Diurnal variation in glycogen phosphorylase activity in rat liver. A quantitative histochemical study

The diurnal variations of the glycogen content and of glycogen phosphorylase activity in periportal and pericentral areas of rat liver parenchyma have been analyzed in periodic acid Schiff (PAS)-stained cryostat sections using quantitative microdensitometry. Glycogen content and phosphorylase activity were always higher in periportal areas than in pericentral areas throughout the daily cycle. The glycogen content was highest at the end of the active period during darkness and lowest at the end of the resting period. Phosphorylase activity appeared to be inversely correlated with the glycogen content in both areas. It is concluded that the glycogen content is regulated by phosphorylase activity, which may be due to local cAMP concentration.     

Circadian rhythm of glycogen content in various brain structures of Serranus scriba Cuv.

In different brain structures (telencephalon, tectum opticum, rhombencephalon, cerebellum and medulla oblongata) of the teleost Serranus scriba Cuv., the content of glycogen was observed during a 24-h period. A circadian rhythm of brain glycogen concentration was found. The results are discussed with particular reference to the possible relation between catecholamines, cyclic adenine nucleotide and glycogen metabolism in the brain.     

Cytofluorimetric study of the content of glycogen and its fractions in rat liver cells in the course of the 1st week of postnatal ontogeny]

A cytofluorometric study of the total glycogen and its fractions in rat liver cells using the fluorescent PAS reaction was made during 1--7 days of the postnatal development. It was established that glycogen content was small on the first two days of development. The glycogen content increases only on the third day after birth. The glycogen of the rat liver cells during a first week of the postnatal development is different from that detected in adult liver cells in two aspects: in 3 day old hepatocytes soluble and stable glycogen fractions are equal, while in adult rat liver cells the former makes 80--90%; during the first week of the postnatal development, the stable fraction of rat liver cell is more labile, while in the adult rat liver the soluble fraction of glycogen is more labiles.     

In vivo 13C NMR assessment of brain glycogen concentration and turnover in the awake rat

Brain glycogen metabolism was recently observed in vivo and found to be very slow in the lightly alpha-chloralose anesthetized rat [J. Neurochem. 73 (1999) 1300]. Based on that slow turnover, the total glycogen content in the awake rat brain and its turnover time were assessed after administering 13C-labeled glucose for 48 h. Label incorporation into glycogen, glucose, amino acid, and N-acetyl-aspartate (NAA) resonances was observed. The amount of 13C label incorporated into glycogen was variable and did not correlate with that in glutamate (r=-0.1, P>0.86). However, the amount of 13C label incorporated into glycogen was very similar to that in NAA (r=0.93), implying similar turnover times between brain glycogen and NAA (approximately 10 h). Absolute quantification of the total concentration of brain glycogen in the awake, normoglycemic rat yielded 3.3+/-0.8 micromol/g (n=6, mean+/-S.D.).     

Brain glycogen re-awakened

The mammalian brain contains glycogen, which is located predominantly in astrocytes, but its function is unclear. A principal role for brain glycogen as an energy reserve, analogous to its role in the periphery, had been universally dismissed based on its relatively low concentration, an assumption apparently reinforced by the limited duration that the brain can function in the absence of glucose. However, during insulin-induced hypoglycaemia, where brain glucose availability is limited, glycogen content falls first in areas with the highest metabolic rate, suggesting that glycogen provides fuel to support brain function during pathological hypoglycaemia. General anaesthesia results in elevated brain glycogen suggesting quiescent neurones allow glycogen accumulation, and as long ago as the 1950s it was shown that brain glycogen accumulates during sleep, is mobilized upon waking, and that sleep deprivation results in region-specific decreases in brain glycogen, implying a supportive functional role for brain glycogen in the conscious, awake brain. Interest in brain glycogen has recently been re-awakened by the first continuous in vivo measurements using NMR spectroscopy, by the general acceptance of metabolic coupling between glia and neurones involving intercellular transfer of energy substrate, and by studies supporting a prominent physiological role for brain glycogen as a provider of supplemental energy substrate during periods of increased tissue energy demand, when ambient normoglycaemic glucose is unable to meet immediate energy requirements.     

Glycogen in the brain of Drosophila melanogaster: diurnal rhythm and the effect of rest deprivation

One function of sleep is thought to be the restoration of energy stores in the brain depleted during wakefulness. One such energy store found in mammalian brains is glycogen. Many of the genes involved in glycogen regulation in mammals have also been found in Drosophila melanogaster and rest behavior in Drosophila has recently been shown to have the characteristics of sleep. We therefore examined, in the fly, variation in the glycogen contents of the brain, the whole head and the body throughout the rest/activity cycle and after rest deprivation. Glycogen in the brain varies significantly throughout the day (p=0.001) and is highest during rest and lowest while flies are active. Glycogen levels in the whole head and body do not show diurnal variation. Brain glycogen drops significantly when flies are rest deprived for 3 h (p=0.034) but no significant differences are observed after 6 h of rest deprivation. In contrast, glycogen is significantly depleted in the body after both 3 and 6 h of rest deprivation (p<0.0001 and p<0.0001, respectively). Glycogen in the fly brain changes in relationship to rest and activity and demonstrates a biphasic response to rest deprivation similar to that observed in mammalian astrocytes in culture.     

Immunohistochemical Localization of Glycogen Synthase and GSK3β: Control of Glycogen Content in Retina

Glycogen has an important role in energy handling in several brain regions. In the brain, glycogen is localized in astrocytes and its role in several normal and pathological processes has been described, whereas in the retina, glycogen metabolism has been scarcely investigated. The enzyme glycogen phosphorylase has been located in retinal Müller cells; however the cellular location of glycogen synthase (GS) and its regulatory partner, glycogen synthase kinase 3β (GSK3β), has not been investigated. Our aim was to localize these enzymes in the rat retina by immunofluorescence techniques. We found both GS and GSK3β in Müller cells in the synaptic layers, and within the inner segments of photoreceptor cells. The presence of these enzymes in Müller cells suggests that glycogen could be regulated within the retina as in other tissues. Indeed, we showed that glycogen content in the whole retina in vitro was increased by high glucose concentrations, glutamate, and insulin. In contrast, retina glycogen levels were not modified by norepinephrine nor by depolarization with high KCl concentrations. Insulin also induced an increase in glycogen content in cultured Müller cells. The effect of insulin in both, whole retina and cultured Müller cells was blocked by inhibitors of phosphatidyl-inositol 3-kinase, strongly suggesting that glycogen content in retina is modulated by the insulin signaling pathway. The expression of GS and GSK3β in the synaptic layers and photoreceptor cells suggests an important role of GSK3β regulating glycogen synthase in neurons, which opens multiple feasible roles of insulin within the retina.     

Influence of pregnancy on diurnal and seasonal changes in cortisol, T3 and T4 levels in the mare blood serum.

1. The diurnal changes in the level of total protein, cortisol, T3 and T4 were studied in four barren and four pregnant standard-bred mares, kept and examined under the same conditions. 2. Blood samples were taken every 4 hr. for one day each month, throughout one year. 3. In barren mares, a diurnal rhythm in cortisol level (acrophase at 0530 hr in summer and at 0830 hr in winter) and in T3 level (acrophase at 1330 hr in summer and at 1800 hr in winter) was found. 4. In pregnant mares, a diurnal rhythm in cortisol level only till 5th month of pregnancy was observed. 5. A diurnal rhythm in T3 level was found throughout the pregnancy, with acrophase always at 1400 hr. 6. No diurnal rhythm in the total protein content and in the T4 level was observed. 7. In both groups of mares the seasonal cyclicity in T3 and T4 levels were found. A seasonal cyclicity in cortisol level was found only in pregnant mares. 8. Pregnancy abolished seasonal cyclicity in total protein and showed it in cortisol level. 9. Pregnancy in mares modifies diurnal rhythms as well as seasonal cycles in secretion and metabolism of the hormones studied.     

Effect of Diabetes on Glycogen Metabolism in Rat Retina

Glucose is the main fuel for energy metabolism in retina. The regulatory mechanisms that maintain glucose homeostasis in retina could include hormonal action. Retinopathy is one of the chemical manifestations of long-standing diabetes mellitus. In order to better understand the effect of hyperglycemia in retina, we studied glycogen content as well as glycogen synthase and phosphorylase activities in both normal and streptozotocin-induced diabetic rat retina and compared them with other tissues. Glycogen levels in normal rat retina are low (46 +/- 4.0 nmol glucosyl residues/mg protein). However, high specific activity of glycogen synthase was found in retina, indicating a substantial capacity for glycogen synthesis. In diabetic rats, glycogen synthase activity increased between 50% and 100% in retina, brain cortex and liver of diabetic rats, but only retina exhibited an increase in glycogen content. Although, total and phosphorylated glycogen synthase levels were similar in normal and diabetic retina, activation of glycogen synthase by glucose-6-P was remarkable increased. Glycogen phosphorylase activity decreased 50% in the liver of diabetic animals; it was not modified in the other tissues examined. We conclude that the increase in glycogen levels in diabetic retina was due to alterations in glycogen synthase regulation.     

Biochemical variations in Gigantocotyle explanatum and Gastrothylax crumenifer with respect to their seasonal reproduction

Biochemical components, glycogen, protein, nucleic acids and lipid fractions were analysed every month from January to December 1986, in the liver and rumen amphistomes Gigantocotyle explanatum and Gastrothylax crumenifer, respectively. The results reveal a considerable seasonal variation. In the rumen amphistome the components reach their maximum level only once a year, whereas in the liver amphistome, more than one peak is observed in a year. In G. crumenifer the content of glycogen and nucleic acids increases before the onset of egg production while protein and lipids reach their maximum level during the egg production phase. The variations in biochemical components were associated with the reproductive cycles and gonad recrudescence of these parasites.     

Correlation between brain glycogen and convulsive state in mice submitted to methionine sulfoximine

It is now well established that in epileptic patients, hypometabolic foci appear during interictal periods. The meaning and the mechanism of such an hypometabolism are as yet unclear. The aim of the present investigation was to look for a putative relationship between glucose metabolism in the brain and the genesis of seizures in mice using administration of the convulsant, methionine sulfoximine. Besides its epileptic action, methionine sulfoximine is a powerful glycogenic agent. We analyzed the epileptogenic and glycogenic effects of methionine sulfoximine in two inbred mouse strains with different susceptibility towards the convulsant. CBA/J mice displayed high response to methionine sulfoximine. The tonic convulsions appeared 5-6 h after MSO administration, without brain glycogen content variations during the preconvulsive period. These mice died of status epilepticus during the first seizure(s). Conversely, C57BL/6J mice displayed low response to MSO. The tonic and clonic seizures appeared 8 to 14 h after MSO administration with only 2% mortality. The seizures were preceded by an increase in brain glycogen content during the preconvulsive period. Moreover, during seizures, C57BL/6J mice were able to mobilize this accumulated brain glycogen, that returned to high value after seizures. The epileptic and glycogenic responses of the parental strains were also observed in mice of the F2 generation. The F2 mice that convulsed early (16%) did not utilize their small increase in brain glycogen content, and resembled CBA/J mice; while the F2 mice that seized tardily (24%) increased their brain glycogen content before convulsion, utilized it during convulsions, and resembled C57BL/6J mice. Sixty percent of the F2 mice presented an intermediate pattern in epileptogenic responses to the convulsant. These data suggest a possible genetic link between the two MSO effects, epileptiform seizures and increase in brain glycogen content. The increase in brain glycogen content and the capability of its mobilization during seizures could delay the seizure's onset and could be considered a "resistance factor" against the seizures.     

Adaptations of glycogen metabolism in rat epididymal adipose tissue during fasting and refeeding.

It is well documented that adipose tissue glycogen content decreases during fasting and increases above control during refeeding. We now present evidence that these fluctuations result from adaptations intrinsic to adipose tissue glycogen metabolism that persist in vitro: in response to insulin (1 milliunit/ml), [3H]glucose incorporation into rat fat pad glycogen was reduced to 10% of control after a 3-day fast; incorporation increased 6-fold over fed control on the 4th day of refeeding following a 3-day fast. We have characterized this adaptation with regard to alterations in glycogen synthase and phosphorylase activity. In addition, we found that incubation of fat pads from fasted rats with insulin (1 milliunit/ml) increased glucose-6-P content, indicating that glucose transport was not the rate-limiting step for glucose incorporation into glycogen in the presence of insulin. In contrast, feeding a fat-free diet resulted in dramatic increases in glycogen content of fat pads without a concomitant increase in glucose incorporation into glycogen in response to insulin (1 milliunit/ml). Thus, fasting and refeeding appeared to alter insulin action on adipose tissue glycogen metabolism more than this dietary manipulation.     

Exercise training attenuated the PKB and GSK-3 dephosphorylation in the myocardium of ZDF rats.

Cardiac dysfunction is a severe secondary effect of Type 2 diabetes. Recruitment of the protein kinase B/glycogen synthase kinase-3 pathway represents an integral event in glucose homeostasis, albeit its regulation in the diabetic heart remains undefined. Thus the following study tested the hypothesis that the regulation of protein kinase B/glycogen synthase kinase-3 was altered in the myocardium of the Zucker diabetic fatty rat. Second, exercise has been shown to improve glucose homeostasis, and, in this regard, the effect of swimming training on the regulation of protein kinase B/glycogen synthase kinase-3 in the diabetic rat heart was examined. In the sedentary Zucker diabetic fatty rats, glucose levels were elevated, and cardiac glycogen content increased, compared with wild type. A 13-wk swimming regimen significantly reduced plasma glucose levels and cardiac glycogen content and partially normalized protein kinase B-serine473, protein kinase B-threonine308, and glycogen synthase kinase-3alpha phosphorylation in Zucker diabetic fatty rats. In conclusion, hyperglycemia and increased cardiac glycogen content in the Zucker diabetic fatty rats were associated with dysregulation of protein kinase B/glycogen synthase kinase-3 phosphorylation. These anomalies in the Zucker diabetic fatty rat were partially normalized with swimming. These data support the premise that exercise training may protect the heart against the deleterious consequences of diabetes.     

The effect of maternal diabetes on glycogen metabolism in the embryonic rat

This study examined the effect of maternal hyperglycemia during pregnancy due to streptozotocin-induced diabetes on the synthesis of glycogen in the brain and liver of embryonic and newborn rats. Maternal hyperglycemia (serum glucose 25.3 +/- 0.9 mM) during gestation had no effect compared to controls (5.7 +/- 0.2 mM) on embryonic and newborn glycogen content in liver. In contrast, embryos experiencing hyperglycemia in utero had a two-fold higher brain glycogen content than controls at term; 1.6 mg/g vs. 0.84 mg/g, respectively. Interestingly there was a significant delay in the mobilization of brain glycogen during the immediate postnatal period in the offspring of diabetic mothers and control animals. These results suggest that uncontrolled maternal diabetes during pregnancy may significantly increase the availability of a potentially important local fuel source for the newborn brain: glycogen.     

Diurnal rhythms in rat plasma amino acids

To obtain detailed data on the diurnal rhythm in rat plasma amino acids, groups of rats were killed every two hours during 24 hours and the amino acids in plasma were measured. By using such a short interval between the blood samples, it was possible to reveal differences in rhythmicity between the various amino acids, more detailed than those previously described. Furthermore, it was found that those large neutral amino acids (LNAA) which compete with each other for the carrier mediated transport from plasma into the brain demonstrated different rhythms, whereby also the relation between these competing amino acids varied during the day. This finding might have implications for the transport of the various LNAAs into the brain, and secondarily also for the synthesis of the monoaminergic neurotransmitters in the neurons, for which the LNAAs tyrosine and tryptophan serve as precursors.     

Correlation between carbohydrate and catecholamine level impairments in methionine sulfoximine epileptogenic rat brain

This work shows that the convulsant methionine sulfoximine induces an increase in glucose and glycogen levels and a parallel decrease in norepinephrine and dopamine levels in rat brain. Among the epileptogenic agents, methionine sulfoximine is known to have a glycogenic property in the central nervous system. The aim of this work is to look for the neurochemical mechanism underlying this property. For this, catecholamines, glucose, and glycogen were measured at the same time in different areas of the brain in rats submitted to methionine sulfoximine. The convulsant induced an increase in glucose and glycogen levels as previously described and a decrease in dopamine and norepinephrine levels in all the areas of the rat brain. These changes were roughly dose dependent. WhenL-dihydroxyphenylalanine and benserazide (a decarboxylase inhibitor) were administered with methionine sulfoximine, the latter failed to induce seizures in rat up to 8 h after dosing. Moreover, the glucose and glycogen amounts did not increase. In all these experiments, there was an obvious evidence of parallelism between seizures, increase in carbohydrate levels, and decrease in catecholamine levels. These results allow to conclude that the glycogenic property of methionine sulfoximine in the central nervous system probably results from its ability to decrease norepinephrine and dopamine levels. Because the effect of the convulsant on the catecholamine levels persisted for long, it is normal that glucose and glycogen levels increased during preconvulsive, convulsive and postconvulsive period. Methionine sulfoximine is probably glycogenic in rat brain because it decreases catecholamine levels for a long time.     

Diurnal variations in the activities of the glycogen metabolizing enzymes in mouse liver

The glycogen level in mouse liver was maximal during the night and decreased to the lowest level during the light period. The peak activity of phosphorylase alpha was observed during the light hours and thus paralleled the decline of hepatic glycogen concentrations. The period of rapid glycogen synthesis (1800-2200 hr) was immediately preceded by maximum glycogen synthase alpha activity. Significant diurnal rhythms for phosphorylase kinase and phosphorylase phosphatase activities were also observed and appear to play a role in regulating the diurnal rhythm of phosphorylase alpha activity.     

Seasonality of glycogen phosphorylase activity in crucian carp (<Emphasis Type="Italic">Carassius carassius</Emphasis> L<Emphasis Type="Italic">.</Emphasis>)

Seasonal changes in the activity of glycogen phosphorylase (GP), a rate-limiting enzyme of glycogen degradation, were examined in an anoxia-tolerant fish species, the crucian carp (Carassius carassius L.). In muscle and brain, the activity of GP remained constant throughout the year when tested at 25°C. In contrast, the activities of liver and heart GP displayed striking increases in summer. When seasonal temperature changes are taken into account, the activity of GP during the anoxic mid-winter is only 4–6% of its summer time activity in the muscle, heart and liver, and 13% in brain. In winter-acclimatized fish, experimental anoxia (1–6 weeks) caused sustained depression of the GP activity in heart and gills. In liver and muscle, a transient depression of GP activity occurred during the first week of anoxia but later GP activity recovered back to the normoxic level. GP of the brain was completely resistant to anoxia. In all studied tissues, the constitutive activity of GP is more than sufficient to degrade glycogen deposits during winter anoxia without anoxia-induced activation of GP. The seemingly paradoxical summer-time increase in the activity of liver and heart GP could be related to active life-style of the summer-acclimatized fish (growth, reproduction), the increased demand of energy and molecular precursors of anabolic metabolism being satisfied by preferential degradation of glycogen. The high glycogen content of winter-acclimatized crucian carp is not associated with the elevated GP activity or anoxic activation of GP.     

Development of diurnal rhythm in some metabolic parameters in foals

1. The development of diurnal rhythm activity of FDPA, AspAT and A1AT and in levels of cortisol, T3 and T4 was observed in the blood serum of six foals. 2. The studies began when a foal was 7 days old and were repeated every month until foals reached 1 year of age. Blood samples were taken every 4 hr for one day each month. 3. As a control group four barren mares were used, kept and examined in the same conditions. 4. In mature mares, diurnal rhythms in activity of A1AT (acrophase at 2200 hr), AspAt (2400 hr) and cortisol (0630 hr) but in T3 only in summer months (acrophase at 0100 hr) were observed. 5. During the first 6 months of foal life, significantly higher mean levels of FDPA, A1AT, T3 and T4 than in control mares were found. 6. The cortisol level in foals was half as much as that of mature mares throughout the year. 7. In foals the diurnal rhythm in A1AT activity occurred in the 5th month and in AspAt--in the 12th month (acrophase at 2400 hr), but in cortisol levels it was developed already in the second month of foal life (acrophase at 0830 hr).     

Age-related and diurnal changes in Met5-Enk-Arg6-Phe7 and Met5-enkephalin contents of pituitary and rat brain structures

The beta-endorphin, met5-enkephalin-arg6-phe7 (MEAP) and met5-enkephalin (ME) changes related to age and diurnal rhythms were studied in various regions of rat brain and in the pituitary by specific radioimmunoassays. The contents of MEAP, met5-enkephalin and beta-endorphin were higher in the pituitary of old rats (18 months old) than that of young rats (23 days old) while the content of these opioid peptides was higher in the hypothalamus of young rats than in that of old rats. Beta-endorphin was also higher in the striatum of 23 days old rats, but no age-associated changes were observed in the hippocampus, brain stem or cortex. In the diurnal rhythm study, it was found that in the hypothalamus and striatum of the adult rat (2-3 months old), both MEAP and ME contents were higher at mid-dark than at mid-light and that in the intermediate posterior lobe of the pituitary, the ME content was also higher at mid-dark.