Regulation of phosphorylase B to A conversion in muscle

Metabolic effects of beta-adrenoceptor blockade on skeletal muscle at rest and during exercise

beta-Adrenoceptor antagonists influence the metabolic responses in man at rest and during exercise. Impaired working capacity and muscular fatigue have been reported in patients on beta-blockers and this could be due to an altered substrate supply to the muscles. The results from several studies show that the main effect of beta-blockade on metabolism is decreased lipolysis, with less fat available to the muscles. This results in an increased carbohydrate demand to maintain an unchanged aerobic metabolism, and liver and muscle glycogen stores are more rapidly depleted. beta-blockade also results in decreased lactate release from the muscles, probably due to a membrane effect and/or changed perfusion. It is concluded that beta-blockade a) decreases fat metabolism in the muscle, which secondarily increases the use of carbohydrates during exercise, resulting in earlier hypoglycaemia and/or depletion of muscle glycogen with reduction of the working capacity, b) impairs lactate transport from the muscle but does not cause lactate accumulation within the muscle which could be responsible for muscular fatigue.

beta-Adrenoceptor blockade and exercise: effects on endurance and physical training

beta-adrenoceptor antagonists influence almost all haemodynamic and metabolic actions in the body. High levels of sympathetic stimulation accompany aerobic exercise and it is known that beta-blockade results in a decreased working capacity. Furthermore it has also been questioned whether beta-blockade inhibits the normal response to physical training. Although adrenergic mechanisms are involved in muscle and liver glycogen breakdown, beta-blockade does not seem to reduce glycogen utilisation during exercise. Both selective and non-selective beta-blockade inhibit lipolysis and result in less free fatty acids being available for muscle utilisation. Surgical and chemical sympathectomy in animals has been shown to inhibit the responses to physical training but results are now available showing that beta-adrenergic blockade does not prevent the effect of physical conditioning in patients treated with propranolol. It is concluded that beta-blockade during prolonged exercise a) does not reduce oxygen uptake by the working muscles b) decreases fat metabolism, which secondarily increases the use of carbohydrates, resulting in earlier hypoglycaemia and/or depletion of muscle glycogen with reduction in working capacity c) does not inhibit central and peripheral adaptation to physical conditioning.

Re-feeding after starvation involves a temporal shift in the control site of glycogen synthesis in rat muscle

The starved-to-fed transition is accompanied by rapid glycogen deposition in skeletal muscles. On the basis of recent findings [Bräu, Ferreira, Nikolovski, Raja, Palmer and Fournier (1997) Biochem. J. 322, 303-308] that during recovery from exercise there is a shift from a glucose 6-phosphate/phosphorylation-based control of glycogen synthesis to a phosphorylation-based control alone, this paper seeks to establish whether a similar shift occurs in muscle during re-feeding after starvation in the rat. Chow re-feeding after 48 h of starvation resulted in glycogen deposition in all muscles examined (white, red and mixed quadriceps, soleus and diaphragm) to levels higher than those in the fed state. Although the early phase of re-feeding was associated with increases in glucose 6-phosphate levels in all muscles, there was no accompanying increase in the fractional velocity of glycogen synthase except in the white quadriceps muscle. This finding, together with the observation that the fractional velocity of glycogen synthase in most muscles was already high in the starved state, suggests that in the initial phase of glycogen deposition the phosphorylation state of the enzyme may be adequate to support net glycogen synthesis. In the later phase of re-feeding, the progressive decrease in the fractional velocity of glycogen synthase in association with a decrease in the rate of glycogen deposition suggests that glycogen synthesis is controlled primarily by changes in the phosphorylation state of glycogen synthase. In conclusion, this study suggests that there is a temporal shift in the site of control of glycogen synthesis as glycogen deposition progresses during re-feeding after starvation.

Regulation of glycogen synthase and phosphorylase during recovery from high-intensity exercise in the rat

The aim of this study was to determine the role of the phosphorylation state of glycogen synthase and glycogen phosphorylase in the regulation of muscle glycogen repletion in fasted animals recovering from high-intensity exercise. Groups of rats were swum to exhaustion and allowed to recover for up to 120 min without access to food. Swimming to exhaustion caused substantial glycogen breakdown and lactate accumulation in the red, white and mixed gastrocnemius muscles, whereas the glycogen content in the soleus muscle remained stable. During the first 40 min of recovery, significant repletion of glycogen occurred in all muscles examined except the soleus muscle. At the onset of recovery, the activity ratios and fractional velocities of glycogen synthase in the red, white and mixed gastrocnemius muscles were higher than basal, but returned to pre-exercise levels within 20 min after exercise. In contrast, after exercise the activity ratios of glycogen phosphorylase in the same muscles were lower than basal, and increased to pre-exercise levels within 20 min. This pattern of changes in glycogen synthase and phosphorylase activities, never reported before, suggests that the integrated regulation of the phosphorylation state of both glycogen synthase and phosphorylase might be involved in the control of glycogen deposition after high-intensity exercise.

Investigation of the effects of beta-2 stimulation on free fatty acids in man

In this study we present evidence that lipolysis in man is under beta-2 adrenergic control and that beta-2 stimulation produces a characteristic profile of individual free fatty acid (FFA) release. Twelve healthy volunteers received infusions of placebo (N Saline), terbutaline (a selective beta-2 agonist) and dilevalol (a new non-selective beta-blocker with beta-2 agonist activity). Plasma FFA concentrations during and after the infusions were measured using gas chromatography. A significant rise in total and individual FFAs was seen after 30 min of terbutaline infusion. This was most marked for oleic acid. Total and individual FFA concentrations also rose after 30 min of dilevalol infusion; this was only significant for oleic acid and was approximately 15% of the rise induced by terbutaline infusion. Placebo infusion did not cause any significant changes in FFA levels.

A comparison of the effects of flosequinan, a new vasodilator, and propranolol on sub-maximal exercise in healthy volunteers

1. The effects of steady state flosequinan, a new vasodilator, and propranolol, on glucose mobilisation, lipolysis and plasma potassium concentration during sub-maximal exercise testing were investigated in a double-blind, randomised, three-way crossover study in 12 healthy volunteers. 2. Plasma glucose, potassium and free fatty acid concentration during and after exercise on flosequinan were similar to those on placebo. Exercise heart rates were 7% (+9.2 beats min-1) higher on flosequinan compared with placebo (P less than 0.05). During exercise on propranolol plasma glucose concentrations were comparable with those on placebo but plasma potassium concentrations were higher (mean increase 0.26 mmol l-1, P less than 0.01) whereas free fatty acid concentrations were lower (mean decrease 0.10 mmol 1-1, P less than 0.01). As expected the heart rate on exercise was 25% less (-35 beats min-1) on propranolol (P less than 0.05). 3. These data suggest that, in contrast to propranolol, flosequinan does not adversely affect the mobilisation of the two major sources of energy during sub-maximal exercise.

Skeletal muscle glucolysis, glycogenolysis and glycogen phosphorylase during electrical stimulation in man

Phosphorylase activity, glycogenolytic and glucolytic rates were estimated in human quadriceps muscle during electrical stimulation at 20 Hz. Two stimulation periods of 10 s duration were separated by a pause of 60 s. The blood circulation to the leg was intact or occluded during the experiment. ATP turnover rates and force production were of the same order during the two contraction periods both with and without intact blood flow. Also the increase in phosphorylase a activity (from approximately 30% to approximately 65%) was the same during the contraction periods. Glycogenolytic and glucolytic rates were however about 30% higher (P less than 0.05) during the second contraction compared with the first when circulation was occluded, but similar when the circulation was intact. During the 60 s rest period, the phosphocreatine (PCr) was maintained at a low level and inorganic phosphate (Pi) remained increased under occluded circulation while PCr was resynthesized in the rest period with intact circulation. We conclude that the increased glycogenolytic rate observed during the second contraction with occluded blood circulation was due to the high [Pi] in the muscle and that the increased glucolytic rate was caused by high [Pi] and low [PCr]. In the rest period with anoxia the glycogenolysis was completely inhibited and glucolysis was inhibited by 95% in spite of the changes in [PCr] and [Pi].

Glyceryl trinitrate inhibits phosphatidylinositol hydrolysis and protein kinase C activity in bovine mesenteric artery

The effect of glyceryl trinitrate (GTN) on relaxation, cGMP levels, phosphorylase a activity, phosphatidylinositol hydrolysis and protein kinase C activity was studied on isolated bovine mesenteric arteries (BMA). Two concentrations of GTN were tested, 0.1 nM representing a high affinity component and 1 microM representing a low affinity component of the GTN induced relaxation of BMA, giving a relaxation of 20% and 60% and a 2-fold and 5-fold increase in cGMP, respectively. Phosphatidylinositol hydrolysis and protein kinase C activity were significantly, and to the same extent, reduced at both concentrations tested, whereas the phosphorylase a activity was significantly reduced at the higher concentration only, which might indicate a reduction of the free intracellular Ca2+-concentration at high concentrations of GTN. It is concluded that a therapeutically relevant concentration (0.1 nM) of GTN induces relaxation and an increase in cGMP in bovine mesenteric arteries. The relaxation seems to be associated with an inhibition of phosphatidylinositol hydrolysis and a reduction of the protein kinase C activity.

Effect of glyceryltrinitrate and 8-Br-cGMP on tension and phosphorylase a activity in vascular smooth muscle

The aim of the present study was to examine the effect of glyceryltrinitrate (GTN) and 8-Br-cGMP on tension and cytosolic calcium concentration in pre-contracted bovine mesenteric arteries (BMA). The activity of glycogen phosphorylase a was used as a measure of the cytosolic calcium concentration. The activity of this enzyme is regulated by the cytosolic calcium concentration and/or cAMP. Since the cAMP level was not found to be affected by GTN-treatment, the use of phosphorylase a activity to monitor changes in the cytosolic calcium concentration can be justified. The vessels were contracted with phenylephrine (10 microM) or 100 mM K+-depolarization, which caused an increase in phosphorylase a activity. Addition of 1 microM GTN to the phenylephrine-contracted vessels resulted in a 3-4-fold rise in intracellular cGMP level, which was accompanied by a large decrease in tension and phosphorylase a activity. The K+-depolarized vessels, on the other hand, were largely resistant to the relaxant action of GTN, and there was only a slight reduction of the phosphorylase a activity. In phenylephrine-contracted vessels, made tolerant to GTN by incubation at elevated pH in the presence of GTN (0.44 mM), no changes in tension and phosphorylase a activity were seen after stimulation with a test dose of GTN (1 microM). The cGMP response was also markedly blunted in the tolerant vessels. Relaxation of phenylephrine-contracted BMA induced by 8-Br-cGMP (0.5 mM) was also accompanied by a reduction in phosphorylase a activity.(ABSTRACT TRUNCATED AT 250 WORDS)

Energy metabolism and transduction in smooth muscle

Early investigations into the nature of the coupling between energy transduction and metabolism in smooth muscle, particularly from the laboratories of Bülbring and Lundholm, suggested that specific metabolic pathways could independently supply energy for ion transport and actin-myosin interactions. Subsequent work has solidified the concept that oxidative phosphorylation is specifically coupled to tension generation and maintenance, whereas, aerobic glycolysis is not only a vital characteristic of smooth muscle metabolism, but also is likely to be independently coupled to Na-K transport at the plasmalemma. The independence of oxidative and glycolytic metabolism is reflected as a compartmentation of carbohydrate metabolism in the porcine carotid artery. The coupling of these independent metabolic pathways with specific energy utilizing processes, indicates a means by which energy production and transduction can be closely and efficiently regulated. The coupling of glycogenolysis to mitochondrial respiration may have evolved as a direct response to the energetic needs of VSM. That is, the large glycogenolytic response in the initial minutes of stimulation may be necessary to maximize the cellular production of ATP during the presteady state. Likewise, the coupling between aerobic glycolysis and Na-K transport indicates a sensitive and efficient means of coordinating energy metabolism with ion transport at the membrane level. Additionally, the regulation of substrate supply, i.e. glucose transport, also may be closely coordinated with changes in ion transport. One may speculate that alterations in the microenvironment of each compartment can independently regulate intermediary metabolism and therefore allow the cell to quickly and efficiently respond to localized stimuli. Thus, stimulation of Na-K transport could effectively regulate energy production at the membrane level without mobilizing or competing with the energy transduction of other cellular processes. This compartmentation of energy utilization may be highly advantageous, since oxidative metabolism is closely coordinated with mechanical activity and therefore regulation of blood flow. Future investigations will attempt to elucidate which intracellular signals which are responsible for the regulation of these functionally independent compartments of energy metabolism and transduction in VSM. In more general terms, our findings provide a basis from which future questions concerning the regulation of cellular metabolism must be directed. The cellular cytoplasm can no longer be envisioned as a homogeneous compartment, but rather a complex array of functional subcompartments which may be individual

Influence of anoxia and dinitrophenol on Ca2+ efflux and phosphorylase a activity in rabbit colon smooth muscle

It was observed in earlier studies that when the phosphorylase alpha activity of rabbit colon smooth muscle was increased by anoxia or 2,4-dinitrophenol (DNP), the calcium content of the mitochondrial fraction decreased. Despite this, under basal conditions there was no significant increase in the Ca2+ content in the fraction consisting of microsomes and cytoplasm. In the present study it was therefore investigated whether mitochondrial Ca2+ released by anoxia and DNP is translocated from the smooth muscle cells into the extracellular fluid. The Ca2+ efflux from rabbit colon into a Ca2+-free Krebs-Ringer bicarbonate buffer was measured by using a Ca2+-selective electrode. Both anoxia and DNP (6.6 X 10(-5)M) increased the Ca2+ efflux from the smooth muscle cells. The local anaesthetic D-mepivacaine, at a concentration of 1 X 10(-3)M, reduced the increase in Ca2+ efflux and simultaneously enhanced the anoxic or DNP-induced rise in phosphorylase alpha activity. The replacement of external Na+ by choline was found to reduce the basal Ca2+ efflux and to moderately increase change in the Ca2+ efflux, but the increase in phosphorylase alpha activity was greater than in the physiological buffer containing 137 mM Na+. These observations support the suggestion that anoxia and DNP, by releasing Ca2+ from the mitochondria, increase the phosphorylase alpha activity of smooth muscle.

Reduced cAMP levels and glycogen phosphorylase activation in isoproterenol perfused SHR myocardium

The effect of isoproterenol perfusion on cAMP levels and phosphorylase activity was investigated in the spontaneously hypertensive rat (SHR) and Kyoto Wistar normotensive control rat (WKY) heart. The basal force of contraction in physiological salt solution perfused hearts was comparable between SHR and WKY. However, the force of contraction in response to 10 nM isoproterenol perfusion was decreased approximately 20-30% in SHR heart as compared to WKY heart. Basal cAMP levels were reduced in SHR hearts as compared to WKY hearts. Isoproterenol perfusion resulted in an increase in cAMP levels over the basal cAMP values which was 50% and 100% in SHR and WKY hearts, respectively. Basal phosphorylase activity was higher in SHR hearts as compared to WKY hearts. However, the percentage increase in phosphorylase activity by isoproterenol perfusion over the basal values was approximately 400% in WKY hearts and only 200% in SHR hearts. The ouabain-sensitive (Na+, K+)-ATPase activity, Ca2+ binding in the absence of ATP, sialic acid content, and 5'-nucleotidase activity of purified cardiac plasma membranes was not altered in SHR as compared to WKY. These results would suggest beta-adrenergic mediated adenylate cyclase stimulation is decreased in SHR myocardium while other plasma membrane properties and associated enzymes may not be altered.

Activation of phosphorylase by anoxia and dinitrophenol in rabbit colon smooth muscle: relation to release of calcium from mitochondria

The effect of anoxia or 2,4-dinitrophenol (DNP) on the phosphorylase a activity and the calcium content in subcellular fractions from rabbit colon smooth muscle was studied. Anoxia for 15 min. as well as DNP (6.6 X 10(-5) M) for 5 min. increased the phosphorylase a activity. The calcium content in the mitochondrial subfraction, prepared from the anoxic- or DNP-treated intact muscle and determined by atomic absorption spectroscopy, was reduced. The calcium content in the nuclear and the microsomal fractions was not changed in preparations with a normal Ca-content. When the muscle was incubated for 60 min. in a Ca2+-free medium containing 2.0 mM EGTA, the calcium content in the mitochondrial fraction was reduced to 38% of the control. This calcium level was still further reduced and the phosphorylase a activity was increased by DNP in this "Ca-poor" muscle. In these preparations the Ca-content of the microsomal + supernatant fraction increased. Only when the muscle was incubated, initially, in an anoxic medium containing 0.1 mM Ca2+ for 120 min. and, subsequently, in an oxygenated medium containing 0.1 mM Ca2+ for 20 min., DNP failed to activate phosphorylase and to decrease the calcium content in the mitochondrial fraction. These results indicate that mitochondrial Ca2+ release is one of the regulatory factors of the anoxic-induced glycogenolysis.

Regulation of phosphorylase kinase in rat ventricular myocardium. Role of calmodulin

Conversion of phosphorylase b to a which is catalyzed by the enzyme phosphorylase kinase is known to require Ca++. Trifluoperazine, an inhibitor of calmodulin-dependent enzymes, was utilized in the present study to clarify the role in vivo of calcium-calmodulin regulation of phosphorylase kinase. Twenty-minute preperfusion of isolated rat ventricles with 10(-5) M trifluoperazine had no effect on basal levels of phosphorylase a but significantly attenuated phosphorylase activation induced by either calcium (3.75 mM) or isoproterenol (3 x 10(-9) M, 3 x 10(-8) M). The positive inotropic effect of both agents and cyclic adenosine 3',5'-monophosphate (cAMP) levels were not altered by trifluoperazine in the perfused hearts. In addition, no effects of 10(-5) M trifluoperazine were noted on beta-adrenergic receptor binding of [3H](+/-)carazolol or on adenylate cyclase activity. In vitro studies with partially purified rat cardiac phosphorylase kinase demonstrated 1.5- to 3-fold stimulation by exogenous calmodulin. The addition of 10(-5) M trifluoperazine prevented calmodulin stimulation but had little effect on activity in the absence of exogenous calmodulin. The present results suggest that reversible binding of calcium-calmodulin may represent a physiological means for regulating phosphorylase kinase activity in rat cardiac muscle.

Physiological and biochemical effects of iron deficiency on rat skeletal muscle

Young rats were made iron deficient by feeding them a low-iron diet for 8 wk. Iron deficiency resulted in a 50% decrease in cytochrome c and cytochrome oxidase and a 26% decrease in mitochondrial glycerol-3-phosphate dehydrogenase activity in skeletal muscle. Respiratory capacity of muscle homogenates was reduced 55%. After 8 days of iron treatment, respiratory capacity, cytochrome c, cytochrome oxidase, and glycerol-3-phosphate dehydrogenase had returned 50% toward normal. Maximum O2 uptake of contracting hindlimb muscles averaged 8.5 mumol O2.min-1.g-1 in control, 4.3 mumol O2.min-1.g-1 in iron-deficient, and 6.2 mumol O2.min-1.g-1 in the 8-day-iron-repleted rats. Muscle fatigue during 10 min of stimulation was greater in the iron-deficient group. Lactate concentration in red muscle was higher in iron-deficient than in control rats after stimulation. The muscle fatigue and lactate responses returned 50% toward normal during 8 days of iron treatment. We conclude that iron deficiency results in a decrease in skeletal muscle capacity for aerobic metabolism and, by this mechanism, increases susceptibility to fatigue.

Role of epinephrine for muscular glycogenolysis and pancreatic hormonal secretion in running rats

We have previously shown that during swimming muscular glycogen breakdown was diminished and plasma glucagon and insulin were lower and higher, respectively, in adrenodemedullated rats compared to controls. These findings might be due to a lower work intensity or higher efficiency in adrenodemedullated rats than in controls. Furthermore, they might be due to either an acute or a chronic influence of epinephrine. Rats were adrenodemedullated (DM) or sham-operated (C). They were chronically cannulated and either rested or ran in a metabolism chamber for 45 min. Running DM rats had either saline (DM-S) or epinephrine (normalizing the concentration in plasma) (DM-E) infused. During running, oxygen uptake was identical in C and DM rats. Muscular glycogen breakdown was similar in DM-E and C rats and higher than in DM-S rats. Blood glucose, lactate, and heart rate increased in C and DM-E, but not in DM-S rats. In spite of the differences in blood glucose, plasma insulin was the same in all groups and plasma glucagon increased identically in all running rats. Plasma FFA and liver glycogen were similar in all groups. In conclusion. in running rats, epinephrine exerts an acute enhancing effect on muscular glycogenolysis, glucagon secretion, and heart rate and an acute depressing effect on insulin secretion.

Comparison of the secretory processes in the parotid and sublingual glands of the mouse. 1. Regulation of the secretory processes

1. Secretion from the mucous sublingual gland of the mouse has been investigated and compared with the serous parotid gland. The influence of acetylcholine, noradrenalin and adrenalin on the secretion of glycoproteins (e.g. mucins) and proteins (e.g. amylase) from these glands in vitro, and the involvement of cyclic AMP and Ca2+ has been studied. 2. Secretion from the parotid gland could be stimulated by both acetylcholine and the catecholamines. It appears that cyclic AMP plays an important role in the adrenergic secretory process, but not in the cholinergic-induced secretion. In the latter case, exogenous Ca2+ strongly increased the secretion. 3. Mucin secretion from the sublingual gland could be affected by acetylcholine in the presence of exogenous Ca2+. Noradrenalin and adrenalin induced only a slow mucin secretion and, for this secretory process, exogenous Ca2+ is also required. Though cyclic AMP is present in the sublingual gland, no influence on its level could be detected in this gland after stimulation of the adrenergic beta-receptor, whereas, in contrast to the parotid gland, dibutyryl cyclic AMP induced only a slow secretion. Because it was observed that the sublingual gland of the mouse is not innervated sympathetically, it seems reasonable to suppose that the catecholamines stimulate the mucin secretion from this gland via hormonal receptors and not via the adrenergic beta-receptor. 4. The protein secretion from the sublingual gland could be stimulated by both acetylcholine and the catecholamines. An involvement of cyclic AMP in this process was not observed. Addition of exogenous Ca2+ is less important, as was found for the mucin secretion. So it has been concluded that protein and mucin secretion from the sublingual gland are regulated via different pathways.

Phosphorylase kinase mediating the effects of cyclic AMP in muscle

In the classic view of the control of phosphorylase b to a conversion by catecholamines, cyclic AMP acts as the second messenger stimulating the activity of cyclic AMP-dependent protein kinase to covalently modify phosphorylase kinase. Phosphorylation of phosphorylase kinase converts this enzyme form with a nonactivated to an activated form with a markedly higher activity at pH 7. There is now considerable evidence that the activity of phospphorylase kinase is also regulated by changeds in the Ca-2+ concentration. The activity of both nonactivated and activated phosphorylase kinase is stimulated by Ca-2+ in the range of concentrations that have been reported to occur in the sacroplasm of contracting muscle, with the activated pphosphorylase kinase having a lower K-alpha for Ca-2+. Thus there are at leaset two mechanisms for the regulation of phosphorylase kinase activity in muscle. These mechanisms may act independently or in concert in controlling glycogenolysis stimulated by catecholamines, anoxia, or tetanic electrical stimulation...