Changes in glycogen metabolism in chick embryo liver in relation to the formation of glycosomes]

In the chick embryo liver the portion of granular glycogen increases from 15 to 90% of the total content during the period from the 8th till the 14th days of developments. The activity of glycogen synthetase (KF 2.4.1.11) localized in the fraction of granular glycogen increases from 40 to 90% of the total activity in the 18 days old embryo. The activity of phosphorylase (KF 2.4.1.1) is detected in the granular glycogen of the liver only on the 12th day of development (10% of the total activity) and increase up to 80% on the 19th day of development. The maximal activation of glycogen synthetase and phosphorylase is noted after the glycosomes of formation in the developing embryoliver. A suggestion is put forward to the effect that the process of glycosome formation is a factor of the control of glycogen synthetase and phosphorylase activity.     

Glycogen metabolic enzymes in the skeletal muscles of the developing chick embryo

In the skeletal muscles of the chick embryo from the 10th till the 15th day of embryogenesis, phosphorylase (EC. 2.4.1.1) is represented by two isozymes one of which corresponds, by electrophoretic mobility, to the liver phosphorylase and another to phosphorylase of the skeletal muscles of the adult rat. From the 17th day of embryogenesis on only one isozyme of phosphorylase is found in the skeletal muscles which is identical with that of the skeletal muscles of the adult bird. The isozyme spectrum of phosphorylase of the whole 4 days old embryo contains, besides phosphorylase L, a special "embryonic" isozyme which differs from that of the skeletal muscles by immunochemical characteristics and electrophoretic mobility. From the 10th day of embryogenesis till hatching, the activity of phosphorylase of the skeletal muscles increases more than 50 times and that of glycogen synthetase (EC. 2.4.1.11) only 4 times.     

Turkey liver xanthine dehydrogenase. Reactivation of the cyanide-inactivated enzyme by sulphide and by selenide

1. The glycogen present in the liver of rat foetuses was labelled by injecting a trace amount of [6-(3)H]glucose into the mother at 19.5 days of gestation. The radioactivity incorporated in the glycogen 4h after the administration of the label was still present 38h later. A large proportion of this radioactivity was on the outer chains of the polysaccharide. These results indicate that there is normally almost no glycogen degradation in the foetal liver. In contrast, glycogen breakdown occurs very rapidly in the livers of foetuses whose mother is anaesthetized. 2. Glycogen synthetase is present in the liver at day 16 of gestation at a concentration as high as 30% of that in the adult, but essentially as an inactive (b) enzyme. The appearance of synthetase phosphatase between days 18 and 19 corresponds to that of synthetase a and to the beginning of glycogen synthesis. From day 19 to 21.5 the amount of synthetase a present in the foetal liver is just sufficient to account for the actual rate of glycogen deposition. 3. The content of total phosphorylase in the foetal liver increases continuously from day 16 to birth. However, a precise measurement of the a and b forms of the enzyme in the liver of non-anaesthetized foetuses is not possible. Taking the rate of glycogenolysis as an appropriate index of phosphorylase activity, we conclude that this enzyme is almost entirely in the inactive form in the foetal liver under normal conditions. 4. The accumulation of glycogen in the liver during late pregnancy may therefore be explained by a relatively slow rate of synthesis and a nearly total absence of degradation.     

Time course for cryoprotectant synthesis in the freeze-tolerant chorus frog, Pseudacris triseriata

Increases in liver glycogen phosphorylase activity, along with inhibition of glycogen synthetase and phosphofructokinase-1, are associated with elevated cryoprotectant (glucose) levels during freezing in some freeze-tolerant anurans. In contrast, freeze-tolerant chorus frogs, Pseudacris triseriata, accumulate glucose during freezing but exhibit no increase in phosphorylase activity following 24-h freezing bouts. In the present study, chorus frogs were frozen for 5- and 30-min and 2- and 24-h durations. After freezing, glucose, glycogen, and glycogen phosphorylase and synthetase activities were measured in leg muscle and liver to determine if enzyme activities varied over shorter freezing durations, along with glucose accumulation. Liver and muscle glucose levels rose significantly (5-12-fold) during freezing. Glycogen showed no significant temporal variation in liver, but in muscle, glycogen was significantly elevated after 24 h of freezing relative to 5 and 30 min-frozen treatments. Hepatic phosphorylase a and total phosphorylase activities, as well as the percent of the enzyme in the active form, showed no significant temporal variation following freezing. Muscle phosphorylase a activity and percent active form increased significantly after 24 h of freezing, suggesting some enhancement of enzyme function following freezing in muscle. However, the significance of this enhanced activity is uncertain because of the concurrent increase in muscle glycogen with freezing. Neither glucose 6-phosphate independent (I) nor total glycogen synthetase activities were reduced in liver or muscle during freezing. Thus, chorus frogs displayed typical cryoprotectant accumulation compared with other freeze-tolerant anurans, but freezing did not significantly alter activities of hepatic enzymes associated with glycogen metabolism.     

Hormonal regulation of glycogen metabolism in neonatal rat liver

1. The development of active and inactive phosphorylase was determined in rat liver during the perinatal period. No inactive form could be found in tissues from animals less than 19 days gestation or older than the fifth postnatal day. 2. The regulation of phosphorylase in organ cultures of foetal rat liver was examined. None of the agents examined [glucagon, insulin or dibutyryl cyclic AMP (6-N,2'-O-dibutyryladenosine 3':5'-cyclic monophosphate)] changed the amount of phosphorylase activity. 3. Glycogen concentration in these explants were nevertheless decreased more than twofold by 4h of incubation with glucagon or dibutyryl cyclic AMP. Incubation with insulin for 4h increased the glycogen content twofold. 4. Glycogen synthetase activity was examined in these explants. I-form activity (without glucose 6-phosphate) was found to decrease by a factor of two after 4h of incubation with dibutyryl cyclic AMP, whereas I+D activity (with glucose 6-phosphate) remained nearly constant. Incubation for 4h with insulin increased I-form activity threefold, with only a slight increase in I+D activity. 5. When explants were incubated with insulin followed by addition of dibutyryl cyclic AMP, the effects of insulin on glycogen concentration and glycogen synthetase activity were reversed. 6. These results indicate that the regulation of glycogen synthesis may be the major factor in the hormonal control of glycogen metabolism in neonatal rat liver.     

The effect of various aminoglycoside antibiotics on glycogen phosphorylase activity in liver and kidney medulla of rabbit

Glycogen phosphorylase activity in both liver and kidney medulla of rabbit was stimulated in the presence of caffeine by various aminoglycoside antibiotics in the following rank order: gentamicin greater than neomycin greater than amikacin = kanamycin greater than or equal tobramycin, while streptomycin did not affect the enzyme activity. In contrast, in the presence of AMP, the stimulatory action of antibiotics was not observed. Since in the gentamicin-treated rabbits stimulation of glycogen phosphorylase activity by about 30% in both liver and kidney medulla was accompanied by a decrease of liver glycogen content by about 60% it is likely that a decline in liver glycogen level following antibiotic treatment is due to an increased glycogen phosphorylase activity.     

Glycogen debranching enzyme in bovine brain

Glycogen debranching enzyme was partially purified from bovine brain using a substrate for measuring the amylo-1,6-glucosidase activity. Bovine cerebrum was homogenized, followed by cell-fractionation of the resulting homogenate. The enzyme activity was found mainly in the cytosolic fraction. The enzyme was purified 5,000-fold by ammonium sulfate precipitation, anion-exchange chromatography, gel-filtration, anion-exchange HPLC, and gel-permeation HPLC. The enzyme preparation had no alpha-glucosidase or alpha-amylase activities and degraded phosphorylase limit dextrin of glycogen with phosphorylase. The molecular weight of the enzyme was 190,000 and the optimal pH was 6.0. The brain enzyme differed from glycogen debranching enzyme of liver or muscle in its mode of action on dextrins with an alpha-1,6-glucosyl branch, indicating an amino acid sequence different from those of the latter two enzymes. It is likely that the enzyme is involved in the breakdown of brain glycogen in concert with phosphorylase as in the cases of liver and muscle, but that this proceeds in a somewhat different manner. The enzyme activity decreased in the presence of ATP, suggesting that the degradation of brain glycogen is controlled by the modification of the debranching enzyme activity as well as the phosphorylase.     

Stimulation of pentose phosphate pathway dehydrogenase enzyme activities in ethionine-treated mice

1. Mice treated with ethionine (intraperitoneally, 5mg./day for 4 days or 10mg./day for 3 days) showed a profound loss of hepatic glycogen, a decrease of glycogen synthetase activity, a development of hypoglycaemia, a two- to five-fold increase in the activity of glucose 6-phosphate dehydrogenase but no change in 6-phosphogluconate dehydrogenase and an earlier manifestation of the solubilization of phosphorylase as compared with glycogen synthetase. The administration of ATP did not prevent these effects. 2. During the early post-injection period (2-3 days) there was a further enhancement of the activity of glucose 6-phosphate dehydrogenase (tenfold) in the liver and a clear elevation of 6-phosphogluconate dehydrogenase activity (twofold). Subsequently, the glycogen concentration was restored, followed by an earlier reassociation of glycogen particle with phosphorylase than with glycogen synthetase, along with a disappearance of ethionine effect at about the eighteenth day. 3. Glucose 6-phosphate dehydrogenase from both control and ethionine-treated animals showed a marked preference for glucose 6-phosphate as substrate rather than for galactose 6-phosphate, whose rate of oxidation was only 10% of that of the glucose 6-phosphate. 4. Since actinomycin D, puromycin, 5-fluorouracil and dl-p-fluorophenylalanine failed to block the ethionine-enhanced glucose 6-phosphate dehydrogenase activity, the possibility that new enzyme protein synthesis is responsible for the effect is doubtful.     

Histochemical studies on the enzymes of glycogen metabolism in hamster epididymis

Summary Active and total (active + inactive) phosphorylase and glycogen synthetase (I- and D-form) were studied in hamster epididymis in relation to glycogen. Immature and adult, sexually active and regressed animals were examined.Epididymis in adult animals, based on their phosphorylase activity, may be divided into 5 zones. The zone 1 epithelium contains particulate glycogen, rich in phosphorylase and glycogen synthetase. The epithelial cytoplasm also contains moderate phosphorylase activity. The zone 2 epithelium is almost devoid of phosphorylase. The zone 3 epithelium shows considerable phosphorylase activity both in principal and holocrine cells. The epithelium of the zone 4 contains the highest total phosphorylase activity. In the zone 5 epithelium phosphorylase and glycogen are absent, but glycogen synthetase is often observed.Holocrine cells, particularly in zones 3 and 4, contain predominating active phosphorylase, some glycogen, but no synthetase activity. The lumen in the zone 4 often shows a faint staining for glycogen.In immature animals, low phosphorylase activity is always present in the epithelial cells. Holocrine cells are detectable, by their phosphorylase activity, in 4 week animals. The division of zones is usually established slightly before sexual maturation.During the period of sexual regression, phosphorylase diminishes considerably. Glycogen, phosphorylase and glycogen synthetase are, however, detectable in the zone 1 of these animals.     

Glutatmine synthetase activity in the chick brain during postnatal growth. Effect of MSO

Glutamine synthetase activity was estimated in the chick cerebral hemispheres, optic lobes and cerebellum between the 1st and the 30th day of postnatal growth. Glutamine synthetase activity is higher in the cerebellum than in the cerebral hemispheres and lowest in the optic lobes at 1 day after hatching; at 30 days after hatching, it is the same in the optic lobes and in the cerebellum and lowest in the cerebral hemispheres. The great increase of glutamine synthetase activity between the 1st and the 4th day after hatching corresponds to the appearance of the heterogeneity of the chick brain glutamate metabolism. The glutamine synthetase activity is inhibited by MSO $\text{in vivo}$ at a concentration of 100 mg kg ^?1 at values of 87, 90 and 89 % in cerebral hemispheres, optic lobes and cerebellum of 1, 2 and 4-day-old chicks. The enzyme inhibition is less pronounced $\text{in vitro}$ and reaches values of about 25 and 75 % for 1 and 10 mM MSO concentrations respectively in the three brain areas of the 1 to 4-day-old chick and values slightly lower in the 30-day-old chick brain.     

Glycogen and glycogen enzymes in the liver and striated muscle of rats under altered thyroid states

Changes induced in liver and striated muscle glycogen and glycogen enzymes (glycogen synthetase, glycogen phosphorylase and alpha-amylase) by hypothyroidism and hyperthyroidism in rats have been determined. There were no changes in liver glycogen synthetase, phosphorylase and amylase activities in the hypothyroid group. Hyperthyroid rats showed lower liver glycogen synthetase, phosphorylase a and amylase activities. In muscle, hypothyroid rats had lower phosphorylase activity. In the hyperthyroid group glycogen synthetase was increased.--The results presented do not completely agree with the glycogen levels found in both tissues studied, and they are obviously more related to other factors such as glucose availability. It can be concluded that under the conditions studied, the glycogen enzyme levels could not alone explain the variations of glycogen levels.     

Glycogen regulation in LPS-stimulated murine splenocytes

Enzymatic glycogen regulation in mouse splenocytes cultured in vitro with and without LPS, was studied from 0-72 h. Increased [3H]glucose uptake and hexokinase activity demonstrated the activation of cells treated with LPS. There was a greater time-dependent increase of cellular glycogen content in LPS-stimulated cells as compared to control. Glycogen synthetase I in LPS-stimulated cells increased about 200% above control cells to a plateau at 48 h, while in unstimulated cells there was little increase throughout. Glycogen synthetase D increased continually to 72 h in both groups. In the stimulated cells, phosphorylase increased only 90% above control cells up to 48 h. It was concluded that the increased glycogen content of LPS-stimulated cells seen at 48 h may result from an increase in both glycogen synthetase I and D activity compared to lesser increase in hydrolysis. However, between 48 and 72 h, the period of RNA and DNA increased synthesis, the glycogen content of stimulated cells did not increase further, consistent with the observation that synthetase I activity remained constant and synthetase D decreased. Thus, following mitogenic stimulation, the net effect of the enzymatic regulation is to increase cellular glycogen, as an energy source for subsequent events.     

Variation of phosphorylase distribution in skeletal muscles

Summary Glycogen phosphorylase, glycogen alpha-4 UDP-glucosyl transferase, glycogen, and some enzymes were histochemically examined in rat skeletal muscles. Phosphorylase activity was abundantly demonstrated not only in large fibers of the white muscle, but also in small red fibers of soleus muscle and those in the deep fascicles of gastrocunemius and quadriceps femoris muscles. Small fibers with high phosphorylase activity did not always revealed high LDH activity.Native glycogen was abundant mostly in small fibers or in middlesized fibers. Neither glycogen synthetase, nor glycogenolytic enzyme activity was directly proportionate to native glycogen content.On Leave from Cancer Research Institute, Faculty of Medicine, Kyushu University, Fukuoka, Japan.     

Expression and regulation of glycogen phosphorylase in preneoplastic and neoplastic hepatic lesions in rats

Glycogen phosphorylase (PHO) was demonstrated immunocytochemically and enzyme histochemically in cryostat sections of liver from rats treated for 7 weeks with N-nitrosomorpholine (120 mg/l and 200 mg/l drinking water) and from untreated controls. The activity and distribution of PHO protein were studied in normal liver and correlated with morphologically defined stages of hepatic tumour development. In normal liver the amount of enzyme protein, as visualized by the immunoperoxidase method using antibodies against phosphorylase, showed some heterogeneity within the liver lobule. The intralobular and intracellular distribution of PHO protein was the same as that of glycogen, namely coarse and granular in periportal hepatocytes and very fine in perivenular cells. In glycogen storage foci the amount of PHO protein was increased. In contrast, PHO activity was generally decreased. In other preneoplastic and neoplastic lesions such as mixed cell foci, neoplastic nodules and hepatocellular carcinomas, PHO protein was increased in all glycogen-loaded cells while PHO activity was reduced. In all glycogen-poor and basophilic cells, both PHO protein and PHO activity were decreased or absent. It was concluded that the decrease in PHO activity in glycogen storage foci was not the direct consequence of genetic changes leading to a loss in enzyme protein but was due to a defect in the cascade of phosphorylation processes resulting in active PHO. Alteration in gene expression leading to a loss of PHO protein was a late event in the process of hepatocarcinogenesis.     

Electron microscopical study of a cytosolic enzyme in unfixed cryostat sections: demonstration of glycogen phosphorylase activity in rat liver and heart tissue

Summary Glycogen phosphorylase activity has been demonstrated at the ultrastructural level in liver and heart tissue of fasted rats. Unfixed cryostat sections were incubated by mounting them on a semipermeable membrane stretched over a gelled incubation medium. The medium contained a high concentration of glucose 1-phosphate which enables indirect detection of glycogen phosphorylase activity on the basis of the synthesis of glycogen. Tissue fixation, dehydration and embedding for electron microscopical study were performed after the incubation had been completed. The ultrastructure of both liver and heart tissue was rather well preserved. Glycogen granules resulting from glycogen phosphorylase activity were found in the cytoplasmic matrix of both hepatocytes and cardiomyocytes; no relationship with membranous structures could be detected. It is concluded that the semipermeable membrane method is well suited for localizing cytosolic enzyme activities at the ultrastructural level without prior tissue fixation; this opens further perspectives for correlations between histochemical and biochemical data.     

Hormonal control of endometrial glycogen metabolism in the Macaca arctoides

Endometrial biopsies obtained throughout the menstrual cycle of the Macaca arctoides show the glycogen content paralleling the serum progesterone fluctuations which occur during the menstrual cycle. Secretory phase samples contained a three-fold higher concentration of glycogen when compared to follicular phase tissue. Changes in the activity levels of the glycogen metabolizing enzymes, glycogen phosphorylase and glycogen synthetase, during various stages of the menstrual cycle are in accord with the concept that the post-ovulatory increase in endometrial metabolism is a function of progesterone influence on this tissue. Endometrial glycogen synthetase activity remains low during the early proliferative phase of the cycle and becomes significantly elevated (two-to three-fold) during the early secretory phase of the cycle. Glycogen phosphorylase shows a similar cyclicity later in the luteal phase, reaching maximal activity between the seventeenth to nineteenth day of the cycle and remaining elevated through the twenty-sixth day of the cycle. The coincident nature of the rise in peripheral progesterone to increases in uterine glycogen metabolism suggest that progesterone may be the prime modulator of uterine endometrial metabolism during the post-ovulatory phase.     

Phosphorylation and inactivation of liver glycogen synthase by liver protein kinases

A rapid method for purifying glycogen synthase a from rat liver was developed and the enzyme was tested as a substrate for nine different protein kinases, six of which were isolated from rat liver. The enzyme was phosphorylated on a 17-kDa CNBr fragment to approximately 1 phosphate/87-kDa subunit by phosphorylase b kinase from muscle or liver with a decrease in the activity ratio (-Glc-6-P/+Glc-6-P) from 0.95 to 0.6. Calmodulin-dependent glycogen synthase kinase from rabbit liver produced a similar phosphorylation pattern, but a smaller activity change. The catalytic subunit of beef heart cAMP-dependent protein kinase incorporated greater than 1 phosphate/subunit initially into a 17-kDa CNBr peptide and then into a 27-30-kDa CNBr peptide, with an activity ratio decrease to 0.5. Glycogen synthase kinases 3, 4, and 5 and casein kinase 1 were purified from rat liver. Glycogen synthase kinase 3 rapidly phosphorylated liver glycogen synthase to 1.5 phosphate/subunit with incorporation of phosphate into 3 CNBr peptides and a decrease in the activity ratio to 0.3. Glycogen synthase kinase 4 produced a pattern of phosphorylation and inactivation of liver synthase which was very similar to that caused by phosphorylase b kinase. Glycogen synthase kinase 5 incorporated 1 phosphate/subunit into a 24-kDa CNBr peptide, but did not alter the activity of the synthase. Casein kinase 1 phosphorylated and inactivated liver synthase with incorporation of phosphate into a 24-kDa CNBr peptide. This kinase and glycogen synthase kinase 4 were more active against muscle glycogen synthase. Calcium-phospholipid-dependent protein kinase from brain phosphorylated liver and muscle glycogen synthase on 17- and 27-kDa CNBr peptides, respectively. However, there was no change in the activity ratio of either enzyme. The following conclusions are drawn. 1) Liver glycogen synthase a is subject to multiple site phosphorylation. 2) Phosphorylation of some sites does not per se control activity of the enzyme under the assay conditions used. 3) Liver contains most, if not all, of the protein kinases active on glycogen synthase previously identified in skeletal muscle.     

Development of glycogen and phospholipid metabolism in fetal and newborn rat lung.

Glucose, a major metabolic substrate for the mammalian fetus, probably makes significant contributions to surface active phospholipid synthesis in adult lung. We examined the developmental patterns of glycogen content, glycogen synthase activity, glycogen phosphorylase activity and glucose oxidation in fetal and newborn rat lung. These patterns were correlated with the development of phosphatidylcholine synthesis, content and the activities of enzymes involved in phosphatidylcholine synthesis. Fetal lung glycogen concentration increased until day 20 of gestation (term is 22 days) after which it declined to low levels. Activity of both glycogen synthase I and total glycogen synthase (I + D) in fetal lung increased late in gestation. Increased lung glycogen concentration preceded changes in enzyme activity. Glycogen phosphorylase a and total glycogen phosphorylase (a + b) activity in fetal lung increased during the period of prenatal glycogen depletion. The activity of the pentose phosphate pathway, as measured by the ratio of CO2 derived from oxidation of C1 and C6 of glucose, declined after birth. Fetal lung total phospholipid, phosphatidycholine and disaturated phosphatidylcholine content increased by 60, 90 and 180%, respectively, between day 19 of gestation and the first postnatal day. Incorporation of choline into phosphatidylcholine and disaturated phosphatidylcholine increased 10-fold during this time. No changes in phosphatidylcholine enzyme activities were noted during gestation, but both choline phosphate cytidylyltransferase and phosphatidate phosphatase activity increased after birth. The possible contributions of carbohydrate derived from fetal lung glycogen to phospholipid synthesis are discussed.     

Turnover of liver glycogen in the rat foetus.

Incorporation and release of the radioactivity in the liver glycogen of 18.5- and 19.5-day-old rat foetuses were studied after intravenous injection of E11-14C]glycerol. Incorporation occurred during 1 h after injection of the radioactive tracer to the foetus; then, the incorporated radioactivity decreased. Glycogen content in the liver, and glycogen phosphorylase and glycogen synthase were not modified during the experiment. It is therefore postulated that a physiological turnover of glycogen exists in the liver of the rat foetus.     

Isolation and study of a liver alpha-amylase. Comparison with glycogen phosphorylase activity

An oligomaltosaccharide-forming amylase has been observed in mice liver crude homogenate. This enzyme has been isolated by binding to amylose. Some of its functional parameters have been studied and compared with those of glycogen phosphorylase demonstrating that amylase activity is not due to a glycogen phosphorylase isoenzyme. It has been further observed that amylase needs Ca2+ of Mg+2 and Cl- for its activity.