Optimization of liver glycogen extraction when considering the fine molecular structure.

Liver glycogen is a branched glucose polymer that functions as a blood-sugar buffer in animals. Previous studies have shown that glycogen's molecular structure affects its properties. This makes it important to develop a technique that extracts and purifies a representative sample of glycogen. Here we aim to optimize the sucrose density gradient centrifugation method for preserving glycogen's molecular structure by varying the density of the sucrose solution. The preservation of glycogen's structure involves: 1) minimizing molecular damage and 2) obtaining a structurally representative sample of glycogen. The addition of a 10-minute boiling step was also tested as a means for denaturing any glycogen degrading enzymes. Lower sucrose concentrations and the introduction of the boiling step were shown to be beneficial in obtaining a more structurally representative sample, with the preservation of smaller glycogen particles and decreased glycogen chain degradation.

Effects of dichloroacetate on glycogen metabolism in B6C3F1 mice.

Dichloroacetate (DCA) is a by-product of drinking water chlorination. Administration of DCA in drinking water results in accumulation of glycogen in the liver of B6C3F1 mice. To investigate the processes affecting liver glycogen accumulation, male B6C3F1 mice were administered DCA in drinking water at levels varying from 0.1 to 3 g/l for up to 8 weeks. Liver glycogen synthase (GS) and glycogen phosphorylase (GP) activities, liver glycogen content, serum glucose and insulin levels were analyzed. To determine whether effects were primary or attributable to increased glycogen synthesis, some mice were fasted and administered a glucose challenge (20 min before sacrifice). DCA treatments in drinking water caused glycogen accumulation in a dose-dependent manner. The DCA treatment in drinking water suppressed the activity ratio of GS measured in mice sacrificed at 9:00 AM, but not at 3:00 AM. However, net glycogen synthesis after glucose challenge was increased with DCA treatments for 1-2 weeks duration, but the effect was no longer observed at 8 weeks. Degradation of glycogen by fasting decreased progressively as the treatment period was increased, and no longer occurred at 8 weeks. A shift of the liver glycogen-iodine spectrum from DCA-treated mice was observed relative to that of control mice, suggesting a change in the physical form of glycogen. These data suggest that DCA-induced glycogen accumulation at high doses is related to decreases in the degradation rate. When DCA was administered by single intraperitoneal (i.p.) injection to naïve mice at doses of 2-200 mg/kg at the time of glucose challenge, a biphasic response was observed. Doses of 10-25 mg/kg increased both plasma glucose and insulin concentrations. In contrast, very high i.p. doses of DCA (> 75 mg/kg) produced progressive decreases in serum glucose and glycogen deposition in the liver. Since the blood levels of DCA produced by these higher i.p. doses were significantly higher than observed with drinking water treatment, we conclude that apparent differences with data of previous investigations is related to substantial differences in systemic dose and/or dose-time relations.

Purification and characterization of the glycogen-bound protein phosphatase from rat liver.

Glycogen-bound protein phosphatase G from rat liver was transferred from glycogen to beta-cyclodextrin (cycloheptaamylose) linked to Sepharose 6B. After removal of the catalytic subunit and of contaminating proteins with 2 M NaCl, elution with beta-cyclodextrin yielded a single protein on native polyacrylamide gel electrophoresis and two polypeptides (161 and 54 kDa) on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Several lines of evidence indicate that the latter polypeptides are subunits of the protein phosphatase G holoenzyme. First, these polypeptides were also present, together with the catalytic subunit, in the extensively purified holoenzyme. Also, polyclonal antibodies against these polypeptides were able to bind the holoenzyme. Further, while bound to cyclodextrin-Sepharose, the polypeptides were able to recombine with separately purified type-1 (AMD) catalytic subunit, but not with type-2A (PCS) catalytic subunit. The characteristics of the reconstituted enzyme resembled those of the nonpurified protein phosphatase G. At low dilutions, the spontaneous phosphorylase phosphatase activity of the reconstituted enzyme was about 10 times lower than that of the catalytic subunit, but it was about 1000-fold more resistant to inhibition by the modulator protein (inhibitor-2). In contrast with the free catalytic subunit, the reconstituted enzyme co-sedimented with glycogen, and it was able to activate purified liver glycogen synthase b. Also, the synthase phosphatase activity was synergistically increased by a cytosolic phosphatase and inhibited by physiological concentrations of phosphorylase alpha and of Ca2+.

Distinct type-1 protein phosphatases are associated with hepatic glycogen and microsomes.

The type-1 protein phosphatase associated with hepatic microsomes has been distinguished from the glycogen-bound enzyme in five ways. (1) The phosphorylase phosphatase/synthase phosphatase activity ratio of the microsomal enzyme (measured using muscle phosphorylase a and glycogen synthase (labelled in sites-3) as substrates) was 50-fold higher than that of the glycogen-bound enzyme. (2) The microsomal enzyme had a greater sensitivity to inhibitors-1 and 2. (3) Release of the catalytic subunit from the microsomal type-1 phosphatase by tryptic digestion was accompanied by a 2-fold increase in synthase phosphatase activity, whereas release of the catalytic subunit from the glycogen-bound enzyme decreased synthase phosphatase activity by 60%. (4) 95% of the synthase phosphatase activity was released from the microsomes with 0.3 M NaCl, whereas little activity could be released from the glycogen fraction with salt. (5) The type-1 phosphatase separated from glycogen by anion-exchange chromatography could be rebound to glycogen, whereas the microsomal enzyme (separated from the microsomes by the same procedure, or by extraction with NaCl) could not. These findings indicate that the synthase phosphatase activity of the microsomal enzyme is not explained by contamination with glycogen-bound enzyme. The microsomal and glycogen-associated enzymes may contain a common catalytic subunit complexed to microsomal and glycogen-binding subunits, respectively. Thiophosphorylase a was a potent inhibitor of the dephosphorylation of ribosomal protein S6, HMG-CoA reductase and glycogen synthase, by the glycogen-associated type-1 protein phosphatase. By contrast, thiophosphorylase a did not inhibit the dephosphorylation of S6 or HMG-CoA reductase by the microsomal enzyme, although the dephosphorylation of glycogen synthase was inhibited. The I50 for inhibition of synthase phosphatase activity by thiophosphorylase a catalysed by either the glycogen-associated or microsomal type-1 phosphatases, or for inhibition of S6 phosphatase activity catalysed by the glycogen-associated enzyme, was decreased 20-fold to 5-10 nM in the presence of glycogen. The results suggest that the physiologically relevant inhibitor of the glycogen-associated type-1 phosphatase is the phosphorylase a-glycogen complex, and that inhibition of the microsomal type-1 phosphatase by phosphorylase a is unlikely to play a role in the hormonal control of cholesterol or protein synthesis. Protein phosphatase-1 appears to be the principal S6 phosphatase in mammalian liver acting on the serine residues phosphorylated by cyclic AMP-dependent protein kinase.

A micromethod for the enzymatic estimation of the degree of glycogen ramification.

A comparison of methods for the evaluation of glycogen content in liver tissue of rats has been carried out by determining the recoveries in the differential ethanol precipitation of glycogen from alkaline tissue digests as well as the actual quantitative equivalence between glycogen content and actual glucose measured. Hydrolytic/enzymatic methods gave lower results than non-specific chemical methods such as anthrone. These lower values, combined with the losses in the purification process resulted in much lower glycogen estimations than the actual estimated tissue content. A method has been devised for the measurement of glycogen ramification in small liver tissue samples, using neutral periodate oxidation of the molecule, followed by determination of the formic acid evolved from the branch ends with formic acid dehydrogenase. The method gave results very similar to the classical methods in which the acid formed is measured titrimetrically. Rat liver tissue contained a mean 323 +/- 69 mmol of glucose equivalents of glycogen per gram of tissue; this glycogen had a mean chain length of 11.4 +/- 0.8 units.

Studies on the substrate for hepatic lipogenesis in the rat.

The contribution of hepatic glycogen to lipogenesis was studied in isolated, intact rat hepatocytes. To establish its importance as a substrate for lipogenesis, the glycogen of isolated hepatocytes was prelabelled with 14C from glucose. Evidence is presented that neither glucose nor glycogen constitute major sources of carbon for de novo synthesis of fatty acids and that less than 1% of glycogen is converted into fatty acids.

Liver glucose, glycogen and lipid synthesis in fed and 24-hour fasted rats soon after a pulse of [3-14C]pyruvate through the portal vein.

1. A pulse of [3-14C]pyruvate was given to rats through the portal vein and blood was collected at brief intervals from the inferior cava vein at the level of the suprahepatic veins. 2. In 24 hr fasted rats, the appearance of [14C]glucose in blood and blood glucose specific radioactivity were higher than in fed animals from the first minute after delivery of the tracer. At this time total radioactivity did not differ between the two groups. 3. After 5 and 20 min. liver radioactivity present in glycogen and glyceride glycerol was enhanced while in fatty acids it was reduced in fasted as compared with fed animals. 4. It is proposed that, in the fasted state, both glycogen and glyceride glycerol synthesis are predominantly gluconeogenic processes.

[Kinetics of the reaction between muscle glycogen phosphorylase B and glycogen]. / Kinetika vzaimodeistviia myshechnoi glikogenfosforilazy B s glikogenom.

Kinetics of glycogen binding by glycogen phosphorylase b has been studied by stopped flow and temperature jump methods. This reaction is followed by increase in light scattering whose amplitude depends upon the enzyme binding sites concentration of glycogen particles occupied by the enzyme. It has been shown that the complex formation has the first order with respect to enzyme and glycogen concentrations. Relaxation kinetics is compatible with proposed bimolecular reaction scheme. Microscopic rate constants of the forward and reverse reactions of glycogen binding by glycogen phosphorylase b are determined in temperature range from 12,7 to 30 degrees C. The possibility of diffusional control of the binding rate is discussed.

Isolation of glycogen from buffalo liver.

The glycogen has been isolated from buffalo (Bos Bubalus bubalis) liver, purified several-fold, and characterized to compare with rabbit and oyster glycogen. Once-purified buffalo glycogen has been found to contain 1.3% protein, 0.16% nitrogen, 0.69% phosphorous, no lipids, and nucleic acids sufficient to cause absorption at 260 mu. The buffalo glycogen may be used as a potential substitute for rabbit and oyster glycogen after two-or three- purifications and a treatment with DEAE-cellulose.

A protein-bound glycogen component of rat liver.

It has long been claimed, but frequently disputed, that part of the glycogen in rat liver is insoluble in 10% trichloroacetic acid, and a physiological significance was ascribed to the existence of the two pools of glycogen, desmo-glycogen, the insoluble form, and lyo-glycogen, the soluble component. Desmo-glycogen was thought to owe its acid insolubility to a covalent binding to protein. Recent claims that glycogen, similarly insoluble in acid, can be synthesized in vitro have renewed the interest in desmo-glycogen. We have obtained trichloroacetic acid-insoluble glycogen from rat liver and find that, despite subjecting the glycogen to proteolysis, peptide material remains in close association with the glycogen through a number of purification procedures and is freed from glycogen only by enzymic decomposition of the latter. The tenacity with which the glycogen and peptide material remain in association with each other is suggestive of the occurrence of protein-bound glycogen.

Masking of pleomorphic glycogen sites by methanolic uranyl acetate.

Rat liver tissue was fixed in 2.5% glutaraldehyde buffered with cacodylic acid (pH 7.3) for 2 hr, washed twice in buffer, and postfixed in 2% osmium tetroxide at 4 C for 1 hr. The tissue then was dehydrated, infiltrated with and embedded in Epon by routine procedures. The ultrathin sections from this tissue, when stained with spectroscopic grade methanol saturated with uranyl acetate (SMUA) for 1 min followed by aqueous lead citrate (PbCi) (Reynolds 1963) for 5 min at room temperature, showed a uniform staining of all major cellular components except glycogen. The SMUA appeared to be specific for ribonuceloprotein granules, rendering them more prominent in the cytoplasm due to the lack of glycogen staining. The question of glycogen removal from the sections due to SMUA treatment was evulated using various extractions and staining methods. It appeared that SMUA pretreatment alters the subsequent binding ability of lead salts, resulting in lack of glycogen staining, although it does not remove the glycogen from the sections.

The fine structure, potassium content, and respiratory activity of isolated rat liver parenchymal cells prepared by improved enzymatic techniques.

Further modifications of the enzymatic technique for the preparation of isolated, intact, parenchymal cells from rat liver as previously described by this laboratory are presented together with a detailed account of several critical factors involved during the procedure. In addition, the fine structure of the cells as revealed by electron microscopy and the characteristics of their respiratory activity in different media and with several added substrates are described. It is shown that cells obtained by adding calcium during the preparative procedure retain approximately 34% more potassium than cells prepared solely in a calcium-free medium. The former cells also demonstrate a higher respiratory activity, which is not due to uncoupling of respiration. Electron microscopy reveals that the cells have an intact plasma membrane and well-preserved intracellular organelles. Glycogen particles are observed in all cells and are particularly abundant when either 20 mM pyruvate is added during the preparation or Eagle's Minimum Essential Medium is employed.