Mechanisms leading to restoration of muscle size with exercise and transplantation after spinal cord injury

We have shown thatcycling exercise combined with fetal spinal cord transplantationrestored muscle mass reduced as a result of complete transection of thespinal cord. In this study, mechanisms whereby this combinedintervention increased the size of atrophied soleus and plantarismuscles were investigated. Rats were divided into five groups(n = 4, per group): control, nontransected; spinal cordtransected at T10 for 8 wk (Tx); spinal cord transected for 8 wk andexercised for the last 4 wk (TxEx); spinal cord transected for 8 wkwith transplantation of fetal spinal cord tissue into the lesion site 4 wk prior to death (TxTp); and spinal cord transected for 8 wk,exercised for the last 4 wk combined with transplantation 4 wk prior todeath (TxExTp). Tx soleus and plantaris muscles were decreased in sizecompared with control. Exercise and transplantation alone did notrestore muscle size in soleus, but exercise alone minimized atrophy inplantaris. However, the combination of exercise and transplantationresulted in a significant increase in muscle size in soleus andplantaris compared with transection alone. Furthermore, myofibernuclear number of soleus was decreased by 40% in Tx and was notaffected in TxEx or TxTp but was restored in TxExTp. A strongcorrelation (r = 0.85) between myofiber cross-sectional area and myofiber nuclear number was observed in soleus, but not inplantaris muscle, in which myonuclear number did not change with any ofthe experimental manipulations. 5'-Bromo-2'-deoxyuridine-positive nuclei inside the myofiber membrane were observed in TxExTp soleus muscles, indicating that satellite cells had divided and subsequently fused into myofibers, contributing to the increase in myonuclear number. The increase in satellite cell activity did not appear to becontrolled by the insulin-like growth factors (IGF), as IGF-I andIGF-II mRNA abundance was decreased in Tx soleus and plantaris, and wasnot restored with the interventions. These results indicate that,following a relatively long postinjury interval, exercise andtransplantation combined restore muscle size. Satellite cell fusion andrestoration of myofiber nuclear number contributed to increased musclesize in the soleus, but not in plantaris, suggesting that cellularmechanisms regulating muscle size differ between muscles with differentfiber type composition.

     

Activated satellite cells fail to restore myonuclear number in spinal cord transected and exercised rats

In this study, possible mechanisms underlying soleus muscleatrophy after spinal cord transection and attenuation of atrophy withcycling exercise were studied. Adult female Sprague-Dawley rats weredivided into three groups; in two groups the spinal cord was transectedby a lesion at T₁₀. One group wastransected and killed 10 days later, and another group was transectedand exercised for 5 days starting 5 days after transection. The third group served as an uninjured control. All animals received acontinuous-release 5'-bromo-2'-deoxyuridine pellet 10 daysbefore they were killed. Transection alone and transection withexercise lead to activation of satellite cells, but only the exercisegroup showed a trend toward an increase in the number of proliferatingsatellite cells. In all cases the number of activated satellite cellswas significantly higher than the number that divided. Although thenumber of cells undergoing proliferation increased with exercise, noincrease in fusion of satellite cells into muscle fibers was apparent. Spinal cord transection resulted in a 25% decrease in myonuclear number, and exercise was not associated with a restoration of myonuclear number. The number of apoptotic nuclei was increased aftertransection, and exercise attenuated this increase. However, thedecrease in apoptotic nuclei with exercise did not significantly affectmyonuclear number. We conclude that apoptotic nuclear loss likelycontributes to loss of nuclei during muscle atrophy associated withspinal cord transection and that exercise can maintain muscle mass, atleast in the short term, without restoration of myonuclear number.

     

Myogenin, MyoD, and myosin expression after pharmacologically and surgically induced hypertrophy

The relationshipbetween myogenin or MyoD expression and hypertrophy of the rat soleusproduced either by clenbuterol and 3,3',5-triiodo-L-thyronine(CT) treatment or by surgical overload was examined. Mature female ratswere subjected to surgical overload of the right soleus with the leftsoleus serving as a control. Another group received the same surgicaltreatment but were administered CT. Soleus muscles were harvested 4 wkafter surgical overload and weighed. Myosin heavy chain isoforms wereseparated by using polyacrylamide gel electrophoresis while myogeninand MyoD expression were evaluated by Northern analysis.CT and functional overload increased soleus muscle weight. CT treatmentinduced the appearance of the fast type IIX myosin heavy chain isoform,depressed myogenin expression, and induced MyoD expression. However,functional overload did not alter myogenin or MyoD expression inCT-treated or non-CT-treated rats. Thus pharmacologically andsurgically induced hypertrophy have differing effects on myogenin andMyoD expression, because their levels were associated with changes inmyosin heavy chain composition (especially type IIX) rather thanchanges in muscle mass.

     

Satellite cell regulation of muscle mass is altered at old age.

Muscle mass is decreased with advancing age, likely due to altered regulation of muscle fiber size. This study was designed to investigate cellular mechanisms contributing to this process. Analysis of male Fischer 344 X Brown Norway rats at 6, 20, and 32 mo of age demonstrated that, even though significant atrophy had occurred in soleus muscle by old age, myofiber nuclear number did not change, resulting in a decreased myonuclear domain. Also, the number of centrally located nuclei was significantly elevated in soleus muscle of 32-mo-old rats, correlating with an increase in gene expression of MyoD and myogenin. Whereas total 5'-bromo-2'deoxyuridine (BrdU)-positive nuclei were decreased at older ages, BrdU-positive myofiber nuclei were increased. These results suggest that, with age, loss of muscle mass is accompanied by increased myofiber nuclear density that involves fusion of proliferative satellite cells, resembling ongoing regeneration. Interestingly, centrally located myofiber nuclei were not BrdU labeled. Rats were subjected to hindlimb suspension (HS) for 7 or 14 days and intermittent reloading during HS for 1 h each day (IR) to investigate how aging affects the response of soleus muscle to disuse and an atrophy-reducing intervention. After 14 days of HS, soleus muscle size was decreased to a similar extent at all three ages. However, myofiber nuclear number and the total number of BrdU-positive nuclei decreased with HS only in the young rats. IR was associated with an attenuation of atrophy in soleus muscles of 6- and 20- but not 32-mo-old rats. Furthermore, IR was associated with an increase in BrdU-positive myofiber nuclei only in young rats. These data indicate that altered satellite cell function with age contributes to the impaired response of soleus muscle to an intervention that attenuates muscle atrophy in young animals during imposed disuse.     

Maternal protein restriction induce skeletal muscle changes without altering the MRFs MyoD and myogenin expression in offspring

Stimuli during pregnancy, such as protein restriction, can affect morphophysiological parameters in the offspring with consequences in adulthood. The phenomenon known as fetal programming can cause short- and long-term changes in the skeletal muscle phenotype. We investigated the morphology and the myogenic regulatory factors (MRFs) MyoD and myogenin expression in soleus, SOL; oxidative and slow twitching and in extensor digitorum longus, EDL; glycolytic and fast twitching muscles in the offspring of dams subjected to protein restriction during pregnancy. Four groups of male Wistar offspring rats were studied. Offspring from dams fed a low-protein diet (6?% protein, LP) and normal protein diet (17?% protein, NP) were euthanized at 30 and 112?days old, and their muscles were removed and kept at ?80?°C. Muscles histological sections (8?μm) were submitted to a myofibrillar adenosine triphosphatase histochemistry reaction for morphometric analysis. Gene and protein expression levels of MyoD and myogenin were determined by RT-qPCR and western blotting. The major findings observed were distinct patterns of morphological changes in SOL and EDL muscles in LP offspring at 30 and 112?days old without changes in MRFs MyoD and myogenin expression. Our results indicate that maternal protein restriction followed by normal diet after birth induced morphological changes in muscles with distinct morphofunctional characteristics over the long term, but did not alter the MRFs MyoD and myogenin expression. Further studies are necessary to better understand the mechanisms underlying the maternal protein restriction response on skeletal muscle.     

Hindlimb suspension suppresses muscle growth and satellite cell proliferation

The effects of long-term hindlimb unweighting by tail suspension on postnatal growth of 20-day rat extensor digitorum longus (EDL) and soleus muscles were studied. Morphological assay indicated that radial growth of soleus myofibers was completely inhibited between 3 and 10 days of suspension and reduced thereafter, leading to a severe attenuation (-76% from control) over the total experimental period. Longitudinal growth rate, however, was accelerated 40% over weight-bearing controls. In addition, myofibers were arranged parallel to the long axis of the muscle, an orientation associated with chronologically younger muscles, suggesting morphological maturation of the soleus muscle had been delayed by suspension. In contrast, radial and longitudinal growth of EDL myofibers were minimally affected under similar conditions and remained within approximately 5% of control at all times. Suspension also influenced the normal changes that occur in satellite cell and myonuclear populations during postnatal growth. Both the number and proliferative activity of satellite cells were severely reduced in individual myofibers after only 3 days in both soleus and EDL muscles. The reduced number of satellite cells within 3 days of initiating hindlimb suspension appeared to be the result of their incorporation into myofibers while the long-lasting reduction appeared to be the added effects of decreased proliferative activity. In the soleus, this reduction in number and proliferation of satellite cells persisted throughout the experimental period and resulted in an overall 43% fewer myonuclei and 45% fewer satellite cells than control at 50 days of age. In contrast, both the total number and mitotic activity of satellite cells in the EDL rapidly returned to weight-bearing control levels by day 10 of suspension, resulting in no overall reduction in myonuclear accretion.     

Satellite cell proliferation in low frequency-stimulated fast muscle of hypothyroid rat

Satellite cell proliferation was assessed inlow-frequency-stimulated hypothyroid rat fast-twitch muscle by5-bromo-2'-deoxyuridine (BrdU) labeling and subsequent staining oflabeled muscle nuclei, and by staining for proliferating cell nuclearantigen (PCNA). BrdU labeling and PCNA staining were highly correlatedand increased approximately fourfold at 5 days of stimulation, decayedthereafter, but remained elevated over control in 10- and 20-daystimulated muscles. Myogenin mRNA was ~4-fold elevated at 5 days and1.5-fold at 10 days. Staining for myogenin protein yielded resultssimilar to that for PCNA and BrdU. Furthermore, a detailed examination of the pattern of myogenin staining revealed that the number of myogenin-positive nuclei was elevated in the fast pure IIB fiber population at 5 and 10 days of chronic low-frequencystimulation. By 20 days, myogenin staining was observed intransforming fast fibers that coexpressed embryonic and adult myosinheavy chain isoforms. In the slower fiber populations (i.e., IIA andI), myogenin-positive transforming fibers that coexpressed embryonicmyosin heavy chain, appeared already at 5 days. Thus the satellite cellprogeny on slower fibers seemed to proliferate less and to fuse earlierto their associated fibers than the satellite cell progeny on fast fibers. We suggest that the increase in muscle nuclei of the fast fibers might be a prerequisite for fast-to-slow fiber type transitions.

     

Effects of one bout of endurance exercise on the expression of myogenin in human quadriceps muscle

The objective of this study was to investigate the cellular localisation of MyoD and myogenin in human skeletal muscle fibres as well as the possible alterations in the expression of MyoD and myogenin in response to a single bout of endurance exercise at 40% and 75% of maximum oxygen uptake (VO₂ max). Twenty-five biopsies (5 per subject) from the vastus lateralis muscle were obtained before exercise, from the exercising leg at 40% and 75% of VO₂ max and from the resting leg following these exercise bouts. The tyramide signal amplification-direct and the Vectastain ABC methods using specific monoclonal antibodies were used to determine the exact location of myogenin and MyoD, to identify muscle satellite cells and to determine myosin heavy chain (MyHC) composition. At rest, myonuclei did not express MyoD or myogenin. Following a single bout of exercise at 40% and 75% of VO₂ max, an accumulation of myogenin in myonuclei and not in satellite cells was observed in biopsies from the exercised leg but not in biopsies before exercise and from the resting leg. The number of myogenin-positive myonuclei varied among individuals indicating differences in the response to a single exercise bout. In conclusion, this immunohistochemical study showed that a rapid rearrangement of myogenin expression occurs in exercised human skeletal muscles in response to a single bout of exercise.     

Differential myogenicity of satellite cells isolated from extensor digitorum longus (EDL) and soleus rat muscles revealed in vitro

Following muscle damage, fast- and slow-contracting fibers regenerate, owing to the activation of their satellite cells. In rats, crush-induced regeneration of extensor digitorum longus (EDL, a fast muscle) and soleus (a slow muscle) present different characteristics, suggesting that intrinsic differences exist among their satellite cells. An in vitro comparative study of the proliferation and differentiation capacities of satellite cells isolated from these muscles is presented there. We observed several differences between soleus and EDL satellite cell cultures plated at high density on gelatin-coated dishes. Soleus satellite cells proliferated more actively and fused into myotubes less efficiently than EDL cells. The rate of muscular creatine kinase enzyme appeared slightly lower in soleus than in EDL cultures at day 11 after plating, when many myotubes were formed, although the levels of muscular creatine kinase mRNA were similar in both cultures. In addition, soleus cultures expressed higher levels of MyoD and myogenin mRNA and of MyoD protein than EDL satellite cell cultures at day 12. A clonal analysis was also carried out on both cell populations in order to determine if distinct lineage features could be detected among satellite cells derived from EDL and soleus muscles. When plated on gelatin at clonal density, cells from both muscles yielded clones within 2 weeks, which stemmed from 3–15 mitotic cycles and were classified into three classes according to their sizes. Myotubes resulting from spontaneous fusion of cells from the progeny of one single cell were seen regardless of the clone size in the standard culture medium we used. The proportion of clones showing myotubes in each class depended on the muscle origin of the cells and was greater in EDL- than in soleus-cell cultures. In addition, soleus cells were shown to improve their differentiation capacity upon changes in the culture condition. Indeed, the proportions of clones showing myotubes, or of cells fusing into myotubes in clones, were increased by treatments with a myotube-conditioned medium, with phorbol ester, and by growth on extra-cellular matrix components (Matrigel). These results, showing differences among satellite cells from fast and slow muscles, might be of importance to muscle repair after trauma and in pathological situations.     

Myogenin and oxidative enzyme gene expression levels are elevated in rat soleus muscles after endurance training.

The intent of this study was to determine whether endurance exercise training regulates increases in metabolic enzymes, which parallel modulations of myogenin and MyoD in skeletal muscle of rats. Adult Sprague-Dawley rats were endurance trained (TR) 5 days weekly for 8 wk on a motorized treadmill. They were killed 48 h after their last bout of exercise. Sedentary control (Con) rats were killed at the same time as TR animals. Myogenin, MyoD, citrate synthase (CS), cytochrome-c oxidase (COX) subunits II and VI, lactate dehydrogenase (LDH), and myosin light chain mRNA contents were determined in soleus muscles by using RT-PCR. Myogenin mRNA content was also estimated by using dot-blot hybridization. Protein expression levels of myogenin and MyoD were measured by Western blots. CS enzymatic activity was also measured. RT-PCR measurements showed that the mRNA contents of myogenin, CS, COX II, COX VI, and LDH were 25, 20, 17, 16, and 18% greater, respectively, in TR animals compared with Con animals (P < 0.05). The ratio of myogenin to MyoD mRNA content estimated by RT-PCR in TR animals was 28% higher than that in Con animals (P < 0.05). Myosin light chain expression was similar in Con and TR muscles. Results from dot-blot hybridization to a riboprobe further confirmed the increase in myogenin mRNA level in TR group. Western blot analysis indicated a 24% greater level of myogenin protein in TR animals compared with Con animals (P < 0.01). The soleus muscles from TR animals had a 25% greater CS enzymatic activity than the Con animals (P < 0.01). Moreover, myogenin mRNA and protein contents were positively correlated to CS activity and mRNA contents of CS, COX II, and COX VI (P < 0.05). These data are consistent with the hypothesis that myogenin is in the pathway for exercise-induced changes in mitochondrial enzymes.     

Hindlimb suspension reduces muscle regeneration

Exposure of juvenile skeletal muscle to a weightless environment reduces growth and satellite cell mitotic activity. However, the effect of a weightless environment on the satellite cell population during muscle repair remains unknown. Muscle injury was induced in rat soleus muscles using the myotoxic snake venom, notexin. Rats were placed into hindlimb-suspended or weightbearing groups for 10 days following injury. Cellular proliferation during regeneration was evaluated using 5-bromo-2′-deoxyuridine (BrdU) immunohistochemistry and image analysis. Hindlimb suspension reduced (P<0.05) regenerated muscle mass, regenerated myofiber diameter, uninjured muscle mass, and uninjured myofiber diameter compared to weightbearing rats. Hindlimb suspension reduced (P<0.05) BrdU labeling in uninjured soleus muscles compared to weightbearing muscles. However, hindlimb suspension did not abolish muscle regeneration because myofibers formed in the injured soleus muscles of hindlimb-suspended rats, and BrdU labeling was equivalent (P>0.10) on myofiber segments isolated from the soleus muscles of hindlimb-suspended and weightbearing rats following injury. Thus, hindlimb suspension (weightlessness) does not suppress satellite cell mitotic activity in regenerating muscles before myofiber formation, but reduces growth of the newly formed myofibers. Accepted: 11 December 1997     

Stretch-induced myogenin, MyoD, and MRF4 expression and acute hypertrophy in quail slow-tonic muscle are not dependent upon satellite cell proliferation

 The objectives of these studies were to determine if (1) hypertrophy-stimulated myogenic regulatory factor (MRF) mRNA increases occur in the absense of proliferating satellite cells, and (2) acute hypertrophy occurs without satellite cell proliferation. Adult and aged quails were exposed to 0 or 2500 Rads gamma irradiation, and then wing muscles were stretch-overloaded for 3 or 7 days. MRF mRNA levels in stretch-overloaded and contralateral anterior latissimus dorsi (ALD) muscles were determined after 3 days; hypertrophy was determined after 7 days. The elimination of proliferating cells in irradiated muscles was verified histologically by bromodeoxyuridine incorporation. Relative levels of MRF4, MyoD, and myogenin mRNA were elevated 100%–400% in stretch-overloaded ALD muscles from irradiated adult quails indicating that satellite cell proliferation was not a prerequisite for MRF mRNA increases. Myogenin was the only MRF that exhibited mRNA increases that were lowered by irradiation. This suggests that satellite cells contribute only to myogenin mRNA increases in non-irradiated adult muscles following 3 days of stretch-overload. Stretch-overloaded ALD muscles from aged quails had a relative increase in myogenin mRNA of ∼150%. The myogenin increase was the same in non-irradiated and irradiated aged animals and also the same as that in stretch-overloaded muscles from irradiated adult quails. Together, these data indicate that attenuated increases in MRF expression in muscles from aged animals are attributable to lower satellite cell MRF expression. ALD muscle masses and protein contents in adult irradiated quails approximately doubled after 7 days of stretch-overload demonstrating hypertrophy despite the elimination of satellite cell proliferation. Received: 5 June 1998 / Accepted: 19 November 1998     

A Threshold Dose of Heavy Ion Radiation that Decreases the Oxidative Enzyme Activity of Spinal Motoneurons in Rats

The effect of heavy ion radiation exposure of the spinal cord on the properties of the motoneurons innervating the slow soleus and fast plantaris muscles was investigated. A 15-, 20-, 40-, 50-, or 70-Gy dose of carbon ions (5 Gy/min) was applied to the 2nd to the 6th lumbar segments of the spinal cord in rats. After a 1-month recovery period, the number and cell body size of the irradiated motoneurons innervating the soleus and plantaris muscles did not differ from that of the non-irradiated controls, irrespective of the dose received. However, the oxidative enzyme activity of these motoneurons was decreased by heavy ion radiation at doses of 40, 50, and 70 Gy compared to that of the non-irradiated controls. This decrease in oxidative enzyme activity levels in the motoneurons returned to that of the non-irradiated controls after a 6-month recovery period. We conclude that heavy ion radiation at doses of 40–70 Gy reversibly decreases the oxidative enzyme activity of motoneurons in the spinal cord of rats.     

In vivo expression patterns of MyoD, p21, and Rb proteins in myonuclei and satellite cells of denervated rat skeletal muscle

MyoD, a myogenic regulatory factor, is rapidly expressed in adult skeletal muscles in response to denervation. However, the function(s) of MyoD expressed in denervated muscle has not been adequately elucidated. In vitro, it directly transactivates cyclin-dependent kinase inhibitor p21 (p21) and retinoblastoma protein (Rb), a downstream target of p21. These factors then act to regulate cell cycle withdrawal and antiapoptotic cell death. Using immunohistochemical approaches, we characterized cell types expressing MyoD, p21, and Rb and the relationship among these factors in the myonucleus of denervated muscles. In addition, we quantitatively examined the time course changes and expression patterns among distinct myofiber types of MyoD, p21, and Rb during denervation. Denervation induced MyoD expression in myonuclei and satellite cell nuclei, whereas p21 and Rb were found only in myonuclei. Furthermore, coexpression of MyoD, p21, and Rb was induced in the myonucleus, and quantitative analysis of these factors determined that there was no difference among the three myofiber types. These observations suggest that MyoD may function in myonuclei in response to denervation to protect against denervation-induced apoptosis via perhaps the activation of p21 and Rb, and function of MyoD expressed in satellite cell nuclei may be negatively regulated. The present study provides a molecular basis to further understand the function of MyoD expressed in the myonuclei and satellite cell nuclei of denervated skeletal muscle. denervation; protein expression; apoptotic cell death; immunohistochemistry     

Analysis of Rat Hindlimb Muscle Proteins by Two-Dimensional Gels Following Spinal Cord Injury

Proteins from extensor digitorum longus (EDL), plantaris (PLN), and soleus (SOL) muscles of adult, female rats were examined by high resolution two-dimensional gel electrophoresis up to 4 weeks following spinal cord transection. The electrophoretograms were analyzed by computer imaging and densitometry. Reproducible and significant changes in the relative concentrations of several proteins in each muscle type were detected. Whereas changes involving the largest number of proteins were observed in SOL, changes in EDL and PLN were also detected. In SOL, approximately 50% of the altered proteins increased in concentration and the remaining decreased: Actin and myosin light chains LCF-1 and LCF-2 were among those proteins whose concentrations increased, whereas myosin light chains LCS-1 and LCS-2 were among those proteins whose concentrations decreased. The present findings regarding the reversal in myosin light chain composition provide biochemical support for previously published data on changes in contractile properties of muscles following spinalization. In EDL, the relative concentration of only one protein was elevated in a time-dependent manner. The concentrations of two protein species in PLN were increased following cord transection. These findings provide new biochemical markers on the effects of spinal cord on gene expression in specific hindlimb skeletal muscles.     

Repair of spinal cord transection and its effects on muscle mass and myosin heavy chain isoform phenotype.

A number of significant advances have been developed for treating spinal cord injury during the past two decades. The combination of peripheral nerve grafts and acidic fibroblast growth factor (hereafter referred to as PNG) has been shown to partially restore hindlimb function. However, very little is known about the effects of such treatments in restoring normal muscle phenotype. The primary goal of the current study was to test the hypothesis that PNG would completely or partially restore 1) muscle mass and muscle fiber cross-sectional area and 2) the slow myosin heavy chain phenotype of the soleus muscle. To test this hypothesis, we assigned female Sprague-Dawley rats to three groups: 1) sham control, 2) spinal cord transection (Tx), and 3) spinal cord transection plus PNG (Tx+PNG). Six months following spinal cord transection, the open-field test was performed to assess locomotor function, and then the soleus muscles were harvested and analyzed. SDS-PAGE for single muscle fiber was used to evaluate the myosin heavy chain (MHC) isoform expression pattern following the injury and treatment. Immunohistochemistry was used to identify serotonin (5-HT) fibers in the spinal cord. Compared with the Tx group, the Tx+PNG group showed 1) significantly improved Basso, Beattie, and Bresnahan scores (hindlimb locomotion test), 2) less muscle atrophy, 3) a higher percentage of slow type I fibers, and 4) 5-HT fibers distal to the lesion site. We conclude that the combined treatment of PNG is partially effective in restoring the muscle mass and slow phenotype of the soleus muscle in a T-8 spinal cord-transected rat model.     

Tumor necrosis factor-alpha promotes the accumulation of neutrophils and macrophages in skeletal muscle.

Tumor necrosis factor-alpha (TNF-alpha) has been associated with cachexia and is known to regulate multiple inflammatory cell (neutrophil and macrophage) responses. We tested the hypothesis that neutrophils and macrophages accumulate in the extensor digitorum longus (EDL) and soleus muscles of mice after chronic TNF-alpha administration. Murine recombinant TNF-alpha (approximately 100 microg x kg(-1) x day(-1)) in vehicle solution or vehicle solution alone (sham) was administered to C57BL/6 mice for 7 days via osmotic minipumps. In EDL muscles from TNF-alpha-treated mice, neutrophil and macrophage concentrations were elevated seven- and threefold, respectively, compared with sham mice. Neutrophil and macrophage concentrations were also elevated five- and twofold, respectively, in solei of TNF-alpha- relative to sham-treated mice. Treatment with TNF-alpha elevated ubiquitin content by approximately 25% relative to sham values for both the EDL and soleus muscles; however, these elevations were not statistically significant. No differences were observed between TNF-alpha- and sham-treated mice in body weight, food consumption, muscle mass, myofiber cross-sectional area, carbonyl groups, total protein content, or relative abundance of myosin heavy chain protein. Furthermore, no overt signs of muscle injury or regeneration were observed in muscles from TNF-alpha-treated mice in either the EDL or soleus muscles. These observations suggest that 7 days of TNF-alpha administration promote muscle inflammation as indicated by the accumulation of neutrophils and macrophages without overt signs of atrophy, injury, or regeneration.