Intermittent acceleration as a countermeasure to soleus muscle atrophy.

The centrifuge proposed for the Space Station will most likely be used, in part, for countermeasure studies. At present, there is a paucity of information concerning the duration and frequency of acceleration necessary to counteract the atrophy process associated with microgravity. The present study was designed to investigate intermittent acceleration during non-weight bearing of the soleus muscle and its resultant effects on muscular atrophy. Each day rats were removed from hindlimbs suspension and accelerated to 1.2 g for four 15-min periods evenly spaced over a 12-h interval. The soleus muscle experienced non-weight bearing the remaining 23 h each day. This paradigm, when repeated for 7 days, did not completely maintain the mass of soleus muscle, which was 84% of control. Interestingly, the identical protocol utilizing ground support in lieu of acceleration successfully maintained the soleus muscle mass. The failure of the centrifugation protocol to adequately maintain soleus muscle mass might be due to an undefined stress placed on the animals inherent in centrifugation itself. This stress may also explain the transient decline in food intake of the intermittent acceleration group on the 2nd and 3rd days of treatment. Also, these data support the concept that the frequency of exposure, as opposed to the duration of exposure, to weight bearing during hindlimb unweighting seems to be the more important determinant of maintaining postural muscle mass.     

Proteomic analysis of rat soleus muscle undergoing hindlimb suspension-induced atrophy and reweighting hypertrophy

A proteomic analysis was performed comparing normal rat soleus muscle to soleus muscle that had undergone either 0.5, 1, 2, 4, 7, 10 and 14 days of hindlimb suspension-induced atrophy or hindlimb suspension-induced atrophied soleus muscle that had undergone 1 hour, 8 hour, 1 day, 2 day, 4 day and 7 days of reweighting-induced hypertrophy. Muscle mass measurements demonstrated continual loss of soleus mass occurred throughout the 21 days of hindlimb suspension; following reweighting, atrophied soleus muscle mass increased dramatically between 8 hours and 1 day post reweighting. Proteomic analysis of normal and atrophied soleus muscle demonstrated statistically significant changes in the relative levels of 29 soleus proteins. Reweighting following atrophy demonstrated statistically significant changes in the relative levels of 15 soleus proteins. Protein identification using mass spectrometry was attempted for all differentially regulated proteins from both atrophied and hypertrophied soleus muscle. Five differentially regulated proteins from the hindlimb suspended atrophied soleus muscle were identified while five proteins were identified in the reweighting-induced hypertrophied soleus muscles. The identified proteins could be generally grouped together as metabolic proteins, chaperone proteins and contractile apparatus proteins. Together these data demonstrate that coordinated temporally regulated changes in the skeletal muscle proteome occur during disuse-induced soleus muscle atrophy and reweighting hypertrophy.     

Mechanical stimulation of the plantar foot surface attenuates soleus muscle atrophy induced by hindlimb unloading in rats.

Unloading-induced muscle atrophy occurs in the aging population, bed-ridden patients, and astronauts. This study was designed to determine whether dynamic foot stimulation (DFS) applied to the plantar surface of the rat foot can serve as a countermeasure to soleus muscle atrophy normally observed in hindlimb unloaded (HU) rats. Forty-four mature (6 mo old), male Wistar rats were randomly assigned to ambulatory control, HU alone, HU with active DFS (i.e., plantar contact with active inflation), HU with passive DFS (i.e., plantar contact without active inflation), and HU while wearing a DFS boot with no plantar contact groups. Application of active DFS during HU significantly counteracted the atrophic response by preventing approximately 85% of the reduction in type I myofiber cross-sectional area (CSA) in the soleus while preventing approximately 57% of the reduction in type I myofiber CSA and 43% of the reduction in type IIA myofiber CSA of the medial gastrocnemius muscle. Wearing of a DFS boot without active inflation prevented myofiber atrophy in the soleus of HU animals in a fashion similar to that observed in HU animals that wore an actively inflated DFS boot. However, when a DFS boot without plantar surface contact was worn during HU, no significant protection from HU-induced myofiber atrophy was observed. These results illustrate that the application of mechanical foot stimulation to the plantar surface of the rat foot is an effective countermeasure to muscle atrophy induced by HU.     

低氧暴露所致大鼠骨骼肌萎缩的蛋白转化调节机制

目的 对比低氧暴露和常氧下配对低氧摄食干预(半饥饿状态)下大鼠骨骼肌蛋白质合成和分解相关基因表达的差异,以探讨低氧暴露诱导骨骼肌萎缩发生的可能机制。方法 SD大鼠分为:①常氧正常饮食组(C组);②低氧正常饮食组(H组),氧气浓度为12.4%;③常氧配对饮食组(P组),投食量即为H组前一天摄食量。4周干预后测量大鼠体成分,取比目鱼肌(SOL)和趾长伸肌(EDL),称量湿重;HE染色观察肌纤维形态,计算肌纤维横截面积(FCSA);WB测试骨骼肌中HIF1α、Akt、p-Akt及骨骼肌蛋白合成和分解相关基因蛋白含量。结果 1)H组大鼠体重较C组持续下降,P组与C组间无显著性差异;干预初期H组(P组同)摄食量较C组显著下降,后期两组间无差异;(2)干预后,H组大鼠体质量和肌肉总量较C组和P组显著性降低,P组与C组间无差异;H组两肌肉湿重较C组显著下降;H组EDL的FCSA显著低于C组和P组;(3)H组EDL中HIF1α蛋白含量显著高于C组;H组和P组SOL中p-Akt/Akt比值显著低于C组;H组EDL中mTOR、4EBP1蛋白含量显著低于C组,atrogin1、MuRF1、beclin1蛋白含量及LC3Ⅱ/Ⅰ比值显著高于C组,H组SOL中MuRF1蛋白含量显著高于C组和P组。结论 低氧所致的骨骼肌萎缩由低氧特异性因素诱发,表现为以快肌为主的骨骼肌蛋白合成减少和分解增加,而非低氧下摄食量减少引起。     

Eccentric exercise training as a countermeasure to non-weight-bearing soleus muscle atrophy.

Although various exercise paradigms have been tested, none has completely prevented muscle atrophy during non-weight bearing. Because loaded eccentric contractions occur during normal daily activity but are absent during non-weight bearing, this investigation tested whether eccentric resistance training could prevent soleus muscle atrophy during non-weight bearing. Adult female rats were randomly assigned to either weight bearing +/- intramuscular electrodes or non-weight bearing +/- intramuscular electrodes groups. Electrically stimulated maximal eccentric contractions (4 sets of 6 repetitions at approximately 0.2 fiber lengths/s, 128 degrees range of motion) were performed on anesthetized animals at 48-h intervals during the 10-day experiment. Non-weight bearing significantly reduced soleus muscle wet weight (28-31%) and noncollagenous protein content (30-31%) compared with controls. Eccentric exercise training during non-weight bearing attenuated but did not prevent the loss of soleus muscle wet weight and noncollagenous protein by 77 and 44%, respectively. The potential of eccentric exercise training as an effective and highly efficient counter-measure to non-weight-bearing atrophy is demonstrated in the 44% attenuation of soleus muscle noncollagenous protein loss by eccentric exercise during only 0.035% of the total non-weight-bearing time period.     

ATP-dependence of 125I-insulin binding by rat soleus muscle

Muscle ATP levels were lowered by incubating rat soleus muscles under anaerobic conditions, or in the presence of 2:4-dinitrophenol (0.5 mM), EDTA (5 mM) or mannitol (400 mM). 125I-insulin binding, measured under equilibrium conditions at 25 degrees C, was reduced by 49-71% in ATP-depleted muscles. Insulin binding was also determined using two other procedures which minimized internalization of 125I-insulin: these were (a) 5 min at 25 degrees C, and (b) 24 h at 3 degrees C. Under these conditions, 125I-insulin binding was reduced by 28-55% in ATP-depleted muscles. These results confirm that in soleus muscle the effect of ATP-depletion on 125I-insulin binding is actually concerned with the binding step itself and not merely a reflection of ATP-dependent internalization of the bound hormone.     

Palmitic acid uptake by the rat soleus muscle in vitro.

Abstract: The rate of fatty acid uptake, oxidation, and deposition in skeletal muscles in relation to total and unbound to albumin fatty acids concentration in the medium were investigated in the incubated rat soleus muscle. An immunohistochemical technique was applied to demonstrate whether the albumin-bound fatty acid complex from the medium penetrates well within all areas of the muscle strips. It was found that the percentage of incorporation of palmitic acid into intramuscular lipids was fairly constant, independently of the fatty acid concentration in the medium, and amounted to 63-72% for triacylglycerols, 7-12% for diacylglycerols-monoacylglycerols, and 19-26% for phospholipids. Both palmitic acid incorporation into the muscle triacylglycerol stores and its oxidation to CO2 closely correlated with an increase in both total and unbound to albumin fatty acid concentrations in the incubation medium. Under conditions of increased total but constant unbound to albumin palmitic acid concentrations, the incorporation of palmitic acid into triacylglycerols and its oxidation to CO2 were also increased, but to a lower extent. This supports the hypothesis that the cellular fatty acid metabolism depends not only on the availability of fatty acids unbound to albumin, but also on the availability of fatty acids complexed to albumin.     

Exercise-induced adaptations of rat soleus muscle grafts

In female Wistar rats (n = 316) under pentobarbital sodium anesthesia, the soleus muscle was autografted with its nerve reimplanted. One purpose was to characterize the chronological development of graft innervation and recruitment during locomotion. Furthermore, we tested hypotheses regarding the efficacy of run conditioning of different intensities, durations, and postgrafting initiation times to alter mass and pyruvate-malate oxidation capacity of grafts. Choline acetyltransferase activity of grafts increased from 10% of control value at 7 days postgrafting to 55 and 100% at days 28 and 56, respectively. Running-induced glycogen depletion occurred in grafts; this is consistent with graft recruitment during locomotion. There was a threshold of conditioning intensity below which no improvements occurred and above which there were improvements. Spring (50 m/min) and endurance (30 m/min) conditioning of a duration of at least 28 days that was initiated at 28 or 56 days postgrafting increased mass of grafts by 30% compared with grafts from nonconditioned rats. Easy conditioning (15 m/min) had no effect on graft mass. Changes in graft total protein content paralleled those of mass. Oxidation capacity of grafts increased significantly with some conditioning protocols, but not to the same extent as mass. The exercise-induced adaptations should improve graft function in the host organism.     

Capillary and fiber size interrelationships in regenerating rat soleus muscle after ischemia: a quantitative study.

The present study examines the influence of ischemia on the muscle fibers and capillarization in rats. Muscle ischemia was achieved by a pneumatic tourniquet at a pressure of 300 mm Hg for 2, 4 and 6 h (groups I, II and III, respectively) to the right hindlimb above the knee. Numerous regenerative fibers were seen at 4 and, especially, 8 and 12 days after ischemia in groups II and III. The quantitative data revealed a significant decrease in the size of muscle fibers (regenerative fibers) in ischemic skeletal muscle, with a concomitant increase in fiber density. The capillary to fiber ratio shows a decrease at 4, 8 and 12 days after ischemia in the three experimental groups: in group I because of a decrease in capillary density; in groups II and III because of an increase in fiber density with respect to capillary density.     

Disorganization of honey-comb immunoreactive pattern of desmin and plectin in rat atrophic soleus muscle fiber induced by hindlimb suspension

Immunoreactivity for desmin, plectin and alpha-actinin was investigated in rat atrophic soleus muscle fibers induced by hindlimb suspension between 1 and 4 weeks (hindlimb suspension group, HSG), and compared with that of the control group (CG). Some of the HSG for 4 weeks were allowed unrestricted cage activity for 2 weeks as the recovery group (RG). In the cross-sectioned muscle fibers of the CG, desmin and plectin showed honey-comb immunoreactive patterns extending throughout the sarcoplasm. Superimposed images by double immunofluorescence labeling showed overlapping of both immunoreactivities. In the longitudinally sectioned profiles, superimposed images of alpha-actinin and desmin were overlapped at the level of Z-discs. The focal disorganization of the above honeycomb immunoreactive patterns, followed by the reduction of the cross-sectional area (CSA) of atrophic soleus muscle fibers and the appearance of Z-streaming, uniquely arose in the HSG from the first week and extended throughout the sarcoplasm in proportion to the suspension period. Such honey-comb patterns of both desmin and plectin were already restored in the RG at 2 weeks, followed by the disappearance of Z-streaming, prior to the recovery of the CSA. These findings indicate that the disorganization of topological and structural relationships of desmin and plectin with Z-discs surrounding individual myofibrils is primarily evoked, which leads to Z-streaming of atrophic soleus muscle fibers, and that the restoration of the muscle activity results in an early arrangement recovery of desmin and plectin around myofibrils.     

Multiple effects of sulphydryl reagents on sugar transport by rat soleus muscle

Iodoacetate, over the range 0.2-2 mM, stimulated the uptake of D-xylose by rat soleus muscle and inhibited anaerobic lactate production by soleus muscle. Stimulation of sugar transport is considered to be due to the resultant fall in ATP. p-Chloromercuribenzene sulphonate (0.5-2 mM) stimulated xylose uptake to a lesser extent than iodoacetate and induced a proportionately smaller fall in ATP, consistent with the inhibitory effect of p-chloromercuribenzene sulphonate on lactate production. Under certain conditions, p-chloromercuribenzene sulphonate stimulated sugar transport without affecting the ATP level. This suggests that whereas p-chloromercuribenzene sulphonate can be expected to stimulate sugar transport through the lowering of muscle ATP, it may also act through some other mechanism. No stimulatory effect on xylose uptake was observed when muscles were exposed to N-ethylmaleimide (0.02-2 mM) either for brief (1 min) or more prolonged (30 min) periods. Because N-ethylmaleimide induced a marked fall in muscle ATP, it is surprising that N-ethylmaleimide did not stimulate sugar transport; in most experiments this inhibitor actually inhibited sugar transport. N-Ethylmaleimide inhibited the stimulation of sugar transport by 2,4-dinitrophenol and anoxia; this inhibitory effect appears to explain why N-ethylmaleimide itself did not stimulate sugar transport. p-Chloromercuribenzene sulphonate also inhibited 2,4-dinitrophenol-stimulated xylose uptake by a mechanism which seems similar to that of N-ethylmaleimide; this could explain in part the modest stimulatory effect of this inhibitor on muscle sugar transport.