An In Vivo Nuclear Magnetic Resonance Spectroscopic Study
6
Citation
31
Reference
20
Related Paper
Citation Trend
Abstract:
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
Glycogenesis
Glycogen debranching enzyme
Phosphorylase kinase
Cite
The effect of fructose on glycogen synthesis was examined in the perfused liver of starved rats. With increasing fructose concentration in the perfusate, glycogen synthesis and the % a form of glycogen synthase increased to a maximum at 2 mM and then decreased, progressively. The glucose 6-P level increased with the increase in fructose concentration. On the other hand, the ATP content was unchanged at a concentration of 2 mM or less and decreased at 3 mM or more. We also showed that the stimulation of glycogen synthesis by fructose at a concentration of 2 mM or less was due to activation of glycogen synthase by accumulated glucose 6-P and that ATP depletion at a concentration of 3 mM or more caused an increase in phosphorylase a and a decrease in glycogen synthase activity even in the presence of a high concentration of glucose 6-P.
Glycogen branching enzyme
Fructolysis
Glycogenesis
Cite
Citations (5)
Glycogenesis
Glycogen branching enzyme
Cite
Citations (11)
Introduction: Glycogen is the primary intracellular storage form of carbohydrates. In contrast to most tissues where stored glycogen can only supply the local tissue with energy, hepatic glycogen is mobilized and released into the blood to maintain appropriate circulating glucose levels, and is delivered to other tissues as glucose in response to energetic demands. Insulin and glucagon, two current targets of high interest in the pharmaceutical industry, are well known glucose-regulating hormones whose primary effect in liver is to modulate glycogen synthesis and breakdown. The purpose of these studies was to develop methods to measure glycogen metabolism in real time non-invasively both in isolated mouse livers, and in non-human primates (NHPs) using 13C MRS. Methods: Livers were harvested from C57/Bl6 mice and perfused with [1-13C] Glucose. To demonstrate the ability to measure acute changes in glycogen metabolism ex-vivo, fructose, glucagon, and insulin were administered to the liver ex-vivo. The C1 resonance of glycogen was measured in real time with 13C MRS using an 11.7T (500 MHz) NMR spectrometer. To demonstrate the translatability of this approach, NHPs (male rhesus monkeys) were studied in a 7 T Philips MRI using a partial volume 1H/13C imaging coil. NPHs were subjected to a variable IV infusion of [1-13C] glucose (to maintain blood glucose at 3-4x basal), along with a constant 1 mg/kg/min infusion of fructose. The C1 resonance of glycogen was again measured in real time with 13C MRS. To demonstrate the ability to measure changes in glycogen metabolism in vivo, animals received a glucagon infusion (1 μg/kg bolus followed by 40 ng/kg/min constant infusion) half way through the study on the second study session. Results: In both perfused mouse livers and in NHPs, hepatic 13C-glycogen synthesis (i.e. monotonic increases in the 13C-glycogen NMR signal) was readily detected. In both paradigms, addition of glucagon resulted in cessation of glycogen synthesis and induction of glycogen breakdown. In the perfused liver, inclusion of insulin was able to dose-dependently block the effect of glucagon. Conclusion: Hepatic glycogen synthesis, as well as acute hormonally-induced changes thereof, can be measured using 13C MRS at high magnetic fields both ex-vivo
Glycogenesis
Glycogenolysis
Basal (medicine)
Ex vivo
Carbohydrate Metabolism
Cite
Citations (6)
Glycogenesis
Gluconeogenesis
Glycogen branching enzyme
Glycogenolysis
Cite
Citations (20)
Refeeding syndrome
Cite
Citations (16)
Glycogen debranching enzyme
Glycogen branching enzyme
Cite
Citations (8)
Cite
Citations (32)
Abstract Intragastric infusion of [1-14C]glucose into awake, fasted rats at rates that produced physiological increases in the circulating glucose concentration resulted in active glycogen deposition in liver. However, degradation of this glycogen revealed extensive randomization of the label among the carbon atoms of glucose. By contrast, muscle glycogen-glucose was labeled primarily in C-1. Treatment of rats with 3-mercaptopicolinic acid, a potent inhibitor of phosphoenol-pyruvate carboxykinase, prior to [1-14C]glucose infusion reduced hepatic glycogen synthesis by 85%; this glycogen contained most of its label in C-1 of glucose. The additional infusion of unlabeled glycerol, which enters the gluconeogenic pathway distal to the 3-mercaptopicolinic acid block, reinstated hepatic glycogen synthesis, but again the label was associated almost exclusively with C-1. In all animals treated with 3-mercaptopicolinic acid, plasma lactate concentrations rose markedly, as did the rate of hepatic lipogenesis. When [1-14C]glucose was infused into pentobarbital-treated rats or administered to awake animals as a large intragastric bolus, the degree of isotopic randomization in liver glycogen-glucose was considerably reduced when compared with that seen in the awake, infused state. The data support the concept that under normal refeeding conditions the bulk of liver glycogen is formed by an indirect pathway involving the sequence glucose ----lactate----glucose-6-P----glycogen, whereas muscle glycogen is formed by the conventional, direct pathway: glucose----glucose-6-P----glycogen. They also establish that a predominantly direct mechanism can be induced in liver, but only under artificial conditions, e.g. chemical blockade of the gluconeogenic sequence, pentobarbital anesthesia, or the administration of massive glucose loads that lead to severe hyperglycemia.
Gluconeogenesis
Carbon fibers
Cite
Citations (197)
To assess whether hepatic glycogen is actively turning over under conditions which promote net glycogen synthesis we perfused livers from 24-h fasted rats with 20 mM D-[1-13C]glucose, 10 mM L-[3-13C]alanine, 10 mM L-[3-13C]lactate, and 1 microM insulin for 90 min followed by a 75-min chase period with perfusate of the same composition containing either 13C-enriched or unlabeled substrates. The peak height of the C-1 resonance of the glucosyl subunits in glycogen was monitored, in real time, using 13C NMR techniques. During the initial 90 min the peak height of the C-1 resonance of glycogen increased at almost a constant rate reflecting a near linear increase in net glycogen synthesis, which persisted for a further 75 min if 13C-enriched substrates were present during the chase period. However, when the perfusate was switched to the unenriched substrates, the peak height of the C-1 resonance of glycogen declined in a nearly linear manner reflecting active glycogenolysis during a time of net glycogen synthesis. By comparing the slopes of the curve describing the time course of the net [1-13C] glucose incorporation into glycogen with the rate of net loss of 13C label from the C-1 resonance of glycogen during the chase period we estimated the relative rate of glycogen breakdown to be 60% of the net glycogen synthetic rate. Whether this same phenomenon occurs to such an appreciable extent in vivo remains to be determined.
Cite
Citations (68)