Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UNIPROT:P01275 (glucagon)
26,492 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Large amounts of glycogen accumulate in rat skeletal muscle fibers during the late fetal stages and are mobilized in the first postnatal days. This glycogen depletion is relatively slow in the immature leg muscles, in which extensive deposits are still found 24 hr after birth and, to some extent, persist until the 3rd day. In the more differentiated psoas muscle and especially in the diaphragm, the glycogen stores are completely mobilized already during the early hours. Section of the sciatic nerve 3 days before birth or within the first 2 hr after delivery does not affect glycogen depletion in the leg muscles. Neonatal glycogenolysis in rat muscle fibers takes place largely by segregation and digestion of glycogen particles in autophagic vacuoles. These vacuoles: (a) are not seen in fetal muscle fibers or at later postnatal stages, but appear concomitantly with the process of glycogen depletion and disappear shortly afterwards; (b) are prematurely formed in skeletal muscles of fetuses at term treated with glucagon; (c) contain almost exclusively glycogen particles and no other recognizable cell constituents; (d) have a double or, more often, single limiting membrane and originate apparently from flattened sacs sequestering glycogen masses; (e) are generally found to contain reaction product in preparations incubated from demonstration of acid phosphatase activity. The findings emphasize the role of the lysosomal system in the physiological process of postnatal glycogen mobilization and appear relevant in the interpretation of type II glycogen storage disease.
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PMID:Autophagic degradation of glycogen in skeletal muscles of the newborn rat. 433

The purpose of the present study was to elucidate the metabolic requirements of autophagocytosis. Two model systems were used for this purpose: a) glucagon-induced autophagocytosis in the rat liver, and b) the wave of autophagocytosis which occurs when isolated flounder kidney tubules are incubated in vitro. In the rat liver, protein synthesis was inhibited by the administration of cycloheximide (1.5 mg/kg) to rats 2 hours prior to glucagon injection. In flounder kidney tubules, protein synthesis was inhibited at least 90% by adding cycloheximide, actinomycin D, pactamycin and puromycin to the medium. In both systems the inhibition of protein synthesis failed to inhibit the formation of autophagic vacuoles or their subsequent transformation into autolysosomes, as depicted from electron microscopic histochemical preparations. In flounder kidney tubules no differences were found in the levels of p-nitrophenylphosphates, beta-DL-glycerophosphatase, N-acetyl-beta-D-glucosaminidase, arylsulphatase, beta-D-galactosidase or acid proteinase when tubules were incubated up to 5 hours in the presence or absence of protein synthesis inhibitors. When ethionine was administered to rats 2 hours before glucagon injection, a decrease of approximately 75% in the ATP levels was observed. After ethionine administration, glucagon failed to induce the formation of autophagic vacuoles. The incubation of flounder kidney tubules in the presence of cyanide or in a nitrogen atmosphere decreased the ATP levels to less than 10% of controls and blocked autophagy. On the other hand, cyanide had little effect on acid hydrolase levels at 1 hour of incubation. A wide variety of other inhibitors were also shown to block autophagy. These results further support the hypothesis that, in the formation of antophagic vacuoles, preexisting enzyme and membrane pools are utilized. On the other hand, the esotropy-exotropy membrane conformational changes occurring in the formation of autophagic vacuoles seem to be energy dependent and can therefore be blocked by lowering intracellular ATP levels.
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PMID:Studies on cellular autophagocytosis. The relationship of autophagocytosis to protein synthesis and to energy metabolism in rat liver and flounder kidney tubules in vitro. 476 57

Up to 4 weeks after partial hepatectomy the concentrations of immunoreactive insulin and glucagon in the blood plasma of rats were determined. Furthermore we measured the activity of acid phosphatase in the serum, the concentration of cyclic AMP in liver cells, the activities of acid phosphatase in whole liver cells and in the cytosol of liver cells after partial hepatectomy. 2 h after partial hepatectomy there was a decline of the concentration of insulin in the plasma to about 13% of the initial value. 12 h after surgery a 5-fold increase of glucagon was found in the plasma. Shortly after this cyclic AMP reached its highest concentration. The activity of acid phosphatase in the whole liver cells and in the cytosol decreases slightly in the first 24 h after surgery whereas there is an increase of the activity of acid phosphatase in the serum.
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PMID:[Insulin and glucagon in the blood plasma of partial hepatectomized rats (author's transl)]. 625 Feb 96

Data are presented on the variation of the residual latent activity of acid phosphatase after hypo-osmotic shock in relation to differences in the functional state of the vacuolar apparatus, as obtained after 24 hours of fasting or treatment with glucagon. It is moreover reported the effect of cycloheximide, which appears able to interfere not only with the glucagon-induced autophagy, but in all likelihood also with the basal autophagic processes.
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PMID:Effect of fasting and glucagon on the residual latent activity of acid phosphatase in rat liver. 743 37

This study was done to determine glucagon's effect on protein biliary excretion in anesthetized, bile duct-cannulated guinea pigs. Glucagon (1.4 nmol.min-1.kg-1) induced choleresis and increased protein biliary concentration from 0.12 +/- 0.04 to 0.20 +/- 0.6 mg/ml and protein output from 22.8 +/- 3.8 to 54.5 +/- 16.1 micrograms.kg-1.min-1. Protein biliary excretion increased during the first 10 min of glucagon infusion and progressively declined thereafter. Biochemical analysis of biliary protein revealed that the increase could be accounted for primarily by an increase in the lysosomal enzymes acid phosphatase and beta-glucuronidase. Biliary excretion of the canalicular membrane enzymes 5'-nucleotidase and alkaline phosphatase only modestly increased, whereas that of [14C]sucrose, a marker of paracellular fluid transport, was unaffected. On the other hand, glucagon enhanced biliary entry of horseradish peroxidase in a fashion similar to that observed with total endogenous protein. These effects were mediated by the adenosine 3',5'-cyclic monophosphate (cAMP) system, since infusion of dibutyryl-cAMP at 0.5 mumol.kg-1.min-1 increased bile flow and biliary protein excretion in a time-dependent manner, as observed with glucagon. Glucagon's failure to sustain enhanced protein biliary output was not due to declining hepatic concentrations of cAMP or to depletion of hepatocellular lysosomal enzymes. These studies provide evidence that glucagon stimulates biliary excretion of protein in guinea pigs that can be accounted for by biliary discharge of enzyme originating from the canalicular membrane and, primarily, from the lysosomal compartment. Although the precise mechanism(s) underlying these effects remains to be elucidated, it is suggested that the increase in canalicular membrane enzyme excretion is due to glucagon's effect on exocytosis.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Glucagon induces biliary protein excretion in guinea pigs. 838 43

The endosome-lysosome transfer of in vivo internalized insulin and glucagon has been studied in a rat liver cell-free system and compared to that of galactosylated bovine serum albumin (GalBSA), a ligand of the asialoglycoprotein receptor. Density-gradient analysis of a postmitochondrial supernatant isolated 8 min after injection of [125I]iodoinsulin showed that the membrane-associated radioactivity (55% of the total) migrated as a single peak at the position of galactosyltransferase, a Golgi marker (1.08-1.10 g/ml). After incubation at 37 degrees C in the presence of ATP, an additional peak of radioactivity (12%) was detected at the position of acid phosphatase, a lysosomal marker (1.12-1.14 g/ml). No such peak was observed in a lysosome-depleted fraction. An ATP-dependent conversion of [125I]iodoinsulin to trichloroacetic-acid-soluble products occurred during incubation (20%) but this was unaffected by lysosome depletion. Gel-filtration and HPLC analysis of acid extracts of gradient fractions isolated after injection of [125I]iodoinsulins selectively labeled at tyrosine residues A14 or B26 revealed the presence of components which differed from intact iodoinsulins by size and/or hydrophobicity. Low molecular-mass components were less abundant and, conversely, intact iodoinsulin and/or high molecular-mass components more abundant in lysosomal fractions than in endosomal fractions. In vivo internalized [125I]iodoglucagon and [125I]iodogalBSA underwent a greater lysosomal transfer (17-21%) and lesser degradation (8-11%) than [125I]iodoinsulin. Glycyl-L-phenylalanine 2-naphtylamide and methionine O-methyl ester, two lysosome-disrupting enzyme substrates, partially released the radioactivity associated with lysosomal fractions (GalBSA > insulin = glucagon) but caused little or no release of that associated with endosomal fractions. Analysis of the alpha and beta subunits of the insulin receptor by cross-linking to [125I]iodoinsulin and Western immunoblotting, respectively, revealed a partial lysosomal transfer of these subunits during endosome-lysosome interaction. We conclude that an endosome-lysosome transfer of insulin and glucagon occurs in a liver cell-free system and suggest that the low recovery of these peptides in lysosomal fractions in vivo results from their rapid degradation within endosomes.
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PMID:Endosome-lysosome transfer of insulin and glucagon in a liver cell-free system. 968 63

Peritoneal and bronchoalveolar macrophages activated in vitro by endotoxin, exhibit alterations in the acid phosphatase activity of cell lysates when certain hormones or autacoids are present in the culture medium. They also show morphological changes concerning general appearance and acid phosphatase cytochemistry. Certain agents known to increase the intracellular levels of cyclic AMP, such as dopamine and prostaglandin E2, decreased this enzyme activity in the lysates of peritoneal macrophages. Adrenalin had no effect on this activity at 14 hours, but was found to increase the activity in the culture medium at the initial hours of incubation. Glucagon decreased whereas insulin increased acid phosphatase activity in bronchoalveolar macrophages. Serotonin or histamine, known to activate phospholipase C, increased this activity in peritoneal or bronchoalveolar macrophages. The results of this study, taken together with previously published data (Kondomerkos et al., 2003), suggest that hormones and autacoids may control certain parameters of macrophage activation including acid phosphatase activity.
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PMID:In vitro effects of hormones and autacoids on the activity of acid phosphatase in the lysates of endotoxin-activated rat peritoneal and bronchoalveolar macrophages. 1297 79

The addition of phosphate groups is an essential requirement for the proper functioning of cyclin and cyclin dependent kinase which control various stages in the mitotic division of cancer cells. Thus limiting the availability of phosphate is likely to interfere with the metabolism of rapidly growing malignant cells. The human hormone glucagon and the anti metabolite mithramycin reduce serum phosphate by increasing phosphaturia and are both very effective in treating Paget's disease of bone, a precancerous condition. In this disorder large doses of glucagon given intravenously relieve bone pain and cause serum phosphate and alkaline phosphatase as well as urine hydroxyproline to fall, indicating a marked reduction in bone turnover. A constant iv infusion of glucagon was given to each of three patients all of whom had secondary malignant bone deposits. Two of the patients had primary prostate cancer and one had a squamous cell lung tumour. All three patients had relief of bone pain and a fall in serum alkaline phosphatase. Serum acid phosphatase also fell in the two patients with prostate cancer. It is proposed that the marked drop in serum phosphate due to glucagon causes intracellular phosphate to fall. This in turn disrupts the addition and removal of phosphate groups essential for the proper functioning of cyclin and cyclin dependent kinase. These two proteins control the transition from G1 to S (DNA synthesis phase) and G2 to M (mitotic phase) in the dividing cycle of malignant cells. Depriving a tumour of an essential ingredient used in phosphorylation reactions will disrupt its growth. It is also proposed that, by the same mechanism, glucagon induced hypophosphataemia renders malignant cells more sensitive to established chemotherapeutic agents and radiation waves. If this hypothesis proves to be correct, lowering intracellular phosphate may become an useful tool in cancer therapy. However extensive studies are necessary to determine whether mitosis in cancer cells can be advantageously disrupted by glucagon induced hypophosphataemia.
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PMID:Inhibition of cancer cell mitosis by reducing the availability of phosphate. 2795 79


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