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.     

The role of glycogen synthase phosphatase in the glucocorticoid-induced deposition of glycogen in foetal rat liver.

1. The mechanism that underlies the induction of glycogen synthesis in the foetal rat liver by glucocorticoids was reinvestigated in conditions where the accumulation of glycogen is either precociously induced with dexamethasone or inhibited by steroid deprivation. It appears that glucocorticoids act as the physiological trigger for glycogen synthesis by inducing both glycogen synthase (a known effect) and its activating enzyme, glycogen synthase phosphatase. 2. The activity of glycogen synthase phosphatase in adult liver stems from the interaction of two protein components [Doperé, Vanstapel & Stalmans (1980) Eur. J. Biochem. 104, 137--146]. Two independent experimental approaches indicate that the cytosolic 'S-component' is already well developed in the foetal liver before the onset of glycogen synthesis. The manifold glucocorticoid-dependent increase in synthase phosphatase activity during late gestation must be attributed to the specific development of the glycogen-bound 'G-component'.     

Hormonal regulation of hepatic glycogen synthase phosphatase

Perfusion of livers from fed rats with medium containing glucagon (2 x 10(-10) or 1 x 10(-8) M) resulted in both time- and concentration-dependent inactivation of glycogen synthase phosphatase. Expected changes occurred in cAMP, cAMP-dependent protein kinase, glycogen synthase, and glycogen phosphorylase. The effect of glucagon on synthase phosphatase was partially reversed by simultaneous addition of insulin (4 x 10(-8) M), an effect paralleled by a decrease in cAMP. Addition of arginine vasopressin (10 milliunits/ml) resulted in a similar inactivation of synthase phosphatase and activation of phosphorylase, but independent of any changes in cAMP or its kinase. Phosphorylase phosphatase activity was unaffected by any of these hormones. Synthase phosphatase activity, measured as the ability of a crude homogenate to catalyze the conversion of purified rat liver synthase D to the I form, was no longer inhibited by glucagon or vasopressin when phosphorylase antiserum was added to the phosphatase assay mixture in sufficient quantity to inhibit 90-95% of the phosphorylase a activity. These data support the following conclusions: 1) hepatic glycogen synthase phosphatase activity is acutely modulated by hormones, 2) hepatic glycogen synthase phosphatase and phosphorylase phosphatase are regulated differently, 3) the hormone-mediated changes in synthase phosphatase cannot be explained by an alteration of the synthase D molecule affecting its behavior as a substrate, and 4) glycogen synthase phosphatase activity is at least partially controlled by the level of phosphorylase a.     

The hepatic defect in glycogen synthesis in chronic diabetes involves the G-component of synthase phosphatase.

Hepatocytes from normal fed rats and from chronically (90 h) alloxan-diabetic rats were compared. The rate and the extent of activation of glycogen synthase in response to 60 mM-glucose were greatly decreased in diabetes. During incubation of gel-filtered extracts from broken hepatocytes, diabetes only decreased the rate of the activation, which became ultimately complete in either preparation. Synthase phosphatase activity, as measured by the activation of purified hepatic synthase b, was decreased in chronic diabetes. The decrease was proportional to the severity of the diabetes, and reached 90% when the plasma glucose concentration was greater than or equal to 55 mM. In contrast, phosphorylase phosphatase activity was not decreased. Synthase phosphatase activity was progressively restored by treatment with insulin for 20-68 h. During the induction of diabetes and during insulin treatment there was a good correlation between the activity of synthase phosphatase and the maximal activation of synthase in glucose-stimulated hepatocytes from the same livers. The decreased activity of synthase phosphatase in diabetes cannot be explained by an inhibitor. The decrease was much less marked when synthase phosphatase was assayed by the dephosphorylation of 32P-labelled synthase from muscle. This observation suggested a loss of only one component of synthase phosphatase. Cross-combination of subcellular fractions from control rats and from diabetic rats showed a preferential loss of G-component, with little or no loss of S-component. No G-component could be detected in severe diabetes. The concentration of G-component is therefore of critical importance in the glucose-induced activation of glycogen synthase in the liver.     

The divalent cation dependence of liver glycogen synthase phosphatase activity

Summary In a previous report it was shown that EDTA inhibition of liver glycogen synthase phosphatase activity in preparations from normal, fed rats could be increased upon glucagon or cAMP treatment. This occurred without a change in the half-maximum inhibitory concentration of EDTA. Glucose administration to animals resulted in decreased EDTA inhibition. The inhibitory action of EDTA has been further characterized by comparing its action with that of other chelators (CDTA and EGTA) and examining the effects of various divalent cations on chelator inhibition. Both CDTA and EDTA which differ structurally were inhibitory at 5 mm concentrations whereas EGTA which is structurally similar to EDTA was not inhibitory at concentrations up to 10 mm. The lack of inhibition by EGTA could be explained by its weak affinity for Mg⁺⁺ in the preparation. A comparison of CDTA and EDTA revealed that CDTA was a more potent inhibitor than EDTA (I_0.5, 0.15 mm vs 0.3 mm). Glucagon and glucose treatment of rats resulted in changes in CDTA inhibition which closely paralleled those of EDTA. A large group of divalent cations were tested but only Mg⁺⁺, Ca⁺⁺, and Mn⁺⁺ both prevented and reversed CDTA or EDTA inhibition. Fifty percent reversal using either chelator occurred at calculated free-metal ion concentrations of approximately 2 µm, 0.08 µm and 0.0004 µm, respectively. Thus, it is clear that EDTA inhibition is due to its chelation effect and is not due to a nonspecific anionic effect.     

Regulation of liver glycogen synthase phosphatase activity by ATP-Mg

The kinetics of a synthase phosphatase reaction inhibited by ATP-Mg in a liver glycogen particle preparation were complex. In the presence of a physiological concentration of ATP-Mg, synthase phosphatase activity in the glycogen particle follows a biphasic course. Initially, the reaction was inhibited but later the reaction rate accelerated. The reaction was inhibited but the rate was constant in the presence of ATP-Mg with the addition of a physiological concentration of glucose 6-phosphate (Glc 6-P). Therefore, in most subsequent experiments Glc 6-P was added. The concentration of ATP-Mg at which 50% maximal inhibition (I0.5) occurred was approximately 0.1 mM in preparations obtained from rats given glucagon prior to being killed. In preparations from animals given glucose, the I0.5 was increased to 2.0 mM. The maximum inhibition was little changed in preparations from glucose- or glucagon-treated animals. Thus, administration of glucose in vivo reduced the sensitivity of the synthase phosphatase to ATP-Mg inhibition. Complexes of ATP with paramagnetic ions such as Co2+ and Mn2+ were less inhibitory than complexes with diamagnetic ions, including Ca2+ and Mg2+. Magnesium complexes of adenosine tetraphosphate and 5'-adenylimidodiphosphate also were inhibitory. Inhibition was independent of phosphorylase a and not a nonspecific, polyvalent anion effect. The best explanation for the distinctive effects of ATP-Mg in preparations from glucagon- and glucose-treated animals is that the respective treatments promote and stabilize different forms of synthase D or possibly synthase phosphatase with different affinities for ATP-Mg. These forms are interconvertible, as previously suggested, in studies employing EDTA (20).     

Control of glycogen synthase activity in developing rat liver.

Fasting newborn and growing young rats, though capable of synthesizing liver glycogen when fed, are, unlike adult fasted animals, insensitive to glucocorticoid stimulation of the rate of glucose and lactate incorporation into glycogen. Hormone resistance parallels a decreased liver capability for the synthase b to a conversion reaction up to 2 days after birth, after which the b to a transformation becomes adult type in nature. A comparison of the level of glucose 6-phosphate in liver to the effect of the activator on the synthase activity from newborn rat shows that the enzyme has a greater affinity toward the activator than comparable enzyme from the adult, suggesting the presence of an intermediate metabolite-regulated form of synthase in neonatal liver.     

Effect of starvation and insulin treatment on glycogen synthase D and synthase D phosphatase activity in rat heart

Summary We have previously shown that synthase phosphatase activity was decreased in starved animals and was rapidly restored by insulin administration (1). In order to determine whether the decreased phosphatase activity was due to a decrease in phosphatase enzyme per se or to a change in the substrate, synthase D, phosphatase activity has been determined using purified synthase D substrate. Using purified heart or liver synthase D, phosphatase activity was lower in extracts from starved animals than in fed animals. Insulin administration rapidly increased phosphatase activity in extracts from the starved animals. The total amount of endogenous synthase D which was convertible to synthase I was lower in extracts from starve animals, but this was rapidly increased within 15 minutes following insulin administration. These data suggest that starvation and insulin have a direct effect on the phosphatase enzyme activity per se and probably on the substrate suitability of synthase D as well.     

The importance of nucleoside triphosphate inhibition of liver glycogen synthase phosphatase activity

The liver glycogen particle contains constitutive glycogen-synthase phosphatase activity which is inhibited by ATP-Mg in a concentration-dependent manner within the physiological range (I0.5 = 0.1 mM). Therefore, we determined whether other nucleoside triphosphate-magnesium complexes also inhibit synthase phosphatase activity. UTP-Mg, CTP-Mg and GTP-Mg were all found to be inhibitory. The maximum inhibition was 85-90% which was greater than that for ATP-Mg. The I0.5 for UTP-Mg was comparable to that of ATP-Mg but it was greater for CTP-Mg and for GTP-Mg. At in vivo physiological concentrations, both UTP and ATP are possible inhibitors of synthase phosphatase activity. In the presence of a saturating concentration of ATP-Mg, added UTP-Mg increased the inhibition suggesting the presence of at least two distinct nucleotide binding sites. Substitution of calcium for magnesium in an ATP complex had no effect on the I0.5, but increased the maximum inhibition. The present studies also suggest that in the multistep conversion of synthase D to synthase I, ATP-Mg inhibition occurs early in the sequence. Addition of glycogen, a known inhibitor of synthase phosphatase activity, to a reaction mixture containing 3 mM ATP-Mg did not further inhibit synthase phosphatase activity when added at concentrations up to 22 mg/ml. The latter data suggest that the presence of a nucleoside triphosphate may desensitize the phosphatase to glycogen inhibition. ATP-Mg and, to a lesser extent, UTP-Mg and CTP-Mg all stimulated phosphorylase phosphatase activity but GTP-Mg did not.     

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.     

The effect of glucose on liver glycogen synthase phosphatase activity in the presence of ATP-Mg

Glycogen particle synthase phosphatase activity is stimulated by glucose with an A0.5 of approximately 27 mM. The A0.5 is higher than the usual concentrations present in the liver. However, in vitro, certain methylxanthines such as caffeine or theophylline reduce the glucose A0.5 to approximately 10 mM, a concentration well within the normal range of liver glucose concentrations. Methylxanthines do not affect the maximum stimulation by glucose (2.3-fold greater than control rate). The phosphatase reaction also is inhibited by ATP-Mg (I0.5 = 0.1 mM). In the present studies, we have determined the interaction of these effectors. The presence of ATP-Mg at a concentration of 3 mM only slightly reduced the maximal stimulation by glucose. The A0.5 for glucose was unaffected (24 mM). The synergistic effect of caffeine with glucose also was not changed by the presence of ATP-Mg. The A0.5 for glucose was reduced to 11 mM, similar to that in the absence of ATP-Mg. In addition, maximum stimulation by glucose was unchanged. Similar results were obtained when theophylline replaced caffeine. We conclude that the ATP-Mg binding site on either the phosphatase or its substrate, synthase D, does not influence the glucose and methylxanthine binding sites. Effectively, ATP-Mg increased the range over which glucose stimulates the phosphatase activity. In the presence of ATP-Mg, the maximum stimulation by glucose is approximately 7-fold; whereas, in the absence of ATP-Mg it is approximately 2.3-fold. Thus, ATP-Mg may serve to increase the sensitivity of the synthase phosphatase reaction to glucose regulation under in vivo conditions.     

Dephosphorylation of glycogen synthase in rat heart extracts by E. coli alkaline phosphatase

Regulation of the dephosphorylation of glycogen synthase in extracts from rat heart has been studied by adding exogenous phosphatase to the extract. These experiments were possible only because the endogenous protein phosphatase activity of the extract could be inhibited by KF under conditions where alkaline phosphatase activity was not. The concentration of substrate (glycogen synthase from the heart extract) and catalyst (purified E. coli alkaline phosphatase) could be varied independently, by adding known amounts of alkaline phosphatase to the KF-containing heart extracts. Alkaline phosphatase could completely dephosphorylate glycogen synthase while phosphorylase was unchanged. The rate of dephosphorylation was proportional to both the concentration of alkaline phosphatase added to the tissue extract and the amount of glycogen synthase in the extract. The Km for glycogen synthase was close to the concentration found in heart tissue. The Km and the maximum rate of dephosphorylation were both dependent on the phosphorylation state of the glycogen synthase. Less phosphorylated enzyme forms were dephosphorylated faster. These results indicate the necessity for precise control of many variables in studying the rate of glycogen synthase dephosphorylation. Alkaline phosphatase-catalyzed dephosphorylation could be inhibited by physiological concentrations of glycogen. Glycogen synthase dephosphorylation in extracts from fasted-refed rats was less sensitive to glycogen inhibition than in extracts from normal animals. The phosphorylation state of the glycogen synthase in these animals was assessed by kinetic studies to show that differences in phosphorylation state probably could not account for the observations. Fasting led to a decreased rate of dephosphorylation of glycogen synthase due to both an apparent change in kinetic properties of glycogen synthase as a substrate for alkaline phosphatase, and an increased inhibitory effect of glycogen. Stable modifications of glycogen synthase caused by altered nutritional states in the animals are thought to produce these effects.     

Association of glycogen synthase phosphatase and phosphorylase phosphatase activities with membranes of hepatic smooth endoplasmic reticulum

A detailed investigation was conducted to determine the precise subcellular localization of the rate-limiting enzymes of hepatic glycogen metabolism (glycogen synthase and phosphorylase) and their regulatory enzymes (synthase phosphatase and phosphorylase phosphatase). Rat liver was homogenized and fractionated to produce soluble, rough and smooth microsomal fractions. Enzyme assays of the fractions were performed, and the results showed that glycogen synthase and phosphorylase were located in the soluble fraction of the livers. Synthase phosphatase and phosphorylase phosphatase activities were also present in soluble fractions, but were clearly identified in both rough and smooth microsomal fractions. It is suggested that the location of smooth endoplasmic reticulum (SER) within the cytosome forms a microenvironment within hepatocytes that establishes conditions necessary for glycogen synthesis (and degradation). Thus the location of SER in the cell determines regions of the hepatocyte that are rich in glycogen particles. Furthermore, the demonstration of the association of synthase phosphatase and phosphorylase phosphatase with membranes of SER may account for the close morphological association of SER with glycogen particles (i.e., disposition of SER membranes brings the membrane-bound regulatory enzymes in close contact with their substrates).     

Regulation of glycogen synthesis in human skeletal muscle: does cellular glycogen control glycogen synthase phosphatase activity?

Contrary to the accepted feedback control mechanism of glycogen biosynthesis in skeletal muscle, evidence is presented here leading to the conclusion that glycogen does not control the activity of glycogen synthase phosphatase in intact human skeletal muscle tissue.     

Contraction-mediated inactivation of glycogen synthase is accompanied by inactivation of glycogen synthase phosphatase in human skeletal muscle.

Activities of glycogen synthase (GS) and GS phosphatase were determined on human muscle biopsies before and after isometric contraction at 2/3 maximal voluntary force. Total GS activity did not change during contraction (4.92 +/- 0.70 at rest versus 5.00 +/- 0.42 mmol/min per kg dry wt.; mean +/- S.E.M.), whereas both the active form of GS and the ratio of active form to total GS decreased by approximately 35% (P less than 0.01). GS phosphatase was inactivated in all subjects by an average of 39%, from 5.95 +/- 1.30 to 3.63 +/- 0.97 mmol/min per kg dry wt. (P less than 0.01). It is suggested that at least part of the contraction-induced inactivation of GS is due to an inactivation of GS phosphatase.