The stimulation of glycogen synthesis and of glycogen synthetase in the liver by the administration of glucose

An assay for adenosine 5'-diphosphate (ADP)-glucose pyrophosphorylase that measures the synthesis of radioactive ADP-glucose with glycogen synthase

Adenosine 5'-diphosphate (ADP)-glucose pyrophosphorylase (ADP-Glc PPase) catalyzes the conversion of glucose 1-phosphate and adenosine 5'-triphosphate to ADP-glucose and pyrophosphate. We present a radioactive assay of this enzyme with a higher signal/noise ratio. After stopping the reaction that uses [14C]glucose 1-phosphate as a substrate, the ADP-[14C]glucose formed as a product is converted to [14C]glycogen by the addition of glycogen synthase and nonradioactive glycogen as primer. The final product is precipitated and washed, and the radioactivity is measured in a scintillation counter. The [14C]glucose 1-phosphate that did not react is easily eliminated during the washes. We have found that this assay produces much lower blanks than previously described radioactive methods based on binding of ADP-[14C]glucose to O-(diethylaminoethyl)-cellulose paper. In addition, we tested the kinetic parameters for the effectors of the Escherichia coli ADP-Glc PPase and both assays yielded identical results. The presented method is more suitable for Km or S(0.5) determinations of ADP-Glc PPases having high apparent affinity for glucose 1-phosphate. It is possible to use a higher specific radioactivity to increase the sensitivity at lower concentrations of [14C]glucose 1-phosphate without compromising the blanks obtained at higher concentrations.

Hepatic glucose uptake, gluconeogenesis and the regulation of glycogen synthesis

Hepatic glycogen is replenished during the absorptive period postprandially. This repletion is prompted partly by an increased hepatic uptake of glucose by the liver, partly by metabolite and hormonal signals in the portal vein, and partly by an increased gluconeogenic flux to glycogen (glyconeogenesis). There is some evidence that the direct formation of glycogen from glucose and that formed by gluconeogenic pathways is linked. This includes: (i) the inhibition of all glycogen synthesis, in vivo, when gluconeogenic flux is blocked by inhibitors; (ii) a dual relationship between glucose concentrations, lactate uptake by the liver and glycogen synthesis (by both pathways) which indicates that glucose sets the maximal rates of glycogen synthesis while lactate uptake determines the actual flux rate to glycogen; (iii) the decrease of both gluconeogenesis and glycogen synthesis by the biguanide, metformin; and (iv) correlations between increased gluconeogenesis and liver glycogen in obese patients and animal models. The degree to which the liver extracts portal glucose is not entirely agreed upon although a preponderance of evidence points to about a 5% extraction rate, following meals, which is dependent on a stimulation of glucokinase. This enzyme may be linked to the expression of other enzymes in the gluconeogenic pathway. Perivenous cells in the liver may induce additional gluconeogenesis in the periportal cells by increasing glycolytically produced lactate. A number of potential mechanisms therefore exist which could link glycogen synthesis from glucose and gluconeogenic substrate.

Intracellular distribution of glycogen synthase and glycogen in primary cultured rat hepatocytes

Changes in the intracellular distribution of liver glycogen synthase (GS) might constitute a new regulatory mechanism for the activity of this enzyme at cellular level. Our previous studies indicated that incubation of isolated hepatocytes with glucose activated GS and resulted in its translocation from a homogeneous cytosolic distribution to the cell periphery. These studies also suggested a relationship with insoluble elements of the cytoskeleton, in particular actin. Here we show the translocation of GS in a different experimental model that allows the analysis of this phenomenon in long-term studies. We describe the reversibility of translocation of GS and its effect on glycogen distribution. Incubation of cultured rat hepatocytes with glucose activated GS and triggered its translocation to the hepatocyte periphery. The relative amount of the enzyme concentrated near the plasma membrane increased with time up to 8 h of incubation with glucose, when the glycogen stores reached their maximal value. The lithium-induced covalent activation of GS was not sufficient to cause its translocation to the cell periphery. The intracellular distribution of GS closely resembled that of glycogen. Our results showed an interaction between GS and an insoluble element of the hepatocyte matrix. Although no co-localization between actin filaments and GS was observed in any condition, disruption of actin cytoskeleton resulted in a significantly lower percentage of cells in which the enzyme translocated to the cell periphery in response to glucose. This observation suggests that the microfilament network has a role in the translocation of GS.

Concept of the noncoenzymatic thiamine effect

The experimental and clinical data on different aspects of vitamin and hormone relationships have been summarized in the form of a general concept of the noncoenzymatic thiamine effect, on the basis of a number of premises: (1) discovery of tissue factors limiting the manifestation of the specific activity of administered thiamine (the presence of a tissue buffer depot of easily accessible coenzymes, and lack of free apoenzymes); (2) evidence of a thiamine effect on the pancreatic insulin-synthesizing function; (3) stimulation of metabolic thiamine effects, including the effects of insulin administration on thiamine-dependent enzymes; (4) determination of the features of hormonal control of thiamine metabolism in the body; (5) confirmation of the predictive force of the concept by clinical trials of the new strategy of thiamine therapy.

Glucose induces the translocation of glycogen synthase to the cell cortex in rat hepatocytes

After incubation with glucose a dramatic change in the intracellular distribution of glycogen synthase was observed in rat hepatocytes. Confocal laser scanning microscopy showed that glycogen synthase existed diffusely in the cytosol of control cells, whereas in cells incubated with glucose it accumulated at the cell periphery. Colocalization analysis between glycogen synthase immunostaining and actin filaments showed that the change in glycogen synthase distribution induced by glucose correlated with a marked increase in the co-distribution of the two proteins, indicating that, in response to glucose, glycogen synthase moves to the actin-rich area close to the membrane. When glycogen synthase was immunostained with rabbit anti-(glycogen synthase) and Protein A-colloidal gold, few particles were observed close to the membrane in control cells. In contrast, in cells incubated with glucose most of the gold particles were found near the membrane, confirming that glycogen synthase had moved to the cell cortex. Furthermore, in agreement with the glycogen synthase distribution, glycogen deposition appeared to be more active at the periphery of the cell.

Altered fluxes responsible for reduced hepatic glucose production and gluconeogenesis by exogenous glucose in rats

The net release of glucose from the liver, or hepatic glucose production (HGP), and apparent gluconeogenesis (GNG) are reduced by exogenous glucose. We investigated the changes in metabolic fluxes responsible. Flux through the hepatic GNG pathway was quantified by mass isotopomer distribution analysis (MIDA) from [2-13C]glycerol. Unidirectional flux across hepatic glucose-6-phosphatase (G-6-Pase), or total hepatic glucose output (THGO), and hepatic glucose cycling (HGC) were also measured by using glucuronate (GlcUA) to correct for glucose 6-phosphate (G-6-P) labeling. Infusion of glucose (15-30 mg.kg-1.min-1 iv) to 24 h-fasted rats caused two important metabolic alterations. First was a significant increase in hepatic glucose uptake and HGC: > 60% of THGO was from HGC. Second, although flux through hepatic G-6-P increased (from 15.7 to 17.7-22.7 mg.kg-1.min-1), the partitioning of G-6-P flux changed markedly [from 30-35% to 55-60% entering UDP-glucose (UDP-Glc), P < 0.01]. Total flux through the GNG pathway remained active during intravenous glucose, but increased partitioning into UDP-Glc lowered GNG flux plasma glucose by 50%. In summary, the suppression of HGP and GNG flux into glucose is not primarily due to reduced carbon flow through hepatic G-6-Pase or the hepatic GNG pathway. THGO persists, but hepatic G-6-P is derived increasingly from plasma glucose, and flow through GNG persists, but the partitioning coefficient of G-6-P into UDP-Glc doubles. These adjustments permit net HGP to fall despite increased total production of hepatic G-6-P during administration of glucose.

Effect of glucose on uptake of radiolabeled glucose, 2-DG, and 3-O-MG by the perfused rat liver

In the transition from the fasting to the fed state, plasma glucose levels rise, and the liver converts from an organ producing glucose to one of storage. To determine the effect of glucose on hepatic glucose uptake, radiolabeled glucose, 2-deoxyglucose, and 3-O-methylglucose were injected into perfused rat livers during different nontracer glucose levels, and the concentrations in the outflow were measured. A mathematical model was developed that described the behavior of the injected compounds as they traveled through the liver and was used to simulate and fit the experimental results. The rates of membrane transport, glucokinase, glucose-6-phosphatase, and the consumption of glucose 6-phosphate were estimated. Membrane transport for all of the tracers decreased as nontracer glucose increased, demonstrating competitive inhibition of the glucose transporter. In contrast, the consumption of injected [2-14C]glucose increased when glucose was elevated, demonstrating that glucose caused an activation of enzyme activity that overcame the competitive inhibition of transport and phosphorylation. When glucose was elevated, the rate coefficient of glucokinase did not decrease, indicating that glucokinase was stimulated by glucose. Both changes would lead to the increased glycogen synthesis and decreased glucose production rate observed in vivo during the fasted-to-fed transition.

Translocation and aggregation of hepatic glycogen synthase during the fasted-to-refed transition in rats

Changes in the activation state and intracellular distribution of liver glycogen synthase have been studied during the fasted-to-refed transition in rats. Glycogen synthase activity and activation state were measured in supernatants and pellets obtained after centrifugation of liver homogenates at 9200 g. Upon refeeding, the glycogen synthase activity ratio increased, in a time-dependent manner, in both fractions. The total activity of the enzyme decreased in supernatants and was quantitatively recovered in the pellets. Therefore, refeeding induced both the activation of glycogen synthase and its translocation from the soluble to the pelletable fraction. Immunocytochemical evidence indicates that refeeding induced the formation of clusters of glycogen synthase, which were recovered in the 9200 g sediments. However, the enzyme clusters did not locate with the glycogen particles in the pelletable fraction. The glycogen synthase activation state responded almost as an of-off switch to changes in the intracellular glucose 6-phosphate concentration in the range 0.2-0.3 mM. The amount of enzyme present in the pellets correlated linearly with the intracellular glucose 6-phosphate levels. These results indicate that glucose 6-phosphate is the key signal for both the activation and changes in intracellular localization of hepatic glycogen synthase in vivo.

Glucose induces the translocation and the aggregation of glycogen synthase in rat hepatocytes

Incubation of rat hepatocytes with glucose results in a decrease in the amount of glycogen synthase activity found in supernatants obtained after centrifugation of cell homogenates at 9200 g. The enzymic activity was quantitatively recovered in the sediments. This effect of translocation was dose- and time-dependent and correlated with the amount of immunoreactive enzyme determined by immunoblotting in both fractions. Hydrolysis by alpha-amylase of glycogen accumulated upon incubation with the sugar did not affect the translocation pattern. Translocation was also observed when cells were incubated with 2-deoxyglucose, which did not result in accumulation of glycogen. Immunocytochemical evidence indicates that glucose induces the aggregation of glycogen synthase molecules into clusters which are recovered in the sediments. These results indicate that glucose, in addition to activating glycogen synthase, may trigger changes in the localization of the enzyme in the cell.

Intraportal glucose delivery enhances the effects of hepatic glucose load on net hepatic glucose uptake in vivo

Although the importance of the hepatic glucose load in the regulation of liver glucose uptake has been clearly demonstrated in in vitro systems, the relationship between the hepatic glucose load and hepatic glucose uptake has yet to be defined in vivo. Likewise, the effects of the route of glucose delivery (peripheral or portal) on this relationship have not been explored. The aims of the present study were to determine the relationship between net hepatic glucose uptake (NHGU) and the hepatic glucose load in vivo and to examine the effects of the route of glucose delivery on this relationship. NHGU was evaluated at three different hepatic glucose loads in 42-h fasted, conscious dogs in both the absence (n = 7) and the presence (n = 6) of intraportal glucose delivery. In the absence of intraportal glucose delivery and in the presence of hepatic glucose loads of 50.5 +/- 5.9, 76.5 +/- 10.0, and 93.6 +/- 10.0 mg/kg/min and arterial insulin levels of approximately 33 microU/ml, NHGU was 1.16 +/- 0.37, 2.78 +/- 0.82, and 5.07 +/- 1.20 mg/kg/min, respectively. When a portion of the glucose load was infused into the portal vein and similar arterial insulin levels (approximately 36 microU/ml) and hepatic glucose loads (52.5 +/- 4.5, 70.4 +/- 5.6, and 103.6 +/- 18.4 mg/kg/min) were maintained, NHGU was twice that seen in the absence of portal loading (3.77 +/- 0.40, 4.80 +/- 0.59, and 9.62 +/- 1.43 mg/kg/min, respectively). Thus, net hepatic glucose uptake demonstrated a direct dependence on the hepatic glucose load that did not reach saturation even at elevations in the hepatic glucose load of greater than three times basal. In addition, the presence of intraportal glucose delivery increased net hepatic glucose uptake apparently by lowering the threshold at which the liver switched from net glucose output to net glucose uptake.

ADP and glucose as possible synergistic partners in the stimulation of liver glycogen synthase activation

Glucose administered either intravenously or orally causes liver glycogen synthase activation independent of a rise in circulating insulin. In vitro, physiological concentrations of glucose stimulate synthase phosphatase activity but only in the presence of a second effector which reduced the A0.5 for glucose. Caffeine and certain methylxanthines have been in vitro models for a putative natural effector. The present study demonstrates that, in vitro, ADP also reduced the A0.5 for glucose comparable to the effect of caffeine. The maximum stimulation by glucose in the presence of caffeine or ADP was comparable. The effect of ADP was specific among the major nucleoside diphosphates. However, the A0.5 for ADP was greater than the normal liver concentration which does not change in response to either glucose or insulin administration. The effect of ADP appeared distinct from that of the methylxanthines since it was observed that at near saturating concentrations of ADP and of glucose, stimulation was increased by addition of theophylline. Similarly, addition of adenosine, a natural cell constituent, caused increased stimulation. Subsequently, it was shown that adenosine reduced the A0.5 for ADP to a nearly physiological concentration. Thus, while ADP is not the inducible putative effector which has been predicted it may be part of an intracellular amplification system for glycogen synthase activation which increases the sensitivity to an induced effector. The present work suggests that the effective concentration of the natural ligand may be less than originally anticipated. This work also suggests that the putative effector could be structurally related to adenosine. Phosphorylase phosphatase activity known to be stimulated by ADP and glucose is further stimulated by the combination which may be acting in synergy.

Mechanisms underlying enhanced glycogenolysis in livers of 3,5,3'-triiodothyronine-treated rats

Rats trained on a diurnal controlled meal-feeding schedule and injected with a single dose of 3,5,3'-triiodothyronine (T3) failed to accumulate liver glycogen and incorporated less D-[6-3H]glucose into glycogen than normally observed during the feeding period. In the experimental group, the concentration of liver adenosine 3',5'-cyclic monophosphate (cAMP) did not fall during feeding and the pattern of activities of glycogen phosphorylase, glycogen synthase, and phosphorylase kinase remained conductive to glycogenolysis. Liver lysosomal alpha-glucosidase activity normally fell during feeding periods. After T3 treatment the activities of alpha-glucosidase and two lysosomal cathepsins (B1 and D) were elevated. The evidence suggests that T3 may induce both liver phosphorylase kinase and lysosomal alpha-glucosidase. This outcome of T3 excess, in concert with previously described T3-inducible systems, provides a plausible explanation for the failure of glycogen accumulation in this experimental model.

Characterization of trehalose-6-phosphate synthase and trehalose-6-phosphate phosphatase of Saccharomyces cerevisiae

The properties of yeast trehalose-6-phosphate synthase were reinvestigated in relation with the recent claim made by Panek et al. [Panek, A. C., de Araujo, P. S., Moura-Neto, V. and Panek, A. D. (1987) Curr. Genet. II, 459-465] that the enzyme would be stimulated by ATP and partially inactivated by cAMP-dependent protein kinase. Trehalose-6-phosphate synthase activity was measured by the sum of [14C]trehalose 6-phosphate and [14C]trehalose formed from UDP-[14C]glucose and glucose 6-phosphate. The activity measured in an extract of Saccharomyces cerevisiae was not affected by any treatment of the cells, such as incubation in the presence of glucose or of dinitrophenol, which are known to greatly increase the intracellular concentration of cAMP, nor by preincubation of the extract in the presence of ATP-Mg, cAMP and bovine heart cAMP-dependent protein kinase. The activity was also not significantly different in several mutants affected in the cAMP system. The kinetic properties of the partially purified enzyme were investigated; no effect of ATP could be detected but Pi acted as a potent noncompetitive inhibitor (Ki = 2 mM). The activity of trehalose-6-phosphate phosphatase was measured by the amount of [14C]trehalose formed from [14C]trehalose 6-phosphate. The enzyme could be separated from other phosphatases and appeared to be highly specific for trehalose 6-phosphate. It was Mg dependent and its kinetics for trehalose 6-phosphate was hyperbolic. Studies performed with intact cells, crude extracts or the purified enzyme did not reveal any cAMP-dependent change in its activity. Remarkably, trehalose-6-phosphate synthase and trehalose-6-phosphate phosphatase copurified in the course of different chromatographic procedures, suggesting that they are part of a single bifunctional protein. A 50-fold purification of the two enzymes could be achieved with a yield of only 2% by chromatography on Mono S followed by gel filtration on Superose 6B.

An improved assay for hepatic glycogen synthase in liver extracts with emphasis on synthase R

An assay for measurement of optimal amounts of glycogen synthase R, the physiologically active form of the enzyme, in liver tissue extracts is described. Tissue extracts enriched in synthase R had a pH profile different from those reported for synthase D and synthase I. In tissue extracts, synthase I had a broad pH optimum but maximal activity was present at pH 7.0-9.0. Synthase D had a sharp pH optimum at pH 8.5 and had little activity at pH 7.0, either in the presence or in the absence of glucose 6-phosphate (G6P). In extracts enriched in synthase R, the pH optimum was 7.0-8.0 without G6P, but 8.0 with G6P. The synthase R activity without G6P rapidly decreased at a higher pH. The proportion of synthase in the physiologically active form traditionally has been reported as an activity ratio based upon the activity in the presence and absence of G6P. The assay has been performed at a single pH. Because of the differences in pH profile, we recommend that the enzyme be measured at pH 7.0 in the absence of G6P and pH 8.5-8.8 in the presence of G6P. In previous assays the substrate UDP-Glc concentration used often has been less than saturating, and the G6P concentration generally has been excessive. A substrate concentration of 11 mM UDP-Glc was found to be necessary for maximal activity. A G6P concentration of 2 mM is adequate for measurement of the D form of the enzyme.

A minimal model of liver glycogen metabolism; feasibility for predicting flux rates

A minimal model of glycogen metabolism can allow the estimation of the flux rates in the glycogen pathway from the time course of the intermediates in the pathway, measured during substrate administration and hormonal stimulation. The comprehensive model of El-Refai & Bergman (Am. J. Physiol. 231, 1608, 1976) consisting of six compartments and 26 non-estimable parameters has successfully accounted for the responses of hepatic glycogenic intermediates in response to a glucose load in hepatocytes (Katz et al., J. biol. Chem. 253, 4530, 1978), in perfused liver (Nordlie et al., J. biol. Chem. 255, 1834, 1980) and during refeeding in vivo (Van DeWerve & Jeanrenaud, Am. J. Physiol. 247, E271, 1984). The comprehensive model is here reduced to a minimal model, consisting of five compartments representing extracellular and intracellular glucose, glucose-phosphate, uridine diphosphate glucose (UDPG), glycogen, and five parameters estimated from the hepatic response to a given stimulus. Estimation of these parameters requires the measurement of the net hepatic glucose balance, the net gluconeogenic flux, and the time course of glycogenic intermediates responding to a hormone or substrate stimulus. The hepatic glycogenolytic response predicted by the comprehensive model in response to an increase in glucagon is closely fitted by the minimal model. When Gaussian distributed random error was added, 0-5% SD in the glucose and glycogen compartments and 0-10% SD in the glucose-phosphate and UDPG compartments, the hepatic response predicted by the minimal model was virtually free of the added error, and the model parameters were found to be within 30% of their true values. When the minimal model was used to interpret the experimental response to an increase in glucose concentration it predicted that: (1) glucokinase can phosphorylate glucose at rates similar to maximal rates of net glycogen synthesis; (2) futile cycling at the glycogen/glucose-1-phosphate level can limit glycogen synthesis; and (3) glucose-6-phosphatase inhibition by glucose has a significant role in net glycogen synthesis.

Patterns of glycogen turnover in liver characterized by computer modeling

We used a computer model of liver glycogen turnover to reexamine the data of Devos and Hers, who reported the time course of accumulation in and loss from glycogen of label originating in [1-14C]galactose injected at different times after the start of refeeding of 40-h fasted mice or rats. In the present study computer representation of individual glycogen molecules was utilized to account for growth and degradation of glycogen according to specific hypothetical patterns. Using this model we could predict the accumulation and localization within glycogen of labeled glucose residues and compare the predictions with the previously published data. We considered three specific hypotheses of glycogen accumulation during refeeding: 1) simultaneous, 2) sequential, and 3) accelerating growth. Hypothetical patterns of glycogen degradation were 1) ordered and 2) random degradation. The pattern of glycogen synthesis consistent with experimental data was a steadily increasing number of growing glycogen molecules, whereas during degradation glycogen molecules are exposed to degrading enzymes randomly, rather than in a specific reverse order of synthesis. These patterns predict the existence of a specific mechanism for the steadily increasing "seeding" of new glycogen molecules during synthesis.

The mechanism of caffeine-enhanced glucose stimulation of liver glycogen synthase phosphatase activity

Our report that glucose within its physiological range stimulates glycogen synthase phosphatase activity, provided an appropriate second effector is present, has been expanded. The nature of the stimulatory process, particularly the roles of glucose, and of caffeine which represents the potential second effectors, has been studied. Glucose and caffeine stimulated synthase phosphatase activity in a synergistic manner. With 0.5 mM caffeine the A0.5 for glucose was 11 mM (from 27 mM), whereas in the presence of 30 mM glucose the A0.5 for caffeine was 0.06 mM (from 0.7 mM). At 10 mM glucose the A0.5 for caffeine was 0.1 mM. Glucose stimulation remained non-cooperative, unaffected by the presence of caffeine, whereas the cooperative stimulation of caffeine was unaffected by glucose. Some slight stimulation of synthase activity was observed with caffeine and with glucose over a wide concentration range. However, they did not act synergistically to influence the measurement of synthase activity. Glucose-6-phosphate, which also stimulates synthase phosphatase activity, acted independently, not synergistically with caffeine. All the methylxanthines were tested as potential second effectors in an effort to discover the essential structural elements of the agent. All dimethylxanthines, 3- and 7-methylxanthine and 1-methyl-3-isobutylxanthine enhanced glucose stimulation but none of them alone was stimulatory. Judged from the half-maximal concentrations, in the presence of 10 mM glucose, caffeine was the most potent second effector by a significant margin. The maximum velocity was also greatest with caffeine, whereas that with other methylxanthines was generally lower, and varied. 1-Methylxanthine with increased concentration was slightly inhibitory even in the presence of 10 mM glucose. Xanthine (0.5 mM), itself, strongly inhibited synthase phosphatase activity, an effect not influenced by glucose. Xanthine did not influence the measurement of synthase or phosphorylase phosphatase activity with or without glucose. In general, conditions of methylxanthine-enhanced, glucose stimulation of synthase phosphatase and phosphorylase phosphatase activities differed markedly, confirming that separate, distinct mechanisms are involved.

Some special characteristics of glycogen synthase from chicken liver

An anomalous initial grade of activation is observed for glycogen synthase from chicken liver when it is compared with synthase from mammalian liver. Some possible experimental causes for this discrepancy are investigated as well as the possibility of a different development stage to explain the special behaviour of avian synthase. It is concluded that avian synthase is less affected by external treatment than mammalian synthase. Avian synthase is always highly active, independently of external conditions and of development stage.

Difference in glucose sensitivity of liver glycolysis and glycogen synthesis. Relationship between lactate production and fructose 2,6-bisphosphate concentration

Incubation of isolated rat hepatocytes from fasted rats with 0-6 mM-glucose caused an increase in [fructose 2,6-bisphosphate] (0.2 to about 5 nmol/g) without net lactate production. A release of 3H2O from [3-3H]glucose was, however, detectable, indicating that phosphofructokinase was active and that cycling occurred between fructose 6-phosphate and fructose 1,6-bisphosphate. A relationship between [fructose 2,6-bisphosphate] and lactate production was observed when hepatocytes were incubated with [glucose] greater than 6 mM. Incubation with glucose caused a dose-dependent increase in [hexose 6-phosphates]. The maximal capacity of liver cytosolic proteins to bind fructose 2,6-bisphosphate was 15 nmol/g, with affinity constants of 5 X 10(6) and 0.5 X 10(6) M-1. One can calculate that, at 5 microM, more than 90% of fructose 2,6-bisphosphate is bound to cytosolic proteins. In livers of non-anaesthetized fasted mice, the activation of glycogen synthase was more sensitive to glucose injection than was the increase in [fructose 2,6-bisphosphate], whereas the opposite situation was observed in livers of fed mice. Glucose injection caused no change in the activity of liver phosphofructokinase-2 and decreased the [hexose 6-phosphates] in livers of fed mice.

The nature of the decreased activity of glycogen synthase phosphatase in the liver of the adrenalectomized starved rat

We have investigated the nature of the decrease in synthase phosphatase activity which occurs progressively in the livers of adrenalectomized rats that are starved for 48h. No evidence could be found for the accumulation of an inhibitor. Addition of the heat-stable deinhibitor protein, which antagonizes the effects of thermostable inhibitor proteins (inhibitor-1 and modulator), did not affect the activity of synthase phosphatase in gel-filtered liver extracts from normal or adrenalectomized starved rats; it did, however, increase the activity of phosphorylase phosphatase about fivefold in either condition. The restoration of synthase phosphatase activity by cortisol in vivo was prevented by actinomycin D. Further evidence concerning the nature of the missing protein came from a comparison of synthase phosphatase activities in liver homogenates from control and adrenalectomized starved rats, with the use of three distinct synthase b substrates. The apparent loss of synthase phosphatase activity in the deficient homogenates varied between 30% and 90% according to the type of substrate. The magnitude of this decrease corresponds to the degree of dependence of these substrates on the G-component of synthase phosphatase for efficient conversion to the alpha-form. No G-component could be isolated from livers of adrenalectomized starved rats. Cross-combination of subcellular fractions from control and deficient livers revealed an almost total loss of G-component, with little loss of S-component. This specific loss of functional G-component is identical to the deficiency previously observed in the livers of rats with severe chronic alloxan-diabetes.

Synthase activation is not a prerequisite for glycogen synthesis in the starved liver

To evaluate the contribution of phosphorylase and synthase interconversion as well as the availability of substrates to the onset of liver glycogen synthesis, this process was studied in rats starved overnight and refed for 4 h. On feeding, phosphorylase kinase and phosphorylase were inactivated in a cAMP-independent way, but the proportion of synthase a was unchanged and associated with increased hexoses 6-phosphate (glucose and fructose 6-phosphate), uridine diphosphoglucose (UDPG), and fructose 2,6-bisphosphate concentrations. These findings serve to support a "push" mechanism whereby substrate availability for synthase a concerted with phosphorylase inactivation provokes glycogen deposition. Anesthesia was compulsory for liver sampling and analysis. If such experiments were carried out in conscious rats killed by decapitation, artefactual cAMP-dependent phosphorylase activation and synthase inactivation were observed in starved animals. The phosphorylase activation persisted in refed animals but by a cAMP-independent mechanism.

Direct glucose stimulation of glycogen synthase phosphatase activity in a liver glycogen particle preparation

In glycogen particle suspensions prepared from fed rats given either glucagon or glucose in order to increase or decrease the phosphorylase a concentration, respectively, glucose stimulation of synthase phosphatase activity was observed. In preparations from glucagon-treated rats, addition of glucose stimulated synthase and phosphorylase phosphatase simultaneously and not sequentially. Synthase phosphatase stimulation was glucose concentration dependent even when phosphorylase a had been rapidly reduced to a low level. The estimated A0.5 for glucose stimulation of synthase phosphatase activity was 27 mM. An A0.5 for glucose stimulation of phosphorylase phosphatase activity could not be estimated since activity was still increasing with concentrations of glucose as high as 200 mM. In preparations from glucose-treated rats which contain virtually no phosphorylase a, glucose stimulation was still apparent but the A0.5 was increased modestly (36 mM). Stimulation of synthase phosphatase activity was specific for glucose. Several other monosaccharides and the polyhydric alcohol sorbitol were ineffective.

Regulation of glycogen metabolism in primary and transformed astrocytes in vitro

Glycogen metabolism was studied in primary and Herpesvirus-transformed cultures of neonatal rat brain astrocytes. A small fraction of the glucose consumed was conserved in glycogen in both the primary and the transformed astrocytic cell cultures. After addition of culture medium containing 5.5 mM glucose, glycogen increased to maximal levels within 2.5 h, the approximate time at which half of the medium glucose was consumed, and rapidly declined thereafter in both the primary and transformed astrocytic cultures. Maximum levels of glycogen were apparently related to the cell density of the Herpesvirus-transformed cultures, but primary cultures did not show this behavior. At any given cell density, maximal levels of glycogen were dependent on the concentration of extracellular glucose. Administration of glucose caused a transient activation of glycogen synthase alpha and a rapid inactivation of glycogen phosphorylase alpha.

Regulation of glycogenolysis in transformed astrocytes in vitro

Cultured astrocytes, transformed by Herpesvirus, were used as a model system to study several aspects of the control of glycogenolysis. Adrenergic agonists such as norepinephrine and isoproterenol caused an immediate and dose-dependent increase in the intracellular levels of cyclic AMP. Concomitant with the initial phase of cyclic AMP increase, conversion of phosphorylase b to a and glycogenolysis were observed. The elevation of cyclic AMP, phosphorylase conversion, and glycogenolysis were simultaneously blocked by beta-adrenergic blockers, but not by alpha-adrenergic blocking agents. Repeated administration of norepinephrine caused an attenuated response in both cyclic AMP accumulation and glycogenolysis. Glycogen degradation is also partially regulated by glucose availability. In the presence of glucose, norepinephrine-induced glycogenolysis is blocked, despite elevations in cyclic AMP. The direct role of glucose is postulated, since glucose analogs mimic the effects of glucose.

Observations on the role of smooth endoplasmic reticulumin glucocorticoid-induced hepatic glycogen deposition

We have studied by quantitative electron microscopy the relationship of specific hepatic cellular organelles to glycogen synthesis using dexamethasone, a potent synthetic glucocorticoid, to induce glycogen deposition in livers of adrenalectomized rats. Chemical and ultrastructural glycogen determinations revealed that the livers of fasted adrenalectomized rats had very low glycogen levels. Dexamethasone caused a time-related increase in hepatic glycogen which was the result of increases in the number of hepatocytes depositing glycogen and the amount of glycogen in each cell. The surface density of smooth endoplasmic reticulum (SER) in centrilobular and periportal hepatocytes also increased after treatment with dexamethasone; this increase preceded glycogen deposition. The newly deposited glycogen was spatially associated with membranes of SER, and a continued increase in SER surface density was correlated temporally with the increasing glycogen volume density. In both centrilobular and periportal hepatocytes, the surface density of rough endoplasmic reticulum (RER) initially decreased after dexamethasone administration but later increased. These data support the hypothesis that dexamethasone-induced enhancement of SER is functionally associated with the increase in glycogen, and that although the initial increase in SER may occur through transformation of RER to SER, later increases in SER require synthesis of new membranes.

The glucose/glucose-6-phosphate cycle in the periportal and perivenous zone of rat liver

Periportal and perivenous hepatocytes contain different activities (V) of antagonistic key enzymes such as glucokinase and glucose-6-phosphatase. In order to get an insight into the metabolism of the periportal and perivenous area the flux rates (v) of the glucose/glucose-6-phosphate cycle were calculated on the basis of the Michaelis-Menten equation using the measured zonal concentrations of glucose and glucose 6-phosphate, the zonal activities of glucokinase and glucose-6-phosphatase previously reported and the half-saturating substrate concentrations (Km) of the two enzymes found in the literature. The concentrations of glucose were obtained as a first approximation by measuring the concentrations in portal (= periportal) and hepatovenous (= perivenous) blood; those of glucose 6-phosphate were calculated from the levels determined in microdissected periportal and perivenous liver tissue. The calculations showed (a) that the overall cycling rates agreed remarkably well with those reported for intact animals and (b) that during a normal feeding rhythm the periportal zone should catalyze net glucose output and the perivenous zone should mediate net glucose uptake, as proposed by the model of 'metabolic zonation'.

Hepatic effects of glucose and insulin independent of cyclic nucleotide changes

To determine if cGMP might function as a second messenger for insulin, an in situ liver perfusion system was established in which hepatic effects of insulin could be correlated with changes in cyclic nucleotides. Several combinations of insulin (10 mU/ml) and glucose (50 mg/ml) were infused (0.1 ml/min) for 30 min into fasted normal and diabetic rats with removal of a similar volume of blood. Samples of livers were removed at the beginning and end and at various times during the perfusion. In normal animals perfused with buffer alone, hepatic glycogen content fell. When glucose (with or without added insulin) was added to the perfusate, glycogen levels rose. With buffer alone, there was no change in the independent (I) form of glycogen synthase at 10 min but a modest increase at 30 min. With insulin and/or glucose, there as a large increase in the I-form of the enzyme at 10 min and a further rise at 30 min. Neither cGMP nor cAMP changed even though tissue samples were obtained at multiple times throughout the perfusion. Cyclic nucleotides were also measured in liver slices exposed to insulin (1 mU/ml) after 30 min of pre-incubation for stabilization. Although significant increases in cGMP were noted in the tissue exposed to insulin, similar significant rises also occurred in appropriately paired control slices. When glucagon was used in both the in situ perfusion and the paired liver slice systems, the expected rapid and large increases in cAMP levels occurred attesting to the validity of both approaches in evaluating hepatic cyclic nucleotide responses. These results plus the paucity of convincing data in the literature strongly suggest that cGMP can no longer be considered a candidate for the putative second messenger of insulin.

Cyclic AMP-mediated activation of hepatic glycogenolysis by fructose

Isolated livers from fed and fasted rats were perfused for 30 min with recirculating blood-buffer medium containing no added substrate and then switched to a flow-through perfusion using the same medium for an additional 5, 10 and 30 min. Continuous infusion of fructose for the final 5, 10 or 30 min resulted in activation of glycogen phosphorylase, an increase in the activity of protein kinase, elevated levels of tissue adenosine 3', 5'-monophosphate (cyclic AMP), and no consistent effect on glycogen synthase. Infusion of glucose under the same conditions resulted in activation of glycogen synthase, inactivation of glycogen phosphorylase, no change in protein kinase, and no consistent change in tissue cyclic AMP. These results demonstrate that while glucose promotes hepatic glycogen synthesis, fructose promotes activation of the enzymatic cascade responsible for glycogen breakdown.

Frog liver glycogen synthase. In vitro and in vivo interconversions between I and D forms

1. Frog liver has enzymatic systems able to interconvert glycogen synthase. 2. D to I conversion is achieved in vitro by incubation at 30 degrees C. ATP, ADP, inorganic phosphate and glycogen are inhibitors of this conversion, whereas glucose-6-P and Mg2+ stimulate it. 3. I to D conversion in vitro depends on ATP-Mg2+. Cyclic-AMP activates this conversion, while glucose-6-P inhibits it. 4. Injection of glucose, ribose, mannose, fructose, galactose, and cortisone into frogs increase liver percentage of I activity. 5. Glucagon and adrenaline decrease percentage of I activity.

Glycogen synthase in the rat tapeworm, Hymenolepis diminuta--II. Control of enzyme activity by glucose and glycogen

1. The proportion of activity in the physiologically active I form of glycogen synthase in Hymenolepis diminuta (Cestoda) decreased in the worm when the rat host was fasted and was greatly increased in the cestode 1 hr after a 24 hr fasted rat was refed. 2. The increase in glycogen synthase I activity was due to glucose present in the host gut after feeding, not to other physiological changes in the rat intestine due to meal consumption. 3. Incubation of intact H. diminuta in vitro with glucose also resulted in the conversion of glycogen synthase D to I. 4. Glucose does not appear to affect the glycogen synthase complex directly, because neither the total synthase converted to I nor the rate of conversion was affected by glucose in a partially purified homogenate. 5. High concentrations of glycogen inhibited the synthase D to I conversion and high mol. wt glycogen was a more effective inhibitor than low mol. wt glycogen.