Regulation of Limulus skeletal muscle contraction

Skeletal muscle contraction of Limulus polyphemus, the horseshoe crab, seemed to be regulated in a dual manner, namely Ca2+ binding to the troponin complex as well phosphorylation of the myosin light chains (MLC) by a Ca2+/calmodulin-dependent myosin light chain kinase. We investigated muscle contraction in Limulus skinned fibers in the presence of Ca2+ and of Ca2+/calmodulin to find out which of the two mechanisms prevails in Limulus skeletal muscle contraction. Although skinned fibers revealed high basal MLC mono- and biphosphorylation levels (0.48 mol phosphate/mol 31 kDa MLC; 0.52 mol phosphate/mol 21 kDa MLC), the muscle fibers were fully relaxed at pCa 8. Upon C2+ or Ca2+/calmodulin activation, the fibers developed force (357+/-78.7 mN/mm2; 338+/-69.7 mN/mm2, respectively) while the MLC phosphorylation remained essentially unchanged. We conclude that Ca2+ activation is the dominant regulatory mechanism in Limulus skeletal muscle contraction.     

Effect of insulin and contraction up on glucose transport in skeletal muscle

The major glucose transporter protein expressed in skeletal muscle is GLUT4. Both muscle contraction and insulin induce translocation of GLUT4 from the intracellular pool to the plasma membrane. The intracellular pathways that lead to contraction- and insulin-stimulated GLUT4 translocation seem to be different, allowing the attainment of a maximal effect when acting together. Insulin utilizes a phosphatidylinositol 3-kinase-dependent mechanism, whereas the exercise signal may be initiated by calcium release from the sarcoplasmic reticulum or from autocrine- or paracrine-mediated activation of glucose transport. During exercise skeletal muscle utilizes more glucose than when at rest. However, endurance training leads to decreased glucose utilization during sub-maximal exercise, in spite of a large increase in the total GLUT4 content associated with training. The mechanisms involved in this reduction have not been totally elucidated, but appear to cause the decrease of the amount of GLUT4 translocated to the plasma membrane by altering the exercise-induced enhancement of glucose transport capacity. On the other hand, the effect of resistance training is controversial. Recent studies, however, demonstrated the improvement in insulin sensitivity correlated with increasing muscle mass. New studies should be designed to define the molecular basis for these important adaptations to skeletal muscle. Since during exercise the muscle may utilize insulin-independent mechanisms to increase glucose uptake, the mechanisms involved should provide important knowledge to the understanding and managing peripheral insulin resistance.     

Effect of acute hypothermia on parameters of tetanic contraction of the rat skeletal muscle

In rats under acute hypothermia, tetanic tension of the medial m. gastrocnemius had a higher amplitude.     

Time- and use-dependent inhibition by ryanodine of caffeine-induced contraction of guinea-pig aortic smooth muscle

We examined how ryanodine interfered with Ca2+-releasing action of caffeine in guinea-pig aorta. Ryanodine (10 microM) decreased the caffeine-induced contraction depending on the time of pretreatment with the agent. The development of ryanodine-effect with time was neither due to a slow access to its binding site nor due to the depletion of stored Ca2+. Ryanodine more potently inhibited the second or the subsequent contraction due to caffeine than the first one even after the agent was removed from the bath after first caffeine. The enhancement of ryanodine-effect depended on the history of Ca2+ release but not on an increase in cytoplasmic Ca2+. The data suggest that an opening of Ca2+ release channel enhances the interaction of ryanodine with the channel.     

黄体酮对离体家兔气管平滑肌收缩活动的影响

目的：研究黄体酮对离体家兔气管平滑肌收缩活动的影响。方法：采用家兔离体气管平滑肌标本,观察黄体酮对ACh及Ca-Cl2量效曲线的影响,同时观察在无钙液中加入CaCl2时单剂量Ach诱发标本双时相收缩反应的影响。结果：黄体酮能使ACh及CaCl2量效曲线明显压低,最大反应降低,且能够抑制ACh引起的第1时相收缩,对第Ⅱ时相收缩作用无明显影响。且黄体酮对ACh量效曲线的影响是上皮依赖性的。结论：黄体酮对离体气管平滑肌的松弛作用与抑制电压依赖性钙通道(PDC)和ACh引起的细胞内Ca^2 释放及上皮细胞的作用有关。     

提高胞外钾引起的蛙骨骼肌咖啡因挛缩增强

用蛙胫前肌小束为材料, 研究了提高胞外钾[K+]O对咖啡因挛缩的作用.[K+]O从2 mmol/L提高到10或25 mmol/L, 由3 mmol/L咖啡因引起的挛缩明显增强.以PKC/PC (PKC和PC分别为在高钾和正常钾条件下的咖啡因挛缩)表示的咖啡因挛缩增强, 依赖[K+]O和高钾作用时间.随着10 mmol/L [K+]O作用时间延长, 直至10 min, 增强逐渐增加.但是, 25 mmol/L [K+]O作用1 min时增强达到最大, 然后下降到对照.PKC/PC变化时程不能用高钾引起的去极化解释, 而与由相似[K+]O引起的胞浆自由钙变化时程相符.提示, 至少在蛙骨骼肌, 高钾引起的咖啡因挛缩增强主要是由胞浆自由钙升高引起的.     

Effect of electrical stimulation on intracellular triacylglycerol in isolated skeletal muscle

The contribution of intracellular triacylglycerol (TG) as a substrate for skeletal muscle during electrical stimulation is equivocal. Therefore, the purpose of this study was to investigate the effect of electrical stimulation on the TG content in the isolated intact rat flexor digitorum brevis skeletal muscle preparation by use of two different stimulation protocols. Muscles were electrically stimulated for 1 h either continuously at 1 Hz or intermittently (30 s on, 60 s off) at 5 Hz while incubated in 21 degrees C Krebs bicarbonate buffer (pH 7.4) that contained 11 mM glucose. Control muscles were either frozen immediately after excision or incubated for 1 h. TG content was significantly decreased (P less than 0.05) compared with control concentrations in both stimulated muscle groups, with the greatest reduction (60%) occurring after 5-Hz intermittent stimulation. These data indicate that intramuscular TG is hydrolyzed in response to electrical stimulation in the isolated flexor digitorum brevis muscle preparation. In addition, the type of stimulation (higher frequency intermittent vs. lower frequency continuous) employed influences the amount of intracellular TG hydrolyzed.     

Optically controlled contraction of photosensitive skeletal muscle cells

As the skeletal muscle cell is an efficient force transducer, it has been incorporated in bio-microdevices using electrical field stimulation for generating contractile patterns. To improve both the spatial and temporal resolutions, we made photosensitive skeletal muscle cells from murine C2C12 myoblasts, which express channelrhodopsin-2 (ChR2), one of archaea-type rhodopsins derived from green algae Chlamydomonas reinhardtii. The cloned ChR2-expressing C2C12 myoblasts were made and fused with untransfected C2C12 to form multinucleated myotubes. The maturation of myotubes was facilitated by electrical field stimulation. Blue LED light pulse depolarized the membrane potential of a ChR2-expressing myotube and eventually evoked an action potential. It also induced a twitch-like contraction in a concurrent manner. A contraction pattern was thus made with a given pattern of LED pulses. This technique would have many applications in the bioengineering field, such as wireless drive of muscle-powered actuators/microdevices.