Mediation of IGF-1-induced skeletal myotube hypertrophy by PI(3)K/Akt/mTOR and PI(3)K/Akt/GSK3 pathways.

Skeletal muscle is composed of multinucleated fibres, formed after the differentiation and fusion of myoblast precursors. Skeletal muscle atrophy and hypertrophy refer to changes in the diameter of these pre-existing muscle fibres. The prevention of atrophy would provide an obvious clinical benefit; insulin-like growth factor 1 (IGF-1) is a promising anti-atrophy agent because of its ability to promote hypertrophy. However, the signalling pathways by which IGF-1 promotes hypertrophy remain unclear, with roles suggested for both the calcineurin/NFAT (nuclear factor of activated T cells) pathway and the PtdIns-3-OH kinase (PI(3)K)/Akt pathway. Here we employ a battery of approaches to examine these pathways during the hypertrophic response of cultured myotubes to IGF-1. We report that Akt promotes hypertrophy by activating downstream signalling pathways previously implicated in activating protein synthesis: the pathways downstream of mammalian target of rapamycin (mTOR) and the pathway activated by phosphorylating and thereby inhibiting glycogen synthase kinase 3 (GSK3). In contrast, in addition to demonstrating that calcineurin does not mediate IGF-1-induced hypertrophy, we show that IGF-1 unexpectedly acts via Akt to antagonize calcineurin signalling during myotube hypertrophy.

Akt/mTOR pathway is a crucial regulator of skeletal muscle hypertrophy and can prevent muscle atrophy in vivo.

Skeletal muscles adapt to changes in their workload by regulating fibre size by unknown mechanisms. The roles of two signalling pathways implicated in muscle hypertrophy on the basis of findings in vitro, Akt/mTOR (mammalian target of rapamycin) and calcineurin/NFAT (nuclear factor of activated T cells), were investigated in several models of skeletal muscle hypertrophy and atrophy in vivo. The Akt/mTOR pathway was upregulated during hypertrophy and downregulated during muscle atrophy. Furthermore, rapamycin, a selective blocker of mTOR, blocked hypertrophy in all models tested, without causing atrophy in control muscles. In contrast, the calcineurin pathway was not activated during hypertrophy in vivo, and inhibitors of calcineurin, cyclosporin A and FK506 did not blunt hypertrophy. Finally, genetic activation of the Akt/mTOR pathway was sufficient to cause hypertrophy and prevent atrophy in vivo, whereas genetic blockade of this pathway blocked hypertrophy in vivo. We conclude that the activation of the Akt/mTOR pathway and its downstream targets, p70S6K and PHAS-1/4E-BP1, is requisitely involved in regulating skeletal muscle fibre size, and that activation of the Akt/mTOR pathway can oppose muscle atrophy induced by disuse.

Identification of ubiquitin ligases required for skeletal muscle atrophy.

Skeletal muscle adapts to decreases in activity and load by undergoing atrophy. To identify candidate molecular mediators of muscle atrophy, we performed transcript profiling. Although many genes were up-regulated in a single rat model of atrophy, only a small subset was universal in all atrophy models. Two of these genes encode ubiquitin ligases: Muscle RING Finger 1 (MuRF1), and a gene we designate Muscle Atrophy F-box (MAFbx), the latter being a member of the SCF family of E3 ubiquitin ligases. Overexpression of MAFbx in myotubes produced atrophy, whereas mice deficient in either MAFbx or MuRF1 were found to be resistant to atrophy. These proteins are potential drug targets for the treatment of muscle atrophy.

Reduced Ia-afferent-mediated Hoffman reflex in streptozotocin-induced diabetic rats.

In addition to reduced nerve conduction velocity, diabetic neuropathic patients often exhibit a reduction in the amplitude of the compound muscle action potential elicited by stimulation of the Ia-afferent-mediated reflex pathway (Hoffman or H wave) that can contribute to diminished or absent tendon reflexes. In contrast to nerve conduction velocity deficits, changes in H-wave amplitudes have not been reproduced in diabetic animal models. Using electrophysiological techniques developed for repeated recordings in individual animals, we report H-wave deficits in streptozotocin (STZ)-treated insulin-dependent diabetic rats. After 4 weeks of diabetes induced by STZ treatment, a 47% reduction in the H-wave amplitude was demonstrated by recording compound muscle action potentials in foot muscles after stimulation of Ia afferents. Interestingly, we also demonstrate that the H-wave amplitude gradually recovers to a 26% deficit after 12 weeks of experimental diabetes. The recovery of the H wave in STZ-treated rats distinguishes this deficit mechanistically from other STZ-induced electrophysiological changes and may model a similar recovery of the H wave reported in diabetic patients.

Size and myonuclear domains in Rhesus soleus muscle fibers: short-term spaceflight.

The cross-sectional area (CSA), myonuclear number per mm of fiber length, and myonuclear domain (cytoplasmic volume/myonucleus) of mechanically isolated single fibers from biopsies of the soleus muscle of 5 vivarium control, 3 flight simulation and 2 flight (BION 11) Rhesus monkeys (Macaca [correction of Macacca] mulatta) were determined using confocal microscopy before and after a 14-day experimental period. Simulation monkeys were confined in chairs placed in capsules identical to those used during the flight. Fibers were classified as type I, type II or hybrid (containing both types I and II) based on myosin heavy chain (MHC) gel electrophoresis. A majority of the fibers sampled contained only type I MHC, i.e. 89, 62 and 68% for the control, simulation and flight groups, respectively. Most of the remaining fibers were hybrids, i.e. 8, 36 and 32% for the same groups. There were no significant pre-post differences in the fiber type composition for any of the experimental groups. There also were no significant pre-post differences in fiber CSA, myonuclear number or myonuclear domain. There was, however, a tendency for the fibers in the post-flight biopsies to have a smaller mean CSA and myonuclear domain (approximately 10%, p=0.07) than the fibers in the pre-flight biopsy. The combined mean cytoplasmic volume/myonucleus for all muscle fiber phenotypes in the Rhesus soleus muscle was approximately 25,000 micrometers3 and there were no differences in pre-post samples for the control and simulated groups. The cytoplasmic domains tended to be lower (p=0.08) after than before flight. No phenotype differences in cytoplasmic domains were observed. These data suggest that after a relatively short period of actual spaceflight, modest fiber atrophy occurs in the soleus muscle fibers without a concomitant change in myonuclear number.

Fiber size and myosin phenotypes of selected rhesus lower limb muscles after a 14-day spaceflight.

Muscle biopsies were taken from the rhesus (Macaca mulatta) soleus (Sol, a slow ankle extensor), medial gastrocnemius (MG, a fast ankle extensor), tibialis anterior (TA, a fast ankle flexor), and vastus lateralis (VL, a fast knee extensor) muscles in vivarium controls (n=5) before and after either a 14-day spaceflight (Bion 11, n=2) or a 14-day ground-based flight simulation (n=3). Myosin heavy chain (MHC) composition (gel electrophoresis), fiber type distribution (immunohistochemistry), and fiber size were determined. Although there were no significant changes, each muscle showed trends towards adaptation.

Fiber size and myosin phenotypes of selected Rhesus hindlimb muscles after a 14-day spaceflight.

Open muscle biopsies were obtained from Rhesus soleus (slow ankle extensor), medial gastrocnemius (fast ankle extensor) and tibialis anterior (fast ankle flexor) muscles before and after either a 14-day spaceflight (BION 11, n=2) or ground-based flight simulation (n=3) and in time-matched controls (n=5). Fiber type distribution (immunohistochemistry), myosin heavy chain (MHC) composition (gel electrophoresis) and fiber size were determined. There was a large amount of inter-animal variability and there were no significant pre-post differences for any variable under any condition for any muscle studied. However, each muscle showed trends towards adaptation. Based on the immunohistochemical analyses, the percentage of type I fibers in the soleus was 68 and 86% in pre and 43 and 70% in post biopsies of the simulation and flight groups. The number of hybrid (containing both fast and slow MHC) fibers increased in both groups. MHC composition changed in a similar direction. Type I and hybrid fibers were 23 and 31% smaller after than before flight. In the medial gastrocnemius, type I fibers were 16, 14 and 32% smaller in post compared to pre biopsies in control, simulation and flight Rhesus. In the tibialis anterior, type I fibers were approximately 14% smaller in post- than pre-flight biopsies. As expected the soleus, a slow anti-gravity muscle, was most affected after 14 days of weightlessness. Further, slow fibers in each muscle were more responsive to microgravity than fast fibers. All changes, however, were smaller than those observed in rats after the same duration of flight. This differential effect may be related to the partial restraint of Rhesus in the chaired position compared to the free-floating position of rats in the cage and/or to differences in the contractile protein turnover rates between species.

Consistent repeated M- and H-Wave recording in the hind limb of rats.

Sensory and motor conduction velocities calculated from latencies of H reflexes and M waves in rat hind limbs have been used to assess experimental peripheral neuropathy. Amplitudes and latencies vary with recording location, and are seldom assessed directly. Using subcutaneous electrodes on the foot, we recorded consistent M waves and H reflexes while stimulating the sciatic or tibial nerve. The late wave disappeared when dorsal roots were cut, verifying that it was an H reflex. However, stimulus-response characteristics differed from those in humans: (a) the threshold was often higher than for M waves; (b) stimulus intensity eliciting a maximum H-reflex amplitude (Hmax) was often higher than adequate for a maximum M-wave amplitude; and (c) the amplitudes of H reflexes stimulated with intensities supramaximal for the M wave were over 90% of Hmax. H reflexes and M waves recorded repeatedly in rats can be useful in assessing sensory and motor function in models of neuropathy, using amplitudes as well as conduction velocities.

Changes in myosin mRNA and protein expression in denervated rat soleus and tibialis anterior.

Denervation differs from other models of reduced neuromuscular activation due to the absence of a nerve-muscle connection and limited data exists regarding the effects of denervation on myosin heavy chain (MHC) expression. Thus, adult MHC expression (I, IIa, IIx, IIb) was studied in the rat soleus and tibialis anterior (TA) at the mRNA and protein levels 2, 4, 7, 10, 14, and 30 days following sciatic nerve transection. MHC protein content was quantified with SDS/PAGE and mRNA levels with the RNase-protection assay. Control soleus consisted predominately of type I MHC mRNA and protein, however, 4 days after denervation type I MHC mRNA was significantly decreased to 41+/-8% of control and continued to remain below control values. Soleus IIa mRNA was significantly elevated 7 and 10 days after denervation while IIx mRNA remained relatively constant until 30 days when it increased to 197+/-23% of control. At the protein level, soleus I MHC significantly decreased to 80% of the total while IIa MHC significantly increased to 20% of the total. At 30 days, Hx MHC protein accounted for 9.4+/-1.6% of the total soleus MHC protein. In the TA, IIb mRNA was significantly decreased to 57% of control by day 4 and remained significantly decreased for up to a month. TA IIx mRNA was also significantly decreased at 10 and 30 days after denervation. Similar to the soleus, TA Ha mRNA was significantly increased over control 7-14 days after denervation. There were no significant changes in TA MHC protein profile during one month of denervation. In both the soleus and TA, denervation significantly shifted the MHC mRNA profile as early as 4 days following denervation without any corresponding changes at the protein level. Significant mRNA changes without large changes in MHC protein composition continued throughout the denervation period suggesting that the muscle may be prevented from premature functional transitions by mechanisms such as decreased mRNA stability, translational block, or increased turnover of newly synthesized proteins.

Velocity, force, power, and Ca2+ sensitivity of fast and slow monkey skeletal muscle fibers.

In this study, we determined the contractile properties of single chemically skinned fibers prepared from the medial gastrocnemius (MG) and soleus (Sol) muscles of adult male rhesus monkeys and assessed the effects of the spaceflight living facility known as the experiment support primate facility (ESOP). Muscle biopsies were obtained 4 wk before and immediately after an 18-day ESOP sit, and fiber type was determined by immunohistochemical techniques. The MG slow type I fiber was significantly smaller than the MG type II, Sol type I, and Sol type II fibers. The ESOP sit caused a significant reduction in the diameter of type I and type I/II (hybrid) fibers of Sol and MG type II and hybrid fibers but no shift in fiber type distribution. Single-fiber peak force (mN and kN/m2) was similar between fiber types and was not significantly different from values previously reported for other species. The ESOP sit significantly reduced the force (mN) of Sol type I and MG type II fibers. This decline was entirely explained by the atrophy of these fiber types because the force per cross-sectional area (kN/m2) was not altered. Peak power of Sol and MG fast type II fiber was 5 and 8.5 times that of slow type I fiber, respectively. The ESOP sit reduced peak power by 25 and 18% in Sol type I and MG type II fibers, respectively, and, for the former fiber type, shifted the force-pCa relationship to the right, increasing the Ca2+ activation threshold and the free Ca2+ concentration, eliciting half-maximal activation. The ESOP sit had no effect on the maximal shortening velocity (Vo) of any fiber type. Vo of the hybrid fibers was only slightly higher than that of slow type I fibers. This result supports the hypothesis that in hybrid fibers the slow myosin heavy chain would be expected to have a disproportionately greater influence on Vo.

Physiological characterization of Taxol-induced large-fiber sensory neuropathy in the rat.

The cancer chemotherapeutic agent Taxol (paclitaxel) causes a dose-related peripheral neuropathy in humans. We produced a dose-dependent large-fiber sensory neuropathy, without detrimental effects on general health, in mature rats by using two intravenous injections 3 days apart. Tests of other dosing schedules demonstrated the dependence of the severity of the neuropathy and of animal health on both the dose and the frequency of dosing. Pathologically, severe axonal degeneration and hypomyelination were observed in sections of dorsal roots, whereas ventral roots remained intact. Electrophysiologically, H-wave amplitudes in the hindlimb and amplitudes of predominantly sensory compound nerve action potentials in the tail were reduced. These effects persisted for at least 4 months after treatment. Motor amplitudes were not affected, but both motor and sensory conduction velocities decreased. The ability of rats to remain balanced on a narrow beam was impaired, indicating proprioceptive deficits. Muscle strength, measured by hindlimb and forelimb grip strength, and heat nociception, measured by tail-flick and hindlimb withdrawal tests, were not affected by Taxol. This model of Taxol-induced neuropathy in mature rats, with minimal effects on general health, parallels closely the clinical syndrome observed after Taxol treatment in humans.

Altered expression of myosin mRNA and protein in rat soleus and tibialis anterior following reinnervation.

Myosin heavy chain (MHC) expression was studied in rat soleus and tibialis anterior (TA) at the mRNA and protein levels following reinnervation 8 and 32 wk after sciatic nerve injury. A sciatic nerve crush or transection injury was produced in the midthigh region of adult female Sprague-Dawley rats. A ribonuclease protection assay was developed to measure four of the adult MHCs (I, IIa, IIx, IIb) in a single sample. MHC mRNA and protein were measured and compared in the same muscles. Eight and thirty-two weeks after a crush injury, the MHC mRNA profiles were similar to control with the exception of soleus MHC IIa and TA MHC IIb, which were significantly less than control at both time points. In contrast, reinnervation of the soleus following a sciatic nerve transection injury resulted in an MHC isoform shift characterized by increases in the relative amounts of fast myosin (IIa and IIx) and a decrease in slow myosin. As expected, significant changes first occurred at the mRNA level followed by changes in protein expression. Thirty-two weeks after transection injury and repair, the primary MHC mRNA isoform in the soleus was MHC IIx. Moreover, at 32 wk, MHC IIb mRNA was detected in 50% of the reinnervated soleus following a transection injury. Reinnervation of the TA following sciatic nerve transection led to replacement of the MHC IIb isoform with MHC IIx.

Myosin heavy chain mRNA and protein expression in single fibers of the rat soleus following reinnervation.

Myosin heavy chain (MHC) expression is regulated by many factors including neural input. To gain a better understanding of myosin transformation following reinnervation we examined both MHC protein and mRNA in single fibers of the soleus. A midthigh sciatic nerve lesion resulted in reinnervation of the soleus by motoneurons from both original and foreign motor pools. MHC expression was examined in individual fibers 8 and 16 weeks post injury in situ histochemistry and immunohistochemistry. Following a sciatic nerve lesion, the reinnervated soleus underwent a transformation from slow toward fast based on physiologic and biochemical measurements. At 8 weeks, fast MHC mRNA isoforms (IIa and IIx) were upregulated and slow mRNA was downregulated, however, the predominant protein isoform was MHC I. At both 8 and 16 weeks, many fibers expressed multiple mRNA isoforms. At 16 weeks there was limited co-expression of slow and fast MHC mRNAs, but continued co-expression of fast MHC mRNAs. Sixteen weeks following reinnervation the predominant fast mRNA and protein in the soleus was IIx MHC.

Identification of a novel myosin heavy chain gene expressed in the rat larynx.

Based on reactivity to antibodies against known myosin heavy chains, expression of a novel fast myosin heavy chain (MHC) gene was suspected in the thyroarytenoid (TA) muscle of the rat larynx. The 3' ends of MHC transcripts in the TA were amplified by RT-PCR using a primer to a highly conserved MHC sequence and to the poly(A) tail. The resultant products were cloned and fourteen PCR products were screened by dot-blotting with oligonucleotides specific for known skeletal muscle MHC genes. A clone that reacted weakly to the 2B oligo was sequenced and found to encode a novel fast MHC transcript, termed 2L, that appears to represent an eighth vertebrate skeletal muscle MHC gene. By homology analysis, the 2L sequence is most similar to the extraocular MHC, suggesting a possible evolutionary relationship between MHCs associated with the branchial arches.

Cloning and in situ hybridization of type 2A and 2B rat skeletal muscle myosin tail region: implications for filament assembly.

Changes in fast myosin expression play a critical role in skeletal muscle adaptation. Two fast myosin isoforms, type 2A and type 2B, are commonly expressed by fast muscle fibers but their sequences have not been determined to allow mRNA expression studies. A complete set of rat skeletal muscle myosins was amplified by PCR of cDNAs derived from skeletal muscle mRNA, cloned in a TA cloning vector, and sequenced. Specificity was demonstrated by in situ hybridization against skeletal muscle and myosin protein identification using monoclonal antibodies. Two novel sequences were cloned: A type 2A myosin which consisted of a 642 bp segment from the 3' end and a type 2B myosin which consisted of a 624 bp segment also from the 3' end. This region encodes that portion of the myosin molecule implicated in the control of filament assembly. The two fast myosins showed 88% homology in the open reading frame and 95% homology at the amino acid level. Based on this homology, it is unlikely that selective myosin filament assembly occurs during muscle fiber type transformation between type 2A and 2B.

Spatial distribution of motor unit fibers in the cat soleus and tibialis anterior muscles: local interactions.

The spatial distribution of muscle fibers belonging to a motor unit was studied in the soleus and tibialis anterior muscles of adult cats. Motor unit fibers were depleted of their glycogen through repetitive stimulation of the motoneuron or of the functionally isolated motor axon. Subsequently, the position of depleted muscle fibers was mapped on serial cross sections taken along the length of the muscle. A subset of fibers was selected from the cross section containing the largest number of motor unit fibers and 4 spatial analyses were performed. These analyses were designed to determine whether the muscle fibers belonging to a single unit were distributed in a random manner. To test whether the actual distribution was other than random, Monte Carlo techniques were used to simulate the random innervation of a muscle. From these simulations, a test statistic was calculated for comparison with the observed data. Adjacency and nearest-neighbor analyses revealed no tendency for grouping or dispersion of fibers belonging to a motor unit. However, measurement of the distances between all motor unit fibers revealed a greater tendency for grouping than spreading, suggesting the existence of some mechanism that restricts the absolute distribution and territory of a motor unit.

Maximal force as a function of anatomical features of motor units in the cat tibialis anterior.

In 11 tibialis anterior muscles of the cat, a single motor unit was characterized physiologically and subsequently depleted of its glycogen through repetitive stimulation of an isolated ventral root filament. Muscle cross sections were stained for glycogen using a periodic acid-Schiff reaction, and single-fiber optical densities were determined to identify those fibers belonging to the stimulated motor unit. Innervation ratios were determined by counting the total number of muscle fibers in a motor unit in sections taken through several levels of the muscle. The average innervation ratios for the fast, fatigueable (FF) and fast, fatigue-resistant (FR) units were similar. However, the slow units (S) contained 61% fewer fibers than the fast units (FF and FR). Muscle fibers belonging to S and FR units were similar in cross-sectional area, whereas fibers belonging to FF units were significantly larger than fibers belonging to either S or FR units. Additionally, muscle fibers innervated by a single motoneuron varied by two- to eightfold in cross-sectional area. Specific tensions, based on total cross-sectional area determined by summing the areas of all muscle fibers of each unit, showed a modest difference between fast and slow units, the means being 23.5 and 17.2 N X cm-2, respectively. Variations in maximum tension among units could be explained principally by innervation ratio, although fiber cross-sectional area and specific tension did contribute to differences between unit types.

Soleus motor units in chronic spinal transected cats: physiological and morphological alterations.

Intracellular recording and stimulation were used to study electrical properties of soleus motoneurons and isometric contractile properties of their muscle units. In addition, some muscle units were depleted of glycogen for purposes of studying their morphology. These data were compared for two experimental groups of barbiturate-anesthetized adult cats: those with spinal cords intact (normal) and others with spinal cords transected (ST) 4 mo before study. The greatest change in soleus motoneurons after ST was a decrease in afterhyperpolarization (AHP) duration. Axonal conduction velocity (CV) increased slightly, yet consistently. These data confirm previous findings. The voltage threshold of motoneurons, estimated from the product of rheobase current and input resistance, increased from the normal value of 7.5 mV to 10.1. This resulted from a significant increase in rheobase current after ST, because input resistance was not altered significantly. These data suggest that motoneuron excitability decreased after ST and therefore cannot account for hyperreflexia in chronic ST cats. Measurement of soleus muscle unit isometric contractile properties generally confirmed earlier reports of decreases in twitch time course [both contraction time (CT) and half-relaxation time] and in twitch (Ptw) and maximum tetanic (Pmax) tensions after chronic ST. The ratio Ptw/Pmax increased as a result of a greater decline in tetanic than in twitch tension. No significant change was observed in the fatigue index. Direct measures of muscle unit morphology showed that the specific tension for three ST units fell below the range of four normal units. This was expected given that the innervation ratio was not altered and that the decrease in muscle fiber area after ST was proportionately smaller than the decrease in Pmax. Two lines of evidence showed that motoneuron and muscle unit properties were coordinated before and after ST. First, the normal correlation between AHP duration and CT was nearly as strong after as before ST, and the slope of this relation was not significantly different for normal and ST groups. Second, multivariate statistics (canonical analysis) showed that a combination of all motoneuron electrical properties listed above was strongly correlated with a combination of muscle unit twitch time, Pmax, and Ptw/Pmax for normal and ST groups. In contrast with the conclusions of Gallego et al., we suggest from these data that SOL motor-unit properties are coordinated after ST.(ABSTRACT TRUNCATED AT 400 WORDS)

How flexible is the neural control of muscle properties?

The issue addressed in this paper is to what extent are selected physiological properties and associated protein systems of muscle fibres controlled or regulated by neuronal systems. One extreme position would be that all muscle proteins are controlled completely by the neural system that innervates the muscle. The opposite position would be that none of the muscle proteins are under neural influence. Although the concept that there is complete neural control of all proteins has generally received more support, it is more likely that there is only partial neural control of some proteins. Identical physiological, morphological and metabolic properties of all muscle fibres within a motor unit would suggest a complete neural control of all protein systems in muscle fibres. However, evidence against this idea is provided by the marked heterogeneity in the activities of two enzymes, alpha glycerophosphate dehydrogenase and succinic dehydrogenase (SDH), and in the wide variations in muscle fibre cross-sectional areas among fibres of the same motor unit in the cat soleus and tibialis anterior.