Comparative purification and characterization of invertebrate muscle glycogen synthase from the porcine parasite Ascaris suum

Glycogen synthase has been purified from the obliquely striated muscle of the swine parasite Ascaris suum. The muscle contains a concentration of glycogen synthase and glycogen which is 20-fold and 15-fold, respectively, greater than rabbit skeletal muscle. The enzyme could not be solubilized with salivary amylase, but partial solubilization was achieved by activation of endogenous phosphorylase. The enzyme was purified to 85-90% homogeneity (specific activity = 4.3 units/mg) by DEAE-cellulose, Sepharose 4B, and glucosamine 6-phosphate chromatography. The purified glycogen synthase was substantially similar to rabbit skeletal muscle enzyme with respect to Mr (gel electrophoresis and gel filtration), pH dependence, aggregation properties, temperature dependence, and kinetic constants for substrates and activators. Glycogen synthase I was converted to glycogen synthase D by the cyclic AMP-dependent protein kinase. The cyclic AMP-dependent protein kinase catalyzed the incorporation of 1.3 mol of phosphate into each glycogen synthase I subunit and the concomitant interconversion to glycogen synthase D. Since glycogen is the sole fuel utilized by this organism during nonfeeding periods of the host, the characterization of this enzyme provides further insight into the regulatory mechanisms which determine glycogen turnover.     

Glycogen synthase kinases. Distribution in mammalian tissues of forms that are independent of cyclic AMP.

Extracts of rat tissues contain kinases which catalyze the conversion of glycogen synthease from the glucose 6-phosphate-independent (I) form to the glucose 6-phosphatate-dependent (D) form. These kinases were stimulated by adenosine 3':5' monophosphate (cyclic AMP). The glycogen synthase kinase activity ratio (activity in the absence of cyclic AMP divided by activity in the presence of cyclic AMP) varied from 0.28 to 0.97. The activity ratio for histone kinase in the same extracts ranged from 0.11 to 0.29. The levels of glycogen synthase kinase varied by a factor of 80 in the following rat tissues (given in order of decreasing enzyme activity): kidney, liver, stomach mucosa, lung, brain, heart, skeletal muscle, and adipose tissue. In the same tissues the levels of histone kinase varied by only a factor of 6 and did not correlate with the levels of glycogen synthase kinase. A modification of the method of Walsh et al. ((1971) J. Biol. Chem. 246, 1977-1985) was developed for purification of the heat-stable inhibitor of cyclic AMP-dependent protein kinases (inhibitor). The modified procedure resulted in good yields of highly purified inhibitor and was much simpler than the previously described procedure. This inhibitor completely inhibited cyclic AMP-dependent histone kinase activity of the extracts but much of the glycogen synthase kinase activity was not inhibited. The portion of glycogen synthase kinase that was insensitive to the inhibitor was: stomach mucosa, 95%; brain, 90%; liver, 82%; kidney, 81%; lung, 68%; adipose tissue, 65%; skeletal muscle, 63%; and heart, 54%. This histone kinase activity in the extracts and hte ratio of glycogen synthase kinase to histone kinase activity of purified catalytic subunit of the cyclic AMP-dependent protein kinase was used to calculate for each extract the glycogen synthase kinase activity contributed by the cyclic AMP-dependent protein kinase. Based on these calculations, the portion of the glycogen synthase kinase which was due to kinases independent of cyclic AMP was: kidney, 97%; liver, 91%; lung, 89%; brain, 87%, heart, 85%; stomach mucosa, 84%; adipose tissue, 38%; and skeletal muscle, 33%. A significant portion of the glycogen synthase kinase activity, but virtually none of the cyclic AMP-dependent histone kinase activity, of these extracts could be adsorbed to phosphocellulose columns. Liver extracts contained, in addition, a form of glycogen synthase kinase which was not adsorbed to phosphocellulose and which could be separated from the cyclic AMP-dependent protein kinase by additional chromatography. These studies demonstrate that kinases independent of cyclic AMP account for most of the glycogen synthase kinase activity of many tissues. The widespread distribution and high concentrations of these enzymes suggest that they are of physiological importance.     

Glycogen synthase activity in Chinese hamster ovary cells: Studies with wild-type and mutant cells defective in cyclic AMP-dependent protein kinase

Glycogen synthase (EC 2.4.1.11) activity was studied in cell extracts from wild-type Chinese hamster ovary (CHO) cells and three mutants resistant to cyclic AMP effects on cell shape and cell growth. Based on the capacity of crude extracts to phosphorylate exogenous hisone, two of the mutants appeared to have altered cyclic AMP-dependent protein kinase (EC 2.7.1.37) and one of them had apparently normal amounts of kinase activity. Glycogen synthase activity was present in comparable amounts in wild-type and all three mutant strains in a presumably inactive phosphorylated form since activity was virtually completely dependent upon the presence of glucose 6-phosphate. The enzyme could be partially dephosphorylated by endogenous phosphatases and rephosphorylated by exogenous cyclic AMP-dependent protein kinase. Attempts to find culture conditions (e.g. glucose starvation)_or cell treatment (e.g. insulin) which might activate glycogen synthase in intact cells were unsuccessful. Since glycogen synthase activity present in CHO cells was independent of the level of cyclic AMP-dependent kinase, we conclude that cyclic AMP-dependent protein kinase does not play a critical role in regulating the state of phosphorylation of the synthase.     

Purification and characterization of two cyclic AMP-independent casein/glycogen synthase kinases from rat liver cytosol

Two cyclic AMP-independent protein kinases (ATP: protein phosphotransferase, EC 2.7.1.37) (casein kinase 1 and 2) have been purified from rat liver cytosol by a method involving chromatography on phosphocellulose and casein-Sepharose 4B. Both kinases were essentially free of endogeneous protein substrates and capable of phosphorylating casein, phosvitin and I-form glycogen synthase, but were inactive on histone IIA, protamine and phosphorylase b. They were neither stimulated by cyclic AMP, Ca2+ and calmodulin, nor inhibited by the cyclic AMP-dependent protein kinase inhibitor protein. The casein and glycogen synthase kinase activities of each enzyme decreased at the same rate when incubated at 50 degrees C. Casein kinase 1 and casein kinase 2 showed differences in molecular weight, sensitivity to KCl, Km for casein and phosvitin and Ka for Mg2+, whereas their Km values for ATP and I-form glycogen synthase were similar. The phosphorylation of glycogen synthase by these kinases correlated with a decrease in the +/- glucose 6-phosphate activity ratio (independence ratio). However, casein kinase 1 catalyzed the incorporation of about 3.6 mol of 32P/85000 dalton subunit, decreasing the independence ratio from 83 to about 15, whereas the phosphorylation achieved by casein kinase 2 was only about 1.9 mol of 32P/850000 dalton subunit, decreasing the independence ratio to about 23. The independence ratio decrease was prevented by the presence of casein but was unaffected by phosphorylase b. These data indicate that casein/glycogen synthase kinases 1 and 2 are different from cyclic AMP-dependent protein kinase and phosphorylase kinase.     

Glycogen synthase activity in Chinese hamster ovary cells. Studies with wild-type and mutant cells defective in cyclic AMP-dependent protein kinase

Glycogen synthase (EC 2.4.1.11) activity was studied in cell extracts from wild-type Chinese hamster ovary (CHO) cells and three mutants resistant to cyclic AMP effects on cell shape and cell growth. Based on the capacity of crude extracts to phosphorylate exogenous histone, two of the mutants appeared to have altered cyclic AMP-dependent protein kinase (EC 2.7.1.37) and one of them had apparently normal amounts of kinase activity. Glycogen synthase activity was present in comparable amounts in wild-type and all three mutant strains in a presumably inactive phosphorylated form since activity was virtually completely dependent upon the presence of glucose 6-phosphate. The enzyme could be partially dephosphorylated by endogenous phosphatases and rephosphorylated by exogenous cyclic AMP-dependent protein kinase. Attempts to find culture conditions (e.g. glucose starvation) or cell treatment (e.g. insulin) which might activate glycogen synthase in intact cells were unsuccessful. since glycogen synthase activity present in CHO cells was independent of the level of cyclic AMP-dependent kinase, we conclude that cyclic AMP-dependent protein kinase does not play a critical role in regulating the state of phosphorylation of the synthase.     

The phosphorylation of rabbit skeletal muscle glycogen synthase by glycogen synthase kinase-2 and adenosine-3':5'-monophosphate-dependent protein kinase.

Purified glycogen synthase is contaminated with traces of two protein kinases that can phosphorylate the enzyme. One is protein kinase dependent on adenosine 3':5'-monophosphate (cyclic AMP) and the second is an activity termed glycogen synthase kinase-2 [Nimmo, H.G. and Cohen P, (1974)]. Glycogen synthase kinase-2 has been found to be localized relatively specifically in the protein-glycogen complex. It has been purified 4000-fold by two procedures, both of which involve disruption of the complex, followed by the DEAE-cellulose and phosphocellulose chromatographies. However the salt concentration at which glycogen synthase kinase-2 is eluted from DEAE-cellulose depends on the method that is used to disrupt the complex. The results indicate that glycogen synthase kinase-2 is firmly attached to a protein component of the complex. The isolation procedures separate glycogen synthase kinase-2 from phosphorylase kinase, cyclic AMP-dependent protein kinase and other glycogen-metabolising enzymes. Glycogen synthase kinase-2 is the major phosvitin kinase in skeletal muscle, although glycogen synthase is a six to eight-fold better substrate than phosvitin under the standard assay conditions. Phosphorylase kinase and phosphorylase b are not substrates for glycogen synthase kinase 2. Following incubation with cyclic-AMP-dependent protein kinase, cyclic AMP and Mg-ATP, the phosphorylation of glycogen synthase reaches a plateau at 1.0 molecules of phosphate incorporated per subunit and the activity ratio measured in the absence and presence of glucose 6-phosphate falls from 0.8 to a plateau of 0.18. The Ka for glucose 6-phosphate of this phosphorylated species, termed glycogen synthase b1, is the 0.6 mM. Following incubation with glycogen synthase kinase-2 and Mg-ATP, the phosphorylation reaches a plateau of 0.92 molecules of phosphate incorporated per subunit and the activity ratio decreases to a plateau of 0.08. The Ka for glucose 6-phosphate of this phosphorylated species, termed glycogen synthetase b2, is 4 mM. In the presence of both cyclic-AMP-dependent protein kinase and glycogen synthase kinase-2, the phosphorylation of glycogen synthase reaches a plateau when 1.95 molecules of phoshophate have been incorporated per subunit. The activity ratio is 0.01 and the Ka for glucose 6-phosphate is 10 mM. The results indicate that glycogen synthase can be regulated by two distinct phosphorylation-dephosphorylation cycles. The implication of these findings for the regulation of glycogen synthase in vivo are discussed.     

Differences between glycogen synthases from rat and rabbit skeletal muscle as indicated by phosphopeptide maps

Glycogen synthase I was purified from rat skeletal muscle. On sodium dodecyl sulfate polyacrylamide gel electrophoresis, the enzyme migrated as a major band with a subunit Mr of 85,000. The specific activity (24 units/mg protein), activity ratio (the activity in the absence of glucose-6-P divided by the activity in the presence of glucose-6-P X 100) (92 +/- 2) and phosphate content (0.6 mol/mol subunit) were similar to the enzyme from rabbit skeletal muscle. Phosphorylation and inactivation of rat muscle glycogen synthase by casein kinase I, casein kinase II (glycogen synthase kinase 5), glycogen synthase kinase 3 (kinase FA), glycogen synthase kinase 4, phosphorylase b kinase, and the catalytic subunit of cAMP-dependent protein kinase were similar to those reported for rabbit muscle synthase. The greatest decrease in rat muscle glycogen synthase activity was seen after phosphorylation of the synthase by casein kinase I. Phosphopeptide maps of glycogen synthase were obtained by digesting the different 32P-labeled forms of glycogen synthase by CNBr, trypsin, or chymotrypsin. The CNBr peptides were separated by sodium dodecyl sulfate polyacrylamide gel electrophoresis and the tryptic and chymotryptic peptides were separated by reversed-phase HPLC. Although the rat and rabbit forms of synthase gave similar peptide maps, there were significant differences between the phosphopeptides derived from the N-terminal region of rabbit glycogen synthase and the corresponding peptides presumably derived from the N-terminal region of rat glycogen synthase. For CNBr peptides, the apparent Mr was 12,500 for rat and 12,000 for the rabbit. The tryptic peptides obtained from the two species had different retention times. A single chymotryptic peptide was produced from rat skeletal muscle glycogen synthase after phosphorylation by phosphorylase kinase whereas two peptides were obtained with the rabbit enzyme. These results indicate that the N-terminus of rabbit glycogen synthase, which contains four phosphorylatable residues (Kuret et al. (1985) Eur. J. Biochem. 151, 39-48), is different from the N-terminus of rat glycogen synthase.     

Activation of rat liver and rabbit skeletal muscle glycogen synthases by rat liver cytosolic protein phosphatases

To gain more insight into the nature of the substrate specificity of protein phosphatases, four forms of glycogen synthase D were used as substrates for previously characterized protein phosphatases, IA, IB, and II, from rat liver cytosol. The phosphatase activity was measured as the conversion of glycogen synthase D to synthase I. While glycogen synthase isolated from rat liver as the D-form was activated mainly by phosphatase IA, rabbit skeletal muscle glycogen synthase previously phosphorylated in vitro by cyclic AMP-dependent protein kinase or phosphorylase kinase was activated efficiently by phosphatases IA, IB, and II. Glycogen synthase isolated from rabbit skeletal muscle as the D-form, however, was a poor substrate for all three phosphatases. These results suggest that the phosphorylation state as well as the primary structure of synthase D markedly affects the rate of its activation by individual protein phosphatases. A protein phosphatase released from rat liver particulate glycogen, on the other hand, activated all forms of synthase D used here readily and at about the same rate.     

Phosphorylation of rabbit liver glycogen synthase by multiple protein kinases

Purified rabbit liver glycogen synthase was found to be a substrate for six different protein kinases: (i) cyclic AMP-dependent protein kinase, (ii) two Ca2+-stimulated protein kinases, phosphorylase kinase (from muscle) and a calmodulin-dependent glycogen synthase kinase, and (iii) three members of a Ca2+ and cyclic nucleotide independent class, PC0.7, FA/GSK-3, and casein kinase-1. Greatest inactivation accompanied phosphorylation by cyclic AMP-dependent protein kinase (to 0.5-0.7 phosphate/subunit, +/- glucose-6-P activity ratio reduced from approximately 1 to 0.6) or FA/GSK-3 (to approximately 1 phosphate/subunit, activity ratio, 0.46). Phosphorylation by the combination FA/GSK-3 plus PC0.7 was synergistic, and more extensive inactivation was achieved. The phosphorylation reactions just described caused significant reductions in the Vmax of the glycogen synthase with little effect on the S0.5 (substrate concentration corresponding to Vmax/2). Phosphorylase kinase achieved a lesser inactivation, to an activity ratio of 0.75 at 0.6 phosphate/subunit. PC0.7 acting alone, casein kinase-1, and the calmodulin-dependent protein kinase did not cause inactivation of liver glycogen synthase with the conditions used. Analysis of CNBr fragments of phosphorylated glycogen synthase indicated that the phosphate was distributed primarily between two polypeptides, with apparent Mr = 12,300 (CB-I) and 16,000-17,000 (CB-II). PC0.7 and casein kinase-1 displayed a decided specificity for CB-II, and the calmodulin-dependent protein kinase was specific for CB-I. The other protein kinases were able, to some extent, to introduce phosphate into both CB-I and CB-II. Studies using limited proteolysis indicated that CB-II was located at a terminal region of the subunit. CB-I contains a minimum of one phosphorylation site and CB-II at least three sites. Liver glycogen synthase is therefore potentially subject to the same type of multisite regulation as skeletal muscle glycogen synthase although the muscle and liver enzymes display significant differences in both structural and kinetic properties.     

Amino acid sequence of the phosphorylation site of rat liver 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase

6-Phosphofructo-2-kinase/fructose-2,6-bisphosphatase from rat liver was phosphorylated by cyclic AMP-dependent protein kinase and [gamma-32P]ATP. Treatment of the 32P-labeled enzyme with thermolysin removed all of the radioactivity from the enzyme core and produced a single labeled peptide. The phosphopeptide was purified by ion exchange chromatography, gel filtration, and reverse phase high pressure liquid chromatography. The sequence of the 12-amino acid peptide was found to be Val-Leu-Gln-Arg-Arg-Arg-Gly-Ser(P)-Ser-Ile-Pro-Gln. Correlation of the extent of phosphorylation with activity showed that a 50% decrease in the ratio of kinase activity to bisphosphate activity occurred when only 0.25 mol of phosphate was incorporated per mol of enzyme subunit, and maximal changes occurred with 0.7 mol incorporated. The kinetics of cyclic AMP-dependent protein kinase-catalyzed phosphorylation of the native bifunctional enzyme was compared with that of other rat liver protein substrates. The Km for 6-phosphofructo-2-kinase/fructose-2, 6-bisphosphatase (10 microM) was less than that for rat liver pyruvate kinase (39 microM), fructose-1,6-bisphosphatase (222 microM), and 6- phosphofructose -1-kinase (230 microM). Comparison of the initial rate of phosphorylation of a number of protein substrates of the cyclic AMP-dependent protein kinase revealed that only skeletal muscle phosphorylase kinase was phosphorylated more rapidly than the bifunctional enzyme. Skeletal muscle glycogen synthase, heart regulatory subunit of cyclic AMP-dependent protein kinase, and liver pyruvate kinase were phosphorylated at rates nearly equal to that of 6-phosphofructo-2-kinase/fructose-2, 6-bisphosphatase, while phosphorylation of fructose-1,6-bisphosphatase and 6-phosphofructo-1-kinase was barely detectable. Phosphorylation of 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase was not catalyzed by any other protein kinase tested. These results are consistent with a primary role of the cyclic AMP-dependent protein kinase in regulation of the enzyme in intact liver.     

The rate of calcium uptake into sarcoplasmic reticulum of cardiac muscle and skeletal muscle. Effects of cyclic AMP-dependent protein kinase and phosphorylase b kinase.

Calcium transport into sarcoplasmic reticulum fragments isolated from dog cardiac and mixed skeletal muscle (quadriceps) and from mixed fast (tibialis), pure fast (caudofemoralis) and pure slow (soleus) skeletal muscles from the cat was studied. Cyclic AMP-dependent protein kinase and phosphorylase b kinase stimulated the rate of calcium transport although some variability was observed. A specific protein kinase inhibitor prevented the effect of protein kinase but not of phosphorylase b kinase. The addition of cyclic AMP to the sarcoplasmic reticulum preparations in the absence of protein kinase had only a slight stimulatory effect despite the presence of endogenous protein kinase. Cyclic AMP-dependent protein kinase catalyzed the phosphorylation of several components present in the sarcoplasmic reticulum fragments; a 19000 to 21 000 dalton peak was phosphorylated with high specific activity in sarcoplasmic reticulum preparations isolated from heart and from slow skeletal muscle, but not from fast skeletal muscle. Phosphorylase b kinase phosphorylated a peak of molecular weight 95000 in all of the preparations. Cyclic AMP-dependent protein kinase-stimulated phosphorylation was optimum at pH 6.8; phosphorylase b kinase phosphorylation had a biphasic curve in cardiac and slow skeletal muscle with optima at pH 6.8 and 8.0. The addition of exogenous phosphorylase b kinase or protein kinase increased the endogenous level of phosphorylation 25-100%. All sarcoplasmic reticulum preparations contained varying amounts of adenylate cyclase, phosphorylase b and a (b:a = 30.1), "debrancher" enzyme and glycogen (0.3 mg/mg protein), as well as varying amounts of protein kinase and phosphorylase b kinase which were responsible for a significant endogenous phosphorylation. Thus, the two phosphorylating enzymes stimulated calcium uptake in the sarcoplasmic reticulum of a variety of muscles possessing different physiologic characteristics and different responses to drugs. In addition, the phosphorylation catalyzed by these enzymes occurred at two different protein moieties which make physiologic interpretation of the role of phosphorylation difficult. While the role phosphorylation in these mechanisms is complex, the presence of a glycogenolytic enzyme system may be an important link in this phenomenon. The sarcoplasmic reticulum represents a new substrate for phosphorylase b kinase.     

Effect of cyclic AMP on glycogen phosphorylase in Coprinus macrorhizus.

Glycogen phosphorylase (1,4-alpha-D-glucan:orthophosphate alpha-glucosyltransfase, EC 2.4.1.1) activity was found in mycelial extracts of Coprinus macrorhizus concurrently with decrease of glycogen content in mycelial cells. Incubation of the enzyme sample with cyclic AMP and ATP leads to a 3-fold activation of the glucogen phosphorylase activity. Activation of the enzyme partially purified through Sepharose 6B required a cellular fraction containing cyclic AMP-dependent protein kinase.     

Phosphorylation of K-casein by glycogen synthase kinase-3 from rabbit skeletal muscle

Glycogen synthase kinase-3 (ATP:protein phosphotransferase, EC 2.7.1.37) phosphorylated K-casein 20-fold more rapidly than beta-casein, while alpha S1-casein was not a substrate. This distinguished it from casein kinase-I and casein kinase-II, which phosphorylate the beta-casein variant preferentially. Glycogen synthase kinase-3 phosphorylated a serine residue(s) in the C-terminal cyanogen bromide fragment on K-casein. In contrast, cyclic AMP-dependent protein kinase phosphorylated the N-terminal fragment, and phosphorylase kinase the N-terminal and intermediate cyanogen bromide fragments. The results emphasize the potential value of casein phosphorylation as a means of classifying protein kinases.     

Comparison of the phosphorylation of microtubule-associated protein tau by non-proline dependent protein kinases

Microtubule-associated protein tau from Alzheimer brain has been shown to be phosphorylated at several ser/thr-pro and ser/thr-X sites (Hasegawa, M. et al., J. Biol. Chem, 267, 17047–17054, 1992). Several proline-dependent protein kinases (PDPKs) (MAP kinase, cdc2 kinase, glycogen synthase kinase-3, tubulin-activated protein kinase, and 40 kDa neurofilament kinase) are implicated in the phosphorylation of the ser-thr-pro sites. The identity of the kinase(s) that phosphorylate that ser/thr-X sites are unknown. To identify the latter kinase(s) we have compared the phosphorylation of bovine tau by several brain protein kinases. Stoichiometric phosphorylation of tau was achieved by casein kinase-1, calmodulin-dependent protein kinase II, Gr kinase, protein kinase C and cyclic AMP-dependent protein kinase, but not with casein kinase-2 or phosphorylase kinase. Casein kinase-1 and calmodulin-dependent protein kinase II were the best tau kinases, with greater than 4 mol and 3 mol³²P incorporated, respectively, into each mol of tau. With the sequential addition of these two kinases,³²P incorporation approached 6 mol. Peptide mapping revealed that the different kinases largely phosphorylate different sites on tau. After phosphorylation by casein kinase-1, calmodulin-dependent protein kinase II, Gr kinase, cyclic AMP-dependent protein kinase and casein kinase-2, the mobility of tau isoforms as detected by SDS-PAGE was decreased. Protein kinase C phosphorylation did not produce such a mobility shift. Our results suggest that one or more of the kinases studied here may participate in the hyperphosphorylation of tau in Alzheimer disease. Such phosphorylation may serve to modulate the activaties of other tau kinases such as the PDPKs.Abbreviations PHF paired helical filaments - A-kinase cyclic AMP-dependent protein kinase - CaM kinase II calcium/calmodulin-dependent protein kinase II - C-kinase calcium-phospholipid-dependent protein kinase - CK-1 casein kinase-1 - CK-2 casein kinase-2 - Gr kinase calcium/calmodulin-dependent protein kinase from rat cerebellum - GSK-3 glycogen synthase kinase-3 - MAP kinase mitogen-activated protein kinase - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis     

Phosphorylation and inactivation of liver glycogen synthase by liver protein kinases

A rapid method for purifying glycogen synthase a from rat liver was developed and the enzyme was tested as a substrate for nine different protein kinases, six of which were isolated from rat liver. The enzyme was phosphorylated on a 17-kDa CNBr fragment to approximately 1 phosphate/87-kDa subunit by phosphorylase b kinase from muscle or liver with a decrease in the activity ratio (-Glc-6-P/+Glc-6-P) from 0.95 to 0.6. Calmodulin-dependent glycogen synthase kinase from rabbit liver produced a similar phosphorylation pattern, but a smaller activity change. The catalytic subunit of beef heart cAMP-dependent protein kinase incorporated greater than 1 phosphate/subunit initially into a 17-kDa CNBr peptide and then into a 27-30-kDa CNBr peptide, with an activity ratio decrease to 0.5. Glycogen synthase kinases 3, 4, and 5 and casein kinase 1 were purified from rat liver. Glycogen synthase kinase 3 rapidly phosphorylated liver glycogen synthase to 1.5 phosphate/subunit with incorporation of phosphate into 3 CNBr peptides and a decrease in the activity ratio to 0.3. Glycogen synthase kinase 4 produced a pattern of phosphorylation and inactivation of liver synthase which was very similar to that caused by phosphorylase b kinase. Glycogen synthase kinase 5 incorporated 1 phosphate/subunit into a 24-kDa CNBr peptide, but did not alter the activity of the synthase. Casein kinase 1 phosphorylated and inactivated liver synthase with incorporation of phosphate into a 24-kDa CNBr peptide. This kinase and glycogen synthase kinase 4 were more active against muscle glycogen synthase. Calcium-phospholipid-dependent protein kinase from brain phosphorylated liver and muscle glycogen synthase on 17- and 27-kDa CNBr peptides, respectively. However, there was no change in the activity ratio of either enzyme. The following conclusions are drawn. 1) Liver glycogen synthase a is subject to multiple site phosphorylation. 2) Phosphorylation of some sites does not per se control activity of the enzyme under the assay conditions used. 3) Liver contains most, if not all, of the protein kinases active on glycogen synthase previously identified in skeletal muscle.     

The calmodulin-dependent glycogen synthase kinase from rabbit skeletal muscle. Purification, subunit structure and substrate specificity

A calmodulin-dependent glycogen synthase kinase distinct from phosphorylase kinase has been purified approximately equal to 5000-fold from rabbit skeletal muscle by a procedure involving fractionation with ammonium sulphate (0-33%), and chromatographies on phosphocellulose, calmodulin-Sepharose and DEAE-Sepharose. 0.75 mg of protein was obtained from 5000 g of muscle within 4 days, corresponding to a yield of approximately equal to 3%. The Km for glycogen synthase was 3.0 microM and the V 1.6-2.0 mumol min-1 mg-1. The purified enzyme showed a major protein staining band (Mr 58 000) and a minor component (Mr 54 000) when examined by dodecyl sulphate polyacrylamide gel electrophoresis. The molecular weight of the native enzyme was determined to be 696 000 by sedimentation equilibrium centrifugation, indicating a dodecameric structure. Electron microscopy suggested that the 12 subunits were arranged as two hexameric rings stacked one upon the other. Following incubation with Mg-ATP and Ca2+-calmodulin, the purified protein kinase underwent an 'autophosphorylation reaction'. The reaction reached a plateau when approximately equal to 5 mol of phosphate had been incorporated per 58 000-Mr subunit. Both the 58 000-Mr and 54 000-Mr species were phosphorylated to a similar extent. Autophosphorylation did not affect the catalytic activity. The calmodulin-dependent protein kinase initially phosphorylated glycogen synthase at site-2, followed by a slower phosphorylation of site-1 b. The protein kinase also phosphorylated smooth muscle myosin light chains, histone H1, acetyl-CoA carboxylase and ATP-citrate lyase. These findings suggest that the calmodulin-dependent glycogen synthase kinase may be a enzyme of broad specificity in vivo. Glycogen synthase kinase-4 is an enzyme that resembles the calmodulin-dependent glycogen synthase kinase in phosphorylating glycogen synthase (at site-2), but not glycogen phosphorylase. Glycogen synthase kinase-4 was unable to phosphorylate any of the other proteins phosphorylated by the calmodulin-dependent glycogen synthase kinase, nor could it phosphorylate site 1 b of glycogen synthase. The results demonstrate that glycogen synthase kinase-4 is not a proteolytic fragment of the calmodulin-dependent glycogen synthase kinase, that has lost its ability to be regulated by Ca2+-calmodulin.     

The role of calcium ion as a mediator of the effects of angiotensin II, catecholamines, and vasopressin on the phosphorylation and activity of enzymes in isolated hepatocytes.

Angiotensin II, catecholamines, and vasopressin are thought to stimulate hepatic glycogenolysis and gluconeogenesis via a cyclic AMP-independent mechanism that requires calcium ion. The present study explores the possibility that angiotensin II and vasopressin control the activity of regulatory enzymes in carbohydrate metabolism through Ca2+-dependent changes in their state of phosphorylation. Intact hepatocytes labeled with [32P]PO43- were stimulated with angiotensin II, glucagon, or vasopressin and 30 to 33 phosphorylated proteins resolved from the cytoplasmic fraction of the cell by electrophoresis in sodium dodecyl sulfate polyacrylamide slab gels. Treatment of the cells with angiotensin II or vasopressin increased the phosphorylation of 10 to 12 of these cytosolic proteins without causing measurable changes in cyclic AMP-dependent protein kinase activity. Glucagon stimulated the phosphorylation of the same set of 11 to 12 proteins through a marked increase in cyclic AMP-dependent protein kinase activity. The molecular weights of three of the protein bands whose phosphorylation was increased by these hormones correspond to the subunit molecular weights of phosphorylase (Mr = 93,000), glycogen synthase (Mr = 85,000), and pyruvate kinase (Mr = 61,000). Two of these phosphoprotein bands were positively identified as phosphorylase and pyruvate kinase by affinity chromatography and immunoprecipitation, respectively. Incubation of hepatocytes in a Ca2+-free medium completely abolished the effects of angiotensin II and vasopressin on protein phosphorylation but did not alter those of glucagon. Treatment of hepatocytes with angiotensin II, glucagon, or vasopressin stimulated phosphorylase activity by 250 to 260%, inhibited glycogen synthase activity by 50%, and inhibited pyruvate kinase activity by 30 to 35% (peptides) to 70% (glucagon). The effects of angiotensin II and vasopressin on the activity of all three enzymes were completely abolished if the cells were incubated in a Ca2+-free medium while those of glucagon were not altered. The results imply that angiotensin II, catecholamines, and vasopressin control hepatic carbohydrate metabolism through a Ca2+-requiring, cyclic AMP-independent pathway that leads to the phosphorylation of important regulatory enzymes.     

Epinephrine effects on cyclic AMP-dependent protein kinases from rat diaphragms

Diaphragm extracts were subjected to electrophoresis on polyacrylamide gels to separate the different molecular species of th cyclic AMP-dependent protein kinase. Using cyclic [3H]AMP, three peaks of binding activity were observed. The peak closest to the origin (peak I) was associated with cyclic AMP-dependent protein kinase activity and was abolished by incubation of the extracts with cyclic AMP prior to electrophoresis. The peak farthest from the origin (peak III) was devoid of kinase activity and was increased by incubation of extracts with cyclic AMP before electrophoresis; furthermore, when extracts were incubated with cyclic [3H]AMP before electrophoresis, essentially all the radioactivity appeared in peak III. Peak II, in an intermediate position, was also abolished by preincubation of the extracts with cyclic AMP and both its binding capacity and cyclic AMP-dependent protein kinase activity were lower than in Peak I. A peak of cyclic AMP-independent protein kinase (peak 0) that migrated more slowly than peak II was also detected. From these and other data it is concluded that peaks I and II are cyclic AMP-dependent protein kinase and that peak III is the dissociated regulatory subunit, respectively. Peak 0 is cyclic AMP-independent protein kinase together with free catalytic subunits from cyclic AMP-dependent protein kinase. Incubation of rat diaphragms with epinephrine resulted in dose- and time-dependent decrease in peak I and increase in peak III. These changes correlated with the decrease of cyclic AMP-dependent protein kinase associated with peak I. No changes in Peak II were observed with epinephrine, but an increased peak 0 was noted. Changes in peak I and peak III correlated with the modification of glycogen synthase and glycogen phosphorylase activities. No regulatory subunits (peak III) were detected as phosphorylated forms in diaphragms previously equilibrated with 32P. Treatment with epinephrine produce no noticeable phosphorylation of these regulatory subunits.     

Glycogen-storage disease in rats, a genetically determined deficiency of liver phosphorylase kinase.

Rats from an inbred strain (NZR/Mh) were found to have high concentrations of glycogen in their livers, even after 24 h of starvation. Despite this, blood glucose concentrations were well maintained on starvation for up to 72 h. The primary defect is a deficiency of liver phosphorylase kinase, causing a lack of active glycogen phosphorylase, although total phosphorylase is normal. The intravenous injection of glucagon caused a rapid activation of cyclic AMP-dependent protein kinase in the liver, but no increase in either phosphorylase kinase or phosphorylase a activity. Although total glycogen synthase activity in the livers of affected rats was higher than normal, glycogen synthase in the active form was very low, presumably as a result of the high liver glycogen content. The condition is transmitted as autosomal recessive and, apart from hepatomegaly, the affected rats appear healthy.     

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.