and skeletal muscle weights were not affected by clenbuterol treatment. Muscle protein concentration was higher, and body fat lower in clenbuterol-treated rats than in vehicle-treated animals (P < 0.05). Polyacrylamide gel electrophoresis of soleus myofibrillar protein indicated a clenbuterol-induced decrease in the relative percentage of type I MHC with a concomitant increase in type IIa MHC (31%, P < 0.001). No degeneration effect was observed after 28 days of recovery on the MHC isoform content, and regenerated soleus muscles exhibited the same phenotypical profile as intact soleus muscles, whether or not they were treated with clenbuterol. In intact and in regenerated soleus muscles, MyoD protein levels were significantly increased by clenbuterol treatment (90 and 77%, respectively, P < 0.001). CONCLUSION: These results show that regenerated soleus muscles, comprising a homogeneous population of fibres deriving from satellite cells, have a similar response to clenbuterol as intact muscle arising from at least two discrete populations of myotubes; it is suggested that the activity of signalling pathways involved in the effects of clenbuterol on MHC transitions is not related to the developmental history of myofibres.