Abnormal distribution of skeletal muscle acetylcholinesterase molecular forms in dystrophic mice

Acetylcholinesterase (AChE) activities and molecular forms, as separated by density gradient centrifugation, were studied in dystrophic and clinically normal mouse muscle. Dystrophic hemidiaphragms exhibited normal AChE activity, but there was little or no 10 S enzyme, a form that constitutes 27% of control tissue AChE. The 10 S-AChE abnormality was similarly present in dystrophic extensor digitorum longus (EDL) muscle, but this muscle exhibited significantly reduced AChE activity. The EDL muscles also had reduced 16 S-AChE but normal 4 S enzyme activity. Chronic denervation of EDL muscles resulted in proportionally similar reductions of weight, total AChE, and 16 S enzyme in dystrophic and control muscles. We conclude that murine dystrophy involves some alterations that resemble denervation, but that there are major qualitative and quantitative differences in AChE that cannot be explained by a denervation-like effect.     

Stimulation of denervated rat soleus muscle with fast and slow activity patterns induces different expression of acetylcholinesterase molecular forms

The relative amount and distribution of acetylcholinesterase (AChE) molecular forms were studied in slow soleus and (less extensively) in fast extensor digitorum longus (EDL) muscles of the rat before and after denervation and direct stimulation. Normal EDL muscles showed higher total and specific AChE activity than normal soleus muscles and contained essentially three different molecular AChE forms (G1, G4, and A12) as opposed to six forms (G1, G2, G4, A4, A8, and A12) in the soleus. Denervation reduced AChE activity in both muscles. In the soleus direct stimulation starting 2 to 3 weeks after denervation increased the specific AChE activity markedly. The increase started 12 to 24 hr after the onset of stimulation, reached 3 to 5 times normal values after 2 to 7 days, and then declined gradually toward normal values over the next 2 weeks. Furthermore, the effect on the different molecular forms depended strongly on the stimulus pattern. Thus, intermittent 100 Hz stimulation (fast pattern) induced essentially the three forms typical of the normal EDL, whereas continuous 10 Hz stimulation induced the six forms characteristic of normal soleus muscles but with some differences in their relative proportions. In the EDL, 2 days of continuous 10 Hz stimulation (the only duration and pattern examined) failed to induce a similar increase in AChE activity.     

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.     

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.     

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.     

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.     

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.     

Influence of innervation on molecular forms of acetylcholinesterase in regenerating fast and slow skeletal muscles

Nerve-intact muscle regenerates were prepared by ischemic-toxic injury of slow soleus (SOL) and fast extensor digitorum longus (EDL) muscles of the rat. Rapid innervation of regenerating myotubes modified intrinsic patterns of AChE molecular forms, revealed by velocity sedimentation in linear sucrose gradients. Regarding their onset, the effects of innervation can be classified as early and late. The earliest changes in the SOL regenerates appeared a few days after innervation by their motoneurons: the activity of the 13 S AChE form (A 8) increased significantly in comparison to non-innervated regenerates. The pattern of AChE molecular forms became similar to that in the normal SOL muscle during the 2nd week after injury. In contrast, no major differences were observed between 8 day-old innervated and non-innervated EDL regenerates. Their patterns of AChE molecular forms resembled that in the normal EDL. However, the predominance of the 10 S AChE form (G 4) characteristic for the 2-week old non-innervated regenerates was prevented by innervation. Early effect of innervation observed in the SOL regenerates but not in the EDL may be due to intrinsically different response of the regenerating SOL myotubes to innervation. Rather high extrajunctional activity of the asymmetric 16 S (A 12) molecular form of AChE in early regenerates was reduced to adult level in about 3 weeks in the SOL, and nearly completely suppressed in 5 weeks after innervation in the EDL regenerates. This reduction is assumed to be a late effect of innervation, as well as a decrease of the activity of the 4 S AChE form (G 1) in the SOL regenerates. A suppressive mechanism is activated in the extra-junctional regions of the innervated muscle regenerates during their maturation.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Dystrophic mouse muscles have leaky cell membranes

We examined the spaces occupied by mannitol, sucrose, polyethylene glycol molecular weight 900 (PEG 900), and polyethylene glycol molecular weight 4000 (PEG 4000) in the soleus and extensor digitorum longus (EDL) muscles of normal and dystrophic mice (strain ReG-129 $\text{dy}\text{dy}$). The space occupied by all those tracers was larger in dystrophic than in normal muscles. The enlargement of tracer space was more marked in EDL than in soleus muscles. The smaller tracers (sucrose, mannitol, and PEG 900) equilibrate with nearly all the water in dystrophic EDL whereas there is a water space inaccesible to the larger tracers (inulin and PEG 4000). We suggest that the tracers penetrate into the cell through defects in the cell membrane of the dystrophic muscles.     

Choline acetyltransferase and acetylcholinesterase activities in muscles of aged mice

The activities of choline acetyltransferase (CAT) and acetylcholinesterase (AChE) were assayed in intact diaphragm, extensor digitorum longus (EDL), and soleus muscles or their homogenates of young (2-6 months) and aged (24-34 months) mice. CAT activity (per mg of protein) was significantly higher in diaphragm and soleus of old mice in comparison with the young but the age change in EDL was negligible. On the other hand, AChE activity (per mg of protein) was significantly higher in EDL of old mice but in diaphragm and soleus muscles the enzyme activity did not show any significant change statistically. The diaphragm muscle was divided into two fractions, one being neuromuscular (NM) fraction and the other the remainder of the muscle (M fraction). No appreciable change in the ratio of the enzyme activities of NM fraction to the one of M fraction was obtained between the young and aged preparations. Thus, it seems likely that there is an age-related change in CAT and AChE activities which might be affected by the degree to which muscle activity is maintained.     

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.     

Membrane acetylcholinesterase in murine muscular dystrophy In vivo and in cultured myotubes

Murine muscular dystrophy is characterized by a reduction of the 10S molecular form of acetylcholinesterase (AChE); this reduction occurs in both strains of dystrophic mice and at the time of the phenotypic appearance of the disease.In the present study we have analyzed the biochemical features, the cellular distribution and the developmental appearance of the AChE alteration. Sequential extractions with low salt, detergent and high salt revealed that this alteration affects only membrane-bound forms (those requiring Triton X-100 for solubilization), while both the low salt soluble and the high salt soluble forms appeared almost identical in normal and dystrophic muscles. Specific activity, sensitivity to different ions, pH dependence and K_m were found to be identical in the enzymes from normal and dystrophic muscles, suggesting that the catalytic site of the 10S form is probably not altered.Further analysis, by non-denaturing gel electrophoresis, of the detergent soluble forms separated by sedimentation, revealed a single band for the 4S, a doublet for the 6S and three bands for the 10S peaks, indicating the existence of charge heterogeneity in AChE molecular forms. The corresponding molecular forms from dystrophic muscles behaved identically upon electrophoresis: the residual activity in the detergent soluble 10S form could still be separated into three bands, comigrating with their normal counterparts. Neuraminidase treatment resulted in a reduction of migration of both the 6S and 10S derived bands, but not of the 4S species, showing that sialic acid is added only to polymeric forms. Interestingly, the reduction of the 10S form appears to be linked to a developmental stage not reached in cell cultures, as cultured myotubes from muscles of dystrophic mice contained normal amounts of membrane-bound AChE forms. The molecular mechanism underlying the reduction of the tetrameric membrane bound AChE form in dystrophic muscle and the possible functional consequences are discussed.     

Muscle activity pattern regulates postnatal development of acetylcholinesterase molecular forms in normal mice and mice with motor endplate disease

We have studied the relative contributions of muscle activity and nerve-supplied materials to the regulation of AChE molecular forms during postnatal development of muscles in normal mice and in mice with motor endplate disease (med mice). Onset of this hereditary disease causes a progressive failure of evoked release of ACh from the motor neuron, which prevents contraction in muscles such as biceps and soleus. In these innervated but inactive muscles, one can examine the consequences of inactivity on the distribution of AChE forms. In normal mouse biceps the distribution of AChE forms, as shown by sucrose-gradient analysis, change substantially after birth; the most dramatic alteration is an increase in G4 AChE from 15 to 45% of total AChE during the third postnatal week. AChE profiles in normal or med biceps are indistinguishable until 10-12 d after birth, but the changes in distribution of AChE forms does not occur in med biceps nor in normal biceps denervated 2 weeks after birth. In contrast, the distributions of AChE forms in a predominantly slow muscle, the soleus, are similar in med and normal mice both early (10 d) and late (20 d) in the course of the disease, and the distributions are affected little by denervation. The profiles of AChE forms seen in normal soleus at all times studied resembled those seen in newborn biceps or biceps inactivated by denervation or the med disease. We conclude that neither innervation, age-dependent changes intrinsic to muscle, nor muscle activity is sufficient to induce the changes we seen in AChE forms in biceps. These results support the hypothesis that neonatal, inactive, or tonically active muscles produce an intrinsic pattern of AChE molecular forms, and that a phasic pattern of activity induces a postnatal redistribution of the AChE molecular forms expressed by the muscle.     

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.     

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.     

The effect of continuous pyridostigmine administration on functional (A12) acetylcholinesterase activity in guinea-pig muscles

Pyridostigmine which causes a reversible inhibition of acetylcholinesterase (AChE), was administered continuously for 6 days to guinea-pigs, via a subcutaneously implanted osmotic pump. This produced 40-50% inhibition of red cell acetylcholinesterase (AChE). Controls were animals treated with saline via pumps, and untreated animals. The activities of the functional A12 molecular form of AChE were compared in diaphragm, extensor digitorum longus (EDL) and soleus muscles in the three animal groups at 6 days. The pumps were removed at 6 days and the A12 AChE activities were determined at various times thereafter As the enzyme separation procedure was lengthy, drug-induced inhibition was no longer present when the enzyme activity was measured. At 6 days, the activity was significantly higher in EDL (over 50% higher) and soleus (over two-fold higher) in pyridostigmine-treated animals than saline-treated animals. In the diaphragm, the activities in pyridostigmine and saline-treated animals were similar but both were significantly (over two-fold) higher than in untreated animals. At 1 day after pump removal (day 7) the activity had declined in all three muscles of the pyridostigmine-treated animals and in the diaphragm of saline-treated animals. Thereafter, in the diaphragm (but not the EDL or soleus) in pyridostigmine-treated animals, there were marked variations in the enzyme activity up to day 20. In saline-treated animals there was a marked transient increase in activity at day 13 in all muscles. The results indicate that the homeostatic control offunctional AChE had been affected in both the pyridostigmine and saline treatment groups.     

Specific impulse patterns regulate acetylcholinesterase activity in skeletal muscles of rats and rabbits

In rats, acetylcholinesterase (AChE) activity in the fast muscles is several times higher than in the slow soleus muscle. The hypothesis that specific neural impulse patterns in fast or slow muscles are responsible for different AChE activities was tested by altering the neural activation pattern in the fast extensor digitorum longus (EDL) muscle by chronic low-frequency stimulation of its nerve. In addition, the soleus muscle was examined after hind limb immobilization, which changed its neural activation pattern from tonic to phasic. Myosin heavy-chain (MHC) isoforms were analyzed by gel electrophoresis. Activity of the molecular forms of AChE was determined by velocity sedimentation. Low-frequency stimulation of the rat EDL for 35 days shifted the profile of MHC II isoforms toward a slower MHCIIa isoform. Activity of the globular G₁ and G₄ molecular forms of AChE decreased by a factor of 4 and 10, respectively, and became comparable with those in the soleus muscle. After hind limb immobilization, the fast MHCIId isoform, which is not normally present, appeared in the soleus muscle. Activity of the globular G₁ form of AChE increased approximately three times and approached the levels in the fast EDL muscle. In the rabbit, on the contrary to the rat, activity of the globular forms of AChE in a fast muscle increased after low-frequency stimulation. The results demonstrate that specific neural activation patterns regulate AChE activity in muscles. Great differences, however, exist among different mammalian species in regard to muscle AChE regulation. J. Neurosci. Res. 47:49–57, 1997. © 1997 Wiley-Liss, Inc.     

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.     

Clenbuterol reduces degeneration of exercised or aged dystrophic (mdx) muscle

Evidence of dystrophic muscle degeneration in the hind limb muscles of young (20-week-old) treadmill-exercised or aged (87-week-old) sedentary mdx mice was greatly reduced by treatment with clenbuterol, a beta(2)-adrenoceptor agonist. Daily treadmill exercise for 10 weeks increased the size of regions within the mdx plantaris but not the soleus or gastrocnemius muscles, in which necrotic muscle fibers or the absence of fibers was observed. Clenbuterol reduced the size of these abnormal regions from 21% of total muscle cross-sectional area to levels (4%) found in sedentary mdx mice. In addition, the muscles obtained from aged clenbuterol-treated mdx or wild-type mice did not display the extensive fibrosis or fiber loss observed in untreated mdx mice. These observations are consistent with a mechanism of dystrophic muscle degeneration caused by work load-induced injury that is cumulative with aging and is opposed by beta(2)-adrenoceptor activation. Optimization of beta(2)-agonist treatment of muscular dystrophy in mdx mice may lead to a useful therapeutic modality for human forms of the disease.