Neural Regulation of Muscle Glucose 6-Phosphate Dehydrogenase: Effect of Batrachotoxin and Tetrodotoxin

Abstract: We tested the hypothesis that glucose 6-phosphate dehydrogenase (G6PD) activity in the rat skeletal muscle is regulated by putative axonally derived neurotrophic factors. This was accomplished by comparing the effects of nerve section and subperineural injection of batrachotoxin (BTX) or tetrodotoxin (TTX) on G6PD in rat extensor digitorum longus (EDL) muscle. BTX, an agent known to block nerve impulse conduction and axonal transport, increased G6PD activity to 155% and 163% of control by days 2 and 4 after injection. Denervation of the EDL muscle by section of the peroneal nerve 10–20 mm from its entrance to the muscle caused G6PD activity to increase to 170% of control by day 1 and to 200% and 180% of control by days 2 and 4, respectively. The increase in enzyme activity after denervation and after subperineural injection of BTX was due in part to muscle inactivity resulting from blockade of nerve impulses. This conclusion is based upon the observation that subperineural injection of TTX at an identical site in the peroneal nerve caused a small but significant (30%) increase in G6PD activity after 4 days. Choline acetyltransferase (CAT) activity was assessed as a measure of the efficacy of blockade of slow axonal transport. Decreases in CAT activity following denervation or injection of BTX or TTX were parallel to increases in G6PD activity observed under these conditions. These results argue for a role of axonal transport in neural regulation of muscle G6PD, with a small contribution by neuromuscular activity.     

Slow myosin heavy chain expression in the absence of muscle activity

Innervation has been generally accepted to be a major factor involved in both triggering and maintaining the expression of slow myosin heavy chain (MHC-1) in skeletal muscle. However, previous findings from our laboratory have suggested that, in the mouse, this is not always the case (30). Based on these results, we hypothesized that neurotomy would not markedly reduced the expression of MHC-1 protein in the mouse soleus muscles. In addition, other cellular, biochemical, and functional parameters were also studied in these denervated soleus muscles to complete our study. Our results show that denervation reduced neither the relative amount of MHC-1 protein, nor the percentage of muscle fibers expressing MHC-1 protein (P > 0.05). The fact that MHC-1 protein did not respond to muscle inactivity was confirmed in three different mouse strains (129/SV, C57BL/6, and CD1). In contrast, all of the other histological, biochemical, and functional muscle parameters were markedly altered by denervation. Cross-sectional area (CSA) of muscle fibers, maximal tetanic isometric force, maximal velocity of shortening, maximal power, and citrate synthase activity were all reduced in denervated muscles compared with innervated muscles (P < 0.05). Contraction and one-half relaxation times of the twitch were also increased by denervation (P < 0.05). Addition of tenotomy to denervation had no further effect on the relative expression of MHC-1 protein (P > 0.05), despite a greater reduction in CSA and citrate synthase activity (P < 0.05). In conclusion, a deficit in neural input leads to marked atrophy and reduction in performance in mouse soleus muscles. However, the maintenance of the relative expression of slow MHC protein is independent of neuromuscular activity in mice.     

Nerve-muscle interaction: changes in the cellular organization of a skeletal muscle upon denervation

The alterations in the organization of lumbrical muscle of the rat have been investigated following denervation, with emphasis on the structure of cytoplasmic constituents, sarcolemma in the synaptic and non-synaptic regions and acetylcholinesterase activity. The appearance of 15--18 nm intramenbranous particles in the non-synaptic sarcolemma is thought to be related to the known acetylcholine extrajunctional sensitivity which is manifested after denervation. The acetylcholinesterase activity is greatly reduced in the synaptic region in the denervated muscle. These changes are discussed in relation to the known physiological and biochemical data.     

Nerve activity-independent regulation of skeletal muscle atrophy: role of MyoD and myogenin in satellite cells and myonuclei

Electrical activity is thought to be the primary neural stimulus regulating muscle mass, expression of myogenic regulatory factor genes, and cellular activity within skeletal muscle. However, the relative contribution of neural influences that are activity-dependent and -independent in modulating these characteristics is unclear. Comparisons of denervation (no neural influence) and spinal cord isolation (SI, neural influence with minimal activity) after 3, 14, and 28 days of treatment were used to demonstrate whether there are neural influences on muscle that are activity independent. Furthermore, the effects of these manipulations were compared for a fast ankle extensor (medial gastrocnemius) and a fast ankle flexor (tibialis anterior). The mass of both muscles plateaued at approximately 60% of control 2 wk after SI, whereas both muscles progressively atrophied to <25% of initial mass at this same time point after denervation. A rapid increase in myogenin and, to a lesser extent, MyoD mRNAs and proteins was observed in denervated and SI muscles: at the later time points, these myogenic regulatory factors remained elevated in denervated, but not in SI, muscles. This widespread neural activity-independent influence on MyoD and myogenin expression was observed in myonuclei and satellite cells and was not specific for fast or slow fiber phenotypes. Mitotic activity of satellite and connective tissue cells also was consistently lower in SI than in denervated muscles. These results demonstrate a neural effect independent of electrical activity that 1) helps preserve muscle mass, 2) regulates muscle-specific genes, and 3) potentially spares the satellite cell pool in inactive muscles.     

Denervation provokes greater reductions in insulin-stimulated glucose transport in muscle than severe diabetes

We have examined the independent and combined effects of insulin insufficiency (streptozotocin (STZ)-induced diabetes, 85 mg/kg i.p.) and reduced muscle activity (denervation) (7 days) on basal, insulin-stimulated and contraction-stimulated glucose transport in rat muscles (soleus, red and white gastrocnemius). There were four treatments: control, denervated, diabetic, and denervated + diabetic muscles. Contraction-stimulated glucose transport was lowered (~ 50%) (p < 0.05) to the same extent in all experimental groups. In contrast, there was a much smaller reduction insulin-stimulated glucose transport in muscles from diabetic animals (18-24% reduction, p < 0.05) than in denervated muscles (40-60% reduction, p < 0.05) and in denervated + diabetic muscles (40-60% reduction, p < 0.05). GLUT-4 mRNA reduction was greatest in denervated + diabetic muscles (~ -75%, p < 0.05). GLUT-4 protein was decreased (p < 0.05) to a similar extent in all three experimental conditions (~ -30-40%). In conclusion, (1) muscle inactivity (denervation) and STZ-induced diabetes had similar effects on reducing contraction-stimulated glucose transport, but (2) muscle inactivity (denervation), rather than severe diabetes, produced a 2-fold greater impairment in skeletal muscle insulin-stimulated glucose transport.     

Skeletal Muscle Diseases: Recent Advances and Some Related Basic Problems

Recent advances in the knowledge of the structure and function of voluntary muscle and some of its diseases are reviewed on the basis of a recently published international symposium. Among the subjects discussed are: the specific metabolic role of various muscle cell constituents (e.g. sarcosomes, microsomes, sarcoplasmic reticulum); the relaxing factor system and the dual (tonic and phasic) innervation of muscle fibres; observations on the physiology of muscle training; the morphologic differential diagnosis of degenerative skeletal muscle diseases; the value of serum enzyme determinations in the early detection of muscular dystrophy and in the identification of dystrophic carriers; the classification and diagnosis of muscular hypotonias of infancy; the role of inactivity and the trophic control of the nervous system in the development of neural (or denervation) atrophies; factors influencing regeneration of muscle fibres; the significance, as a research tool, of the identification of hereditary primary muscle disease in laboratory animals.     

Comparison Between the Effects of Botulinum Toxin-Induced Paralysis and Denervation on Molecular Forms of Acetylcholinesterase in Muscles

Abstract: Velocity sedimentation analysis of acetylcholinesterase (AChE) molecular forms in the fast extensor digitorum longus muscle and in the slow soleus muscle of the rat was carried out on days 4, 8, and 14 after induction of muscle paralysis by botulinum toxin type A (BoTx). The results were compared with those observed after muscle denervation. In addition, the ability of BoTx-paralyzed muscles to resynthesize AChE was studied after irreversible inhibition of the preexistent enzyme by diisopropyl phosphorofluoridate. Major differences were observed between the effects of BoTx treatment and nerve section on AChE in the junctional region of the muscles. A precipitous drop in content of the asymmetric A12 AChE form was observed after denervation, whereas its decrease was much slower and less extensive in the BoTx-paralyzed muscles. Recovery of junctional AChE and of its A12 form after irreversible inhibition of the preexistent AChE in BoTx-paralyzed muscles was nevertheless very slow. It seems that a greater part of the junctional A12 AChE form pertains to a fraction with a very slow turnover that is rapidly degraded after denervation but not after BoTx-produced muscle paralysis. The postdenervation decrease in content of junctional A12 AChE is therefore not primarily due to muscle inactivity. The extrajunctional molecular forms of AChE seem to be regulated mostly by muscle activity because they undergo virtually identical changes both after denervation and BoTx paralysis. The differences observed in this respect between the fast and slow muscles after their inactivation must be intrinsic to muscles.     

Characteristics of post-traumatic differentiation of satellite cells in skeletal muscles

Muscle trauma during preliminary denervation stimulates generation and differentiation of satellite cells. There are two types of posttraumatic cells with different types of albumin synthesis (intracellular and extracellular) under the sarcolemma of the muscle fibers. It is assumed that either two different types of cells differentiating along myogenic and fibrogenic lines are to be found under muscle sarcolemma, or the original satellite cell is capable of differentiating in several directions.     

Absence of nitric oxide synthase I despite the presence of the dystrophin complex in human striated muscle

Summary  Recently, it has been shown that in human striated muscle the signalling enzyme, brain-type nitric oxide synthase I (NOS I), is associated with the sarcolemma and complexes with dystrophin and/or members of the dystrophin complex. In order to find out whether there exists a regular association between NOS I and the complex, muscle biopsies from patients with various muscle disorders were analysed by enzyme histochemistry and immunohistochemistry. In patients suffering from Duchenne muscular dystrophy, and to a lesser extent in those with Becker-type dystrophy, NOS I and dystrophin complex components were absent or drastically reduced in the sarcolemma region. In other dystrophies, as well as in metabolic and inflammatory myopathies, NOS I and dystrophin complex constituents were expressed normally, while in the case of neurogenic diseases leading to denervation atrophy and especially congenital idiopathic clubfoot, the immunohistochemical patterns of the distribution of the dystrophin complex constituents were normal, but NOS I activity and protein were deficient or dramatically diminished. The results can be interpreted as indicating that, in general, NOS I targeting to the sarcolemma is dependent on particular members of the dystrophin complex, such as ·-1 syntrophin, yet the expression and/or positioning of NOS I may be under the control of further factors, probably of neurogenic origin. NOS I-associated diaphorase may thus be a useful complementary tool in the diagnosis of muscle disorders. This revised version was published online in November 2006 with corrections to the Cover Date.     

Absence of nitric oxide synthase I despite the presence of the dystrophin complex in human striated muscle

Summary Recently, it has been shown that in human striated muscle the signalling enzyme, brain-type nitric oxide synthase I (NOS I), is associated with the sarcolemma and complexes with dystrophin and/or members of the dystrophin complex. In order to find out whether there exists a regular association between NOS I and the complex, muscle biopsies from patients with various muscle disorders were analysed by enzyme histochemistry and immunohistochemistry. In patients suffering from Duchenne muscular dystrophy, and to a lesser extent in those with Becker-type dystrophy, NOS I and dystrophin complex components were absent or drastically reduced in the sarcolemma region. In other dystrophies, as well as in metabolic and inflammatory myopathies, NOS I and dystrophin complex constituents were expressed normally, while in the case of neurogenic diseases leading to denervation atrophy and especially congenital idiopathic clubfoot, the immunohistochemical patterns of the distribution of the dystrophin complex constituents were normal, but NOS I activity and protein were deficient or dramatically diminished. The results can be interpreted as indicating that, in general, NOS I targeting to the sarcolemma is dependent on particular members of the dystrophin complex, such as ·-1 syntrophin, yet the expression and/or positioning of NOS I may be under the control of further factors, probably of neurogenic origin. NOS I-associated diaphorase may thus be a useful complementary tool in the diagnosis of muscle disorders. This revised version was published online in November 2006 with corrections to the Cover Date.     

Trophic interrelations at the neuromuscular junction as revealed by the use of botulinal neurotoxins

1. From denervation studies the trophic influence of the motor nerve on the muscle cell is well documented while little is known about the influence of the muscle on the nerve. Sectioning the axon invariably destroys the nerve terminals and produces nerve degeneration products which themselves may affect nerve and muscle properties. With regard to those difficulties we believe that the botulinal neurotoxins (BoTx) are valuable complements to denervation since they selectively interrupt impulse transmission across the synapse without damaging its morphology. 2. Paralysis of mouse or rat skeletal muscle in vivo with BoTx type A causes marked growth of motor nerve terminals. The sprouting terminals are rich in large dense-core synaptic vesicles containing various neuropeptides and they spontaneously release large quanta of ACh. Thus, it appears that paralysis by BoTx is a strong stimulus for motor nerve growth and the delivery of "trophic" substances to the nerve terminals. 3. Postsynaptically, in extrajunctional areas, paralysis by BoTx induces all the changes observed following denervation, i.e. atrophy, appearance of extra-junctional ACh receptors, TTX-resistant action potentials, a fall of resting membrane potential, fibrillation potentials and the disappearance of extrajunctional acetylcholinesterase activity. Endplate properties are, however, largely maintained. 4. BoTx blockade delays and prevents the retraction of polyneuronal innervation and motoneurone death during development. This supports the suggestion that the paralysed muscle secretes factors essential for growth and for the survival of motoneurones. 5. Like denervated muscle, BoTx paralysed ones, express a high endocytotic activity restricted to a segment in the endplate region.(ABSTRACT TRUNCATED AT 250 WORDS)     

Activity of alkaline phosphatase in rat skeletal muscle localized along the sarcolemma and endothelial cell membranes

Alkaline phosphatase (AP), a membrane-associated glycoprotein which enhances the hydrolysis of monophosphate esters at alkaline pH, is widely distributed in animal tissues. AP activity is increased in a variety of muscle disorders, i.e., myopathies and denervation. Established histochemical methods at the light microscopy level failed to demonstrate AP in skeletal muscles. In the present study we applied the Gomori lead nitrate method for ultrastructural examination of AP in rat gastrocnemius muscles and showed that the enzyme was linked to the sarcolemma of the striated muscle and to the membranes of endothelial cells in adjacent capillaries. In comparison with ATPase activity, AP activity was inhibited by both levamisole and a pH of 7.2, but not by ouabain. Hence, it appears that in skeletal muscles AP is active at a high pH and is bound to cell membranes.     

In vitro studies of skeletal muscle membranes. Effects of denervation on the macromolecular components of cation transport in red and white skeletal muscle.

The effects of denervation on the macromolecular components of active monovalent cation transport in skeletal muscle have been studied using purified sarcolemma membranes. A comparison of membrane activities of fast-twitch, slow-twitch, and mixed-fiber muscles was made to determine what role, if any, the motor nerve has in regulating this important aspect of muscle metabolism. A dramatic increase in the basal sarcolemmal Mg++ ATPase activity (three- to fourfold) was found for both major muscle types. An increase in the ouabain-inhibitable (Na+ + K+)-stimulated enzyme was also found, but the effect was substantially less (1.5- to twofold). [3H]-ouabain binding, as an index of glycoside receptor sites, also increased (two- to threefold) midway in the course of denervation. On the other hand, the phosphorylated intermediate activity, a functional component of the transport system, clearly decreased over the same time course and remained below control values for the remainder of the course. This resulted in a two- to threefold increase in the turnover number, suggesting that active transport of cations should increase dramatically with denervation. The membrane protein patterns on SDS gels were less obvious than the changes observed in the functional components. The major effects appeared after only one week and seemed to be restricted to high molecular weight membrane proteins, especially in the 100,000 to 250,000 daltons range. This effect was more prominent in slow-twitch membranes with an apparent semiquantitative decrease in stain at 240,000 daltons. In gels of membranes from fast-twitch muscles a decreased stain in the range of 100,000 to 110,000 daltons occurred, and this became more obvious with longer periods of denervation. The results suggest that considerable influence on the macromolecular components of active cation transport in skeletal muscle is exerted by the motor nerve. No appreciable difference was found in this effect when the two major types of skeletal muscle, fast-twitch and slow-twitch, were compared, suggesting that motor nerve regulation of this membrane property is qualitatively the same.     

The Ubiquitin Ligase Nedd4-1 Participates in Denervation-Induced Skeletal Muscle Atrophy in Mice

Skeletal muscle atrophy is a consequence of muscle inactivity resulting from denervation, unloading and immobility. It accompanies many chronic disease states and also occurs as a pathophysiologic consequence of normal aging. In all these conditions, ubiquitin-dependent proteolysis is a key regulator of the loss of muscle mass, and ubiquitin ligases confer specificity to this process by interacting with, and linking ubiquitin moieties to target substrates through protein∶protein interaction domains. Our previous work suggested that the ubiquitin-protein ligase Nedd4-1 is a potential mediator of skeletal muscle atrophy associated with inactivity (denervation, unloading and immobility). Here we generated a novel tool, the Nedd4-1 skeletal muscle-specific knockout mouse (myo^Cre;Nedd4-1^flox/flox) and subjected it to a well validated model of denervation induced skeletal muscle atrophy. The absence of Nedd4-1 resulted in increased weights and cross-sectional area of type II fast twitch fibres of denervated gastrocnemius muscle compared with wild type littermates controls, at seven and fourteen days following tibial nerve transection. These effects are not mediated by the Nedd4-1 substrates MTMR4, FGFR1 and Notch-1. These results demonstrate that Nedd4-1 plays an important role in mediating denervation-induced skeletal muscle atrophy in vivo.     

Combination of agrin and laminin increase acetylcholine receptor clustering and enhance functional neuromuscular junction formation In vitro

Clustering of acetylcholine receptors (AChR) at the postsynaptic membrane is a crucial step in the development of neuromuscular junctions (NMJ). During development and after denervation, aneural AChR clusters form on the sarcolemma. Recent studies suggest that these receptors are critical for guiding and initiating synaptogenesis. The aim of this study is to investigate the effect of agrin and laminin‐1; agents with known AChR clustering activity; on NMJ formation and muscle maturation. Primary myoblasts were differentiated in vitro on collagen, laminin or collagen and laminin‐coated surfaces in the presence or absence of agrin and laminin. The pretreated cells were then subject to innervation by PC12 cells. The number of neuromuscular junctions was assessed by immunocytochemical co‐localization of AChR clusters and the presynaptic marker synaptophysin. Functional neuromuscular junctions were quantitated by analysis of the level of spontaneous as well as neuromuscular blocker responsive contractile activity and muscle maturation was assessed by the degree of myotube striation. Agrin alone did not prime muscle for innervation while a combination of agrin and laminin pretreatment increased the number of neuromuscular junctions formed and enhanced acetylcholine based neurotransmission and myotube striation. This study has direct clinical relevance for treatment of denervation injuries and creating functional neuromuscular constructs for muscle tissue repair. © 2015 Wiley Periodicals, Inc. Develop Neurobiol 76: 551–565, 2016     

Satellite cells on isolated myofibers from normal and denervated adult rat muscle.

Satellite cells (SCs) in normal adult muscle are quiescent. They can enter the mitotic program when stimulated with growth factors such as basic FGF. Short-term denervation stimulates SC to enter the mitotic cycle in vivo, whereas long-term denervation depletes the SC pool. The molecular basis for the neural influence on SCs has not been established. We studied the phenotype and the proliferative capacity of SCs from muscle that had been denervated before being cultured in vitro. The expression of PCNA, myogenin, and muscle (M)-cadherin in SCs of normal and denervated muscle fibers was examined at the single-cell level by immunolabeling in a culture system of isolated rat muscle fibers with attached SCs. Immediately after plating (Day 0), neither PCNA nor myogenin was present on normal muscle fibers, but we detected an average of 0.5 M-cadherin(+) SCs per muscle fiber. The number of these M-cadherin(+) cells (which are negative for PCNA and myogenin) increased over the time course examined. A larger fraction of cells negative for M-cadherin underwent mitosis and expressed PCNA, followed by myogenin. The kinetics of SCs from muscle fibers denervated for 4 days before culturing were similar to those of normal controls. Denervation from 1 to 32 weeks before plating, however, suppressed PCNA and myogenin expression almost completely. The fraction of M-cadherin(+) (PCNA(-)/myogenin(-)) SCs was decreased after 1 week of denervation, increased above normal after denervation for 4 or 8 weeks, and decreased again after denervation for 16 or 32 weeks. We suggest that the M-cadherin(+) cells are nondividing SCs because they co-express neither PCNA or myogenin, whereas the cells positive for PCNA or myogenin (and negative for M-cadherin) have entered the mitotic cycle. SCs from denervated muscle were different from normal controls when denervated for 1 week or longer. The effect of denervation on the phenotypic modulation of SCs includes resistance to recruitment into the mitotic cycle under the conditions studied here and a robust extension of the nonproliferative compartment. These characteristics of SCs deprived of neural influence may account for the failure of denervated muscle to fully regenerate. (J Histochem Cytochem 47:1375-1383, 1999)