The effect of prolonged restriction of physical activity on exercise performance in dogs.

2-months restriction of physical activity of dogs markedly reduced their capacity for prolonged running. The rate of exercise-induced Tre increases was significantly higher in the cage-confined dogs in comparison with controls. At the point of exhaustion blood glucose concentration and muscle glycogen content were similar in the control and cage-confined animals, in spite of the much shorter time of exercise until exhaustion in the latter. The exercise-induced increases in plasma FFA concentration were considerably lower in dogs after prolonged inactivity period in spite of the greater activation of the adrenergic system. It is concluded, that there are several factors which may contribute to the reduction of the ability of cage-confined dogs to perform prolonged physical exercise. The most important seems to be the diminished muscle glycogen content, modifications in exercise metabolism and exercise-induced hyperthermia.     

Influence of fasting on glycogen depletion in rats during exercise

We recently observed that a 24-h fasted group of rats could run longer than an ad libitum fed control group before becoming exhausted. Because of the demonstrated importance of glycogen levels and free fatty acid availability during endurance exercise, we have investigated several parameters of carbohydrate and lipid metabolism in exercised and nonexercised rats that were either fed ad libitum or fasted for 24 h. A 24-h fast depleted liver glycogen, lowered plasma glucose concentration, decreased muscle glycogen levels, and increased free fatty acid and beta-hydroxybutyrate concentrations in plasma. During exercise the fasted group had lower plasma glucose concentration, higher plasma concentration of free fatty acids and beta-hydroxybutyrate, and a lower muscle glycogen depletion rate than did the ad libitum fed group. Since fasted rats were able to continue running even when plasma glucose had dropped to levels lower than those of fed-exhausted rats, it seems unlikely that blood glucose level, per se, is a factor in causing exhaustion. These results suggest that fasting increases fatty acid utilization during exercise and the resulting "glycogen sparing" effect may result in increased endurance.     

Overexpression of protein targeting to glycogen in cultured human muscle cells stimulates glycogen synthesis independent of glycogen and glucose 6-phosphate levels

There is growing evidence that glycogen targeting subunits of protein phosphatase-1 play a critical role in regulation of glycogen metabolism. In the current study, we have investigated the effects of adenovirus-mediated overexpression of a specific glycogen targeting subunit known as protein targeting to glycogen (PTG) in cultured human muscle cells. PTG was overexpressed both in muscle cells cultured at high glucose (glycogen replete) or in cells incubated for 18 h in the absence of glucose and then incubated in high glucose (glycogen re-synthesizing). In both glycogen replete and glycogen resynthesizing cells, PTG overexpression caused glycogen to be synthesized at a linear rate 1-5 days after viral treatment, while in cells treated with a virus lacking a cDNA insert (control virus), glycogen content reached a plateau at day 1 with no further increase. In the glycogen replete PTG overexpressing cells, glycogen content was 20 times that in controls at day 5. Furthermore, in cells undergoing glycogen resynthesis, PTG overexpression caused a doubling of the initial rate of glycogen synthesis over the first 24 h relative to cells treated with control virus. In both sets of experiments, the effects of PTG on glycogen synthesis were correlated with a 2-3-fold increase in glycogen synthase activity state, with no changes in glycogen phosphorylase activity. The alterations in glycogen synthase activity were not accompanied by changes in the intracellular concentration of glucose 6-phosphate. We conclude that PTG overexpression activates glycogen synthesis in a glucose 6-phosphate-independent manner in human muscle cells while overriding glycogen-mediated inhibition. Our findings suggest that modulation of PTG expression in muscle may be a mechanism for enhancing muscle glucose disposal and improving glucose tolerance in diabetes.     

Carbohydrate nutrition before, during, and after exercise

The role of dietary carbohydrates (CHO) in the resynthesis of muscle and liver glycogen after prolonged, exhaustive exercise has been clearly demonstrated. The mechanisms responsible for optimal glycogen storage are linked to the activation of glycogen synthetase by depletion of glycogen and the subsequent intake of CHO. Although diets rich in CHO may increase the muscle glycogen stores and enhance endurance exercise performance when consumed in the days before the activity, they also increase the rate of CHO oxidation and the use of muscle glycogen. When consumed in the last hour before exercise, the insulin stimulated-uptake of glucose from blood often results in hypoglycemia, greater dependence on muscle glycogen, and an earlier onset of exhaustion than when no CHO is fed. Ingesting CHO during exercise appears to be of minimal value to performance except in events lasting 2 h or longer. The form of CHO (i.e., glucose, fructose, sucrose) ingested may produce different blood glucose and insulin responses, but the rate of muscle glycogen resynthesis is about the same regardless of the structure.     

鳜对葡萄糖和糊精利用差异比较研究

研究通过比较鳜(Siniperca chuatsi)对不同碳水化合物的利用差异, 探究肉食性鱼类对碳水化合物利用的分子机制。按照1670 mg/kg剂量对鳜灌喂葡萄糖和糊精后, 分别在0、1h、2h、3h、4h、8h、12h和24h收集水样、血浆、肝脏和肌肉, 检测尿糖、血糖、血甘油三酯、血胰岛素、肝糖原、肌糖原含量及糖代谢相关基因表达水平等指标。结果显示: (1) 灌喂后1—12h内, 两组鳜相比, 葡萄糖组尿糖显著高于糊精组, 血糖及胰岛素含量在两组间无显著差异; (2) 两组鳜甘油三酯含量在2h时达到最大值, 糊精组甘油三酯含量在4h时显著高于葡萄糖组, 糊精组肝糖原含量在1h时显著高于葡萄糖组, 且糊精组肌糖原含量在24h内均显著高于葡萄糖组; (3) 灌喂后1h, 灌喂糊精组葡萄糖激酶(Glucokinase, GK)、脂肪酸合成酶(Fatty Acid Synthetase, FAS)、乙酰辅酶A羧化酶Ⅰ型(Acetyl-CoA Carboxylase Type Ⅰ, ACC1)、柠檬酸合成酶(Citroyl Synthetase, CS)基因表达水平显著高于葡萄糖组, 而在灌喂后8h, 糊精组糖原合酶(Glycogen Synthase, GS)和CS基因表达水平却显著低于葡萄糖组。结果表明, 肉食性鱼类鳜摄入糖后可以促进糖原和脂肪的合成, 转化为糖原和甘油三酯, 从而减少未利用糖的排出, 且鳜对葡萄糖的利用效率低于糊精。     

Metabolic effects of testosterone during prolonged physical exercise and fasting

Previous studies have shown a decrease in plasma testosterone during prolonged physical exercise and 72 h fasting in rats. To determine whether this hormonal change has an influence upon energy metabolism, two experiments were carried out, in which the plasma levels of testosterone were elevated during prolonged physical exercise and fasting in male wistar rats. The effects of acute and chronic increases in the levels of circulating testosterone were studied, on the one hand after human chorionic gonadotropin (H.C.G.) injection, and on the other by prolonged testosterone perfusion with an osmotic minipump. Blood and tissue sampling were performed to evaluate blood glucose, alanine, and lactate, and tissue glycogen. The results in fed and rest control rats showed no changes in blood parameters under the effect of hypertestosteronemia but there was an increase in muscle glycogen after testosterone perfusion. In 72 h fasted rats both types of hypertestosteronemia were associated with a decrease in blood alanine and lactate ranging from 25% to 35%. Only testosterone perfusion was associated with higher concentrations of muscle glycogen. After 7 h of treadmill running, testosterone perfusion and H.C.G. injection induced a 35% decrease in blood alanine and a slight decrease in blood glucose, with no change in other parameters. Whereas an elevation in the level of testosterone can induce muscle glycogen compensation in the fed resting state, it cannot counteract the exhaustion of muscle glycogen during running.     

Control of glycogen synthesis is shared between glucose transport and glycogen synthase in skeletal muscle fibers

The effects of transgenic overexpression of glycogen synthase in different types of fast-twitch muscle fibers were investigated in individual fibers from the anterior tibialis muscle. Glycogen synthase was severalfold higher in all transgenic fibers, although the extent of overexpression was twofold greater in type IIB fibers. Effects of the transgene on increasing glycogen and phosphorylase and on decreasing UDP-glucose were also more pronounced in type IIB fibers. However, in any grouping of fibers having equivalent malate dehydrogenase activity (an index of oxidative potential), glycogen was higher in the transgenic fibers. Thus increasing synthase is sufficient to enhance glycogen accumulation in all types of fast-twitch fibers. Effects on glucose transport and glycogen synthesis were investigated in experiments in which diaphragm, extensor digitorum longus (EDL), and soleus muscles were incubated in vitro. Transport was not increased by the transgene in any of the muscles. The transgene increased basal [(14)C]glucose into glycogen by 2.5-fold in the EDL, which is composed primarily of IIB fibers. The transgene also enhanced insulin-stimulated glycogen synthesis in the diaphragm and soleus muscles, which are composed of oxidative fiber types. We conclude that increasing glycogen synthase activity increases the rate of glycogen synthesis in both oxidative and glycolytic fibers, implying that the control of glycogen accumulation by insulin in skeletal muscle is distributed between the glucose transport and glycogen synthase steps.     

The effects of starvation and force-feeding on the metabolism of the Northern pike, Esox lucius L.

The effects of starvation and force-feeding on certain tissue and blood constituents were studied in the Northern pike, Esox lucius L. Starvation resulted in a reduction of liver and muscle glycogen and liver lipid. Blood glucose concentration and haematocrit were reduced, total plasma cholesterol levels were increased, while the levels of plasma free fatty acids (FFA), amio acid nitrogen and protein remained unaltered. No significant changes were observed in either muscle protein, muscle water or the response to amino acid loading during the starvation period.
The force-feeding of pike starved for 3 months resulted in liver lipid and muscle glycogen being increased to levels higher than those observed in freshly-captured fish. Liver glycogen, however, increased to values only slightly higher than those of starved animals. Furthermore, while force-feeding had little effect on plasma FFA or protein concentrations, blood glucose, plasma cholesterol and haematocrit returned to the levels found in freshlycaptured fish and those of amino acid nitrogen were higher.
The results indicate that pike are well adapted for periods of prolonged starvation and that hepatic and extra-hepatic lipid and glycogen stores serve for metabolic needs during food shortage, while body protein is conserved. The endocrine basis for these changes in the tissue and blood constituents is discussed.     

Metabolic responses to exercise after fasting

Fasting before exercise increases fat utilization and lowers the rate of muscle glycogen depletion. Since a 24-h fast also depletes liver glycogen, we were interested in blood glucose homeostasis during exercise after fasting. An experiment was conducted with human subjects to determine the effect of fasting on blood metabolite concentrations during exercise. Nine male subjects ran (70% maximum O2 consumption) two counterbalanced trials, once fed and once after a 23-h fast. Plasma glucose was elevated by exercise in the fasted trial but there was no difference between fed and fasted during exercise. Lactate was significantly higher (P less than 0.05) in fasted than fed throughout the exercise bout. Fat mobilization and utilization appeared to be greater in the fasted trial as evidenced by higher plasma concentrations of free fatty acids, glycerol, and beta-hydroxybutyrate as well as lower respiratory exchange ratio in the fasted trial during the first 30 min of exercise. These results demonstrate that in humans blood glucose concentration is maintained at normal levels during exercise after fasting despite the depletion of liver glycogen. Homeostasis is probably maintained as a result of increased gluconeogenesis and decreased utilization of glucose in the muscle as a result of lowered pyruvate dehydrogenase activity.     

Effect of chronic metformin treatment of hepatic and muscle glycogen metabolism in KK mice.

Noninsulin-dependent diabetic KK mice, aged 90-100 days, with hyperinsulinemia and insulin resistance were treated with either metformin (N = 13) or water (control, N = 10) orally at a concentration of 50 mg/kg twice daily for 28 weeks. Age-matched nondiabetic Swiss Webster (SW) mice were also similarly treated. Liver and skeletal muscle glycogen synthase and phosphorylase enzymes were determined in all groups of mice. Both enzymes were significantly lower in control KK than in control SW mice. Metformin did not influence either of these enzymes in nondiabetic SW mice. However, it significantly increased the active form of glycogen synthase (a form) in both the liver and muscle of KK mice. Metformin also increased the active form of phosphorylase (a form) in the liver but not in the muscle of these mice. Hepatic glycogen content was similar in both control and metformin-treated KK mice. However, the muscle glycogen content was significantly higher in metformin-treated than in control KK mice. These data suggest that metformin preferentially stimulates glycogen synthesis in skeletal muscle, and this seems to be responsible for the observed improvement in fasting glucose and glucose response to an oral glucose load in KK mice.     

Effect of carbohydrate ingestion on exercise metabolism

Five male cyclists were studied during 2 h of cycle ergometer exercise (70% VO2 max) on two occasions to examine the effect of carbohydrate ingestion on muscle glycogen utilization. In the experimental trial (CHO) subjects ingested 250 ml of a glucose polymer solution containing 30 g of carbohydrate at 0, 30, 60, and 90 min of exercise; in the control trial (CON) they received an equal volume of a sweet placebo. No differences between trials were seen in O2 uptake or heart rate during exercise. Venous blood glucose was similar before exercise in both trials, but, on average, was higher during exercise in CHO [5.2 +/- 0.2 (SE) mmol/l] compared with CON (4.8 +/- 0.1, P less than 0.05). Plasma insulin levels were similar in both trials. Muscle glycogen levels were also similar in CHO and CON both before and after exercise; accordingly, there was no difference between trials in the amount of glycogen used during the 2 h of exercise (CHO = 62.8 +/- 10.1 mmol/kg wet wt, CON = 56.9 +/- 10.1). The results of this study indicate that carbohydrate ingestion does not influence the utilization of muscle glycogen during prolonged strenuous exercise.     

Impaired glucose homeostasis in mice lacking the alpha1b-adrenergic receptor subtype

To assess the role of the alpha1b-adrenergic receptor (AR) in glucose homeostasis, we investigated glucose metabolism in knockout mice deficient of this receptor subtype (alpha1b-AR-/-). Mutant mice had normal blood glucose and insulin levels, but elevated leptin concentrations in the fed state. During the transition to fasting, glucose and insulin blood concentrations remained markedly elevated for at least 6 h and returned to control levels after 24 h whereas leptin levels remained high at all times. Hyperinsulinemia in the post-absorptive phase was normalized by atropine or methylatropine indicating an elevated parasympathetic activity on the pancreatic beta cells, which was associated with increased levels of hypothalamic NPY mRNA. Euglycemic clamps at both low and high insulin infusion rates revealed whole body insulin resistance with reduced muscle glycogen synthesis and impaired suppression of endogenous glucose production at the low insulin infusion rate. The liver glycogen stores were 2-fold higher in the fed state in the alpha1b-AR-/- compared with control mice, but were mobilized at the same rate during the fed to fast transition or following glucagon injections. Finally, high fat feeding for one month increased glucose intolerance and body weight in the alpha1b-AR-/-, but not in control mice. Altogether, our results indicate that in the absence of the alpha1b-AR the expression of hypotalamic NPY and the parasympathetic nervous activity are both increased resulting in hyperinsulinemia and insulin resistance as well as favoring obesity and glucose intolerance development during high fat feeding.     

The effects of orthovanadate,vanadyl and peroxides of vanadate on glucose metabolism in skeletal muscle preparations in vitro

The insulin-like effects of various vanadium compounds (orthovanadate, vanadyl and peroxides of vanadate) on rates of glucose oxidation, lactate formation and glycogen synthesis were measured in isolated incubated epitrochlearis (mainly type 11 fibres) and soleus (mainly type I fibres) muscle preparations. There was a small stimulation of the rate of glucose utilisation in soleus muscle preparations in vitro by orthovanadate (1 mM). Orthovanadate or vanadyl, at 1 mM, had little effect on the rates of lactate formation or glycogen synthesis in isolated incubated epitrochlearis muscle preparations. In contrast, peroxides of vanadate (peroxovanadates, at 1 mM) significantly stimulated glucose utilisation in both soleus and epitrochlearis muscle preparations in vitro. The stimulation of the rate of glycogen synthesis was associated with an increase in the percentage of glycogen synthase in the I (or a) form. Peroxovanadates were administered in the drinking water to rats made insulin deficient by streptozotocin treatment. There was no decrease in the elevated level of blood glucose over an 8 day administration period. (Mol Cell Biochem 109: 157–162, 1992)     

Muscle glycogen inharmoniously regulates glycogen synthase activity, glucose uptake, and proximal insulin signaling

Insulin-stimulated glucose uptake and incorporation of glucose into skeletal muscle glycogen contribute to physiological regulation of blood glucose concentration. In the present study, glucose handling and insulin signaling in isolated rat muscles with low glycogen (LG, 24-h fasting) and high glycogen (HG, refed for 24 h) content were compared with muscles with normal glycogen (NG, rats kept on their normal diet). In LG, basal and insulin-stimulated glycogen synthesis and glycogen synthase activation were higher and glycogen synthase phosphorylation (Ser(645), Ser(649), Ser(653), Ser(657)) lower than in NG. GLUT4 expression, insulin-stimulated glucose uptake, and PKB phosphorylation were higher in LG than in NG, whereas insulin receptor tyrosyl phosphorylation, insulin receptor substrate-1-associated phosphatidylinositol 3-kinase activity, and GSK-3 phosphorylation were unchanged. Muscles with HG showed lower insulin-stimulated glycogen synthesis and glycogen synthase activation than NG despite similar dephosphorylation. Insulin signaling, glucose uptake, and GLUT4 expression were similar in HG and NG. This discordant regulation of glucose uptake and glycogen synthesis in HG resulted in higher insulin-stimulated glucose 6-phosphate concentration, higher glycolytic flux, and intracellular accumulation of nonphosphorylated 2-deoxyglucose. In conclusion, elevated glycogen synthase activation, glucose uptake, and GLUT4 expression enhance glycogen resynthesis in muscles with low glycogen. High glycogen concentration per se does not impair proximal insulin signaling or glucose uptake. "Insulin resistance" is observed at the level of glycogen synthase, and the reduced glycogen synthesis leads to increased levels of glucose 6-phosphate, glycolytic flux, and accumulation of nonphosphorylated 2-deoxyglucose.     

Hemodynamic and metabolic responses to exercise after adrenoceptor blockade in humans

The effects of acute alpha 1-adrenoceptor blockade with prazosin, beta 1-adrenoceptor blockade with atenolol, and nonselective beta-adrenoceptor blockade with propranolol were compared in a placebo-controlled crossover study of the hemodynamic and metabolic responses to acute exercise 2 h after prolonged prior exercise to induce skeletal muscle glycogen depletion, enhancing the dependence on hepatic glucose output and circulating free fatty acids (FFA). Plasma catecholamines were higher during exercise after, as opposed to before, glycogen depletion and were elevated further by all three drugs. Propranolol failed to produce a significant reduction in systolic blood pressure and elevated diastolic blood pressure. Atenolol reduced systolic blood pressure and did not change diastolic blood pressure. Both beta-blockers reduced FFA levels, but only propranolol lowered plasma glucose relative to placebo during exercise after glycogen depletion. In contrast, prazosin reduced systolic and diastolic blood pressures and resulted in elevated FFA and glucose levels. The results indicate important differences in the hemodynamic effects of beta 1-selective vs. nonselective beta-blockade during exercise after skeletal muscle glycogen depletion. Furthermore they confirm the importance of beta 2-mediated hepatic glucose production in maintaining plasma glucose levels during exercise. Acute alpha 1-blockade with prazosin induces reflex elevation of catecholamines, which in the absence of blockade of hepatic beta 2-receptors produces elevation of plasma glucose. The results suggest there is little role for alpha 1-mediated hepatic glucose production during exercise in humans.     

Increased insulin sensitivity and maintenance of glucose utilization rates in fetal sheep with placental insufficiency and intrauterine growth restriction

In this study we determined body weight-specific fetal (umbilical) glucose uptake (UGU), utilization (GUR), and production rates (GPR) and insulin action in intrauterine growth-restricted (IUGR) fetal sheep. During basal conditions, UGU from the placenta was 33% lower in IUGR fetuses, but GUR was not different between IUGR and control fetuses. The difference between glucose utilization and UGU rates in the IUGR fetuses demonstrated the presence and rate of fetal GPR (41% of GUR). The mRNA concentrations of the gluconeogenic enzymes glucose-6-phophatase and PEPCK were higher in the livers of IUGR fetuses, perhaps in response to CREB activation, as phosphorylated CREB/total CREB was increased 4.2-fold. A hyperglycemic clamp resulted in similar rates of glucose uptake and utilization in IUGR and control fetuses. The nearly identical GURs in IUGR and control fetuses at both basal and high glucose concentrations occurred at mean plasma insulin concentrations in the IUGR fetuses that were approximately 70% lower than controls, indicating increased insulin sensitivity. Furthermore, under basal conditions, hepatic glycogen content was similar, skeletal muscle glycogen was increased 2.2-fold, the fraction of fetal GUR that was oxidized was 32% lower, and GLUT1 and GLUT4 concentrations in liver and skeletal muscle were the same in IUGR fetuses compared with controls. These results indicate that insulin-responsive fetal tissues (liver and skeletal muscle) adapt to the hypoglycemic-hypoinsulinemic IUGR environment with mechanisms that promote glucose utilization, particularly for glucose storage, including increased insulin action, glucose production, shunting of glucose utilization to glycogen production, and maintenance of glucose transporter concentrations.     

The glucosidic pathways and glucose production by frog muscle.

Resting muscle is generally perceived as a glucose-utilizing organ; however, we show that resting well-oxygenated frog muscle recovering from strenuous exercise can release significant amounts of glucose. The metabolic pathway responsible for this process does not involve glucose-6-phosphatase because this enzyme is undetectable in frog muscle. The participation of amylo-1,6-glucosidase in the production of glucose is also ruled out since neither marked net phosphorolytic breakdown of glycogen nor considerable cycling between glycogen and glucose 6-phosphate occur. The glucosidic pathways of glycogen breakdown are the likely source of glucose as they are the only metabolic avenues with sufficient capacity to account for the rate at which glucose is released from post-exercised muscle. This rate of glucose production is high enough to be of physiological importance. Our results clearly indicate that to measure lactate glycogenesis in muscle, the simultaneous hydrolysis of muscle glycogen by the glucosidic pathways must be taken into account to prevent marked underestimation of the rate of glycogen synthesis. The glucosidic pathways seem the predominant avenues of glycogen breakdown in post-exercised resting frog muscle and are active enough to account for the rate of glycogen breakdown in resting muscle, suggesting that these rather than the phosphorolytic pathways are the chief routes of glycogen breakdown in resting muscle.     

Glucose transport rate and glycogen synthase activity both limit skeletal muscle glycogen accumulation

We varied rates of glucose transport and glycogen synthase I (GS-I) activity (%GS-I) in isolated rat epitrochlearis muscle to examine the role of each process in determining the rate of glycogen accumulation. %GS-I was maintained at or above the fasting basal range during 3 h of incubation with 36 mM glucose and 60 microU/ml insulin. Lithium (2 mM LiCl) added to insulin increased glucose transport rate and muscle glycogen content compared with insulin alone. The glycogen synthase kinase-3beta inhibitor GF-109203 x (GF; 10 microM) maintained %GS-I about twofold higher than insulin with or without lithium but did not increase glycogen accumulation. When %GS-I was lowered below the fasting range by prolonged incubation with 36 mM glucose and 2 mU/ml insulin, raising rates of glucose transport with bpV(phen) or of %GS-I with GF produced additive increases in glycogen concentration. Phosphorylase activity was unaffected by GF or bpV(phen). In muscles of fed animals, %GS-I was approximately 30% lower than in those of fasted rats, and insulin-stimulated glycogen accumulation did not occur unless %GS-I was raised with GF. We conclude that the rate of glucose transport is rate limiting for glycogen accumulation unless %GS-I is below the fasting range, in which case both glucose transport rate and GS activity can limit glycogen accumulation.     

Effect of glycogen depletion on the ventilatory response to exercise

Five male subjects performed two graded exercise studies, one during control conditions and the other after reduction of muscle glycogen content by repeated maximum exercise and a high fat-protein diet. Reduction in preexercise muscle glycogen from 59.1 to 17.1 mumol X g-1 (n = 3) was associated with a 14% reduction in maximum power output but no change in maximum O2 intake; at any given power output O2 intake, heart rate, and ventilation (VE) were significantly higher, CO2 output (VCO2) was similar, and the respiratory exchange ratio was lower during glycogen depletion compared with control. The higher VE during glycogen depletion was associated with a higher VE/VCO2 ratio, lower end-tidal and mixed venous CO2 partial pressures, and higher blood pH than in the control studies. Changes in exercise VE accompanying glycogen depletion were not explained by changes in CO2 flux to the lungs suggesting that other factors served to modulate VE in these experimental conditions.     

Effects of stress on carbohydrate metabolism in the teleost Notopterus notopterus (Pallas)*

The effects of different types of stre35 on carbohydrate metabolism in N. notopterus were investigated. Starvation alone brings about a signifiant increse in the glycogen content of the saccus vasculosus and a significant decrease in the brain glycogen concentration. The increased glycogen concentration in the saccus vasculosus may be a device to safeguard the brain against glucose deficiency during starvation stress. Rapid depletion of the muscle glycogen following fasting shows that the muscle glycogen IS the readily utilizable source of energy during starvation. Exposure of N. noropierus to air brought about an increaSe in the liver glycogen and blood glucose levels but did not affect other paramcters studied. Physical exhaustion of N. notopierus is noticed within 1–2 min of exercise. The readily available source of energy for exercise is the muscle glycogen. and the lactic acid produced is probably metabolized in the muscle itself. Saccus vasculosus glycogen. though inde-pendent of changes in the blood glucose levels, may possibly be controlled by variations in the brain glycogen.