Effect of training on skeletal muscle injury from downhill running in rats

Experiments were conducted to test the hypothesis that injury to skeletal muscle in rats resulting from prolonged downhill running is prevented to a greater extent by prior downhill training than by either uphill or level training. Changes in plasma creatine phosphokinase (CPK) activity and glucose-6-phosphate dehydrogenase (G-6-PDase) activity in the soleus (S), vastus intermedius (VI), and medial head of triceps brachii (TM) muscles were evaluated as markers of muscle injury 48 h after 90 min of intermittent downhill running (16 m . min -1). Prior to this acute downhill run, groups of rats were trained by either downhill (-16 degrees), level (0 degrees), or uphill (+16 degrees) running (16 m . min -1) for 30 min/day. Training duration was either 5 days or 1 day. A training effect (i.e., reduced muscle injury) was indicated if muscle G-6-PDase or plasma CPK activity in a trained group following the 90-min downhill run was not different from that of nonexercised control animals and/or if it was lower than that of nontrained runners. A significant training effect was achieved in all three muscles with 5 days of either downhill or level training, but only in S after 5 days of uphill training. Elevation of plasma CPK activity was prevented by 5 days of training on all three inclines.(ABSTRACT TRUNCATED AT 250 WORDS)     

Selected contribution: skeletal muscle capillarity and enzyme activity in rats selectively bred for running endurance.

To attempt to explain the difference in intrinsic (untrained) endurance running capacity in rats selectively bred over seven generations for either low (LCR) or high running capacity (HCR), the relationship among skeletal muscle capillarity, fiber composition, enzyme activity, and O(2) transport was studied. Ten females from each group [body wt: 228 g (HCR), 247 g (LCR); P = 0.03] were studied at 25 wk of age. Peak normoxic maximum O(2) consumption and muscle O(2) conductance were previously reported to be 12 and 33% higher, respectively, in HCR, despite similar ventilation, arterial O(2) saturation, and a cardiac output that was <10% greater in HCR compared with LCR. Total capillary and fiber number in the medial gastrocnemius were similar in HCR and LCR, but, because fiber area was 37% lower in HCR, the number of capillaries per unit area (or mass) of muscle was higher in HCR by 32% (P < 0.001). A positive correlation (r = 0.92) was seen between capillary density and muscle O(2) conductance. Skeletal muscle enzymes citrate synthase and beta-hydroxyacyl-CoA dehydrogenase were both approximately 40% higher (P < 0.001) in HCR (12.4 +/- 0.7 vs. 8.7 +/- 0.4 and 3.4 +/- 0.2 vs. 2.4 +/- 0.2 mmol. kg(-1). min(-1), respectively), whereas phosphofructokinase was significantly (P = 0.02) lower in HCR (27.8 +/- 1.2 vs. 35.2 +/- 2.5 mmol. kg(-1). min(-1)) and hexokinase was the same (0.65 +/- 0.04 vs. 0.65 +/- 0.03 mmol. kg(-1). min(-1)). Resting muscle ATP, phosphocreatine, and glycogen contents were not different between groups. Taken together, these data suggest that, in rats selectively bred for high-endurance exercise capacity, most of the adaptations for improved O(2) utilization occur peripherally in the skeletal muscles and not in differences at the level of the heart or lung.     

Effect of ginger extract ingestion on skeletal muscle glycogen contents and endurance exercise in male rats

[Purpose]Skeletal muscle glycogen is a determinant of endurance capacity for some athletes. Ginger is well known to possess nutritional effects, such as anti-diabetic effects. We hypothesized that ginger extract (GE) ingestion increases skeletal muscle glycogen by enhancing fat oxidation. Thus, we investigated the effect of GE ingestion on exercise capacity, skeletal muscle glycogen, and certain blood metabolites in exercised rats. [Methods]First, we evaluated the influence of GE ingestion on body weight and elevation of exercise performance in rats fed with different volumes of GE. Next, we measured the skeletal muscle glycogen content and free fatty acid (FFA) levels in GE-fed rats. Finally, we demonstrated that GE ingestion contributes to endurance capacity during intermittent exercise to exhaustion. [Results]We confirmed that GE ingestion increased exercise performance (p<0.05) and elevated the skeletal muscle glycogen content compared to the non-GE-fed (CE, control exercise) group before exercise (Soleus: p<0.01, Plantaris: p<0.01, Gastrocnemius: p<0.05). Blood FFA levels in the GE group were significantly higher than those in the CE group after exercise (p<0.05). Moreover, we demonstrated that exercise capacity was maintained in the CE group during intermittent exercise (p<0.05). [Conclusion]These findings indicate that GE ingestion increases skeletal muscle glycogen content and exercise performance through the upregulation of fat oxidation.     

Intensity-controlled treadmill running in mice: cardiac and skeletal muscle hypertrophy.

Whereas novel pathways of pathological heart enlargement have been unveiled by thoracic aorta constriction in genetically modified mice, the molecular mechanisms of adaptive cardiac hypertrophy remain virtually unexplored and call for an effective and well-characterized model of physiological mechanical loading. Experimental procedures of maximal oxygen consumption (VO(2 max)) and intensity-controlled treadmill running were established in 40 female and 36 male C57BL/6J mice. An inclination-dependent VO(2 max) with 0.98 test-retest correlation was found at 25 degrees treadmill grade. Running for 2 h/day, 5 days/wk, in intervals of 8 min at 85-90% of VO(2 max) and 2 min at 50% (adjusted to weekly VO(2 max) testing) increased VO(2 max) to a plateau 49% above sedentary females and 29% in males. Running economy improved in both sexes, and echocardiography indicated significantly increased left ventricle posterior wall thickness. Ventricular weights increased by 19-29 and 12-17% in females and males, respectively, whereas cardiomyocyte dimensions increased by 20-32, and 17-23% in females and males, respectively; skeletal muscle mass increased by 12-18%. Thus the model mimics human responses to exercise and can be used in future studies of molecular mechanisms underlying these adaptations.     

Effect of endurance exercise training on muscle glycogen supercompensation in rats

Nakatani, Akira, Dong-Ho Han, Polly A. Hansen, Lorraine A. Nolte, Helen H. Host, Robert C. Hickner, and John O. Holloszy. Effect of endurance exercise training on muscle glycogensupercompensation in rats. J. Appl.Physiol. 82(2): 711-715, 1997.The purpose of this study was to test the hypothesis that the rate and extent ofglycogen supercompensation in skeletal muscle are increased byendurance exercise training. Rats were trained by using a 5-wk-long swimming program in which the duration of swimming was gradually increased to 6 h/day over 3 wk and then maintained at 6 h/day for anadditional 2 wk. Glycogen repletion was measured in trained anduntrained rats after a glycogen-depleting bout of exercise. The ratswere given a rodent chow diet plus 5% sucrose in their drinking waterad libitum during the recovery period. There were remarkabledifferences in both the rates of glycogen accumulation and the glycogenconcentrations attained in the two groups. The concentration ofglycogen in epitrochlearis muscle averaged 13.1 ± 0.9 mg/g wet wtin the untrained group and 31.7 ± 2.7 mg/g in the trained group(P < 0.001) 24 h after the exercise.This difference could not be explained by a training effect on glycogensynthase. The training induced ~50% increases in muscle GLUT-4glucose transporter protein and in hexokinase activity inepitrochlearis muscles. We conclude that endurance exercise trainingresults in increases in both the rate and magnitude of muscle glycogensupercompensation in rats.

     

Effects of selective hepatic vagotomy on running endurance in rats

The liver, through the afferent ways of the vagus hepatic nerve, may influence metabolic adaptations during exercise. This study assesses the functional significance of this hepatic innervation by determining the effect of a selective hepatic vagotomy (HV) on running endurance time during submaximal activity in rats subjected to an overnight 50% food restriction. The time to exhaustion was similar for the groups of HV and sham-operated (SHM) rats [66 +/- 15 vs. 64 +/- 21 (SD) min]. The HV group was associated with higher resting levels (P less than 0.05) of hepatic glycogen and plasma glucose. No significant differences were observed between HV and SHM rats at rest and after exercise for muscle glycogen, free fatty acids, insulin, glucagon, and lactate concentrations. These data indicate that if hepatic glucoreceptors do exist and contribute to the metabolic regulation of exercise, their functional significance is secondary to more important regulatory mechanisms.     

Enhanced skeletal muscle glycogen repletion after endurance exercise is associated with higher plasma insulin and skeletal muscle hexokinase 2 protein levels in mice: comparison of level running and downhill running model

Journal of Physiology and Biochemistry - To identify factors that influence post-exercise muscle glycogen repletion, we compared the glycogen recovery after level running with downhill running, an...     

Effect of endurance training and chronic isoproterenol treatment on skeletal muscle sensitivity to norepinephrine

The purpose of this study was to determine the influence of metabolic stresses, such as endurance training and chronic isoproterenol treatment, on skeletal muscle sensitivity to norepinephrine. Using an isolated perfused rat hindlimb preparation, dose-response curves for skeletal muscle oxygen consumption (VO2) and vascular resistance were obtained with control, endurance trained, and isoproterenol treated rats. No significant difference was found between control and experimental groups for non-stimulated VO2. In response to NE infusion, trained rats showed a significantly greater increase in VO2 compared to control rats while the response of the isoproterenol treated rats was of the same magnitude as the one for their respective control rats. At the highest dose of NE infused, the vasopressor response was significantly lower in trained rats compared to control rats. At none of the doses was there a significant difference in the vasopressor response between control and isoproterenol treated rats. These results suggest that repeated exposures to high levels of catecholamines, as produced during endurance training, leads to an increased sensitivity of skeletal muscle to the effect of norepinephrine.     

耐力运动对大鼠骨骼肌ERK1/2活性的影响

目的:探讨耐力运动对大鼠骨骼肌蛋白总量(t-ERK1/2)及磷酸化ERK1/2(p-ERK1/2)及ERK2mRMA表达的影响。方法:SD大鼠随机分为对照组和运动组。运动组分为1h/d和1.5h/d组,共7周,运动结束后24h和48h取材,测定葡萄糖和胰岛素浓度;Westernblot法检测骨骼肌t-ERK1/2、p-ERK1/2蛋白表达;RT-PCR法分析ERK2mRNA表达。结果:与对照组比较,运动组胰岛素浓度降低;各运动组p-ERK1/2升高;1.5h/d-24h和-48h组t-ERK1/2增高;1h/d-24h组与1.5h/d-24h和-48hERK2mRNA表达增高。结论:耐力运动可能通过增加ERK1/2活性,提高大鼠骨骼肌对胰岛素的敏感性。     

Effect of insulin on dexamethasone-induced ultrastructural changes in skeletal and cardiac muscle

Glucocorticoids help animals respond to stressors but excessive glucocorticoids cause muscle atrophy, while insulin can promote anabolism and growth. In order to compare the glucocorticoids-induced ultrastructural changes between skeletal muscle and cardiac muscle, and investigate the preventive effects of insulin on the changes, eighteen male chicks with similar initial weight were randomly divided into three groups. The two test groups were respectively treated with high-dose dexamethasone alone or together with low-dose insulin by intraperitoneal injection, and the control group was treated with an equal volume of saline solution. The experiment lasted for ten days, and then the body weight, muscle size and ultrastructure in skeletal and cardiac muscles of twelve chicks were qualitatively or quantitatively analyzed. The results showed that high-dose dexamethasone induced obvious skeletal and cardiac muscle atrophy. The differences of ultrastructural changes between skeletal muscle and cardiac muscle (such as for the former or the latter, the intermyofibrillar-and-interfilamentary spaces reducing or enlarging, the mitochondria swelling seriously or enlarging lightly, the myofibril filaments compacting or loosing) suggested that dexamethasone induced skeletal and cardiac muscle atrophy by different mechanisms. Low-dose insulin did not affect the dexamethasone-induced decreases of body weight and skeletal muscle size, but alleviated lightly the dexamethasone-induced ultrastructural changes in skeletal muscle. Different from skeletal muscle, low-dose insulin almost resisted the dexamethasone-induced ultrastructural changes in cardiac muscle.     

Effect of cold environment on skeletal muscle mitochondria in growing rats

Summary Growing rats (4 weeks old) were kept for 3 weeks at 11° C and 24° C respectively. The cold-adapted animals showed a significantly higher oxygen consumption (64%). Volume density of subsarcolemmal and interfibrillar mitochondria as well as volume density of fat droplets were estimated in M. soleus and the diaphragm of both groups. In cold-adapted animals, the total volume of mitochondria was significantly increased by 24% in diaphragm and 37% in M. soleus. The volume of subsarcolemmal mitochondria was almost doubled in each muscle, but the volume of interfibrillar mitochondria did not change significantly. The surface of the inner mitochondrial membranes per unit volume of mitochondrion in M. soleus was significantly increased both in interfibrillar and subsarcolemmal mitochondria, whereas the surface of the outer mitochondrial membranes per unit volume of mitochondrion was increased only in the subsarcolemmal mitochondria. The volume of fat droplets in the diaphragm and M. soleus of cold adapted animals increased significantly by 62% and 150% respectively.     

Myofibril ATPase activity of cardiac and skeletal muscle of exhaustively exercised rats

The activation characteristics of Mg-ATP and Ca2+ on cardiac and skeletal muscle myofibril ATPase activity were studied in rats following a run to exhaustion. In addition, the effect of varying ionic strength was determined on skeletal muscle from exhausted animals. The exhausted group (E) ran at a speed of 25 m min-1 with an 8% incline. Myofibril ATPase activities for control (C) and E were determined with 1, 3 and 5 mM Mg-ATP and 1 and 10 microM Ca2+ at pH 7.0 and 30 degrees C. For control skeletal muscle, at 1 and 10 microM Ca2+, there was an increase in ATPase activity from 1 to 5 mM Mg-ATP (P less than 0.05). For E animals the myofibril ATPase activities at 10 microM Ca2+ and all Mg-ATP concentrations were similar to C (P greater than 0.05). At 1.0 microM Ca2+ and all Mg-ATP concentrations were similar to C (P greater than 0.05). At 1.0 microM Ca2+ the activities at 3 and 5 mM Mg-ATP were greater for the E animals (P less than 0.05). Increasing KCl concentrations resulted in greater inhibition for E animals. With cardiac muscle, the myofibril ATPase activities at 1.0 microM free Ca2+ were lower for E at all Mg-ATP levels (P less than 0.05). In contrast, at 10 microM Ca2+, the E group exhibited an elevated myofibril ATPase activity. The results indicate that Mg-ATP and Ca2+ activation of cardiac and skeletal muscle myofibril ATPase is altered with exhaustive exercise.     

Effect of exercise on cardiac muscle performance in aged rats

Most investigations of a direct impact of chronic physical conditioning on cardiac muscle physiology and biochemistry have utilized relatively young animal models. Some, but not all, of these studies have demonstrated beneficial effect of relatively modest magnitude. With advancing age, i.e., with the onset of senescence, characteristic changes in many aspects of cardiac physiology and biochemistry in rodent models have been noted to occur. In general, these consist of a reduction in the kinetics of events that determine myocardial excitation-contraction relaxation and energetics. Recently it has been shown that several of these apparent age-related functional declines can be reversed by chronic physical conditioning, which in some instances have no effect on cardiac muscle of younger animals. This suggests that the relative efficacy of chronic exercise to modulate myocardial performance may, in part, be determined by the level of function present before the intervention, as is the case for other modulators of cardiac muscle function. In addition, that apparent age-related deficits in myocardial function can be reversed by conditioning suggests an interaction between life-style and aging.