Glycogen phosphorylase from human leukocytes. Isolation and kinetic properties

Homogeneous glycogen phosphorylase from human leukocytes has been obtained. A one-step bioluminescent procedure for the enzyme activity assay has been developed. This method is based on a continuous recording of the product of the glycogen phosphorylase-catalyzed reaction using a coimmobilized multienzyme system (phosphoglucomutase, glucose-6-phosphate dehydrogenase, NADH:FMN oxidoreductase and bacterial luciferase). The method sensitivity is 10 times as high compared to earlier described methods. The Km values for glycogen (0.2 mg/ml) and phosphate (3.9 mM) at pH 7.9 were determined. AMP was shown to be the enzyme effector.     

A stopped-flow assay for glycogen phosphorylase appropriate to measure catalytic activity at high enzyme concentrations

Glycogen phosphorylase (EC 2.4.1.1) may be assayed in the glycogen degradation direction by a continuous spectrophotometric method. The formation of glucose 1-phosphate from glycogen and phosphate produces a controlled change of pH which can be measured by the changes in absorbance of phenol red added to the system. The procedure may be conveniently applied to a stopped-flow spectrophotometer to measure the rate of the reaction. Therefore the activity of the enzyme may be determined at low conventional concentrations and, by the same technique, at high enzyme concentrations approaching those supposed to exist in vivo.     

Specific mixed disulfide formation with purified bovine cardiac glycogen synthase I and glutathione

Bovine cardiac glycogen-free glycogen synthase I reacts with oxidized glutathione at low temperature to partially inactivate the enzyme. Evidence is presented that a mixed disulfide between glutathione and the enzyme is formed in this reaction. A short incubation of the GSSG-treated enzyme with dithiothreitol restores full enzyme activity. The reaction with GSSG is pH dependent and the product is quite stable at neutral pH. Oxidation of one sulfhydryl group in glycogen synthase is associated with a loss of 60-70% of the enzyme activity. Further modification of protein sulfhydryls has less effect on the enzyme activity. Other low molecular weight disulfides also inactivate glycogen synthase and treatment with [35S]cystine to produce a 40% loss of enzyme activity gave rise to a single major radioactive peptide after cyanogen bromide digestion. Thus the GSSG-mediated inactivation of glycogen synthase apparently occurs through a single reactive sulfhydryl group that forms a mixed disulfide with low molecular weight disulfide molecules. Uridine 5'-diphosphate glucose and glycogen prevent the inactivation of glycogen-free glycogen synthase with GSSG, and glucose 6-phosphate retards the rate of inactivation. Reduction and reactivation of the GSSG-oxidized glycogen synthase is not affected by glycogen and it occurs readily at neutral pH with dithiothreitol, mercaptoethanol, or cysteamine. Oxidation of the reactive sulfhydryl group with GSSG has no effect on the rate of glycogen synthase phosphorylation by the catalytic subunit of cAMP-dependent protein kinase.     

A tentative mechanism of the ternary complex formation between phosphorylase kinase, glycogen phosphorylase b and glycogen

The kinetics of rabbit skeletal muscle phosphorylase kinase interaction with glycogen has been studied. At pH 6.8 the binding of phosphorylase kinase to glycogen proceeds only in the presence of Mg2+, whereas at pH 8.2 formation of the complex occurs even in the absence of Mg2+. On the other hand, the interaction of phosphorylase kinase with glycogen requires Ca2+ at both pH values. The initial rate of the complex formation is proportional to the enzyme and glycogen concentrations, suggesting the formation of the complex with stoichiometry 1:1 at the initial step of phosphorylase kinase binding by glycogen. According to the kinetic and sedimentation data, the substrate of the phosphorylase kinase reaction, glycogen phosphorylase b, favors the binding of phosphorylase kinase with glycogen. We suggest a model for the ordered binding of phosphorylase b and phosphorylase kinase to the glycogen particle that explains the increase in the tightness of phosphorylase kinase binding with glycogen in the presence of phosphorylase b.     

Turbidimetric method for determination of glycogen phosphorylase activity and its use for estimation of equilibrium position of enzymic reaction

A turbidimetric method has been developed for the continous monitoring of the enzyme reaction catalyzed by glycogen phosphorylase. This method is based on the registration of the turbidity of glycogen solution at wavelengths above 300 nm. It has been shown that increase in the turbidity is strictly proportional to the quantity of glucose 1-phosphate formed during the enzyme reaction. The method has the advantage of continuity, and it is suitable for determining the initial rate of catalytic synthesis or degradation of glycogen in a relatively simple and fast way. The kinetic experiments may be carried out under various conditions. The method of calculation of the overall equilibrium constant of the enzyme reaction catalyzed by glycogen phosphorylase has been elaborated. This method is based on the analysis of the dependence of the initial rate of the enzyme reaction on the proportiona of the substrate of the forward reaction: [P_i]/([P_i]+[G-1-P]).     

Histochemical demonstration of rat liver glycogen phosphorylase activity with iron (Fe++)

Summary A new histochemical method for light microscopic demonstration of liver glycogen phosphorylase activity has been introduced in this study.The method demonstrates phosphorylase activity by precipitating phosphate ions, liberated in the reaction catalyzed by the enzyme, with Fe⁺⁺ present in the incubating medium. The precipitate is visualized as ferrous sulphide.The new glycogen, formed in the same reaction, can also be demonstrated in this method after staining with iodine.The lobular localization of the reaction products obtained according to this method in the liver, corresponds well to that obtained according to earlier methods for the demonstration of only new-formed glycogen.     

Demonstration of intracytoplasmic glycogen of megakaryocytes and blood platelets by means of the periodic acid-thiocarbohydrazide-silver proteinate method

Summary The glycogen of megakaryocytes and blood platelets has been investigated in glutaraldehyde and osmium tetroxide fixed tissues by the periodic acid-thiocarbohydrazide-silver proteinate method (PA-TCH-SP). The PA-TCH-SP method involves the staining of intracytoplasmic glycogens more densely than the routine lead citrate method. Glycogen having a mean particle diameter of 21.1 nm has been shown localizing in the matrix of mature megakaryocytes, while that of glycogen in the platelets was 26.2 nm. The staining pattern of the glycogen in blood platelets was classified into three groups according to staining intensity.It is found that the PA-TCH-SP method is a very suitable one for the demonstration of intracytoplasmic glycogen from the viewpoints of reaction specificity, reproducibility, fineness of reaction products, sufficiency of electron density, and experimental cost. This method is also a very useful one for differentiating intracytoplasmic glycogens and ribosomes.     

Demonstration of intracytoplasmic glycogen of megakaryocytes and blood platelets by means of the periodic acid-thiocarbohydrazide-silver proteinate method.

The glycogen of megakaryocytes and blood platelets has been investigated in glutaraldehyde and osmium tetroxide fixed tissues by the periodic acid-thiocarbohydrozide-silver proteinate method (PA-TCH-SP). The PA-TCH-SP method involves the staining of intracytoplasmic glycogens more densely than the routine lead citrate method. Glycogen having a mean particle diameter of 21.1 nm has been shown localizing in the matrix of mature megakaryocytes, while that of glycogen in the platelets was 26.2 nm. The staining pattern of the glycogen in blood platelets was classified into three groups according to staining intensity. It is found that the PA-TCH-SP method is a very suitable one for the demonstration of intracytoplasmic glycogen from the viewpoints of reaction specificity, reproducibility, fineness of reaction products, sufficiency of electron density, and experimental cost. This method is also a very useful one for differentiating intracytoplasmic glycogens and ribosomes.     

Amylopectin Synthase of Eimeria tenella: Identification and Kinetic Characterization

ABSTRACT. A soluble enzyme amylopectin synthase (UDP-glucose-α 1,4-glucan α-4-glucosyltransferase) which transfers glucose from uridine 5'-diphosphate glucose (UDP-glucose) to a primer to form α-I,4-glucosyl linkages has been identified in the extracts of unsporulated oocysts of Eimeria tenella . UDP-glucose and not ADP-glucose was the most active glucosyl donor. Corn amylopectin, rabbit liver glycogen, oyster glycogen and corn starch served as primers; the latter two were less efficient. The enzyme has an apparent pH optimum of 7.5 and exhibited typical Michaelis-Menten kinetics with dependence on both the primer and substrate concentrations. The Michaelis constants (Km). with respect to UDP-glucose, was 0.5 mM; and 0.25 mg/ml and 1.25 mg/ml with respect to amylopectin and rabbit liver glycogen. The product formed by the reaction was predominantly a glucan containing α-1,4 linkages. The specificity of the enzyme suggests that this enzyme is similar to glycogen synthase in eukaryotes and has been designated as amylopectin synthase (UDP-glucose-α-1,4-glucosetransferase EC 2.4.1.11).     

Kinetics of the reaction between muscle glycogen phosphorylase B and glycogen

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.     

High-resolution light microscopy (HRLM) and digital analysis of Pompe disease pathology.

Pompe disease is an autosomal recessive lysosomal storage disorder caused by a deficiency of the lysosomal enzyme acid alpha-glucosidase, responsible for the degradation of lysosomal glycogen. Absent or low levels of the enzyme leads to lysosomal glycogen accumulation in cardiac and skeletal muscle cells, resulting in progressive muscle weakness and death from cardiac or respiratory failure. Recombinant enzyme replacement and gene therapy are now being investigated as treatment modalities for this disease. A knockout mouse model for Pompe disease, induced by the disruption of exon 6 within the acid alpha-glucosidase gene, mimics the human disease and has been used to evaluate the efficacy of treatment modalities for clearing glycogen. However, for accurate histopathological assessment of glycogen clearance, maximal preservation of in situ lysosomal glycogen is essential. To improve retention of glycogen in Pompe tissues, several fixation and embedding regimens were evaluated. The best glycogen preservation was obtained when tissues fixed with 3% glutaraldehyde and postfixed with 1% osmium tetroxide were processed into epon-araldite. Preservation was confirmed by staining with the Periodic acid-Schiff's reaction and by electron microscopy. This methodology resulted in high-resolution light microscopy (HRLM) sections suitable for digital quantification of glycogen content in heart and skeletal muscle. Combining this method of tissue fixation with computer-assisted histomorphometry has provided us with what we believe is the most objective and reproducible means of evaluating histological glycogen load in Pompe disease.     

Cyclic 3′,5′-nucleotide phosphodiesterase: A continuous titrimetric assay

A direct and continuous assay for cyclic 3′,5′-nucleotide phosphodiesterase has been developed. This method is based on the fact that the phosphate group of adenosine 3′,5′-phosphate has one titratable species whereas that of 5′-adenosine monophosphate has two. Hydrolysis of cyclic AMP to 5′-AMP by phosphodiesterase is accompanied by a stoichiometric generation of protons. The rate of addition of an alkaline solution to the reaction mixture to maintain a constant pH with a pH stat is thus stoichiometrically related to the rate of cyclic AMP hydrolysis. A reaction producing 10 mμmoles of H⁺ or more per minute in 1.5 ml of reaction mixture is accurately measured by this technique. Duplicates are usually within 5% of each other. Results obtained by the titrimetric method correlate well with those obtained by conventional methods. This technique has been successfully used to assay phosphodiesterase of bovine brain in the purified as well as the crude stage.     

Electron microscopic demonstration of rat liver glycogen phosphorylase activity with iron (Fe++)

Summary In this study a new electron microscopic method for the demonstration of liver glycogen phosphorylase activity has been presented.Prior to incubation the liver samples were shortly fixed in cold paraformaldehyde. Inorganic phosphate, liberated in the reaction catalyzed by the enzyme, were precipitated with iron (Fe⁺⁺) present in the incubating medium. Postfixation was performed in glutaraldehyde and osmium tetroxide.The ferrous phosphate precipitate was detected electron microscopically in unstained sections.The precipitate was mainly localized to endoplasmic membranes but also in glycogen particles. The method is imperfect in demonstrating phosphorylase activity bound to glycogen particles because of poor preservation of glycogen during treatment.     

Truly continuous low pH viral inactivation for biopharmaceutical process integration

Continuous virus inactivation (VI) has received little attention in the efforts to realize fully continuous biomanufacturing in the future. Implementation of continuous VI must assure a specific minimum incubation time, typically 60 min. To guarantee the minimum incubation time, we implemented a packed bed continuous viral inactivation reactor (CVIR) with narrow residence time distribution (RTD) for low pH incubation. We show that the RTD does not broaden significantly over a wide range of linear flow velocities—which highlights the flexibility and robustness of the design. Prolonged exposure to acidic pH has no impact on bed stability, assuring constant RTD throughout long term operation. The suitability of the packed bed CVIR for low pH inactivation is shown with two industry-standard model viruses, that is xenotropic murine leukemia virus and pseudorabies virus. Controls at neutral pH showed no system-induced VI. At low pH, significant VI is observed, even after only 15 min. Based on the low pH inactivation kinetics, the continuous process is equivalent to traditional batch operation. This study establishes a concept for continuous low pH inactivation and, together with previous reports, highlights the versatility of the packed bed reactor for continuous VI, regardless of the inactivation method.     

The mechanism of glycogen synthetase as determined by deuterium isotope effects and positional isotope exchange experiments

The reaction mechanism for glycogen synthetase from rabbit muscle was examined by alpha-secondary deuterium isotope effects and positional exchange experiments. Incubation of glycogen synthetase with [beta-18O2,alpha beta-18O]UDP-Glc did not result in any detectable positional isotope exchange from the beta-nonbridge position to the anomeric oxygen of the glucose moiety. Glucono-1,5-lactone was found to be a noncompetitive inhibitor versus UDP-Glc. The kinetic constants, K(is) and K(ii), were found to be 91 +/- 4 microM and 0.70 +/- 0.09 mM, respectively. Deoxynojirimycin was a nonlinear inhibitor at pH 7.5. The alpha-secondary deuterium isotope effects were measured with [1-2H]UDP-Glc by the direct comparison method. The isotope effects on Vmax and Vmax/K were found to be 1.23 +/- 0.04 and 1.09 +/- 0.06, respectively. The inhibitory effects by glucono-lactone and deoxynojirimycon plus the large alpha-secondary isotope effect on Vmax have been interpreted to show that an oxocarbonium ion is an intermediate in this reaction mechanism. The lack of a detectable positional isotope exchange reaction in the absence of glycogen suggests the formation of a rigid tight ion pair between UDP and the oxocarbonium ion intermediate.     

Directed autoselection of bacteria during turbidostat cultivation]

A method has been proposed for directed bacteria autoselection, based on their sensitivity to growth inhibitors during continuous unlimited cultivation. A smooth increase of a growth inhibitor concentration in the medium has been used in response to the appearance and autoselection of more resistant strains. The aim can be reached by continuous measurements of the specific microbial growth rate during the process and its keeping at the required level by the inhibitor additions. The experimental data are given showing application of the method for Escherichia coli and Pseudomonas sp. turbidostat cultivation with valine, low pH and formaldehyde as inhibitors.     

Assay of inorganic phosphate in the mild pH range, suitable for measurement of glycogen phosphorylase activity

A spectrophotometric assay of orthophosphate at mild pH is described. Phosphomolybdate complex is reduced by ascorbic acid at pH 5.0 in the presence of Zn2+. The chromophore produced is measured at 850 nm. The method is simple and sensitive, and the reaction proceeds normally in the presence of "interfering substances" such as metal-chelating agents and thiol compounds. The method could be widely employed for the assay of phosphate-releasing reaction from labile organic phosphates, such as for the assay of glycogen phosphorylase.     

Brain glycogen re-awakened

The mammalian brain contains glycogen, which is located predominantly in astrocytes, but its function is unclear. A principal role for brain glycogen as an energy reserve, analogous to its role in the periphery, had been universally dismissed based on its relatively low concentration, an assumption apparently reinforced by the limited duration that the brain can function in the absence of glucose. However, during insulin-induced hypoglycaemia, where brain glucose availability is limited, glycogen content falls first in areas with the highest metabolic rate, suggesting that glycogen provides fuel to support brain function during pathological hypoglycaemia. General anaesthesia results in elevated brain glycogen suggesting quiescent neurones allow glycogen accumulation, and as long ago as the 1950s it was shown that brain glycogen accumulates during sleep, is mobilized upon waking, and that sleep deprivation results in region-specific decreases in brain glycogen, implying a supportive functional role for brain glycogen in the conscious, awake brain. Interest in brain glycogen has recently been re-awakened by the first continuous in vivo measurements using NMR spectroscopy, by the general acceptance of metabolic coupling between glia and neurones involving intercellular transfer of energy substrate, and by studies supporting a prominent physiological role for brain glycogen as a provider of supplemental energy substrate during periods of increased tissue energy demand, when ambient normoglycaemic glucose is unable to meet immediate energy requirements.     

Escherichia coli K-12 glycogen synthase: ability to use UDPglucose and ADP glucose as glucosyl donors in the absence of added primer.

A mechanism of initiation of glycogen biosynthesis in Escherichia coli has been previously postulated: In a first step, the glucosyl groups would be transferred into an acceptor protein from UDPglucose or ADPglucose by two glucosyl transferases, distinct from the glycogen synthase. In this work, the activity of transfer from UDPglucose into a methanol-insoluble fraction could not be found in the crude extracts of six independently isolated glycogen synthase-deficient mutants of E. coli K-12. Purified E. coli K-12 glycogen synthase was able to catalyze the unprimed reaction from ADPglucose and UDPglucose but at a very low rate; the rate with UDPglucose is 6–7% the rate observed with ADPglucose. With these two substrates, the unprimed reaction was strongly stimulated by the simultaneous presence of salts and branching enzyme. However the activity with UDPglucose increased rapidly at low concentrations of branching enzyme and was inhibited at physiological concentrations whereas the activity with ADPglucose reached a maximum only at these concentrations. Consequently, the relative activities found with ADPglucose and UDPglucose varied with the branching enzyme concentration. Transfer from UDPglucose was inhibited by low concentrations of ADPglucose and high concentrations of glycogen. These results suggest that the same enzyme, namely the glycogen synthase, catalyzes the unprimed transfer from ADPglucose and UDPglucose and that ADPglucose is probably the most important physiological donor in glycogen biosynthesis in E. coli.     

The Motor Neuron-Like Cell Line NSC-34 and Its Parent Cell Line N18TG2 Have Glycogen that is Degraded Under Cellular Stress

Brain glycogen has a long and versatile history: Primarily regarded as an evolutionary remnant, it was then thought of as an unspecific emergency fuel store. A dynamic role for glycogen in normal brain function has been proposed later but exclusively attributed to astrocytes, its main storage site. Neuronal glycogen had long been neglected, but came into focus when sensitive technical methods allowed quantification of glycogen at low concentration range and the detection of glycogen metabolizing enzymes in cells and cell lysates. Recently, an active role of neuronal glycogen and even its contribution to neuronal survival could be demonstrated. We used the neuronal cell lines NSC-34 and N18TG2 and could demonstrate that they express the key-enzymes of glycogen metabolism, glycogen phosphorylase and glycogen synthase and contain glycogen which is mobilized on glucose deprivation and elevated potassium concentrations, but not by hormones stimulating cAMP formation. Conditions of metabolic stress, namely hypoxia, oxidative stress and pH lowering, induce glycogen degradation. Our studies revealed that glycogen can contribute to the energy supply of neuronal cell lines in situations of metabolic stress. These findings shed new light on the so far neglected role of neuronal glycogen. The key-enzyme in glycogen degradation is glycogen phosphorylase. Neurons express only the brain isoform of the enzyme that is supposed to be activated primarily by the allosteric activator AMP and less by covalent phosphorylation via the cAMP cascade. Our results indicate that neuronal glycogen is not degraded upon hormone action but by factors lowering the energy charge of the cells directly.