Kinetics of glycogen phosphorylase a from the muscle of the blue crab, Callinectes danae

The kinetics of purified glycogen phosphorylase a from the muscle of the blue crab (Callinectes danae) were studied in the direction of glycogen synthesis, and in the direction of glycogen degradation with P_i or arsenate as substrates. The effects of AMP, UDPG, G-6-P, glucose, and arsenate on the appropriate systems were studied. AMP is an activator of the enzyme. Inhibition by UDPG with respect to P_i changes from noncompetitive to competitive when AMP is added; it changes from noncompetitive to mixed with respect to glycogen when AMP is added. G-6-P is a competitive inhibitor of G-1-P and arsenate. Inhibition by glucose with respect to glycogen changes from noncompetitive to competitive when AMP is added in the direction of glycogen breakdown; it is noncompetitive with respect to P_i. Arsenate is a competitive inhibitor with respect to P_i. The K_m for AMP increases in the presence of UDPG, and decreases with increasing concentrations of P_i or glycogen. We propose a model in which the enzyme bears three interacting sites: an active site, an activator (AMP) site, and an inhibitor (glucose) site. The active site has three subsites: one for P_i, one for glycogen, and one for a glucose moiety which may be part of the substrates or inhibitors.     

Molecular Basis of Impaired Glycogen Metabolism during Ischemic Stroke and Hypoxia

Background

Ischemic stroke is the combinatorial effect of many pathological processes including the loss of energy supplies, excessive intracellular calcium accumulation, oxidative stress, and inflammatory responses. The brain''s ability to maintain energy demand through this process involves metabolism of glycogen, which is critical for release of stored glucose. However, regulation of glycogen metabolism in ischemic stroke remains unknown. In the present study, we investigate the role and regulation of glycogen metabolizing enzymes and their effects on the fate of glycogen during ischemic stroke.

Results

Ischemic stroke was induced in rats by peri-vascular application of the vasoconstrictor endothelin-1 and forebrains were collected at 1, 3, 6 and 24 hours post-stroke. Glycogen levels and the expression and activity of enzymes involved in glycogen metabolism were analyzed. We found elevated glycogen levels in the ipsilateral hemispheres compared with contralateral hemispheres at 6 and 24 hours (25% and 39% increase respectively; P<0.05). Glycogen synthase activity and glycogen branching enzyme expression were found to be similar between the ipsilateral, contralateral, and sham control hemispheres. In contrast, the rate-limiting enzyme for glycogen breakdown, glycogen phosphorylase, had 58% lower activity (P<0.01) in the ipsilateral hemisphere (24 hours post-stroke), which corresponded with a 48% reduction in cAMP-dependent protein kinase A (PKA) activity (P<0.01). In addition, glycogen debranching enzyme expression 24 hours post-stroke was 77% (P<0.01) and 72% lower (P<0.01) at the protein and mRNA level, respectively. In cultured rat primary cerebellar astrocytes, hypoxia and inhibition of PKA activity significantly reduced glycogen phosphorylase activity and increased glycogen accumulation but did not alter glycogen synthase activity. Furthermore, elevated glycogen levels provided metabolic support to astrocytes during hypoxia.

Conclusion

Our study has identified that glycogen breakdown is impaired during ischemic stroke, the molecular basis of which includes reduced glycogen debranching enzyme expression level together with reduced glycogen phosphorylase and PKA activity.     

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]).     

Changes in intracellular pH during repeated exercise

The rates of change in intracellular pH during repeated exercise sessions with rest periods was determined by 31 phosphorus-nuclear magnetic resonance spectroscopy (³¹P-MRS). Five long-distance runners and six healthy male subjects as controls performed a 2-min femoral flexion at 20 kg · m · min^–1 in a 2.1 T superconducting magnet with a 67-cm bore and repeated this exercise four times with 2-min rest periods intervening. In all cases during exercise the inorganic phosphate (P_i) peak split into two, the earlier increased rapidly (high-pH P_i) and the later (low-pH P_i) increased more slowly. The P_i peaks were separated by a fitting procedure using the least square mean method. The high-pH P_i area during exercise decreased as the number of repeated exercise periods increased, while the low-pH P_i area gradually increased. Although the total P_i area decreased exponentially during the recovery period, the high-pH P_i area decreased first and then the low-pH P_i area reduced gradually. The pH values were estimated from the chemical shift between the phosphocreatine peak and each split peak in the P_i. The high-pH in pooled data ranged from 6.6 to 7.0 during exercise and recovery, while the low pH decreased to 6.2 during exercise. As the number of exercise periods increased, each pH value gradually became less acidic, although there was a tendency to more acidity in the control subjects than in the long-distance runners. In conclusion, it was possible to obtain by non-invasive, continuous³¹P-MRS, a split pattern of P_i peaks during exercise and there were at least tow different intracellular pH values during exercise, suggesting that each P_i peak might be attributed to the types of muscle fibre recruited.     

Phosphorylation of glycogen synthase in a homogenate of human polymorphonuclear leukocytes

Summary Glycogen synthase I in a homogenate of human polymorphonuclear leukocytes was phosphorylated under imitated physiological conditions utilizing the endogenous protein kinases. At subsequent steps of phosphorylation the³²P-labelled synthase was purified and characterized. Limited tryptic hydrolysis of the³²P-labelled synthase released four phosphopeptides (t-A, t-B, t-C, t-D) and subsequent chymotrypsinization of the trypsin resistant core released three phosphopeptides (c-A, c-B, c-C). One P_i/subunit was incorporated within 8–10 min and 2.2 P_i/subunit within 60 min increasing the K_c for Gle-6-P to 4–6 mM. The initial phosphorylation up to 0.8 P_i/subunit occurred mainly in peptide c-A and a linear relation between ratio of independence (RI) of glycogen synthase in the interval RI 0.85 to RI 0.05 and phosphorylation of this peptide to 0.5 P_i was observed. Phosphorylation of this peptide is responsible for the decrease in ratio of independence. From experiments with inhibitors and activators, the initial phosphorylation was found predominantly catalysed by the endogenous cAMP independent synthase kinase, however, the endogenous cAMP dependent protein kinase and phosphorylase kinase also phosphorylate endogenous glycogen synthase I to a minor degree. Circumstantial evidence for a Ca-dependent synthase kinase different from phosphorylase kinase is presented. The endogenous Gle-6-P dependent glycogen synthase occurring in a homogenate of leukocytes disrupted in the presence of NaF incorporated 1.07 P_i/subunit and K_c for Glc-6-P was increased from 6–8 mM to 20 mM. From the present and previous experiments [7] a total of 8 major phosphorylatable sites have been defined, one on each of the peptides t-A, t-B, t-C, c-B and c-C and two on peptide c-A, which in addition may contain a third site for phosphorylase kinase. Assuming identical subunits, only 13 out of 32 sites are thus covalently modified at maximum phosphorylation. The operational defined synthase R (K_c for Glc-6-P 0.5 mM) and D (K_c for Glc-6-P 2–8 mM) activities correspond to synthase with about 0.8 P_i and 1.8–2.3 P_i/subunit, respectively.     

The effects of insulin on myocardial metabolism and acidosis in normoxia and ischaemia: A 31P-NMR study

1. The effect of insulin on the perfused rat heart during normoxia and total ischaemia was studied by ³¹P-NMR. 2. During normoxic perfusion, insulin increased the phosphocreatine to ATP ratio at the expense of P_i, when glucose was the substrate. No change was observed when acetate was used as the sole substrate. The intracellular pH (as measured from the position of the 2-deoxyglucose 6-phosphate resonance peak) was unaffected by insulin treatment. 3. Infusion of insulin prior to ischaemia caused an increase in the rate and extent of acidosis during the period of no flow while the rate of ATP depletion was decreased. 4. Freezeclamped studies showed an increase in glycogen levels upon insulin treatment of the glucose perfused rat heart. During ischaemia, a decrease in glycogen content concomitant with an increase in lactate was observed. The accessibility of glycogen to phosphorylase during ischaemia is increased as a result of insulin treatment. The control of glycolysis during ischaemia is discussed with respect to the content and structure of glycogen in heart tissue.     

Hepatic glycogen metabolism in the db/db mouse

Summary Knowledge of the metabolic changes that occur in insulin-resistant type 2 diabetes is relatively lacking compared to insulin-deficient type 1 diabetes. This paper summarizes the importance of the C57BL/KsJ-db/db mouse as a model of type 2 diabetes, and illustrates the effects that insulin-deficient and insulin-resistant states have on hepatic glycogen metabolism. A longitudinal study of db/db mice of ages 2–15 weeks revealed that significant changes in certain parameters of hepatic glycogen metabolism occur during this period. The liver glycogen levels were similar between diabetic and control mice. However, glycogen particles from db/db mice were on average smaller in mass and had shorter exterior and interior chain lengths. Total phosphorylase and phosphorylase a activities were elevated in the genetically diabetic mice. This was primarily due to an increase in the amount of enzymic protein apparently the result of a decreased rate of degradation. It was not possible to find a consistent alteration in glycogen synthase activity in the db/db mice. Glycogen synthase and phosphorylase from diabetic liver revealed some changes in kinetic properties in the form of a decrease in V_max, and altered sensitivity to inhibitors like ATP. The altered glycogen structure in db/db mice may have contributed to changes in the activities and properties of glycogen synthase and phosphorylase. The exact role played by hormones (insulin and glucagon) in these changes is not clear but further studies should reveal their contributions. The db/db mouse provides a good model for type 2 diabetes and for fluctuating insulin and glucagon ratios. Its use should clarify the regulation of hepatic glycogen metabolism and other metabolic processes known to be controlled by these hormones. The other animal models of type 2 diabetes, ob/ob mouse and fatty Zucker (fa/fa) rat, show similar impairment of hepatic glycogen metabolism. The concentrations of glycogen metabolizing enzymes are high and in vitro studies indicate enhanced rate of glycogen synthesis and breakdown. However, streptozotocin-induced diabetic animals and BB rats which resemble insulin-deficient type 1 diabetes are characterized by decreased glycogen turnover as a result of reduction in the levels of glycogen metabolizing enzymes.     

Guanosine triphosphate catabolism in purine nucleoside phosphorylase deficient human B lymphoblastoid cells

GTP catabolism induced by sodium azide or deoxyglucose was studied in purine nucleoside phosphorylase (PNP) deficient human B lymphoblastoid cells. In PNP deficient cells, as in control cells, guanylate was both dephosphorylated and deaminated but dephosphorylation was the major pathway. Only nucleosides were excreted during GTP catabolism by PNP deficient cells and the main product was guanosine. The level of nucleoside excretion was largely affected by intracellular orthophosphate (P_i) level. In contrast, normal cells excreted nucleosides only at low P_i level while at high P_i levels, purine bases (guanine and hypoxanthine) were exclusively excreted. PNP deficiency had no effect on the extent of GMP deamination.     

Physical training in man. Skeletal muscle metabolism in relation to muscle morphology and running ability.

The metabolic and morphologic adaptation to physical training in skeletal muscle tissue of eleven middle-aged, physically untrained men was studied. Muscle biopsies were taken from the vastus lateralis before, after 8 weeks and after 6 months of physical training for analysis of metabolic and morphologic variables. Glucose tolerance test indicated increased insulin sensitivity after 6 months of physical training. The activities of glycogen phosphorylase, hexokinase and glucose-6-P-dehydrogenase were increased but other enzymes involved in glycogen turnover and glycolysis were unchanged after 6 months of physical traning. The activities of citrate synthase and cytochrome-c-oxidase, representing the oxidative capacity were significantly increased already after 8 weeks of physical training. The incorporation rate of palmitate-carbon into CO2 and triglycerides increased, and the incorporation rate of leucine-carbon into CO2 decreased with 6 months of physical training. The fiber diameter of both Type 1- and Type 2-fibers increased, while the mitochondrial volume increased predominantly in Type 2-fibers. Significant correlations were found between metabolic, physiologic and morphologic variables before and after physical training. The results indicate an increased oxidative capacity, mainly located to Type 2-fibers, and an increased utilization of fatty acids in response to this type of physical training.     

Glycogen phosphorylase, the product of the glgP Gene, catalyzes glycogen breakdown by removing glucose units from the nonreducing ends in Escherichia coli

To understand the biological function of bacterial glycogen phosphorylase (GlgP), we have produced and characterized Escherichia coli cells with null or altered glgP expression. glgP deletion mutants (DeltaglgP) totally lacked glycogen phosphorylase activity, indicating that all the enzymatic activity is dependent upon the glgP product. Moderate increases of glycogen phosphorylase activity were accompanied by marked reductions of the intracellular glycogen levels in cells cultured in the presence of glucose. In turn, both glycogen content and rates of glycogen accumulation in DeltaglgP cells were severalfold higher than those of wild-type cells. These defects correlated with the presence of longer external chains in the polysaccharide accumulated by DeltaglgP cells. The overall results thus show that GlgP catalyzes glycogen breakdown and affects glycogen structure by removing glucose units from the polysaccharide outer chains in E. coli.     

Regulation of 5-phosphoribosyl-1-pyrophosphate synthesis in human fibroblasts by the concentration of inorganic phosphate

During the growth cycle of normal fibroblasts and of fibroblasts deficient in glucose-6-phosphate dehydrogenase activity, the concentration of 5-phosphoribosyl-1-pyrophosphate and of P_i, as well as the activity of 5-phosphoribosyl-1-pyrophosphate synthetase, decreased to stable values in confluent cultures. A high degree of correlation (0.89 and 0.91 for two normal and 0.69 for one glucose-6-phosphate dehydrogenase-deficient cell strain, respectively) was shown between intracellular P_i and 5-phosphoribosyl-1-pyrophosphate concentrations under varying culture and incubation conditions. 5-phosphoribosyl-1-pyrophosphate concentrations were elevated in normal fibroblasts incubated with methylene blue only if intracellular P_i levels were high. Neither methylene blue nor 6-aminonicotinamide, singly, affected intracellular P_i concentrations. However, when normal cells were pretreated with 6-aminonicotinamide and then with methylene blue, intracellular P_i decreased, 5-phosphoribosyl-1-pyrophosphate was depleted, and its rate of generation decreased. Under similar conditions, glucose-6-phosphate dehydrogenase-deficient fibroblasts maintained unaltered P_i levels, and 5-phosphoribosyl-1-pyrophosphate concentration and generation were slightly increased. The decrease in intracellular P_i in normal cells after the combined treatment was commensurate with an accumulation of 6-phosphogluconate, which did not take place in mutant cells. The changes in 5-phosphoribosyl-1-pyrophosphate synthesis, whether due to the stage of growth or various experimental manipulations, were always concordant with changes in intracellular P_i level. The regulatory role of P_i is consistent with the known enzymic properties of 5-phosphoribosyl-1-pyrophosphate synthetase.     

Role of the sympathoadrenal system in the regulation of glycogen metabolism in resting and exercising skeletal muscles.

The purpose of the present study was to characterize the role of catecholamines in the regulation of skeletal muscle glycogen metabolism during exercise. Using the rat hindlimb perfusion technique we have measured skeletal muscle glycogen content, glycogen phosphorylase and synthase activities in sympathectomized and/or demedullated rats under epinephrine treatment (10(-7) M) at rest and during muscle contraction. When epinephrine and/or norepinephrine deficiency was induced, muscle contraction resulted in a decrease in glycogen content (-63%) despite a decrease in glycogen phosphorylase activity ratio (0.25 to 0.11; p less than 0.001) and an increase in glycogen synthase activity ratio (0.13 to 0.27; p less than 0.001). Under these conditions, epinephrine treatment further reduced glycogen content while blunting the changes in the activity ratio of the rate-limiting enzymes. These data indicate that catecholamines do not play a primary role in skeletal muscle glycogen breakdown during acute exercise and suggest that allosteric regulators may be of prime importance.     

Wine Yeast Strains Engineered for Glycogen Overproduction Display Enhanced Viability under Glucose Deprivation Conditions

We used metabolic engineering to produce wine yeasts with enhanced resistance to glucose deprivation conditions. Glycogen metabolism was genetically modified to overproduce glycogen by increasing the glycogen synthase activity and eliminating glycogen phosphorylase activity. All of the modified strains had a higher glycogen content at the stationary phase, but accumulation was still regulated during growth. Strains lacking GPH1, which encodes glycogen phosphorylase, are unable to mobilize glycogen. Enhanced viability under glucose deprivation conditions occurs when glycogen accumulates in the strain that overexpresses GSY2, which encodes glycogen synthase and maintains normal glycogen phosphorylase activity. This enhanced viability is observed under laboratory growth conditions and under vinification conditions in synthetic and natural musts. Wines obtained from this modified strain and from the parental wild-type strain don't differ significantly in the analyzed enological parameters. The engineered strain might better resist some stages of nutrient depletion during industrial use.     

Changes in the Pi uptake and polyP accumulation in Saccharomyces cerevisiae strains deficient in the synthesis of trehalose and/or glycerol

The intracellular level of free inorganic orthophosphate (P_i) in yeast cells generally depends on the P_i uptake capacity, energy state of the cells in respect to the activity of the membrane-associated ATPases and on the activity of metabolic pathways involved in the production of glycerol and trehalose. Batch fermentation was performed to investigate the carbon substrate consumption, the P_i uptake capacity and product formation by four Saccharomyces cerevisiae strains differing in their ability to produce glycerol and/or trehalose. The consumption of P_i in mutant strains with a lack of the synthesis of the trehalose and/or glycerol exceeded the level for a wild type strain about two times. Maximum intracellular polyP content (29.9 mg/g DW) was shown for tps1Δ gpd1Δ mutant. In this study we showed that the P_i uptake and polyP accumulation level were closely connected with the changes in the synthesis of trehalose and glycerol.     

Preferential intracellular pH regulation represents a general pattern of pH homeostasis during acid–base disturbances in the armoured catfish,Pterygoplichthys pardalis

Preferential intracellular pH (pH_i) regulation, where pH_i is tightly regulated in the face of a blood acidosis, has been observed in a few species of fish, but only during elevated blood PCO₂. To determine whether preferential pH_i regulation may represent a general pattern for acid–base regulation during other pH disturbances we challenged the armoured catfish, Pterygoplichthys pardalis, with anoxia and exhaustive exercise, to induce a metabolic acidosis, and bicarbonate injections to induce a metabolic alkalosis. Fish were terminally sampled 2–3 h following the respective treatments and extracellular blood pH, pH_i of red blood cells (RBC), brain, heart, liver and white muscle, and plasma lactate and total CO₂ were measured. All treatments resulted in significant changes in extracellular pH and RBC pH_i that likely cover a large portion of the pH tolerance limits of this species (pH 7.15–7.86). In all tissues other than RBC, pH_i remained tightly regulated and did not differ significantly from control values, with the exception of a decrease in white muscle pH_i after anoxia and an increase in liver pH_i following a metabolic alkalosis. Thus preferential pH_i regulation appears to be a general pattern for acid–base homeostasis in the armoured catfish and may be a common response in Amazonian fishes.     

A forage-only diet alters the metabolic response of horses in training

Most athletic horses are fed a high-starch diet despite the risk of health problems. Replacing starch concentrate with high-energy forage would alleviate these health problems, but could result in a shift in major substrates for muscle energy supply from glucose to short-chain fatty acids (SCFA) due to more hindgut fermentation of fibre. Dietary fat inclusion has previously been shown to promote aerobic energy supply during exercise, but the contribution of SCFA to exercise metabolism has received little attention. This study compared metabolic response with exercise and lactate threshold (V_La4) in horses fed a forage-only diet (F) and a more traditional high-starch, low-energy forage diet (forage–concentrate diet - FC). The hypothesis was that diet F would increase plasma acetate concentration and increase V_La4 compared with diet FC. Six Standardbred geldings in race training were used in a 29-day change-over experiment. Plasma acetate, non-esterified fatty acids (NEFA), lactate, glucose and insulin concentrations and venous pH were measured in samples collected before, during and after a treadmill exercise test (ET, day 25) and muscle glycogen concentrations before and after ET. Plasma acetate concentration was higher before and after exercise in horses on diet F compared with diet FC, and there was a tendency (P = 0.09) for increased V_La4 on diet F. Venous pH and plasma glucose concentrations during exercise were higher in horses on diet F than diet FC, as was plasma NEFA on the day after ET. Plasma insulin and muscle glycogen concentrations were lower for diet F, but glycogen utilisation was similar for the two diets. The results show that a high-energy, forage-only diet alters the metabolic response to exercise and, with the exception of lowered glycogen stores, appears to have positive rather than negative effects on performance traits.     

Aminoacetone Induces Loss of Ferritin Ferroxidase and Iron Uptake Activities

The effects of inorganic phosphate (P_i), the main intracellular membrane permeable anion capable of altering mitochondrial pH gradients (ΔpH), were measured on mitochondrial H₂O₂ release. As expected, P_i decreased ΔpH and increased the electric membrane potential (ΔΨ). Mitochondrial H₂O₂ release was stimulated by P_i and also by its structural analogue arsenate. However, acetate, another membrane-permeable anion, did not stimulate mitochondrial H₂O₂ release. The stimulatory effect promoted by P_i was prevented by CCCP, which decreases transport of P_i across the inner mitochondrial membrane, indicating that P_i must be in the mitochondrial matrix to stimulate H₂O₂ release. In conclusion, we found that P_i and arsenate stimulate mitochondrial reactive oxygen release, an effect that may contribute towards oxidative stress under conditions such as ischemia/reperfusion, in which high-energy phosphate bonds are hydrolyzed.     

Dissociation and reassociation of creatine kinase with heart mitochondria; pH and phosphate dependence.

Experimental evidence is given of mitochondrial creatine kinase ability to dissociate from or reassociate with mitochondrial membrane as compared to the behaviour of adenylate kinase. CK release occurs for P_i concentrations higher than 5 mM and is strongly pH-dependant. Solubilized CK is able to reassociate with mitochondrial inner membrane when either P_i concentration or pH are decreased. The possible physiological effects of events, such as ischemia, which modify the intracellular pH or P_i concentration are discussed, in view of the special role which has been attributed to mitochondrial CK in the transfer of energy in heart cells.     

Regulation of glycogen metabolism in the adrenal gland. IV. The effect of insulin on glycogen synthetase, phosphorylase, and related metabolites

Previous studies have indicated that the glycogen content of adrenal glands of fasted rats can be depleted by insulin per se (Bindstein, E., Piras, R., and Piras, M. M., Endocrinology88, 223, 1971). In order to establish the mechanism of action of this hormone in the adrenal gland, the effect of insulin has been now investigated on glycogen synthetase (UDP-glucose: α-1,4 glucan α-4-glueosyl-transferase, EC 2.4.1.11), glycogen phosphorylase (α-1,4 glucan: orthophosphate glucosyl-transferase, EC 2.4.1.1) and metabolites related to these enzymes.Approximately 40% of total adrenal glycogen phosphorylase of fasted rats is in the active form, which increases to 75% 1 hr after insulin treatment (75 mU/100 g body wt). This conversion occurs without apparent large changes of 3′-5′ cyclic AMP. Concomitantly with the enzymatic change, the levels of glucose-6-P, UDP-glucose and P_i suffer alterations which favor an increased phosphorolytic activity during the first hour of insulin treatment. Glycogen synthetase, which did not change during this period, is converted to the glucose-6-P independent form during the 2–3 hr of treatment. This conversion is preceded by an increased glycogen synthetase phosphatase activity, which seems to follow an inverse relationship with the glycogen level.The results obtained suggest that the effect of insulin on the adrenal gland of fasted rats is glycogenolytic, that is, opposite to that described for this hormone in other normal tissues. The glycogen depletion, on the other hand, seems to set in motion the mechanism for glycogen synthetase activation, with the subsequent glycogen resynthesis.