Influence of neural and humoral beta-adrenoceptor stimulation on dynamic myogenic microvascular reactivity in cat skeletal muscle.

Analysis of myogenic microvascular reactivity in terms of its recently described prominent dynamic component was performed before and during graded sympathetic stimulation and catecholamine infusion. Phenoxybenzamine and propranolol were used to differentiate between alpha- and beta-adrenoceptor effects. The study first confirmed previous findings of a beta-adrenergic inhibitory component in the neural control of microvascular resistance which attenuated the alpha-adrenergic constriction. The results concerning the interaction between adrenergic and myogenic control mechanisms corroborated the conclusion that the sympathoadrenal system, via its beta-adrenergic link, exerts effective inhibitory action on myogenic excitatory reactions. As regards the neural control, its beta-adrenergic component seemed to quite precisely compensate for the reinforcing effect on the myogenic constrictor response which results from increased vascular tone per se (in this case caused by alpha-adrenergic constriction), interpreted as a physical 'gain' effect inherent in the inverse fourth power relationship between radius and resistance. The latter complicating factor, which implies non-linearity in integrated peripheral resistance control, was thus revealed only after beta-blockade, but not on the vascular bed with intact adrenoceptors, where a given transmural pressure stimulus evoked an almost equally large myogenic constrictor response irrespective of the prevailing level of vascular tone. The beta-inhibitory action of blood-borne noradrenaline was similar to the neural one, whereas that of adrenaline was more effective, causing decline of myogenic reactivity below control.     

Effects of aging on microvascular oxygen pressures in rat skeletal muscle

Aging alters skeletal muscle vascular geometry and control such that the dynamics of muscular blood flow (Q) and O2 delivery (Q(O2)) may be impaired across the rest-exercise transition. If, at the onset of muscle contractions, Q dynamics are slowed disproportionately to those of muscle O2 uptake (V(O2), microvascular PO2 (PO2m) would be reduced and blood-tissue O2 transfer compromised. This investigation determined the effects of aging on PO2m (a direct reflection of the Q(O2)-to-V(O2) ratio), at rest and across the rest-contractions transition in the spinotrapezius of young (approximately 6 months, n = 9) and old (>24 months, n = 10) male Fisher 344/Brown Norway hybrid rats. Phosphorescence quenching techniques were used to quantify PO2m, and test the hypothesis that, across the rest-contractions (twitch, 1 Hz; 4-6 V, 240 s) transition, aging would transiently reduce the Q(O2)-to-V(O2) ratio causing a biphasic profile in which PO2m fell below steady-state contracting values. Old rats had a lower pre-contraction baseline PO2m than young (27.1+/-1.9 versus 33.8+/-1.6 mmHg, P<0.05, respectively). In addition, in old rats PO2m demonstrated a pronounced difference between the absolute nadir and end-contracting values (2.5+/-0.9 mmHg), which was absent in young rats. In conclusion, unlike their young counterparts, old rats exhibited a transiently reduced PO2m across the rest-contractions transition that may impair blood-tissue O2 exchange and elevate the O2 deficit, thereby contributing to premature fatigue.     

多囊卵巢综合征骨骼肌胰岛素抵抗大鼠模型的建立

背景：研究表明胰岛素抵抗在多囊卵巢综合征的发生与发展过程中起重要作用,建立理想的多囊卵巢综合征骨骼肌胰岛素抵抗动物模型是研究该疾病的基础。 目的：探讨建立较为理想的多囊卵巢综合征骨骼肌胰岛素抵抗大鼠模型的方法。 方法：将八九周龄SD雌性大鼠随机分为模型组和对照组。模型组给予胰岛素联合人绒毛膜促性腺激素皮下注射,并以高脂饲料和50 g/L葡萄糖水喂养,对照组皮下注射生理盐水,常规饮食喂养。 结果与结论：造模6周后,模型组大鼠卵巢体积明显增大,且呈多囊性改变;血清睾酮、黄体生成素、空腹血糖和胰岛素水平高于对照组;骨骼肌组织中葡萄糖转运蛋白4表达明显低于对照组,且其葡萄糖转运蛋白4阳性颗粒靠近骨骼肌细胞膜边缘者较少。可见胰岛素联合人绒毛膜促性腺激素皮下注射,并饲以高脂饲料和50 g/L葡萄糖水是建立多囊卵巢综合征骨骼肌胰岛素抵抗大鼠模型较为理想的方法。     

Decreased skeletal muscle potassium in obesity

The effect of body weight on total body potassium, skeletal muscle electrolytes and fat content was studied in seven lean and seven obese middle-aged men and seven lean and eight obese middle-aged women. Total body potassium and total body fat increased with body weight (p less than 0.01 and less than 0.05 for men, and p less than 0.05 and p less than 0.001 for women, respectively). So did muscle fat in men (p less than 0.01), while muscle tissue potassium was decreased in both obese men (p less than 0.001) and obese women (p less than 0.05). The skeletal muscle Na/K-ratio tended to be higher in obese men (p less than 0.1) but was not related to body weight in women. Skeletal muscle magnesium was higher (p less than 0.01) in obese men than in lean men. No differences between lean and obese women were found. Obese men had higher diastolic blood pressure (p less than 0.05) than lean men, while there was no difference between obese and lean women. Compared with lean subjects, obese subjects thus had lower relative skeletal muscle mass and men, especially, had more fat and less potassium in the skeletal muscle.     

Decreased irisin secretion contributes to muscle insulin resistance in high-fat diet mice

Aims: Recent studies have revealed the relationship between irisin and insulin signaling, while positive associations of muscle FNDC5 with insulin resistance is observed. However, the functional mechanism of irisin on muscle insulin resistance is still obscure. This study aims to investigate the effect of irisin on muscle insulin action. Methods: Diabetic mouse model was established by high fat diet (HFD) induced obesity in C57BL/6 mice. Body indexes and serum levels of triglyceride (TG), blood glucose and insulin were record. Oral glucose tolerance test (OGTT) was performed before being killed. Circulating irisin level was also detected, while FNDC5/irisin expression was determined by RT-PCR and western blot analysis in both muscle and adipose tissues. Insulin action was further evaluated by the phosphorylation of AKT and Erk, and palmitic acid treated muscle cells were introduced for mimicking diabetic status in vitro. Results: Obvious obese feathers associated with type 2 diabetes were observed in HFD feeding mice, with decreased circulating irisin level and FNDC5/irisin secretion in adipose tissues. Although FNDC5/irisin expression showed little change in skeletal muscle, the insulin action was inhibited significantly. Moreover, palmitic acid treated muscle cells showed similar inhibition of insulin action, and FNDC5/irisin expression change. Besides, insulin action could be reversed by irisin addition in muscle cells. Conclusion: HFD induced obese mice showed decreased irisin secretion from adipose tissues, which might contribute to muscle insulin resistance. Furthermore, irisin addition could recover insulin action in palmitic acid treated muscle cells, indicating the importance of irisin for preserving insulin signaling.     

Effects of contusion and cryotherapy on microvascular perfusion in rat dorsal skeletal muscle

Dorsal microcirculatory chambers (DMCs) were surgically implanted in the backs of rats to expose, beneath a transparent coverslip, the skeletal muscle microvasculature under the skin; two studies were completed using this model. In one study, microvascular perfusion was monitored for 96 h with laser Doppler fluxmetry and laser Doppler perfusion imaging to measure microvascular perfusion before and after contusion of the skeletal muscle within the DMC. There were statistically significant differences in microvascular perfusion observed with laser Doppler fluxmetry (baseline vs. postcontusion at 48 h) and with the scanning laser Doppler perfusion imager (baseline vs. postcontusion at 96 h). The second study monitored changes in microvascular perfusion following 20 min of local ice application to the back side (fur and skin side) of the DMC. Ice application resulted in a statistically significant reduction in microvascular perfusion as demonstrated by both laser Doppler instruments. The use of the two laser Doppler instruments with this model of skeletal muscle microcirculation provides direct measurements of microvascular perfusion that can be used to monitor the effect of contusion and cryotherapy on skeletal muscle microcirculation.     

Interrelations of myogenic response, progressive atrophy of muscle fibers, and cell death in denervated skeletal muscle

Little is known concerning the time-course and structural dynamics of reactivation of compensatory myogenesis in denervated muscle, its initiating cellular mechanisms, and the relationship between this process and the progression of postdenervation atrophy. The purpose of this study was to investigate the interrelations between temporal and spatial patterns of the myogenic response in denervated muscle and progressive atrophy of muscle fibers. Another objective was to study whether reactivation of myogenesis correlates with destabilization of the differentiated state and death of denervated muscle cells. It has remained unclear whether muscle fiber atrophy was the primary factor activating the myogenic response, what levels of cellular atrophy were associated with its activation, and whether the initiation and intensity of myogenesis depended on the local and individual heterogeneity of atrophic changes among fibers. For this reason, our objective was also to identify the levels of atrophic and degenerative changes in denervated muscle fibers that are correlated with activation of the myogenic response. We found that the reactivation of myogenesis in the tibialis anterior and extensor digitorum longus muscles of the rat starts between days 10-21 following nerve transection, before atrophy has attained advanced level, long before dead cells are found in the tissue. Formation of new muscle fibers reaches its maximum between 2 and 4 months following denervation and gradually decreases with progressive postdenervation atrophy. The myogenic response is biphasic and includes two distinct processes. The first process resembles the formation of secondary and tertiary generations of myotubes during normal muscle development and dominates during the first 2 months of denervation. During this period, activated satellite cells form new myotubes on live differentiated muscle fibers. Most of the daughter myotubes in 1- and 2-month denervated muscle develop on the surface of fast type parent muscle fibers, and some of the newly formed muscle fibers express slow myosin. Some fast type parent fibers are weakly or, more rarely, moderately immunopositive for embryonic isomyosin. This indicates that reactivation of myogenesis may also depend on the fiber type. The level of atrophy, destabilization of the differentiated myofiber phenotype, and degenerative changes of individual fibers in denervated muscle are very heterogeneous. The myogenic response of the first type is associated predominantly with fibers of average and higher than average levels of atrophy. Muscle cells that undergo a lesser degree of atrophy also form daughter fibers, although with a lower incidence. We did not find any correlation between the size of newly formed fibers and the level of atrophy of parent fibers. The topographical distribution of new myotubes both in the peripheral and central areas of the mid-belly equatorial sections at the early stages following nerve transection indicates that myogenesis of the first type represents a systemic reaction of muscle to the loss of neural control. These data indicate that activation of the myogenic response does not depend on cell death and degenerative processes per se. The second type of myogenesis is a typical regenerative reaction that occurs mainly within the spaces surrounded by the basal laminae of dead muscle fibers. Myocytes of different sizes are susceptible to degeneration and death, which indicates that cell death in denervated muscle does not correlate with levels of muscle cell atrophy. The regenerative process frequently results in development of abnormal muscle cells that branch or form small clusters. Replacement of lost fibers becomes activated between 2 and 4 months following nerve transection, i.e., mainly at advanced stages of postdenervation atrophy, when cell death becomes a contributing factor of the atrophic process. In long-term denervated muscle, the first and second types of myogenesisoccur concurrently, and the topographical distribution of the myogenic response becomes more heterogeneous than during the first weeks following denervation. Thus, our data demonstrate differential temporal and spatial expression of two patterns of myogenesis in denervated muscle that appear to be controlled by different regulatory mechanisms during the postdenervation period. (c) 2001 Wiley-Liss, Inc.     

Influence of neural and humoral beta–adrenoceptor stimulation on dynamic myogenic microvascular reactivity in cat skeletal muscle

Analysis of myogenic microvascular reactivity in terms of its recently described prominent dynamic component was performed before and during graded sympathetic stimulation and catecholamine infusion. Phenoxybenzamine and propranolol were used to differentiate between α– and β–adrenoceptor effects. The study first confirmed previous findings of a β–adrenergic inhibitory component in the neural control of microvascular resistance which attenuated the a–adrenergic constriction. The results concerning the interaction between adrenergic and myogenic control mechanisms corroborated the conclusion that the sympathoadrenal system, via its β–adrenergic link, exerts effective inhibitory action on myogenic excitatory reactions. As regards the neural control, its –adrenergic component seemed to quite precisely compensate for the reinforcing effect on the myogenic constrictor response which results from increased vascular tone per se (in this case caused by a–adrenergic constriction), interpreted as a physical ‘gain’ effect inherent in the inverse fourth power relationship between radius and resistance. The latter complicating factor, which implies non–linearity in integrated peripheral resistance control, was thus revealed only after β–blockade, but not on the vascular bed with intact adrenoceptors, where a given transmural pressure stimulus evoked an almost equally large myogenic constrictor response irrespective of the prevailing level of vascular tone. The β–inhibitory action of blood–borne noradrenaline was similar to the neural one, whereas that of adrenaline was more effective, causing decline of myogenic reactivity below control.     

Adaptations in rat skeletal muscle following long-term resistance exercise training

The purpose of this investigation was to determine whether long-term, heavy resistance training would cause adaptations in rat skeletal muscle structure and function. Ten male Wistar rats (3 weeks old) were trained to climb a 40-cm vertical ladder (4 days/week) while carrying progressively heavier loads secured to their tails. After 26 weeks of training the rats were capable of lifting up to 800?g or 140% of their individual body mass for four sets of 12–15 repetitions per session. No difference in body mass was observed between the trained rats and age-matched sedentary control rats. Absolute and relative heart mass were greater in trained rats than control rats. When expressed relative to body mass, the mass of the extensor digitorum longus (EDL) and soleus muscles was greater in trained rats than control rats. No difference in absolute muscle mass or maximum force-producing capacity was evident in either the EDL or soleus muscles after training, although both muscles exhibited an increased resistance to fatigue. Individual fibre hypertrophy was evident in all four skeletal muscles investigated, i.e. EDL, soleus, plantaris and rectus femoris muscles of trained rats, but muscle fibre type proportions within each of the muscles tested remained unchanged. Despite an increased ability of the rats to lift progressively heavier loads, this heavy resistance training model did not induce gross muscle hypertrophy nor did it increase the force-producing capacity of the EDL or soleus muscles.     

The myogenic response in isolated rat cerebrovascular arteries: smooth muscle cell model

Previous models of the cerebrovascular smooth muscle cell have not addressed the interaction between the electrical, chemical, and mechanical components of cell function during the development of active tension. These models are primarily electrical, biochemical or mechanical in their orientation, and do not permit a full exploration of how the smooth muscle responds to electrical or mechanical forcing. To address this issue, we have developed a new model that consists of two major components: electrochemical and chemomechanical subsystem models of the smooth muscle cell. Included in the electrochemical model are models of the electrophysiological behavior of the cell membrane, fluid compartments, Ca2+ release and uptake by the sarcoplasmic reticulum (SR), and cytosolic Ca2+ buffering, particularly by calmodulin (CM). With this subsystem model, we can study the mechanics of the production of intracellular Ca2+ transient in response to membrane voltage clamp pulses. The chemomechanical model includes models of: (a) the chemical kinetics of myosin phosphorylation, and the formation of phosphorylated (cycling) myosin cross-bridges with actin, as well as attached (non-cycling) latch-type cross-bridges; and (b) a model of force generation and mechanical coupling to the contractile filaments and their attachments to protein structures and the skeletal framework of the cell. The two subsystem models are tested independently and compared with data. Likewise, the complete (combined) cell model responses to voltage pulse stimulation under isometric and isotonic conditions are calculated and compared with measured single cell length-force and force-velocity data obtained from literature. This integrated cell model provides biophysically based explanations of electrical, chemical, and mechanical phenomena in cerebrovascular smooth muscle, and has considerable utility as an adjunct to laboratory research and experimental design.     

Nitric oxide blunts myogenic autoregulation in rat renal but not skeletal muscle circulation via tubuloglomerular feedback

This rat renal blood flow (RBF) study quantified the impact of nitric oxide synthase (NOS) inhibition on the myogenic response and the balance of autoregulatory mechanisms in the time domain following a 20 mmHg-step increase or decrease in renal arterial pressure (RAP). When RAP was increased, the myogenic component of renal vascular resistance (RVR) rapidly rose within the initial 7–10 s, exhibiting an ∼5 s time constant and providing ∼36% of perfect autoregulation. A secondary rise between 10 and 40 s brought RVR to 95% total autoregulatory efficiency, reflecting tubuloglomerular feedback (TGF) and possibly one or two additional mechanisms. The kinetics were similar after the RAP decrease. Inhibition of NOS (by l -NAME) increased RAP, enhanced the strength (79% autoregulation) and doubled the speed of the myogenic response, and promoted the emergence of RVR oscillations (∼0.2 Hz); the strength (52%) was lower at control RAP. An equi-pressor dose of angiotensin II had no effect on myogenic or total autoregulation. Inhibition of TGF (by furosemide) abolished the l -NAME effect on the myogenic response. RVR responses during furosemide treatment, assuming complete inhibition of TGF, suggest a third mechanism that contributes 10–20% and is independent of TGF, slower than the myogenic response, and abolished by NOS inhibition. The hindlimb circulation displayed a solitary myogenic response similar to the kidney (35% autoregulation) that was not enhanced by l -NAME. We conclude that NO normally restrains the strength and speed of the myogenic response in RBF but not hindlimb autoregulation, an action dependent on TGF, thereby allowing more and slow RAP fluctuations to reach glomerular capillaries.     

Royal jelly supplementation reduces skeletal muscle lipotoxicity and insulin resistance in aged obese rats

Background

Consumption of a high-fat diet (HFD) in aged rats is associated with several metabolic disorders. The mechanism of skeletal muscle lipotoxicity and insulin resistance (IR) is multi-factorial, but the exact mechanism of how aging affects these processes unknown. Royal jelly (RJ) is a dietary supplement with many physiological and pharmacological properties. No previous studies have demonstrated the protective effects and mechanism of RJ in aged obese rats.

Hierarchization of myogenic and adipogenic progenitors within human skeletal muscle

Skeletal muscle cells constitute a heterogeneous population that maintains muscle integrity through a high myogenic regenerative capacity. More unexpectedly, this population is also endowed with an adipogenic potential, even in humans, and intramuscular adipocytes have been found to be present in several disorders. We tested the distribution of myogenic and adipogenic commitments in human muscle-derived cells to decipher the cellular basis of the myoadipogenic balance. Clonal analysis showed that adipogenic progenitors can be separated from myogenic progenitors and, interestingly, from myoadipogenic bipotent progenitors. These progenitors were isolated in the CD34(+) population on the basis of the expression of CD56 and CD15 cell surface markers. In vivo, these different cell types have been found in the interstitial compartment of human muscle. In vitro, we show that the proliferation of bipotent myoadipogenic CD56(+)CD15(+) progenitors gives rise to myogenic CD56(+)CD15(-) progenitors and adipogenic CD56(-)CD15(+) progenitors. A cellular hierarchy of muscle and fat progenitors thus occurs within human muscle. These results provide cellular bases for adipogenic differentiation in human skeletal muscle, which may explain the fat development encountered in different muscle pathological situations.     

Beta-adrenergic dilator interaction with the constrictor response in resistance vessels of skeletal muscle during hemorrhage

A marked beta-adrenergic dilator interaction with the vasoconstrictor response in skeletal muscle during hemorrhage is described. The dilator influence corresponded to some 40% of the constrictor response both at mild and moderate as well as at large bleeding. In absolute resistance units, the beta-adrenergic dilator influence averaged no less than 14 mmHg/ml X min-1 X 100 g-1) at large bleeding (hemorrhagic hypotension of 50 mmHg). Comparison of the hemorrhage induced resistance effects in the autoperfused innervated muscle, in the autoperfused denervated muscle, and in the innervated muscle cross-circulated from a donor animal, showed that the beta-adrenergic dilator influence more or less completely was caused by blood-borne catecholamines, in all likelihood by adrenaline, which is known to be secreted in large amounts during hemorrhage. The described beta-adrenergic dilator mechanism may serve to maintain nutritional blood flow by counteracting the constrictor response. It deserves consideration also from the point of view that it obviously has to be taken into account for proper evaluation of other vascular control mechanisms brought into action in hemorrhage.     

Calorie restriction increases insulin-stimulated tyrosine phosphorylation of insulin receptor and insulin receptor substrate-1 in rat skeletal muscle

A moderate reduction in calorie intake (calorie restriction, CR) improves insulin-stimulated glucose transport in skeletal muscle. Therefore, we studied muscle insulin signalling in ad libitum (AL) and CR ( approximately 60% AL intake for 20 days) fed rats, which received a control injection (sterile water) or an insulin injection (30 U kg-1 body weight). In control (not insulin-treated) rats, there was no detectable tyrosine phosphorylation of insulin receptor (IR), regardless of diet; no diet effect on tyrosine phosphorylation of insulin receptor substrate-1 (IRS1) or IRS1-associated phosphatidylinositol 3-kinase (PI3K) protein and 21% higher IRS1-associated PI3K activity in AL vs. CR. In insulin-treated rats, tyrosine-phosphorylated IR was 79% higher for CR vs. AL; tyrosine-phosphorylated IRS1 was 109% higher for CR vs. AL; IRS1-associated PI3K protein and IRS1-associated PI3K activity were unaffected by diet. Calorie restriction amplifies early insulin signalling steps without changing IRS1-associated PI3K, suggesting enhanced glucose transport is mediated by altering: IRS1-PI3K localization, PI3K associated with proteins other than IRS1 or post-PI3K events.     

The correlation between insulin resistance and the visceral fat to skeletal muscle ratio in middle-aged women

Central obesity with visceral fat accumulation and the amount of skeletal muscle mass may influence insulin sensitivity via its capacity for glucose load uptake. We investigated the relationships among the following metabolic variables: ratio of fat area to skeletal muscle area (VMR), percent ideal body weight, body mass index, waist-to-hip circumference (WHR) and visceral fat to subcutaneous fat ratio (VSR) in 114 nondiabetic middle-aged women. Anthropometric parameters, lipid profiles and sex hormone- binding globulin were measured. Visceral and subcutaneous fat areas at the umbilical level and the skeletal muscle area at the mid-thigh level were measured and computed. 75-gram OGTT tests were performed, along with measuring plasma glucose, insulin and free fatty acid levels, according to which area under the curve of glucose (Glu-AUC), insulin (Ins-AUC), free fatty acid (FFA-AUC) and glucose/insulin ratio (GIR=Glu- AUC/Ins-AUC), were calculated. 1) Triglyceride was more correlated with VSR than VMR. 2) The independent anthropometric parameters for each metabolic variable were In conclusion, VMR for Ins-AUC, WHR for Glu-AUC and total cholesterol, and VSR for triglyceride. 3) For subjects with higher VMR, age, Ins-AUC and triglyceride were significantly higher. 4) Subjects with higher VMR were older and showed higher Ins-AUC and lower GIR than the subjects with lower VMR. In conclusion, VMR is an anthropometric parameter that reflects insulin resistance concerning glucose metabolism, and VSR is thought to be a good parameter that that reflects the serum lipid levels. Further prospective studies are necessary to reevaluate the visceral fat vs. skeletal muscle relationship.     

SD大鼠骨骼肌卫星细胞系的建立及诱导其向成肌、成脂和成骨分化

目的:建立SD大鼠骨骼肌卫星细胞的细胞系,为组织工程学提供种子细胞和研究资料.方法:采用两步酶消化法结合差速贴壁技术,获得较高纯度的骨骼肌卫星细胞.MTT法观察骨骼肌卫星细胞的体外增殖特性并绘制生长曲线图,流式细胞仪检测细胞周期.观察不同诱导条件下骨骼肌卫星细胞的成肌、成脂、成骨的分化特性.结果:骨骼肌卫星细胞可传50代以上,第7代时,倍增时间约为60 h,80.7%的细胞处于G1期,在特定诱导作用下骨骼肌卫星细胞可以向成肌、成脂、成骨方向分化,显示了骨骼肌卫星细胞的多向分化潜能,成功建立了骨骼肌卫星细胞的细胞系.结论:建立了SD大鼠骨骼肌卫星细胞系,为组织工程学提供种子细胞.