Histochemistry of the development of the digestive system of Siberian sturgeon during early ontogeny

At hatching, the yolk-sac matrix of Siberian sturgeon Acipenser baeri contained neutral glycoconjugates, glycogen, proteins rich in arginine, lysine, tyrosine, cysteine and cystine, glycoproteins containing mannose (Man) and/or glucose (Glc), N -acetyl-D-galactosamine (GalNAc), L-fucose (Fuc), sialic acid and/or N -acetyl-D-glucosamine (GlcNAc) residues, as well as neutral and acidic lipids. Buccopharyngeal and anterior oesophageal goblet cellls produced a combination of neutral and acid sialoglycoproteins, while those from the posterior oesophagus secreted only neutral glycoproteins; both types of secretions contained tryptophan and -S-S- groups and were unreactive to lectin techniques. Most intestinal goblet cells secreted mainly carboxylated and sulphated sialoglycoproteins with some rests of neutral glycoconjugates, while few of them produced only acid or neutral glycoproteins. Intestinal glycoproteins were rich in GalNAc, GlcNAc and sialic acid residues. Close relationships between digestive enzymes and morphological development of digestive organs were observed. Histochemistry of enzymes revealed that just after hatching, alkaline and acid phosphatase, ATP -ase and non-specific esterase activities were detected in the yolk sac. From the onset of exogenous feeding to the juvenile stage (30 days post-hatch), an enhancement of enzymatic activities was observed, as alkaline and acid phosphatase, ATP -ase, aminopeptidase M and nonspecific esterase sharply increased. However, lipase activity decreased in the liver and brush border of enterocytes by 13–14 days post-hatch. Two types of lipase were detected in the alimentary canal, a non-pancreatic lipase that was secreted in the cardiac stomach by gastric glands, and a pancreatic lipase, which activity was mainly detected in the brush border of the intestinal epithelium.     

A dramatic accumulation of glycogen in the brown adipose tissue of rats following recovery from cold exposure

In a morphological study of brown adipose tissue (BAT) of rats returned after exposure to cold (+5 degrees C) to neutral temperature (+25 degrees C), striking periodic acid Schiff staining was observed, indicating substantial glycogen accumulation. Enzymatic analysis revealed that the glycogen content increased from the 4.05 +/- 0.51 (micromol glucose unit per gram of tissue, mean +/- SE) control value to 57.3 +/- 9.66 when the animals were returned to neutral temperature for 24 h after a 1-week cold period. Glycogen repletion was also observed in liver and skeletal muscle; however, the glycogen levels in these tissues never exceeded the control values. The accumulation of glycogen in the BAT started by the 3rd hour of replacement and peaked by the 24th hour. This glycogen was readily utilized during the next short cold exposure of the animals. The plasma leptin concentration was reduced at the cold temperature. The hexokinase II activity in the BAT increased to 29.3 +/- 1.46 vs the 11.8 +/- 1.06 control (mU/mg protein +/- SE) after a 1-week cold exposure and this level was maintained during the return to neutral temperature. The total glycogen synthetase (GStot) and the glycogen synthetase a activity also increased after a 1-week cold exposure and increased further during the replacement. The level of GStot reached 26.9 +/- 1.39 vs 9.54 +/- 1.43 control by the 24th hour of replacement. At the same time, the glycogen phosphorylase a activity declined during the replacement. The concentration of glucose 6-phosphate (an activator of GS) decreased in the cold but returned to normal during the replacement. These changes in the BAT are in favor of glycogen synthesis.     

Organogenesis of the colon in rats

Colonic organogenesis in rats was studied using light microscopic techniques for the demonstration of mucosubstances, glycogen, and connective tissue fibers. Crypts began as intraepithelial spaces which were in continuity with the colonic lumen. The cells forming the floors of these spaces invaded the nonsulfated acid glycosaminoglycan-rich mesenchyme as the basement membrane became discontinuous. As the diameter of the colon increased, the crypts lengthened and the lamina propria thickened until a layer of collagen and sulfated acid glycosaminoglycans formed at the bases of the crypts and the basement membrane was reestablished. The circular layer of the muscularis externa developed first, then the longitudinal layer, and finally the muscularis mucosae. Three types of mucous cells arose in these newly formed crypts. The initial epithelial cell type contained glycogen and gave rise to cells with apical coats of nonsulfated acid glycoproteins. This cell type was followed by the appearance of cells at the bases of the crypts containing nonsulfated acid glycoproteins. As the crypts lengthened, the goblet cells near the base contained nonsulfated and/or sulfated acid glycoproteins. Closer to and on the surface, the cells contained sulfated acid glycoproteins, a mixture of sulfated acid and neutral glycoproteins, or just neutral glycoproteins. Striated-border cells appeared intermingled with the mucous cells close to the bases of the crypts and continued onto the surface. A comparison was made between regeneration following placement of a surgical lesion in adult rats and events in organogenesis of the colon.     

Glycogen and trehalose accumulation during colony development in Streptomyces antibioticus

Streptomyces antibioticus accumulated glycogen and trehalose in a characteristic way during growth on solid medium. Glycogen storage in the substrate mycelium took place during development of the aerial mycelium. The concentration of nitrogen source in the culture medium influenced the time at which accumulation started as well as the maximum levels of polysaccharide stored. Degradation of these glycogen reserves was observed near the beginning of sporulation. The onset of sporogenesis was always accompanied by a new accumulation of glycogen in sporulating hyphae. During spore maturation the accumulated polysaccharide was degraded. No glycogen was observed in aerial non-sporulating hyphae or in mature spores. Trehalose was detected during all phases of colony development. A preferential accumulation was found in aerial hyphae and spores, where it reached levels up to 12% of the cell dry weight. The possible roles of both carbohydrates in the developmental cycle of Streptomyces are discussed.     

Histochemical studies of mucosubstances in the epidermis of a nonscaly teleost Mystus (Mystus) vittatus Bl. (Pisces-Bagridae)

The epidermis of Mystus (Mystus) vittatus contains two well differentiated mucous cells which secrete different mucosubstances. The goblet cells contain periodate reactive neutral mucosubstances, glycogen, testicular hyaluronidase resistant sulphated mucosubstances, and sialic acid rich glycoproteins. The clavate cells contain small amounts of neutral and sulphated mucosubstances and no glycoproteins. The difference in the histochemical nature of the two types of mucous cells is discussed in relation to their physiological activities.     

Lipid- and glycogen-rich carcinoma of the breast

The authors observed a solid breast carcinoma in a patient aged 70 years. The tumor cells contained lipids, glycogen and neutral glycoproteins. Axillary lymph node metastasis had already existed at the operation.     

The detection by X-ray microanalysis of noradrenaline in sympathetic nerve terminals of the rat vas deferens

Summary The epidermis of Mystus (Mystus) vittatus contains two well differentiated mucous cells which secrete different mucosubstances. The goblet cells contain periodate reactive neutral mucosubstances, glycogen, testicular hyaluronidase resistant sulphated mucosubstances, and sialic acid rich glycoproteins. The clavate cells contain small amounts of neutral and sulphated mucosubstances and no glycoproteins. The difference in the histochemical nature of the two types of mucous cells is discussed in relation to their physiological activities.This investigation was supported by research Fellowship No. 7/176(138)77 from the Council of Scientific & Industrial Research, New Delhi to the first author     

An effective sporulation of Myxococcus xanthus requires glycogen consumption via Pkn4-activated 6-phosphofructokinase

6-Phosphofructokinase (PFK) is a key enzyme for glycolysis in both prokaryotes and eukaryotes. Previously, it was found that the activity of Myxococcus xanthus PFK increased 2.7-fold upon phosphorylation at Thr-226 by the Ser/Thr kinase Pkn4. The pkn4 gene is located 18 bp downstream of the pfk gene forming an operon, and both genes are expressed during vegetative growth and development. Here, we show that glycogen, which accumulates during stationary phase and early in development, is consumed during sporulation. A pfk-pkn4 deletion strain accumulated glycogen at a higher level than the wild-type strain, was unable to consume glycogen during developmental progression and exhibited a poor spore yield. From genetic complementation analysis of the pfk-pkn4 deletion strain with the pfk and pkn4 genes, it was found that glycogen consumption and a high spore yield require not only the pfk gene but also the pkn4 gene. Furthermore, phosphorylation is critical for glycogen consumption because the pfk gene engineered to express the mutant PFK (Thr-226-Ala) did not complement a pfk mutant. We propose that glycogen metabolism in M. xanthus is regulated in a similar manner to that in eukaryotes requiring a protein Ser/Thr kinase.     

Manganese sulfate-dependent glycosylation of endogenous glycoproteins in human skeletal muscle is catalyzed by a nonglucose 6-P-dependent glycogen synthase and not glycogenin

Glycogenin, a Mn2+-dependent, self-glucosylating protein, is considered to catalyze the initial glucosyl transfer steps in glycogen biogenesis. To study the physiologic significance of this enzyme, measurements of glycogenin mediated glucose transfer to endogenous trichloroacetic acid precipitable material (protein-bound glycogen, i.e., glycoproteins) in human skeletal muscle were attempted. Although glycogenin protein was detected in muscle extracts, activity was not, even after exercise that resulted in marked glycogen depletion. Instead, a MnSO4-dependent glucose transfer to glycoproteins, inhibited by glycogen and UDP-pyridoxal (which do not affect glycogenin), and unaffected by CDP (a potent inhibitor of glycogenin), was consistently detected. MnSO4-dependent activity increased in concert with glycogen synthase fractional activity after prolonged exercise, and the MnSO4-dependent enzyme stimulated glucosylation of glycoproteins with molecular masses lower than those glucosylated by glucose 6-P-dependent glycogen synthase. Addition of purified glucose 6-P-dependent glycogen synthase to the muscle extract did not affect MnSO4-dependent glucose transfer, whereas glycogen synthase antibody completely abolished MnSO4-dependent activity. It is concluded that: (1) MnSO4-dependent glucose transfer to glycoproteins is catalyzed by a nonglucose 6-P-dependent form of glycogen synthase; (2) MnSO4-dependent glycogen synthase has a greater affinity for low molecular mass glycoproteins and may thus play a more important role than glucose 6-P-dependent glycogen synthase in the initial stages of glycogen biogenesis; and (3) glycogenin is generally inactive in human muscle in vivo.     

Ontogenetic development and composition of the mucous cells and the occurrence of saccular cells in the epidermis of Atlantic halibut

An increase in the number of mucous cells of the epidermis, as well as qualitative changes of the mucus composition from predominantly neutral to a mixture of neutral and sulphated glycoproteins occurred during the development from a pelagic larva to a bottom-dwelling flatfish. Numerous saccular cells were observed in the epidermis of the yolk-sac larvae that disappeared simultaneously as the mucous cells increased in number in the epidermis of the metamorphosed halibut. These findings may help to understand the protective role of the mucus layer of Atlantic halibut during development as compared to other fish species in aquaculture.     

Role of glycogen content in insulin resistance in human muscle cells

We have used primary human muscle cell cultures to investigate the role of glycogen loading in cellular insulin resistance. Insulin pre-treatment for 2 h markedly impaired insulin signaling, as assessed by protein kinase B (PKB) phosphorylation. In contrast, insulin-dependent glycogen synthesis, glycogen synthase (GS) activation, and GS sites 3 de-phosphorylation were impaired only after 5 h of insulin pre-treatment, whereas 2-deoxyglucose transport was only decreased after 18 h pre-treatment. Insulin-resistant glycogen synthesis was associated closely with maximal glycogen loading. Both glucose limitation and 5-aminoimidazole-4-carboxamide 1-beta-D-ribofuranoside (AICAR) treatment during insulin pre-treatment curtailed glycogen accumulation, and concomitantly restored insulin-sensitive glycogen synthesis and GS activation, although GS de-phosphorylation and PKB phosphorylation remained impaired. Conversely, glycogen super-compensation diminished insulin-sensitive glycogen synthesis and GS activity. Insulin acutely promoted GS translocation to particulate subcellular fractions; this was abolished by insulin pre-treatment, as was GS dephosphorylation therein. Limiting glycogen accumulation during insulin pre-treatment re-instated GS dephosphorylation in particulate fractions, whereas glycogen super-compensation prevented insulin-stimulated GS translocation and dephosphorylation. Our data suggest that diminished insulin signaling alone is insufficient to impair glucose disposal, and indicate a role for glycogen accumulation in inducing insulin resistance in human muscle cells.     

Reserve carbohydrate metabolism in Saccharomyces cerevisiae: responses to nutrient limitation.

The amounts of glycogen and trehalose have been measured in cells of a prototrophic diploid yeast strain subjected to a variety of nutrient limitations. Both glycogen and trehalose were accumulated in cells deprived specifically of nirogen, sulfur, or phosphorus, suggesting that reserve carbohydrate accumulation is a general response to nutrient limitation. The patterns of accumulation and utilization of glycogen and trehalose were not identical under these conditions, suggesting that the two carbohydrates may play distinct physiological roles. Glycogen and trehalose were also accumulated by cells undergoing carbon and energy limitation, both during diauxic growth in a relatively poor medium and during the approach to stationary phase in a rich medium. Growth in the rich medium was shown to be carbon or energy limited or both, although the interaction between carbon source limitation and oxygen limitation was complex. In both media, the pattern of glycogen accumulation and utilization was compatible with its serving as a source of energy both during respiratory adaptation and during a subsequent starvation. In contrast, the pattern of trehalose accumulation and utilization seemed compatible only with the latter role. In cultures that were depleting their supplies of exogenous glucose, the accumulation of glycogen began at glucose concentrations well above those sufficient to suppress glycogen accumulation in cultures growing with a constant concentration of exogenous glucose. The mechanism of this effect is not clear, but may involve a response to the rapid rate of change in the glucose concentration.     

A glycogen phosphorylase inhibitor selectively enhances local rates of glucose utilization in brain during sensory stimulation of conscious rats: implications for glycogen turnover

Glycogen is degraded during brain activation but its role and contribution to functional energetics in normal activated brain have not been established. In the present study, glycogen utilization in brain of normal conscious rats during sensory stimulation was assessed by three approaches, change in concentration, release of (14)C from pre-labeled glycogen and compensatory increase in utilization of blood glucose (CMR(glc)) evoked by treatment with a glycogen phosphorylase inhibitor. Glycogen level fell in cortex, (14)C release increased in three structures and inhibitor treatment caused regionally selective compensatory increases in CMR(glc) over and above the activation-induced rise in vehicle-treated rats. The compensatory rise in CMR(glc) was highest in sensory-parietal cortex where it corresponded to about half of the stimulus-induced rise in CMR(glcf) in vehicle-treated rats; this response did not correlate with metabolic rate, stimulus-induced rise in CMR(glc) or sequential station in sensory pathway. Thus, glycogen is an active fuel for specific structures in normal activated brain, not simply an emergency fuel depot and flux-generated pyruvate greatly exceeded net accumulation of lactate or net consumption of glycogen during activation. The metabolic fate of glycogen is unknown, but adding glycogen to the fuel consumed during activation would contribute to a fall in CMR(O2)/CMR(glc) ratio.     

Modulation of glycogen and trehalose levels in Micromonospora echinospora (ATCC 15837)

The growth of Micromonospora echinospora was studied in high and low C/N ratio medium using both batch and continuous culture. Asparagine was consumed rapidly in batch cultures where it served as both a nitrogen and carbon source. Glucose consumption was low suggesting that asparagine functions as the major carbon source under these conditions. The effect of nutrient limitation on the accumulation of storage carbohydrate in batch culture revealed an intimate association between nitrogen limitation and the accumulation of carbonaceous reserves. This study revealed that glycogen constituted the major carbohydrate reserve associated with the onset of sporulation. Intracellular trehalose levels were found to be relatively low and may have been affected by the availability of carbon. Continuous culture studies revealed a correlation between glycogen accumulation and increasing growth rate. It was also found that elevated cellular ATP levels correlated with the increase in glycogen, and reduced glycolytic activity. At the higher growth rates cellular ATP levels were elevated and coincided with reduced activity of the key glycolytic enzyme, phosphofructokinase, suggesting that glycogen can act as a convenient energy reservoir when excess carbon flux dictates.     

GLYCOGEN METABOLISM AND CHANGES IN THE ACTIVITIES OF PHOSPHORYLASE, PHOSPHOFRUCTOKINASE AND PYRUVATE KINASE DURING DEVELOPMENT OF SEA URCHIN EGGS

The glucose and glycogen contents of sea urchin eggs and embryos were measured enzymatically. Unfertilized eggs of Hemicentrotus pulcherrimus and Anthocidaris crassispina contain about 20.9 and 24.4 μg of glycogen per mg protein, respectively. As for glucose, unfertilized eggs of Hemicentrotus and Anthocidaris contain about 0.7 and 1.9 μg per mg protein, respectively. Glycogen consumption during embryonic development differs with different species of sea urchins. In Anthocidaris , glycogen decreases significantly after fertilization. The oxidation of glucose and glycogen accounts for about 50% of oxygen consumed until the early blastula stage in this species. The contribution ratio of glucose and glycogen to the overall energy pool becomes less than 10% at later stages. In Hemicentrotus , however, the glycogen content remains unchanged until the early blastula stage and thereafter decreases. The importance of glucose and glycogen as an energy fuel seems little throughout the development of Hemicentrotus. Activities of phosphorylase (EC 2.4.1.1), phosphofructokinase (EC 2.7.1.11) and pyruvate kinase (EC 2.7.1.40) were measured at various embryonic stages in both species of sea urchins. The difference between two species in the consumption of glucose and glycogen can not be elucidated by the differences in the activities of these enzymes.     

Glycogen metabolism in rat liver during transition form the fed to fasted states

Hepatic glycogen metabolism was studied in rats during the period of transition from the fed to fasted states. Glycogenic activity was measured in vivo based on the incorporation of [¹⁴C]glucose into liver glycogen. Its changes were almost parallel to the changes in glucogen synthase activity. Progressive accumulation of liver glycogen that occurred in the fed state was associated with a proportional increase in glycogenic activity. Within 4 h after the cessation of food intake, glycogenic activity showd a precipitous fall from the peak to its nadir without significant changes in glycogen content. Meanwhile, the glucose concentration in the portal vein decreased. Upon further development of fasting, glycogenic activity displayed a progressive regain, reciprocally as glycogen contents gradually decreased. The precipitous fall of glycogenic activity during the transition from the fed to fasted states was associated with a transient increase in plasma glucagon, and was partly overcome by the injection of anti-glucagon serum. It is concluded that the fall of portal venous concentration of glucose and secretion of glucagon act as a signal to initiate liver glycogen metabolism characteristics of the fasted or postabsorptive state.     

Histochemical study on the eccrine glands in the foot pad of the cat

Enzyme and carbohydrate histochemical methods were used to study the secretory activities and secretion properties of the eccrine tubular glands in the foot pad of the cat. The activity spectra of the different oxidative and hydrolytic enzymes investigated indicate high metabolic rates within the secretory epithelium. Additionally the enzyme reactions emphasize a double innervation of the glands by cholinergic and adrenergic nerve fibres. The carbohydrate histochemical differentiation reveals mostly neutral and very few acidic glycoproteins in the secretory cells and the secretion, respectively. Clear (basal) cells contain distinct amounts of glycogen, and dark (superficial) cells show neutral glycoproteins, which reveal after PO-lectin-DAB procedures the following saccharide residues: alpha-D-mannose, alpha-D-galactose, N-acetyl-alpha-D-glucosamine, alpha-L-fucose, beta-D-galactose-D-N-galactosamine, beta-D-galactose, and sialic acid. The results obtained confirm the view that the normal biological functions of the eccrine glands of the feline foot pad are to improve the frictional capacities of the paw and to leave typical scent marks.     

The role of glycogen synthase phosphatase in the glucocorticoid-induced deposition of glycogen in foetal rat liver.

1. The mechanism that underlies the induction of glycogen synthesis in the foetal rat liver by glucocorticoids was reinvestigated in conditions where the accumulation of glycogen is either precociously induced with dexamethasone or inhibited by steroid deprivation. It appears that glucocorticoids act as the physiological trigger for glycogen synthesis by inducing both glycogen synthase (a known effect) and its activating enzyme, glycogen synthase phosphatase. 2. The activity of glycogen synthase phosphatase in adult liver stems from the interaction of two protein components [Doperé, Vanstapel & Stalmans (1980) Eur. J. Biochem. 104, 137--146]. Two independent experimental approaches indicate that the cytosolic 'S-component' is already well developed in the foetal liver before the onset of glycogen synthesis. The manifold glucocorticoid-dependent increase in synthase phosphatase activity during late gestation must be attributed to the specific development of the glycogen-bound 'G-component'.     

The role of diet in glycogen storage by juvenile bullfrogs prior to overwintering

Juvenile bullfrogs from natural populations doubled their glycogen stores during their predormancy period, while their blood glucose and lipid stores declined. Glycogen stores were replenished in natural populations as food consumption decreased. Some liver glycogen was stored during fasting if the bullfrogs were collected in the storage phase of their energy reserve cycle, but the amount of glycogen stored was increased by feeding.