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.     

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).     

Non-hormonal and hormonal control of glycogen metabolism in isolated sheep liver cells

1. Control of glycogen metabolism by various substrates and hormones was studied in ruminant liver using isolated hepatocytes from fed sheep. 2. In these cells glucose appeared uneffective to stimulate glycogen synthesis whereas fructose and propionate activated glycogen synthase owing to (i) a decrease in phosphorylase a activity and (ii) changes in the intracellular concentrations of glucose 6-phosphate and adenine nucleotides. 3. The activation of hepatic glycogenolysis by glucagon and alpha 1-adrenergic agents was associated with increased phosphorylase a and decreased glycogen synthase activities. 4. The simultaneous changes in these two enzyme activities suggest that in sheep liver, activation of phosphorylase a is not a prerequisite step for synthase inactivation. 5. In sheep hepatocytes, in the presence of propionate and after a lag period, insulin activated glycogen synthase without affecting phosphorylase a. 6. This latter result suggests that the direct activation of glycogen synthase by insulin is mediated by a glycogen synthase-specific kinase or phosphatase. Insulin also antagonized glucagon effect on glycogen synthesis by counteracting the rise of cAMP.     

Studies on the alpha-adrenergic activation of hepatic glucose output. I. Studies on the alpha-adrenergic activation of phosphorylase and gluconeogenesis and inactivation of glycogen synthase in isolated rat liver parenchymal cells.

Epinephrine and the alpha-adrenergic agonist phenylephrine activated phosphorylase, glycogenolysis, and gluconeogenesis from lactate in a dose-dependent manner in isolated rat liver parenchymal cells. The half-maximally active dose of epinephrine was 10-7 M and of phenylephrine was 10(-6) M. These effects were blocked by alpha-adrenergic antagonists including phenoxybenzamine, but were largely unaffected by beta-adrenergic antagonists including propranolol. Epinephrine caused a transient 2-fold elevation of adenosine 3':5'-monophosphate (cAMP) which was abolished by propranolol and other beta blockers, but was unaffected by phenoxybenzamine and other alpha blockers. Phenoxybenzamine and propranolol were shown to be specific for their respective adrenergic receptors and to not affect the actions of glucagon or exogenous cAMP. Neither epinephrine (10-7 M), phenylephrine (10-5 M), nor glucagon (10-7 M) inactivated glycogen synthase in liver cells from fed rats. When the glycogen synthase activity ratio (-glucose 6-phosphate/+ glucose 6-phosphate) was increased from 0.09 to 0.66 by preincubation of such cells with 40 mM glucose, these agents substantially inactivated the enzyme. Incubation of hepatocytes from fed rats resulted in glycogen depletion which was correlated with an increase in the glycogen synthase activity ratio and a decrease in phosphorylase alpha activity. In hepatocytes from fasted animals, the glycogen synthase activity ratio was 0.32 +/- 0.03, and epinephrine, glucagon, and phenylephrine were able to lower this significantly. The effects of epinephrine and phenylephrine on the enzyme were blocked by phenoxybenzamine, but were largely unaffected by propranolol. Maximal phosphorylase activation in hepatocytes from fasted rats incubated with 10(-5) M phenylephrine preceded the maximal inactivation of glycogen synthase. Addition of glucose rapidly reduced, in a dose-dependent manner, both basal and phenylephrine-elevated phosphorylase alpha activity in hepatocytes prepared from fasted rats. Glucose also increased the glycogen synthase activity ratio, but this effect lagged behind the change in phosphorylase. Phenylephrine (10-5 M) and glucagon (5 x 10(-10) M) decreased by one-half the fall in phosphoryalse alpha activity seen with 10 mM glucose and markedly suppressed the elevation of glycogen synthase activity. The following conclusions are drawn from these findings. (a) The effects of epinephrine and phenylephrine on carbohydrate metabolism in rat liver parenchymal cells are mediated predominantly by alpha-adrenergic receptors. (b) Stimulation of these receptors by epinephrine or phenylephrine results in activation of phosphorylase and gluconeogenesis and inactivation of glycogen synthase by mechanisms not involving an increase in cellular cAMP. (c) Activation of beta-adrenergic receptors by epinephrine leads to the accumulation of cAMP, but this is associated with minimal activation of phosphorylase or inactivation of glycogen synthase...     

Acute regulation of hepatic protein phosphatases by glucagon, insulin, and glucose

The intravenous administration of glucagon to anesthetized rats resulted within 5 min in a 20% drop in the hepatic phosphorylase phosphatase activity, as measured in a post-mitochondrial supernatant at low dilution, but it did not affect the activity of glycogensynthase phosphatase. On the other hand, the injection of insulin plus glucose caused increases by about 35% in both phosphatase activities. Upon subcellular fractionation these effects were recovered in the cytosol, but not in the glycogen/microsomal fraction. However, activity changes in the latter fraction were observed after recombination with the liver cytosol from a hormone-treated animal. Preincubation of the liver cytosol with modulator protein (a specific inhibitor of type-1 protein phosphatases) cancelled the activity changes induced by insulin plus glucose. No hormonal effects on hepatic protein phosphatase activities were observed when the fractions were either diluted an additional 10-fold or pretreated with trypsin. An acute hormonal regulation of protein phosphatases could also be demonstrated in the perfused liver. When added to the perfusion medium, glucose as well as insulin increased the cytosolic protein phosphatase activities by about 25%. Their effect was additive, irrespective of the order of addition. On the other hand, the addition of glucagon and/or vasopressin resulted in a 20% drop in the phosphorylase phosphatase activity. The presence of glucagon did not interfere with the effectiveness of insulin, and vice versa. The changes in the phosphorylase phosphatase activities induced by glucagon, insulin, and glucose represented changes in the Vmax only. We propose that the acute control of the hepatic glycogen synthase phosphatase and phosphorylase phosphatase activities is mediated by transferable, cytosolic effector(s).     

Effects of adrenalectomy on hormone action on hepatic glucose metabolism. Impaired glucagon activation of glycogen phosphorylase in hepatocytes from adrenalectomized rats.

The effects of adrenalectomy on glucagon activation of liver glycogen phosphorylase and glycogenolysis were studied in isolated hepatocytes. Adrenalectomy resulted in reduced responsiveness of glycogenolysis and phosphorylase to glucagon activation. Stimulation of cAMP accumulation and cAMP-dependent protein kinase activity by glucagon was unaltered in cells from adrenalectomized rats. Adrenalectomy did not alter the proportion of type I and type II protein kinase isozymes in liver, whereas this was changed by fasting. Activation of phosphorylase kinase by glucagon was reduced in hepatocytes from adrenalectomized rats, although the half-maximal effective concentration of glucagon was unchanged. No difference in phosphorylase phosphatase activity between liver cells from control and adrenalectomized rats was detected. Glucagon-activated phosphorylase declined rapidly in hepatocytes from adrenalectomized rats, whereas the time course of cAMP increase in response to glucagon was normal. Addition of glucose (15 mM) rapidly inactivated glucagon-stimulated phosphorylase in both adrenalectomized and control rat hepatocytes. The inactivation by glucose was reversed by increasing glucagon concentration in cells from control rats, but was accelerated in cells from adrenalectomized rats. It is concluded that impaired activation of phosphorylase kinase contributes to the reduced glucagon stimulation of hepatic glycogenolysis in adrenalectomized rats. The possible role of changes in phosphorylase phosphatase is discussed.     

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.     

Liver glycogen synthase phosphatase and phosphorylase phosphatase activities in vitro following glucose and glucagon administration

Correlation of the changes in phosphorylase a concentration with the synthase phosphatase velocity in a glycogen particle preparation in the presence of EDTA revealed that the initial synthase phosphatase rate was greatest in extracts from glucose-treated rats and least in extracts from glucagon-treated rats. In all cases the velocity increased with time and with a decrease in phosphorylase a. However, a threshold release of phosphatase activity when phosphorylase a reached a critical level was not observed. The data are compatible with either an independent regulation of synthase phosphatase by glucose and glucagon or regulation of the activity by phosphorylase over a range of phosphorylase a concentrations.     

Effect of metabolites and phosphorylase on the D to I conversion of glycogen synthase from human polymorphonuclear leukocytes.

The D to I conversion of glycogen synthase from human polymorphonuclear leukocytes was examined both in a gel-filtered homogenate and in a preparation of glycogen particles with adhering enzymes, purified by chromatography on concanavalin A bound to Sepharose. It was found that glucose 6-phosphate as well as mannose 6-phosphate, glucosamine 6-phosphate, and 2-deoxy-glucose 6-phosphate activated the reaction, whereas the corresponding sugars were without effect. Mn2+ and Ca2+ increased the conversion rate by 51% and 27%, respectively, whereas Mg2+ and inorganic phosphate were without effect. Sodium fluoride inhibited the reaction completely. Glycogen inhibited the reaction in physiological concentrations and 0.5 mM glucose 6-phosphate was able to overcome this inhibition. MgATP greatly augmented the inhibition caused by glycogen in the glycogen particle preparation. This combined effect could be overcome by glucose 6-phosphate in concentrations from 0.1 to 1 mM. Phosphorylase alpha purified from human polymorphonuclear leukocytes inhibited the D to I conversion in a glycogen particle preparation. The inhibition was counteracted by glucose 6-phosphate and to a lesser degree by AMP. Phosphorylase beta was also inhibitory, but only at higher concentrations than phosphorylase alpha. No phosphorylase phosphatase activity was found in the glycogen particle preparation, which may indicate that chromatography on concanavalin A-Sepharose separates this enzyme from the synthase phosphatase or partially destroys the activity of a hypothetical common protein phosphatase.     

Regulation of renal glycogen synthase interconversion of two forms in vitro

Glycogen synthase (UDP glucose: glycogen α-4-glucosyltransferase, EC 2.4. 1.11) from rat kidney was stimulated 4- to 5-fold by glucose 6-phosphate. The for glucose 6-phosphate stimulation was about 0.45 mM. Glycogen synthase was not evenly distributed throughout the kidney. Total synthase activity was greatest in the outer cortex and cortico-medullary junction and least in the inner medulla. Glucose 6-phosphate stimulation was greatest in the outer cortex and least in the inner medulla. Glycogen synthase in crude homogenates was not complexed with glycogen and eluted from Sepharose 6-B with an apparent molecular weight of about 390 000.Renal glycogen synthase appeared to exist in two interconvertible forms, synthase I (activity in the absence of glucose 6-phosphate) and synthase D (requires glucose 6-phosphate for activity). The conversion of synthase D to I (synthase D phosphatase) was inhibited by F⁻, glycogen, ATP, Mn²⁺, and Co²⁺. The conversion was not altered by mercaptoethanol, AMP, Mg²⁺, or Ca²⁺. The conversion of synthase I to D (synthase I kinase) required ATP-Mg and was stimulated by cyclic AMP.It was suggested that the interconversion of renal glycogen synthase involved a phosphorylation-dephosphorylation. The significance of glycogen synthase interconversion to the regulation of renal glycogen synthesis is discussed.     

Synergistic inhibition of glucagon-induced effects on hepatic glucose metabolism in the presence of insulin and a cAMP antagonist

Inhibition of hepatic glycogenolysis by an intracellular inhibitor of cAMP-dependent protein kinase in glucagon-stimulated hepatocytes was potentiated by insulin. When hepatocytes isolated from fed rats were treated with 0.3 nM glucagon, which activates glycogen breakdown half-maximally, the Rp diastereomer of adenosine cyclic 3',5'-phosphorothioate [Rp-cAMPS), a cAMP antagonist, inhibited glucose production half-maximally at 3 microM. A 10-fold lower concentration of antagonist was required to half-maximally inhibit glucose production in the presence of 10 nM insulin, which alone produced only 15% inhibition. Under the same experimental conditions, the maximal effect of (Rp)-cAMPS was also potentiated. In addition, the increase in the concentration of glucagon required for half-maximal activation of phosphorylase activity and inactivation of glycogen synthase activity in the presence of minimally effective concentrations of insulin and (Rp)-cAMPS were clearly synergistic. It is postulated that the synergism observed is a consequence of action at several enzymatic sites leading to, and including, alteration of the phosphorylation state of the two rate-limiting enzymes in glycogen metabolism.     

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.     

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 activity of glycogen synthase phosphatase limits hepatic glycogen deposition in the adrenalectomized starved rat.

Hepatocytes from adrenalectomized 48 h-starved rats responded to increasing glucose concentrations with a progressively more complete inactivation of phosphorylase. Yet no activation of glycogen synthase occurred, even in a K+-rich medium. Protein phosphatase activities in crude liver preparations were assayed with purified substrates. Adrenalectomy plus starvation decreased synthase phosphatase activity by about 90%, but hardly affected phosphorylase phosphatase activity. Synthase b present in liver extracts from adrenalectomized starved rats was rapidly and completely converted into the a form on addition of liver extract from a normal fed rat. Glycogen synthesis can be slowly re-induced by administration of either glucose or cortisol to the deficient rats. In these conditions there was a close correspondence between the initial recovery of synthase phosphatase activity and the amount of synthase a present in the liver. The latter parameter was strictly correlated with the measured rate of glycogen synthesis in vivo. The decreased activity of synthase phosphatase emerges thus as the single factor that limits hepatic glycogen deposition in the adrenalectomized starved rat.     

Dephosphorylation and activation of exogenous glycogen synthase by adipose-tissue phosphatase

Exogenous purified rabbit skeletal-muscle glycogen synthase was used as a substrate for adipose-tissue phosphoprotein phosphatase from fed and starved rats in order to (1) compare the relationship between phosphate released from, and the kinetic changes imparted to, the substrate and (2) ascertain if decreases in adipose-tissue phosphatase activity account for the apparent decreased activation of endogenous glycogen synthase from starved as compared with fed rats. Muscle glycogen synthase was phosphorylated with [gamma-(32)P]ATP and cyclic AMP-dependent protein kinase alone, or in combination with a cyclic AMP-independent protein kinase, to 1.7 or 3mol of phosphate per subunit. Adipose-tissue phosphatase activity determined with phosphorylated skeletal-muscle glycogen synthase as substrate was decreased by 35-60% as a consequence of starvation. This decrease in phosphatase activity had little effect on the capacity of adipose-tissue extracts to activate exogenous glycogen synthase (i.e. to increase the glucose 6-phosphate-independent enzyme activity), although there were marked differences in the activation profiles for the two exogenous substrates. Glycogen synthase phosphorylated to 1.7mol of phosphate per subunit was activated rapidly by adipose-tissue extracts from either fed or starved rats, and activation paralleled enzyme dephosphorylation. Glycogen synthase phosphorylated to 3mol of phosphate per subunit was activated more slowly and after a lag period, since release of the first mol of phosphate did not increase the glucose 6-phosphate-independent activity of the enzyme. These patterns of enzyme activation were similar to those observed for the endogenous adipose-tissue glycogen synthase(s): the glucose 6-phosphate-independent activity of the endogenous enzyme from fed rats increased rapidly during incubation, whereas that of starved rats, like that of the more highly phosphorylated muscle enzyme, increased only very slowly after a lag period. The observations made here suggest that (1) changes in glucose 6-phosphate-independent glycogen synthase activity are at best only a qualitative measure of phosphoprotein phosphatase activity and (2) the decrease in glycogen synthase phosphatase activity during starvation is not sufficient to explain the differential glycogen synthase activation in adipose tissue from fed and starved rats. However, alterations in the phosphorylation state of glycogen synthase combined with decreased activity of phosphoprotein phosphatase, both as a consequence of starvation, could explain the apparent markedly decreased enzyme activation.     

Insulin stimulation of heart glycogen synthase D phosphatase (protein phosphatase).

Insulin rapidly produced an increase in per cent of total heart glycogen synthase in the I form in fed rats. In fasted rats the response was diminished and delayed. In diabetic animals there was no response over the 15-min time period studied. Since synthase phosphatase activity is necessary for synthase D to I conversion, the phosphatase activity was determined in extracts from these groups of animals. In the fasted and diabetic rats phosphatase activity was less than one-half of that in fed animals. Administration of insulin to fasting animals increased synthase phosphatase activity to a level approaching that of fed animals by 15 min. In diabetic animals insulin also stimulated an increase in synthase phosphatase activity but 30 min were required for full activation. Insulin had no effect in normal fed animals. Insulin activation of synthase phosphatase activity in heart extracts from fasted animals was still present after Sephadex G-25 chromatography and ammonium sulfate precipitation. Thus insulin had induced a stable modification of the phosphatase itself or of its substrate synthase D rendering the latter a more favorable substrate for the reaction. A difference in sensitivity of the reaction to glycogen inhibition was present between fed and fasted animals. Increasing concentrations of glycogen had only a slight inhibitory effect in extracts from fed animals but considerably reduced activity in extracts from fasted animals. Insulin administration reduced the sensitivity of the phosphatase reaction to glycogen inhibition. This could explain, at least in part, the increased phosphatase activity noted in the insulin-treated, fasted rats since glycogen was routinely added to the homogenizing buffer.     

High-affinity binding of glycogen-synthase phosphatase to glycogen particles in the liver. Role of glycogen in the inhibition of synthase phosphatase by phosphorylase a.

1. Post-mitochondrial supernatants were prepared from the livers of 24 h-fasted rats. Upon centrifugation at high speed, the major part of the glycogen-synthase phosphatase activity sedimented with the microsomal fraction. However, two approaches showed that the enzyme was associated with residual glycogen rather than with vesicles of the endoplasmic reticulum. Indeed, the activity was entirely solubilized when the remaining glycogen was degraded either by glucagon treatment in vivo or by alpha-amylolysis in vitro. No evidence could be found for an association of glycogen-synthase phosphatase with the smooth endoplasmic reticulum, as isolated with the use of discontinuous sucrose gradients. 2. After solubilization by glucagon treatment in vivo, synthase phosphatase could be transferred to glycogen particles with very high affinity. Half-maximal binding occurred at a glycogen concentration of about 0.25 mg/ml, whereas glycogen synthase and phosphorylase required 1.5-2 mg/ml. 3. In gel-filtered extracts prepared from glycogen-depleted livers, the activation of glycogen synthase was not inhibited at all by phosphorylase alpha. The inhibition was restored when the liver homogenates were prepared in a glycogen-containing buffer. The effect was half-maximal at a glycogen concentration of about 0.25 mg/ml, and virtually complete at 1 mg/ml. These findings explain long-standing observations that in fasted animals the liver contains appreciable amounts of both synthase and phosphorylase in the active form.     

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.     

Insulin action in intact mouse diaphragm I.

Summary The incubation of intact mouse diaphragms with insulin caused a dose and time dependent increase in the independent activity of glycogen synthase in tissue extracts. 2-deoxyglucose (2–10 mm) alone markedly stimulated the conversion of glycogen synthase to the independent activity under conditions in which tissue ATP concentrations were not affected. The incubation of diaphragms with both insulin and 2-deoxyglucose resulted in a greater than additive effect. Insulin stimulated the uptake of 2-deoxyglucose into mouse diaphragms, accumulating as 2-deoxyglucose-6-phosphate. The accumulation of 2-deoxyglucose-6-phosphate correlated well with the increase in the independent activity of glycogen synthase and with the activation of glycogen synthase phosphatase in tissue extracts. The uptake of 3-0-methyl glucose was also markedly stimulated by insulin, without affecting the activity of glycogen synthase. Both glucose-6-phosphate and 2-deoxyglucose-6-phosphate stimulated the activation of endogenous glycogen synthase phosphatase activity in muscle homogenates. We conclude that insulin, in addition to its effects in the absence of exogenous sugars, increases the independent activity of glycogen synthase through increased sugar transport resulting in increased concentrations of sugar-phosphates which promote the activity of glycogen synthase phosphatase.Abbreviations GS Glycogen synthase - GS-I Glycogen synthase activity independent of G6P - GS-D Glycogen synthase activity dependent on G6P - G6P Glucose-6-phosphate - ATP Adenosine triphosphate - EDTA Ethylene diamine tetracetic acid - Mops Morpholinopropane sulfonic acid - 2DG 2-Deoxy glucose - 3-0-MG 3-0-Methyl glucose - tricine N-tris(Hydroxymethyl)methyl glycine Enzymes: Glycogen Synthase — UDPGlucose — Glycogen Glucosyl — Transferase (EC 2.4.1.11) J. Larner is an established investigator of the American Diabetes Association.     

Regulation of glycogen metabolism in primary cultures of rat hepatocytes. Restoration of acute effects of glucose in cells from diabetic rats involves protein synthesis

Defective acute regulation of hepatic glycogen synthase by glucose and insulin, caused by severe insulin deficiency, can be corrected in adult rat hepatocytes in primary culture by inclusion of insulin, triiodothyronine, and cortisol in a chemically defined serum-free culture medium over a 3-day period (Miller, T. B., Jr., Garnache, A. K., Cruz, J., McPherson, R. K., and Wolleben, C. (1986) J. Biol. Chem. 261, 785-790). Using primary cultures of hepatocytes isolated from normal and diabetic rats in the same serum-free chemically defined medium, the present study addresses the effects of cycloheximide and actinomycin D on the chronic actions of insulin, triiodothyronine, and cortisol to facilitate the direct effects of glucose on the short-term activation of glycogen synthase. The short-term presence (1 h) of the protein synthesis blockers had no effect on acute activation of glycogen synthase by glucose in primary hepatocyte cultures from normal rats. Normal cells maintained in the presence of cycloheximide or actinomycin D for 2 and 3 days exhibited unimpaired responsiveness to glucose activation of synthase. The protein synthesis inhibitors were effective at blocking the restoration of glucose activation of synthase in diabetic cells in media which restored the activation in their absence. Restoration of glycogen synthase phosphatase activity by insulin, triiodothyronine, and cortisol in primary cultures of diabetic hepatocytes was also blocked by cycloheximide or actinomycin D. These data clearly demonstrate that restoration of acute glycogen synthase activation by glucose and restoration of glycogen synthase phosphatase activity in primary cultures of hepatocytes from adult diabetic rats are dependent upon the synthesis of new protein.