An In Vivo Nuclear Magnetic Resonance Spectroscopic Study
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Using 3C nuclear magnetic resonance spectroscopic methods we examined in vivo the synthesis of liver glycogen during the infusion of D-11-13Cjglucose and the turnover of labeled glycogen during subsequent infusion of D-11-13Cjglucose. In fasted rats the processes of glycogen synthesis and degradation were observed to occur simultaneously with the rate of synthesis > degradation leading to net glycogen synthesis. In fed rats, incorporation of infused D-[1-_3Cjglucose occurred briskly; however, over 2 h there was no net glycogen accumulated. Degradation of labeled glycogen was greater in the fed versus the fasted rats (P < 0.001), and the lack of net glycogen synthesis in fed rats was due to degradation and synthesis occurring at similar rates throughout the infusion period. There was no indication that suppression of phosphorylase a or subsequent activation of glycogen synthase was involved in modulation of the flux of tracer into liver glycogen. We conclude that in both fed and fasted rats, glycogen synthase and phosphorylase are active simultaneously and the levels of liver glycogen reached during refeeding are determined by the balance between ongoing synthetic and degradaKeywords:
Glycogen branching enzyme
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Glycogen debranching enzyme
Phosphorylase kinase
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Glucogen synthesis in rat liver in vivo was measured by the incorporation of 3H from 3H2O into glycogen. In meal-fed rats incorporation and the incorporation of 3H into glycogen was linear up to 100 min. Before feeding glycogen concentration and the incorporation of 3H were both low; and both rose on feeding to give maximal values after 2-3h. The glycogen concentration was maintained for a further 5h but the incorporation of 3H rapidly declined to pre-feeding values. This shows that glycogen turnover was low in the post-prandial rat. Streptozotocin diabetes decreased the rise in glycogen concentration on feeding and had a similar effect on 3H2O incorporation. Both effects were reversed by insulin administration. The number of 3H atoms incorporated per glycogen glucose moiety formed in biosynthetic experiments (2.84 +/- 0.47) was relatively constant and allowed absolute biosynthetic rates to be calculated. Degradation of glucose from glycogen labelled by 3H2O showed that most of the 3H was located at C-2 and C-5. The incorporation would arise by rapid equilibration of hexose phosphates through phosphoglucose isomerase, transaldolase and triose phosphate isomerase.
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Glucose-6-phosphate isomerase
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The activities of glycogen synthase and glycogen phosphorylase were quantitated in liver and skeletal muscle removed following glucose infusion in hemodynamically stable endotoxin-treated rats. Four hours after the IV injection of endotoxin or saline, rats were infused with 235 mumole/min/kg of glucose or saline for up to 4 additional hr. Saline-infused endotoxemic rats had lower basal glycogen content in muscle and liver, which was associated with an increased phosphorylase a activity in both tissues compared to controls. During the glucose infusion, the rate of glycogen repletion in muscle was similar in the two groups. Skeletal muscle phosphorylase a and glycogen synthase I & D activities were elevated above control values in endotoxemia, while glycogen synthase I activity remain unchanged. These changes in the activity of muscle phosphorylase and synthase are consistent with an increased flux of carbon into and out of glycogen and a normal rate of net glycogen synthesis during glucose infusion in endotoxin-treated rats. In contrast to muscle, hepatic glycogen synthesis by endotoxemic animals was reduced compared to glucose-infused controls. Hepatic glycogen repletion in control animals appeared to be mediated primarily by a glucose-induced suppression of phosphorylase a activity rather than an increased glycogen synthase activity. Glucose infusion failed to decrease phosphorylase a activity in endotoxin-treated rats, which may be causally related to the impaired ability of these animals to replete liver glycogen.
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Glycogen branching enzyme
Glycogen debranching enzyme
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1. In the isolated perfused liver from 48h-starved rats, glycogen synthesis was followed by sequential sampling of the two major lobes. 2. The fastest observed rates of glycogen deposition (0.68-0.82mumol of glucose/min per g fresh liver) were obtained in the left lateral lobe, when glucose in the medium was 25-30mm and when gluconeogenic substrates were present (pyruvate, glycerol and serine: each initially 5mm). In this situation there was no net disappearance of glucose from the perfusion medium, although (14)C from [U-(14)C]glucose was incorporated into glycogen. There was no requirement for added hormones. 3. In the absence of gluconeogenic precursors, glycogen synthesis from glucose (30mm) was 0-0.4mumol/min per g. 4. When livers were perfused with gluconeogenic precursors alone, no glycogen was deposited. The total amount of glucose formed was similar to the amount converted into glycogen when 30mm-glucose was also present. 5. The time-course, maximal rates and glucose dependence of hepatic glycogen deposition in the perfused liver resembled those found in vivo in 48h-starved rats, during infusion of glucose. 6. In the perfused liver, added insulin or sodium oleate did not significantly affect glycogen synthesis in optimum conditions. In suboptimum conditions (i.e. glucose less than 25mm, or with gluconeogenic precursors absent) insulin caused a moderate acceleration of glycogen deposition. 7. These results suggest that on re-feeding after starvation in the rat, hepatic glycogen deposition could be initially the result of continued gluconeogenesis, even after the ingestion of glucose. This conclusion is discussed, particularly in connexion with the role of hepatic glucokinase, and the involvement of the liver in the glucose intolerance of starvation.
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Conference Article| February 01 1989 Glucose disposal as glycogen on glucose refeeding after starvation DIMITY J. COX; DIMITY J. COX *Department of Biochemistry, Charing Cross and Westminster Medical School, Fulham Palace Road, London W6 8RF, U.K. Search for other works by this author on: This Site PubMed Google Scholar MARY C. SUGDEN; MARY C. SUGDEN †Department of Chemical Pathology, London Hospital Medical College, Turner Street, London E1 2AD, U.K. Search for other works by this author on: This Site PubMed Google Scholar T. NORMAN PALMER T. NORMAN PALMER *Department of Biochemistry, Charing Cross and Westminster Medical School, Fulham Palace Road, London W6 8RF, U.K. Search for other works by this author on: This Site PubMed Google Scholar Biochem Soc Trans (1989) 17 (1): 155. https://doi.org/10.1042/bst0170155 Article history Received: June 17 1988 Views Icon Views Article contents Figures & tables Video Audio Supplementary Data Peer Review Share Icon Share Facebook Twitter LinkedIn MailTo Cite Icon Cite Get Permissions Citation DIMITY J. COX, MARY C. SUGDEN, T. NORMAN PALMER; Glucose disposal as glycogen on glucose refeeding after starvation. Biochem Soc Trans 1 February 1989; 17 (1): 155. doi: https://doi.org/10.1042/bst0170155 Download citation file: Ris (Zotero) Reference Manager EasyBib Bookends Mendeley Papers EndNote RefWorks BibTex toolbar search Search Dropdown Menu toolbar search search input Search input auto suggest filter your search All ContentAll JournalsBiochemical Society Transactions Search Advanced Search This content is only available as a PDF. © 1989 Biochemical Society1989 Article PDF first page preview Close Modal You do not currently have access to this content.
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Using 13C and 1H NMR we measured the rate of glycogen synthesis (0.23 +/- 0.10 mumol/min gram wet weight tissue (gww) in rat heart in vivo during an intravenous infusion of D-[1-13C]glucose and insulin. Glycogen was observed within 10 min of starting and increased linearly throughout a 50-min infusion. This compared closely with the average activity of glycogen synthase I (0.22 +/- 0.03 mumol/min gww) measured at physiologic concentrations of UDP-glucose (92 microM) and glucose-6-phosphate (110 microM). When unlabeled glycogen replaced D-[1-13C]glucose in the infusate after 50 min the D-[1-13C]glycogen signal remained stable for another 60 min, indicating that no turnover of the newly synthesized glycogen had occurred. Despite this phosphorylase a activity in heart extracts from rats given a 1 h glucose and insulin infusion (3.8 +/- 2.4 mumol/min gww) greatly exceeded the total synthase activity and if active in vivo should promote glycogenolysis. We conclude that during glucose and insulin infusion in the rat: (a) the absolute rate of myocardial glycogen synthesis can be measured in vivo by NMR; (b) glycogen synthase I can account for the observed rates of heart glycogen synthesis; (c) there is no futile cycling of glucose in and out of heart glycogen; and (d) the activity of phosphorylase a measured in tissue extracts is not reflected in vivo. These studies raise the question whether significant regulation of phosphorylase a activity in vivo is mediated by factors in addition to its phosphorylation state.
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Characterization of in vivo glycogen synthesis in the rat uterus after estrogen administration revealed: a) an initial lag phase of less than 2 hr; b) a period, from 2 to 10 hr, when glycogen concentrations increased at a constant rate; c) an equilibrium period from 10 to 24 hr, followed by: d) a decline in glycogen concentration approximately 24 hr after estrogen administration. The glycogen synthesis induced by 1 μg of estradiol, which was 3 to 4 times control levels at 10–12 hr, appeared to be maximal. Larger doses (10 μg) of estradiol or repeated estrogen injections did not result in a reaction rate different from that observed with 1 μg, suggesting that maximal stimulation of the glycogenic systems had probably been attained. Glycogen synthesis adhered to first order reaction rate kinetics. The rate constant (K) was 1.94 ×1O-3 min-1, which resulted in an increase in glycogen synthesis of about 12% each hour. (Endocrinology76: 63, 1965)
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In order to quantitate the pathways by which liver glycogen is repleted, we administered [1-13C]glucose by gavage into awake 24-h fasted rats and examined the labeling pattern of 13C in hepatic glycogen. Two doses of [1-13C]glucose, 1 and 6 mg/g body wt, were given to examine whether differences in the plasma glucose concentration altered the metabolic pathways via which liver glycogen was replenished. After 1 and 3 h (high-dose group) and after 1 and 2 h (low-dose group), the animals were anesthetized and the liver was quickly freeze-clamped. Liver glycogen was extracted and the purified glycogen hydrolyzed to glucose with amyloglucosidase. The distribution of the 13C-label was subsequently determined by 13C-nuclear magnetic resonance spectroscopy. The percent 13C enrichment of the glucosyl units in glycogen was: 15.1 +/- 0.8%(C-1), 1.5 +/- 0.1%(C-2), 1.2 +/- 0.1%(C-3), 1.1 +/- 0.1%(C-4), 1.6 +/- 0.1%(C-5), and 2.2 +/- 0.1%(C-6) for the high-dose study (n = 4, at 3 h); 16.5 +/- 0.5%(C-1), 2.0 +/- 0.1%(C-2), 1.3 +/- 0.1%(C-3), 1.1 +/- 0.1%(C-4), 2.2 +/- 0.1%(C-5), and 2.4 +/- 0.1%(C-6) in the low-dose study (n = 4, at 2 h). The average 13C-enrichment of C-1 glucose in the portal vein was found to be 43 +/- 1 and 40 +/- 2% in the high- and low-dose groups, respectively. Therefore, the amount of glycogen that was synthesized from the direct pathway (i.e., glucose----glucose-6-phosphate----glucose-1-phosphate----UDP-glucose---- glycogen) was calculated to be 31 and 36% in the high- and low-dose groups, respectively. The 13C-enrichments of portal vein lactate and alanine were 14 and 14%, respectively, in the high-dose group and 11 and 8%, respectively, in the low-dose group. From these enrichments, the minimum contribution of these gluconeogenic precursors to glycogen repletion can be calculated to be 7 and 20% in the high- and low-dose groups, respectively. The maximum contribution of glucose recycling at the triose isomerase step to glycogen synthesis (i.e., glucose----triose-phosphates----glycogen) was estimated to be 3 and 1% in the high- and low-dose groups, respectively. In conclusion, our results demonstrate that (a) only one-third of liver glycogen repletion occurs via the direct conversion of glucose to glycogen, and that (b) only a very small amount of glycogen synthesis can be accounted for by the conversion of glucose to triose phosphates and back to glycogen; this suggests that futile cycling between fructose-6-phosphate and fructose-1,6-diphosphate under these conditions is minimal. Our results also show that (c) alanine and lactate account for a minimum of between 7 and 20% of the glycogen synthesized, and that (d) the three pathways through which the labeled flux is measured account for a total of only 50% of the total glycogen synthesized. These results suggest that either there is a sizeable amount of glycogen synthesis via pathway(s) that were not examined in the present experiment or that there is a much greater dilution of labeled alanine/lactate in the oxaloacetate pool than previously appreciated, or some combination of these two explanations.
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Glycogenolysis
Fructolysis
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Glycogen branching enzyme
Carbohydrate Metabolism
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Glycogen branching enzyme
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