Skeletal muscle blood bed in growing rats

Morphometric study of vascular bifurcations and capillaries in biceps femoris artery basin was performed in 2-week old, 1-month old, and adult Wistar rats. Proceeding from the results, the blood tree was digitally reconstructed, and the main haemodynamic parameters in digital simulation were evaluated in this vascular bed: the blood flow velocity, wall shear stress, drop of perfusion pressure, and resistance. The comparison with a similar study of cerebral vascular bed revealed peculiarities of the vascular bed formation and intraorgan haemodynamics in these organs.     

Skeletal muscle fiber quality in older men and women

Wholemuscle strength and cross-sectional area (WMCSA), andcontractile properties of chemically skinned segments from single fibers of the quadriceps were studied in 7 young men (YM, 36.5 ± 3.0 yr), 12 older men (OM, 74.4 ± 5.9 yr), and 12 olderwomen (OW, 72.1 ± 4.3 yr). WMCSA was smaller in OMcompared with YM (56.1 ± 10.1 vs. 79.7 ± 13.1 cm²; P = 0.031) and in OW (44.9 ± 7.5; P < 0.003) compared with OM. Age-related, but notsex-related, differences in strength were eliminated after adjustingfor WMCSA. Maximal force was measured in 552 type I and 230 type IIAfibers. Fibers from YM (type I = 725 ± 221; type IIA = 792 ± 271 µN) were stronger (P < 0.001) thanfibers from OM (I = 505 ± 179; IIA = 577 ± 262 µN) even after correcting for size. Type IIA fibers were stronger(P < 0.005) than type I fibers in YM and OM but not inOW (I = 472 ± 154; IIA = 422 ± 97 µN).Sex-related differences in type I and IIA fibers were dependent onfiber size. In conclusion, differences in WMCSA explain age-relateddifferences in strength. An intrinsic defect in contractile proteinscould explain weakness in single fibers from OM. Sex-relateddifferences exist at the whole muscle and single fiber levels.

     

Skeletal muscle reflex-mediated changes in sympathetic nerve activity are abnormal in spontaneously hypertensive rats

In hypertension, the blood pressure response to exercise is exaggerated. We demonstrated previously that this heightened pressor response to physical activity is mediated by an overactive skeletal muscle exercise pressor reflex (EPR), with important contributions from its metaboreflex and mechanoreflex components. However, the mechanisms driving the abnormal blood pressure response to EPR activation are largely unknown. Recent evidence in humans suggests that the muscle metaboreflex partially mediates the enhanced EPR-induced pressor response via abnormally large changes in sympathetic nerve activity (SNA). Whether the muscle mechanoreflex induces similarly exaggerated alterations in SNA in hypertension remains unknown, as does the role of the mechanoreceptors mediating muscle reflex activity. To address these issues, the EPR was selectively activated by electrically inducing hindlimb muscle contraction in decerebrate normotensive Wistar-Kyoto (WKY) and spontaneously hypertensive (SHR) rats. Stimulation of the EPR evoked significantly larger increases in mean arterial pressure (MAP) and renal SNA (RSNA) in SHR compared with WKY (ΔRSNA from baseline: 140 ± 11 vs. 48 ± 8%). The mechanoreflex was stimulated by stretching hindlimb muscle which likewise elicited significantly greater elevations in MAP and RSNA in SHR than WKY (ΔRSNA from baseline: 105 ± 11 vs. 35 ± 7%). Blockade of mechanoreceptors in muscle with gadolinium significantly attenuated the MAP and RSNA responses to contraction and stretch in SHR. These data suggest that 1) the exaggerated pressor response to activation of the EPR and muscle mechanoreflex in hypertension is mediated by abnormally large reflex-induced augmentations in SNA and 2) this accentuated sympathetic responsiveness is evoked, in part, by stimulation of muscle mechanoreceptors.     

Skeletal muscle: Energy metabolism, fiber types, fatigue and adaptability

Skeletal muscles cope with a large range of activities, from being able to support the body weight during long periods of upright standing to perform explosive movements in response to an unexpected threat. This requires systems for energy metabolism that can provide energy during long periods of moderately increased energy consumption as well as being able to rapidly increasing the rate of energy production more than 100-fold in response to explosive contractions. In this short review we discuss how muscles can deal with these divergent demands. We first outline the major energy metabolism pathways in skeletal muscle. Next we describe metabolic differences between different muscle fiber types. Contractile performance declines during intense activation, i.e. fatigue develops, and we discuss likely underlying mechanisms. Finally, we discuss the ability of muscle fibers to adapt to altered demands, and mechanisms behind these adaptations. The accumulated experimental evidence forces us to conclude that most aspects of energy metabolism involve multiple and overlapping signaling pathways, which indicates that the control of energy metabolism is too important to depend on one single molecule or mechanism.     

Plasticity of skeletal muscle fibres in space-flown primates

Skeletal muscle atrophy and fibre type transitions were observed as a rule in rats exposed to micro- and zero-gravity, flown on boards of biosatellites and space shuttle ships. Much less is known about the spaceflight-induced muscle events in primates. The latter are animals of special interest since pattern of their onground motor activities works in ways alike to the human one, though the opportunities of studies are much wider. One of the targets of the study was to investigate the influence of spaceflight conditions on tissue morphology in monkey skeletal muscles of different functional and structural organization.     

Effect of magnetic field on excitation propagation in a nerve fiber innervating a blood vessel]

It was shown that external magnetic field indirectly affects the blood flow due to the increments of local currents in the surroundings of action potentials that propagate along nerve fibres innervating the smooth muscle cells of the vessel wall. This reduces their tension due to nonconcurrent propagation of excitation in space and to changes in the frequency of action potentials. The dependence of this effect on the electrophysiological parameters is estimated.     

Skeletal muscle fiber type comparison of pyruvate dehydrogenase phosphatase activity and isoform expression in fed and food-deprived rats

Fiber type specificity of pyruvate dehydrogenase (PDH) phosphatase (PDP) was determined in fed (CON) and 48-h food-deprived (FD) rats. PDP activity and isoform protein content were determined in soleus (slow-twitch oxidative), red gastrocnemius (RG; fast-twitch oxidative glycolytic), and white gastrocnemius (WG; fast-twitch glycolytic) muscles. When normalized for mitochondrial volume, there was no difference in PDP activity between muscle types or CON and FD. When expressed per gram wet tissue weight, PDP activity was higher in RG compared with soleus and WG in both CON and FD rats. PDP activities from CON muscles were 1.48 +/- 0.19, 2.68 +/- 0.65, and 1.20 +/- 0.33 nmol x min(-1) x g wet tissue wt(-1) in soleus, RG, and WG, respectively, and decreased in FD muscles (1.22 +/- 0.22, 2.00 +/- 0.57, and 0.84 +/- 0.18 nmol x min(-1) x g wet tissue wt(-1)). This correlated with increased PDP2 protein, however, only in RG, as PDP2 was not detectable in soleus or WG. PDP1 protein was not responsive to food deprivation in all fiber types. In conclusion, PDP activity and protein content were higher in fast-twitch oxidative glycolytic muscles from CON and FD rats, identifying a unique inter- and intramuscular distribution. FD induced a small but significant decrease in PDP activity that was partially due to decreases in PDP2 protein. As a result, coordinate changes to PDP activity opposite to those of the other regulatory enzyme, PDH kinase, during food deprivation would maximize the inactivation of skeletal muscle PDH and enhance carbohydrate conservation during periods of limited carbohydrate supply.     

Skeletal muscle fiber regeneration following heterotopic autotransplantation in cats.

Whole 3 g extensor digitorum longus (EDL) muscles of cats were autotransplanted. The EDL muscles were either transplanted without denervation prior to transplantation (normal transplants) or denervated 3 to 4 weeks prior to transplantation (pre-denervated transplants). A few peripheral skeletal muscle fibers survived transplantation but most fibers degenerated and then regenerated as the transplant became revascularized. Both normal and pre-denervated muscles regenerated successfully and by 50 days after transplantation fibers which had reinnervated showed high and low myofibrillar ATPase activity. Compared to controls, the smaller mean fiber cross-sectional area of the transplants was due to the large number of small fibers, but some fibers in the transplant were larger than any fibers observed in the controls. Transplants regained 57 percent of the muscle mass of the controls. Contraction and half relaxation times of transplanted muscles were slower than controls, but peak isometric tetanus tension per cm² of muscle was nearly normal. Fifty to 170 days after transplantation, muscles showed low oxidative capacity and fatigued rapidly.     

Skeletal muscle response to spaceflight, whole body suspension, and recovery in rats

Comparisons of soleus and extensor digitorum longus (EDL) muscles from male Sprague-Dawley rats (350-400 g) after 7 days of weightlessness, 7 and 14 days of whole body suspension (WBS), and 7 days of recovery from WBS and from vivarium controls were made. Muscle mass loss of approximately 30% was observed in soleus after 7 and 14 days of WBS. Measurement of slow- and fast-twitch fibers showed significant alterations. Reductions in cross-sectional areas and increases in fiber densities in soleus after spaceflight and WBS were related to previous findings of muscle atrophy during unloading. Capillary density also showed a marked increase with unloading. Seven days of weightlessness were sufficient to effect a 20 and 15% loss in absolute muscle mass in soleus and EDL, respectively. However, the antigravity soleus was more responsive in terms of cross-sectional area reductions. After 7 days of recovery from WBS, with normal ambulatory loading, the parameters studied showed a reversal to control levels. Muscle plasticity, in terms of fiber and capillary responses, indicated differences in responses in the two types of muscles and further amplified that antigravity posture muscles are highly susceptible to unloading. Studies of recovery from spaceflight for both muscle metabolism and microvascular modifications are further justified.     

Skeletal muscle HIF-1alpha expression is dependent on muscle fiber type

Oxygen homeostasis is an essential regulation system for cell energy production and survival. The oxygen-sensitive subunit alpha of the hypoxia inducible factor-1 (HIF-1) complex is a key protein of this system. In this work, we analyzed mouse and rat HIF-1alpha protein and mRNA expression in parallel to energetic metabolism variations within skeletal muscle. Two physiological situations were studied using HIF-1alpha-specific Western blotting and semiquantitative RT-PCR. First, we compared HIF-1alpha expression between the predominantly oxidative soleus muscle and three predominantly glycolytic muscles. Second, HIF-1alpha expression was assessed in an energy metabolism switch model that was based on muscle disuse. These two in vivo situations were compared with the in vitro HIF-1alpha induction by CoCl(2) treatment on C(2)C(12) mouse muscle cells. HIF-1alpha mRNA and protein levels were found to be constitutively higher in the more glycolytic muscles compared with the more oxidative muscles. Our results gave rise to the hypothesis that the oxygen homeostasis regulation system depends on the fiber type.     

Skeletal muscle hypertrophy in rats having growth hormone-secreting tumor

Plantaris muscle hypertrophy resulting from surgical ablation of the synergistic gastrocnemius muscle was compared between nontumor- and GH3 tumor-bearing rat groups (n = 8-10). GH3 cells (10(6)) were subcutaneously injected into 150-g female Wistar-Furth rats to initiate the tumor. After 17 days, the tumor-bearing rats gained 5.7 g body wt/day compared with 2.0 for the nontumor-bearing rats. The left gastrocnemius muscle was surgically removed from both nontumor and tumor groups. The gastrocnemius was removed from the tumor group after an increased growth rate was achieved. Seven days after surgery, the animals were killed and plantaris muscles were removed. The wet weight of the left plantaris muscle increased 45.6 and 44.0% over the unoperated contralateral control (right side) in the nontumor and tumor groups, respectively. The right control plantaris muscle in the tumor group was 63% heavier than the right control plantaris from the nontumor group; however, the proportion of body weight for plantaris was similar between the two groups. The effect of gastrocnemius ablation and tumor treatment on plantaris weight was additive, and the percent increase over the unoperated contralateral control side was similar between the two groups. These data demonstrate that skeletal muscle hypertrophy occurs in adult animals in which growth has been stimulated by a growth hormone-secreting tumor and could suggest that the muscle growth response caused by the tumor is operating by a mechanism different than work-induced hypertrophy.     

Skeletal muscle adaptation in rats flown on Cosmos 1667

Seven male Wistar rats were subjected to 7 days of weightlessness on the Soviet biosatellite Cosmos 1667. Muscle histomorphometry and biochemical analyses were performed on the soleus (SOL) and extensor digitorum longus (EDL) of flight rats (group F) and compared with data from three groups of terrestrial controls: one subjected to conditions similar to group F in space except for the state of weightlessness (group S) and the others living free in a vivarium (V1, V2). Relative to group V2 (its age and weight-matched control group), group F showed a greater decrease of muscle mass in SOL (23%) than in EDL (11%). In SOL a decrease in the percentage of type I fibers was counterbalanced by a simultaneous increase in type IIa fibers. The cross-sectional area of type I fiber was reduced by 24%. No statistically significant difference in capillarization and enzymatic activities was observed between the groups. In EDL a reduction in type I fiber distribution and 3-hydroxyacyl-CoA-dehydrogenase activity (27%) occurred after the flight. The small histochemical and biochemical changes reported suggest the interest in studying muscular adaptation during a flight of longer duration.     

Skeletal muscle enzymes and fiber composition in male and female track athletes.

Muscle samples were obtained from the gastrocnemius of 17 female and 23 male track athletes, 10 untrained women, and 11 untrained men. Portions of the specimen were analyzed for total phosphorylase, lactic dehydrogenase (LDH), and succinate dehydrogenase (SDH) activities. Sections of the muscle were stained for myosin adenosine triphosphatase, NADH2 tetrazolium reductase, and alpha-glycerophosphate dehydrogenase. Maximal oxygen uptake (VO2max) was measured on a treadmill for 23 of the volunteers (6 female athletes, 11 male athletes, 10 untrained women, and 6 untrained men). These measurements confirm earlier reports which suggest that the athlete's preference for strength, speed, and/or endurance events is in part a matter of genetic endowment. Aside from differences in fiber composition and enzymes among middle-distance runners, the only distinction between the sexes was the larger fiber areas of the male athletes. SDH activity was found to correlate 0.79 with VO2max, while muscle LDH appeared to be a function of muscle fiber composition. While sprint- and endurance-trained athletes are characterized by distinct fiber compositions and enzyme activities, participants in strength events (e.g., shot-put) have relatively low muscle enzyme activities and a variety of fiber compositions.     

Skeletal muscle enlargement with weight-lifting exercise by rats

A rat model of weight lifting that produces skeletal muscle enlargement utilizing regimens of resistance training similar to those employed in human training programs is described. The model consists of electrically stimulating the lower leg muscles to contract against a weighted pulley bar. Animals were subjected to training protocols employing low-frequency repetitions with high training loads within a training session. Initial maximum loads of between 200 and 800 g were progressively increased during the 16 wk of training. Work done at the end of the training period increased to an average value 66% higher than that performed at the start of training. The gastrocnemius wet weight and protein content increased (P less than 0.001) by 18 and 17%, respectively, in the stimulated loaded leg in all but one training protocol, a program in which rats were exercised more frequently. RNA content, but not concentration, was increased in the trained gastrocnemius muscle from each protocol, resulting in muscle enlargement. These data indicate that the basic model presented here provides a suitable vehicle for future studies into the biochemical events that may cause skeletal muscle enlargement during resistance training but, based on limited data, suggests that an increased frequency of training days may hinder muscle enlargement in this model.