ON THE DIFFERENTIAL RESPONSE OF SARCOPLASM AND MYOPLASM TO DENERVATION IN FROG MUSCLE

Electron microscopic evidence is presented that the early response to denervation ("simple atrophy") of the semitendinosus m. of the frog is characterized by a greater prominence of the sarcoplasmic reticulum and by the presence, in the interfibrillar spaces, of mitochondria which are more numerous and smaller than in normal muscle. In contrast with the dynamic changes of the sarcoplasmic structural components, the myofibrils showed a progressive decrease in diameter after denervation and throughout the period studied. By carrying out tissue fractionation experiments, the yield of microsome-protein was found significantly greater in the denervated muscles, as compared with the contralateral controls, in this initial stage. Under the conditions attending the overdevelopment of the sarcoplasmic reticulum (SR), denervated semitendinosus m. incorporated valine-C¹⁴ into proteins more actively than the control pairs. The denervated muscles also showed an increase in the number of freely scattered and membrane-bound ribosomes and of polyribosomes, suggesting a more active synthesis of the SR membranes. Pronounced atrophy of the myofibrils, disorganization of the SR, and an increased number of ribonucleoprotein particles lying in the enlarged interfibrillar spaces were the main ultrastructural features of "degenerative atrophy" in frog muscle in the late periods after denervation. The probably adaptive character of the early changes occurring on denervation of frog muscle is discussed.     

Expression of ARPP-16/19 in rat denervated skeletal muscle

It is known that denervation of rat skeletal muscle causes atrophy and this is often adopted as a model for human muscle atrophy. To understand the molecular changes that occur, it is important to identify the profiles of differential gene expression. In the present study, we investigated differentially expressed genes in denervated muscle using DNA microarrays with printed genes preferentially expressed in skeletal muscle. We found that several genes are differentially expressed. Of these genes, ARPP-16/19 (cAMP-regulated phosphoprotein 16/19) is selectively enhanced after denervation. The expression of ARPP-16/19 in denervated muscles starts to increase from two days after denervation surgery. On the other hand, the expression of ARPP-16/19 does not change in hind-limb suspended muscles, such as EDL and soleus muscles. These results suggest that the increase in ARPP-16/19 mRNA expression is regulated by unknown factor(s) secreted from nerves, and not by electrical muscle activity.     

The effect of denervation upon the functional properties of myosin and its fragments.

A study has been made of some structural and enzymatic properties of myosin and its fragments from denervated white muscles of rabbit in the course of atrophy using different methods: UV-luminiscence, flow birefringence, electromicroscopy, viscosimetry and enzymatic measurements. All the studied parameters had a tendency to decrease; at prolonged observation some properties were partially restored. Considerable changes of structural properties of LMM were revealed: the ability of LMM from denervated muscle to form high-ordered structures which is characteristic of LMM from normal muscle decreased considerably.     

Proteasome-dependent Activation of Mammalian Target of Rapamycin Complex 1 (mTORC1) Is Essential for Autophagy Suppression and Muscle Remodeling Following Denervation

Drastic protein degradation occurs during muscle atrophy induced by denervation, fasting, immobility, and various systemic diseases. Although the ubiquitin-proteasome system is highly up-regulated in denervated muscles, the involvement of autophagy and protein synthesis has been controversial. Here, we report that autophagy is rather suppressed in denervated muscles even under autophagy-inducible starvation conditions. This is due to a constitutive activation of mammalian target of rapamycin complex 1 (mTORC1). We further reveal that denervation-induced mTORC1 activation is dependent on the proteasome, which is likely mediated by amino acids generated from proteasomal degradation. Protein synthesis and ribosome biogenesis are paradoxically increased in denervated muscles in an mTORC1-dependent manner, and mTORC1 activation plays an anabolic role against denervation-induced muscle atrophy. These results suggest that denervation induces not only muscle degradation but also adaptive muscle response in a proteasome- and mTORC1-dependent manner.     

Atrophy, but not necrosis, in rabbit skeletal muscle denervated for periods up to one year

Our understanding of the effects of long-term denervation on skeletal muscle is heavily influenced by an extensive literature based on the rat. We have studied physiological and morphological changes in an alternative model, the rabbit. In adult rabbits, tibialis anterior muscles were denervated unilaterally by selective section of motor branches of the common peroneal nerve and examined after 10, 36, or 51 wk. Denervation reduced muscle mass and cross-sectional area by 50–60% and tetanic force by 75%, with no apparent reduction in specific force (force per cross-sectional area of muscle fibers). The loss of mass was associated with atrophy of fast fibers and an increase in fibrous and adipose connective tissue; the diameter of slow fibers was preserved. Within fibers, electron microscopy revealed signs of ultrastructural disorganization of sarcomeres and tubular systems. This, rather than the observed transformation of fiber type from IIx to IIa, was probably responsible for the slow contractile speed of the muscles. The muscle groups denervated for 10, 36, or 51 wk showed no significant differences. At no stage was there any evidence of necrosis or regeneration, and the total number of fibers remained constant. These changes are in marked contrast to the necrotic degeneration and progressive decline in mass and force that have previously been found in long-term denervated rat muscles. The rabbit may be a better choice for a model of the effects of denervation in humans, at least up to 1 yr after lesion. force; shortening velocity; electron microscopy; histochemistry     

Analysis of the interaction between properdin and factor B, components of the alternative-pathway C3 convertase of complement.

Denervated (1-10 days) rat epitrochlearis muscles were isolated, and basal and insulin-stimulated protein and glucose metabolism were studied. Although basal rates of glycolysis and glucose transport were increased in 1-10-day-denervated muscles, basal glycogen-synthesis rates were unaltered and glycogen concentrations were decreased. Basal rates of protein degradation and synthesis were increased in 1-10-day-denervated muscles. The increase in degradation was greater than that in synthesis, resulting in muscle atrophy. Increased rates of proteolysis and glycolysis were accompanied by elevated release rates of leucine, alanine, glutamate, pyruvate and lactate from 3-10-day-denervated muscles. ATP and phosphocreatine were decreased in 3-10-day-denervated muscles. Insulin resistance of glycogen synthesis occurred in 1-10-day denervated muscles. Insulin-stimulated glycolysis and glucose transport were inhibited by day 3 of denervation, and recovered by day 10. Inhibition of insulin-stimulated protein synthesis was observed only in 3-day-denervated muscles, whereas regulation by insulin of net proteolysis was unaffected in 1-10-day-denervated muscles. Thus the results demonstrate enhanced glycolysis, proteolysis and protein synthesis, and decreased energy stores, in denervated muscle. They further suggest a defect in insulin's action on protein synthesis in denervated muscles as well as on glucose metabolism. However, the lack of concurrent changes in all insulin-sensitive pathways and the absence of insulin-resistance for proteolysis suggest multiple and specific cellular defects in insulin's action in denervated muscle.     

Regulation of skeletal muscle dihydropyridine receptor gene expression by biomechanical unloading.

Biomechanical unloading of the rat soleus by hindlimb unweighting is known to induce atrophy and a slow- to fast-twitch transition of skeletal muscle contractile properties, particularly in slow-twitch muscles such as the soleus. The purpose of this study was to determine whether the expression of the dihydropyridine (DHP) receptor gene is upregulated in unloaded slow-twitch soleus muscles. A rat DHP receptor cDNA was isolated by screening a random-primed cDNA lambda gt10 library from denervated rat skeletal muscle with oligonucleotide probes complementary to the coding region of the rabbit DHP receptor cDNA. Muscle mass and DHP receptor mRNA expression were assessed 1, 4, 7, 14, and 28 days after hindlimb unweighting in rats by tail suspension. Isometric twitch contraction times of soleus muscles were measured at 28 days of unweighting. Northern blot analysis showed that tissue distribution of DHP receptor mRNA was specific for skeletal muscle and expression was 200% greater in control fast-twitch extensor digitorum longus (EDL) than in control soleus muscles. A significant stimulation (80%) in receptor message of the soleus was induced as early as 24 h of unloading without changes in muscle mass. Unloading for 28 days induced marked atrophy (control = 133 +/- 3 vs. unweighted = 62.4 +/- 1.8 mg), and expression of the DHP receptor mRNA in the soleus was indistinguishable from levels normally expressed in EDL muscles. These changes in mRNA expression are in the same direction as the 37% reduction in time to peak tension and 28% decrease in half-relaxation time 28 days after unweighting. Our results suggest that muscle loading necessary for weight support modulates the expression of the DHP receptor gene in the soleus muscle.     

Electron microscopy of the nuclei of denervated skeletal muscle

Summary Denervated musculi gastrocnemii and solei of adult rats and rabbits were studied by weight analysis and by light and electron microscopy. The weight loss was severe and indicative of degenerative atrophy. Microscopic examinations showed no difference between the changes of nuclei in the gastrocnemius as compared with the soleus or between these muscles whether they were from rats or rabbits.Mitoses were found neither in normal nor in denervated muscle fibers, not even in animals which were killed at 3 o'clock in the morning or injected with colcemid at appropriate periods before death.Electron microscopic studies showed the earliest changes in the nuclei of denervated muscle to appear four hours after denervation. They involved aggregation of chromatin granules, loosening of nucleolar substance and uneven density of the nuclear membrane. They became very pronounced one to five days after denervation. Between the first week and the third month of denervation atrophy, infoldings and constrictions of muscle nuclei were conspicuous. From the fourth to fifth month, additional changes were the partitioning of muscle nuclei and the condensation of nuclear fragments and of nucleoli.Our findings gave no indication of mitoses to account for nuclear proliferation. Numerous and deep infoldings seen under the electron microscope indicated processes of nuclear partition which might produce viable nuclei, or nuclei subject to pyknosis, or might lead to ultimate disintegration of the fragments.Supported partly by the Medical Research Council of Canada and partly by the Canadian Association of Muscular Dystrophy.     

The effects of denervation on protein turnover of the soleus and extensor digitorum longus muscles of adult mice.

1. Changes in protein turnover of the soleus and EDL muscles of adult mice have been studied 1, 7 and 80 days after denervation. 2. Increased rates of protein degradation 7 and 80 days post-denervation correlated with the atrophy and loss of protein from these muscles. 3. Rates of protein synthesis in the EDL decreased 24 hr after nerve section. However, these synthetic rates increased again to become higher in the 7 day denervated muscles compared with their controls. These latter anabolic changes are inconsistent with the concept of a denervated muscle being inactive. 4. These findings have been compared with a similar study on muscles of growing rats. Any passive stretching of the denervated muscles by continued bone growth appears unlikely to be a crucial factor explaining the increased rates of protein synthesis 7 days after denervation.     

The study of energy metabolism in denervated skeletal muscle with 31P-NMR

1. The denervated frog sartorius muscle showed a decrease in the energy store more than that in the control. 2. In the caffeine contractures, both the denervated and the innervated muscles showed similar sequential changes in the relative concentration of phosphocreatine (PCr) to beta-adenosine triphosphate (beta-ATP) and inorganic phosphate (Pi) to beta-ATP. Instead, the intracellular pH value of the denervated muscle was lower than that of the control. 3. It is suggested that phosphate metabolism of the denervated muscle during contracture shows little difference from that of the control, nevertheless, the buffering capacity is decreased in the early stage of atrophy.     

Reduction of skeletal muscle atrophy by a proteasome inhibitor in a rat model of denervation

The ubiquitin-proteasome system is the primary proteolytic pathway implicated in skeletal muscle atrophy under catabolic conditions. Although several studies showed that proteasome inhibitors reduced proteolysis under catabolic conditions, few studies have demonstrated the ability of these inhibitors to preserve skeletal muscle mass and architecture in vivo. To explore this, we studied the effect of the proteasome inhibitor Velcade (also known as PS-341 and bortezomib) in denervated skeletal muscle in rats. Rats were given vehicle or Velcade (3 mg/kg po) daily for 7 days beginning immediately after induction of muscle atrophy by crushing the sciatic nerve. At the end of the study, the rats were euthanized and the soleus and extensor digitorum longus (EDL) muscles were harvested. In vehicle-treated rats, denervation caused a 33.5 +/- 2.8% and 16.2 +/- 2.7% decrease in the soleus and EDL muscle wet weights (% atrophy), respectively, compared to muscles from the contralateral (innervated) limb. Velcade significantly reduced denervation-induced atrophy to 17.1 +/- 3.3% in the soleus (P < 0.01), a 51.6% reduction in atrophy associated with denervation, with little effect on the EDL (9.8 +/- 3.2% atrophy). Histology showed a preservation of muscle mass and preservation of normal cellular architecture after Velcade treatment. Ubiquitin mRNA levels in denervated soleus muscle at the end of the study were significantly elevated 120 +/- 25% above sham control levels and were reduced to control levels by Velcade. In contrast, testosterone proprionate (3 mg/kg sc) did not alleviate denervation-induced skeletal muscle atrophy but did prevent castration-induced levator ani atrophy, while Velcade was without effect. These results show that proteasome inhibition attenuates denervation-induced muscle atrophy in vivo in soleus muscles. However, this mechanism may not be operative in all types of atrophy.     

Response to denervation of rabbit soleus and gastrocnemius muscles. Time-course study of postnatal changes in myosin isoforms,fiber types,and contractile properties

Summary— In contrast to general belief, the response of rabbit muscles to denervation is maturation to slow-like type muscles [7]. We report now an investigation by biochemical, morphological, and mechanical studies of the time course effects of muscle denervation on the slow-type soleus and fast-type gastrocnemius to help clucidate the mechanism of maturation of rabbit denervated muscles to slow-like muscles. In both muscles, denervation induced selective progressive atrophy of most fast fibers and hypertrophy of many slow fibers which displayed wide Z-lines; this was accompanied by the appearance of hybrid LC1F- and LC1E-associated slow myosins. The percentage of slow myosins increased with age similarly in the contralateral and denervated soleus. On the other hand, the percentage of slow myosins remained low in the contralateral gastrocnemius, whereas it increased to 95% in the denervated gastrocnemius; in the denervated gastrocnemius, the percentage of slow myosins reached 50% at about 35 days postnatal. At this age, the maximal shortening velocity of the denervated gastrocnemius and its twitch contraction time were already those of a slow-type muscle. This suggests that in addition to myosin, other proteins contributed to the mechanical properties of the denervated gastrocnemius. Transformation of rabbit denervated muscles to slow-like type muscles, which are associated with a lower energy requirement and higher muscle endurance than fast-type muscles, may constitute an adequate model for human neuromuscular pathology.     

Sustained cell proliferation in denervated skeletal muscle of mice

Summary Cellular proliferation in skeletal muscle was measured throughout the first 4 weeks after denervation. Twenty four mice had one leg denervated, and 4 groups of 6 of these mice were injected with tritiated thymidine once daily for 7 days, either during the first, second, third or fourth week after denervation. Autoradiographic labelling of muscle and connective tissue nuclei in denervated muscles was compared with innervated muscles from the opposite innervated legs of the same mice. Labelling of connective tissue and muscle (myonuclear and satellite cell) nuclei was significantly higher in denervated muscles, compared with innervated muscles on the unoperated side. There were no significant differences among labelling of nuclei in muscles denervated for 1, 2, 3 or 4 weeks. However, connective tissue labelling after 1 week of denervation was significantly higher than at later times. This study shows that nuclei of muscle and connective tissue cells proliferate and turnover at high levels for at least one month after denervation.     

Reduced glycogen phosphorylase activity in denervated hindlimb muscles of rat is related to muscle atrophy and fibre type

Changes in the activity of muscle glycogen synthase or phosphorylase (GP) may be responsible for the deregulation of glycogen synthesis and storage which occurs in diabetes mellitus. To clarify the relationship between muscle atrophy, fibre type, insulin-stimulated glucose uptake and GP activity during insulin resistance, we used sciatic nerve severance to induce insulin resistance in rat hindlimb muscles and compared the above parameters in muscles with a range of fibre types. Changes were analysed by comparison with the contralateral hindlimb, which bears more weight due to denervation of the opposing limb, as well as the sham-operated and contralateral limb of a separate rat. Denervation caused a decrease in insulin-stimulated glucose uptake by 1 day after denervation and a decline of GP activity after 7 days in all muscles investigated. GP activity decreased by 73% in soleus, 36% in red gastrocnemius, 35% in tibialis and 13% in white gastrocnemius, which was related to the degree of muscle atrophy and inversely related to the overall GP activity in non-denervated muscles. GP activity in muscles of the contralateral limb from the denervated rat did not differ from either hindlimb of the sham-operated rat. We conclude that the fibre-type related reduction in insulin-stimulated glucose uptake of denervated muscle determines the change in its metabolism and it is this metabolic change which determines the mechanism, rate and degree of muscle atrophy, which is directly related to the decline in GP activity.     

Role of different proteolytic systems in the degradation of muscle proteins during denervation atrophy

In order to clarify the cellular mechanisms of denervation atrophy of skeletal muscle, we have studied protein turnover in denervated and control rat soleus muscles in vitro under different conditions. By 24 h after cutting the sciatic nerve, overall protein breakdown was greater in the denervated soleus than in the contralateral control muscle, and by 3 days, net proteolysis had increased about 3-fold. Since protein synthesis increased slightly following denervation, the rise in proteolysis must be responsible for the muscle atrophy and the differential loss of contractile proteins. Like overall proteolysis, the breakdown of actin (as shown by 3-methyl-histidine production by the muscles) increased each day after denervation and by 3 days was 2.5 times faster than in controls. Treatments that block the lysosomal and Ca2(+)-dependent proteolytic systems did not reduce the increase in overall protein degradation and actin breakdown in the denervated muscles (maintained in complete medium at resting length). However, the content of the lysosomal protease, cathepsin B, increased about 2-fold by 3 days after denervation. Furthermore, conditions that activate intralysosomal proteolysis (incubation without insulin or amino acids) stimulated proteolysis 2-3-fold more in the denervated muscles than in controls. Also, incubation conditions that activate the Ca2(+)-dependent pathway (incubation with Ca2+ ionophores or allowing muscles to shorten) were 2-3 times more effective in enhancing overall proteolysis in the denervated muscle. None of these treatments affected 3-methylhistidine production. Thus, multiple proteolytic systems increase in parallel in the denervated muscle, but a nonlysosomal process (independent of Ca2+) appears mainly responsible for the rapid loss of cell proteins, especially of myofibrillar components.     

Effect of denervation and tenotomy on slow and fast muscles of the chicken

Summary Changes of muscle weights, fiber diameters and ultrastructure were studied in the slow anterior latissimus dorsi (ALD) and in the fast posterior latissimus dorsi (PLD) of the chick three weeks after denervation and tenotomy, and after combined denervation and tenotomy of the two muscles.The slow ALD muscle becomes hypertrophic after denervation (Feng, Jung and Wu, 1962). Three weeks after nerve section, wet weights of ALD muscles are increased by 60% and fiber diameters become by 30% larger than those of contralateral control muscles. In spite of this hypertrophy, degenerative changes are seen in the ultrastructure, similar to those described in denervated atrophic muscles. Areas of dedifferentiation with autophagic vacuoles and aggregates of tubules are found in superficial layers of some fibers. Disintegration of Z lines and filaments along one or two sarcomeres occurs in a number of myofibrils, especially in muscles of young animals.In contrast to denervation alone, simultaneous denervation and tenotomy of the ALD muscles results in atrophy. Decrease of muscle weights and reduction of fiber diameters are similar as after tenotomy; in both cases muscle fibers waste by degeneration and atrophy of myofibrils.The fast PLD muscles underwent extensive atrophy in all three series of experiments. Corresponding atrophic and degenerative changes of ultrastructure were found in all instances.The authors wish to acknowledge gratefully the skillful technical assistance of Mrs. M. Sobotková and Ing. M. Doubek, and editorial assistance of Miss Virginia Hamilton.