Phosphorylation of glycogen synthase by the Ca2+- and phospholipid-activated protein kinase (protein kinase C)

Glycogen synthase from human and bovine polymorphonuclear leukocyte. Immunochemical characterization and comparison to glycogen synthase from rat and rabbit muscle and liver cells

Glycogen synthase from human and bovine polymorphonuclear leukocytes was purified to homogeneity. Rabbit antisera were raised against the two glycogen synthases and used for immunochemical analysis. Western blotting analysis showed that the subunit of glycogen synthase in crude homogenates of human and bovine leukocytes in both cases has an Mr of 85,000. The existence of a cross-reactivity between the two enzymes and the corresponding antisera demonstrates immunological similarities between bovine and human leukocyte glycogen synthase. In addition, both antisera recognize glycogen synthase in crude cellular extracts from rabbit and rat liver and from skeletal muscle. Leukocyte glycogen synthase, therefore, cannot be classified as either muscle (M-type) or liver (L-type) glycogen synthase and our results do not support the proposed immunochemical distinction between M- and L-type glycogen synthase.

Effect of protein kinase C activation and depletion on insulin stimulation of glycogen synthesis in cultured hepatoma cells

Insulin stimulation of glycogen synthesis was nearly abolished in hepatoma cells shortly treated with 4 beta-phorbol 12 beta-myristate, 13 alpha-acetate (protein kinase C activation) but remained unmodified in cells chronically treated with the phorbol ester (protein kinase C depletion). Thus, although exogenous activation of protein kinase C results in an inhibition of insulin action, protein kinase C depletion has no influence on this process. The results suggest that, in hepatoma cells, no endogenous activation of protein kinase C may occur in response to the signal triggered by insulin.

Multiple phosphorylation of mouse muscle glycogen synthase

Glycogen synthase was isolated from extracts of mouse diaphragm muscle by immunoprecipitation with specific antibodies raised against the rabbit muscle enzyme. A procedure was developed which permitted phosphorylation of the immunoprecipitated enzyme by several purified protein kinases. Peptide mapping techniques (including reverse-phase HPLC and thin-layer electrophoresis and chromatography) were used to compare tryptic phosphopeptides of the rabbit and mouse muscle enzymes. The results demonstrated a high degree of similarity in the chemical properties of these peptides, suggesting significant homology around the phosphorylation sites in these proteins. Thus, mouse peptides corresponding to the rabbit muscle peptides containing sites 1a, 1b, 2, 3, and 5 were identified, with protein kinase recognition specificities identical to those of the rabbit enzyme. The study indicates significant conservation in the muscle isozymes of glycogen synthase between mouse and rabbit as well as a similar distribution of phosphorylation sites throughout the enzyme subunit.

Modulation of the enzymic activity of 3-hydroxy-3-methylglutaryl coenzyme A reductase by multiple kinase systems involving reversible phosphorylation: a review

This report summarizes the current concepts regarding the in vitro and in vivo modulation of the enzymic activity of HMG-CoA reductase and mevalonate formation in rat and human liver, as well as in cultured fibroblasts from normal and familial hypercholesterolemic subjects. Three separate mechanisms for the short-term modulation of hepatic HMG-CoA reductase activity by covalent phosphorylation have been described. These mechanisms involved three separate specific kinase systems including reductase kinase, protein kinase C, and a Ca+2, calmodulin-dependent kinase. The conceptual schemes presented in this report will provide a basis for future research as well as an overview for improved understanding of the complex and multifaceted short-term regulation of this key enzyme in the biosynthetic pathways of mevalonate, ubiquinones, dolichols, isopentenyl-tRNAs, and cholesterol.

Effects of phorbol esters, A23187 and vasopressin on oleate metabolism in isolated rat hepatocytes

Studies were conducted to compare the metabolic effects of vasopressin, 4 beta-phorbol-12-myristate-13-acetate (PMA) and A23187 on ketogenesis and oleate metabolism in isolated hepatocytes from fed rats. Vasopressin inhibited the formation of acid-soluble products from [1-14C]oleate (0.25 mM, 0.5 mM and 1 mM), the inhibition being most marked at low (0.25 mM) concentration of oleate. Conversion of [1-14C]oleate into 14CO2 and esterified products was stimulated by vasopressin. The stimulatory effect of this hormone on 14CO2 production was most marked at high (1 mM) concentration of oleate, whereas that on [1-14C]oleate esterification was most marked at low (0.25 mM) concentration of oleate. These vasopressin actions were abolished when hepatocytes were incubated in the absence of calcium in the medium. Our results strongly suggest that both increase in esterification and increase in oxidation to CO2 contribute to the anti-ketogenic action of vasopressin when oleate is added as substrate, although the relative extent of their contribution varies according to the oleate concentration. The anti-ketogenic action of vasopressin was mimicked by PMA but not by A23187. PMA also caused a stimulation of [1-14C]oleate esterification although the effect was diminished at 1 mM [1-14C]oleate. A23187 failed to affect [1-14C]oleate esterification. The metabolic effects of PMA were elicited in the absence of extracellular calcium, too. Conversion of [1-14C]oleate into 14CO2 was only slightly increased by both PMA and A23187 when 1 mM [1-14C]oleate was added as substrate. The marked stimulatory effect of vasopressin on 14CO2 production from [1-14C]oleate was not reproduced even by the combination of PMA and A23187.(ABSTRACT TRUNCATED AT 250 WORDS)

Changes in protein kinase C activity are associated with the differentiation of Friend erythroleukemia cells

We investigated the activity and cellular distribution of protein kinase C during the dimethylsulfoxide (DMSO) and hypoxanthine-induced differentiation of Friend murine erythroleukemia cells. Most of the cellular protein kinase C activity was found in the soluble fraction of unstimulated Friend cells. Within 15 min of the addition of DMSO or hypoxanthine, protein kinase C underwent a dramatic and prolonged reversal of this distribution which was accompanied by a gradual decline in total cellular protein kinase C activity over the ensuing 5 days. The loss of total activity was found to be dose dependent although maximal translocation from soluble to insoluble components occurred at even lower concentrations of the inducers tested. Two clones of Friend cells, selected for their failure to differentiate in response to DMSO, showed alterations in protein kinase C activity and/or distribution following DMSO addition when compared to wild-type Friend cells. These data show that different inducers of Friend cell differentiation have similar effects on cellular protein kinase C, that the protein kinase C changes accompanying this process are immediate but prolonged, and that changes in protein kinase C activity and distribution are associated with Friend cell differentiation.

Calcium . calmodulin-dependent protein kinase II and calcium . phospholipid-dependent protein kinase activities in rat tissues assayed with a synthetic peptide

Rat tissue levels of Ca2+ . calmodulin-dependent protein kinase II (protein kinase II) and Ca2+ . phospholipid-dependent protein kinase (protein kinase C) were selectively assayed using the synthetic peptide syntide-2 as substrate. The sequence of syntide-2 (pro-leu-ala-arg-thr-leu-ser-val-ala-gly-leu-pro-gly-lys-lys) is homologous to phosphorylation site 2 in glycogen synthase. The relative Vmax/Km ratios of the known Ca2+-dependent protein kinases for syntide-2 were determined to be as follows: protein kinase II, 100; protein kinase C, 22; phosphorylase kinase, 2; myosin light chain kinase, 0.005. Levels of protein kinase II were highest in cerebrum (3.36 units/g tissue) and spleen (0.85 units/g) and lowest in testis (0.05 units/g) and kidney (0.04 units/g). Protein kinase II activity was localized predominantly in the 100,000g particulate fraction of cerebrum and testis, in the supernatant fraction of heart, liver, adrenal, and kidney, and about equally distributed between particulate and supernatant in spleen and lung. Likewise, protein kinase C activity was highest in cerebrum (0.56 units/g) and spleen (0.47 units/g), and the majority of activity was present in the cytosolic fraction for all tissues measured except for cerebrum and testis in which the kinase activity was equal in both fractions. Finally, the ratios of protein kinase II to protein kinase C were different in various rat tissues and between particulate and supernatant fractions. These results suggest somewhat different functions for these two Ca2+-regulated, multifunctional protein kinases.

Mechanisms of hormonal regulation of hepatic glucose metabolism

Acute hormonal regulation of liver carbohydrate metabolism mainly involves changes in the cytosolic levels of cAMP and Ca2+. Epinephrine, acting through beta 2-adrenergic receptors, and glucagon activate adenylate cyclase in the liver plasma membrane through a mechanism involving a guanine nucleotide-binding protein that is stimulatory to the enzyme. The resulting accumulation of cAMP leads to activation of cAMP-dependent protein kinase, which, in turn, phosphorylates many intracellular enzymes involved in the regulation of glycogen metabolism, gluconeogenesis, and glycolysis. These are (1) phosphorylase b kinase, which is activated and, in turn, phosphorylates and activates phosphorylase, the rate-limiting enzyme for glycogen breakdown; (2) glycogen synthase, which is inactivated and is rate-controlling for glycogen synthesis; (3) pyruvate kinase, which is inactivated and is an important regulatory enzyme for glycolysis; and (4) the 6-phosphofructo-2-kinase/fructose 2,6-bisphosphatase bifunctional enzyme, phosphorylation of which leads to decreased formation of fructose 2,6-P2, which is an activator of 6-phosphofructo-1-kinase and an inhibitor of fructose 1,6-bisphosphatase, both of which are important regulatory enzymes for glycolysis and gluconeogenesis. In addition to rapid effects of glucagon and beta-adrenergic agonists to increase hepatic glucose output by stimulating glycogenolysis and gluconeogenesis and inhibiting glycogen synthesis and glycolysis, these agents produce longer-term stimulatory effects on gluconeogenesis through altered synthesis of certain enzymes of gluconeogenesis/glycolysis and amino acid metabolism. For example, P-enolpyruvate carboxykinase is induced through an effect at the level of transcription mediated by cAMP-dependent protein kinase. Tyrosine amino-transferase, serine dehydratase, tryptophan oxygenase, and glucokinase are also regulated by cAMP, in part at the level of specific messenger RNA synthesis. The sympathetic nervous system and its neurohumoral agonists epinephrine and norepinephrine also rapidly alter hepatic glycogen metabolism and gluconeogenesis acting through alpha 1-adrenergic receptors. The primary response to these agonists is the phosphodiesterase-mediated breakdown of the plasma membrane polyphosphoinositide phosphatidylinositol 4,5-P2 to inositol 1,4,5-P3 and 1,2-diacylglycerol. This involves a guanine nucleotide-binding protein that is different from those involved in the regulation of adenylate cyclase. Inositol 1,4,5-P3 acts as an intracellular messenger for Ca2+ mobilization by releasing Ca2+ from the endoplasmic reticulum.(ABSTRACT TRUNCATED AT 400 WORDS)

Role of protein kinase C in the regulation of rat liver glycogen synthase

Rat liver glycogen synthase was phosphorylated by purified protein kinase C in a Ca2+- and phospholipid-dependent fashion to 1-1.4 mol PO4/subunit. Analysis of the 32P-labeled tryptic peptides derived from the phosphorylated synthase by isoelectric focusing and two-dimensional peptide mapping revealed the presence of a major radioactive peptide. The sites in liver synthase phosphorylated by protein kinase C appears to be different from those phosphorylated by other kinases. Prior phosphorylation of the synthase by protein kinase C has no significant effect on the subsequent phosphorylation by glycogen synthase (casein) kinase-1 or kinase Fa, but prevents the synthase from further phosphorylation by cAMP-dependent protein kinase, Ca2+/calmodulin-dependent protein kinase, phosphorylase kinase, or casein kinase-2. Additive phosphorylation of liver glycogen synthase can be observed by the combination of protein kinase C with the former set of kinases but not with the latter. Phosphorylation of liver synthase by protein kinase C alone did not cause an inactivation nor did the combination of this kinase with glycogen synthase (casein) kinase-1 or kinase Fa produce a synergistic effect on the inactivation of the synthase. Based on these findings we conclude that the phorbol ester-induced inactivation of glycogen synthase previously observed in hepatocytes cannot be accounted for entirely by the activation of protein kinase C.

Control of glycogen synthesis in health and disease

Investigations in our laboratory have shown that the activity of glycogen synthase phosphatase in the liver is shared by at least two functionally distinct proteins: a G-component, which is tightly associated with glycogen particles, and a soluble S-component. Most preparations of glycogen synthase-b that are isolated from the liver of fed glucagon-treated animals require the presence of both components in order to be converted to synthase-a. The G-component is subject to control mechanisms that do not affect the S-component. Its activity is strongly inhibited by phosphorylase-a. This feature explains why glycogen synthesis and glycogenolysis do not normally occur simultaneously, except in the glycogen-depleted liver, where a futile cycle may occur. Experiments in vitro have shown that a minimal glycogen concentration is required to ensure the interaction between the G-component and phosphorylase-a. The G-component is also selectively inhibited by Ca2+, and the magnitude of this inhibition depends markedly on the glycogen concentration. The latter inhibition is probably one of the mechanisms by which cyclic adenosine monophosphate (cAMP)-independent glycogenolytic agents achieve the inactivation of glycogen synthase in the liver. Glucocorticoid hormones and insulin are required for the induction and/or maintenance of the G-component in the liver. During the development of the fetal rat, glucocorticoids induce the G-component in the liver. This is an essential event in the glucocorticoid-triggered deposition of glycogen in the fetal liver. A functional adrenal cortex is also required in the adult animal to prevent a loss of the capacity for hepatic glycogen storage during starvation. The latter capacity depends on the concentration of functional G-component in the liver. Chronic diabetes causes a similar functional loss. However, the effect of glucocorticoids is not mediated by a putative secretion of insulin.

Substrate specificity of protein kinase C. Use of synthetic peptides corresponding to physiological sites as probes for substrate recognition requirements

Although the Ca2+/phospholipid-dependent protein kinase, protein kinase C, has a broad substrate specificity in vitro, the enzyme appears considerably less promiscuous in vivo. To date only a handful of proteins have been identified as physiological substrates for this protein kinase. In order to determine the basis for this selectivity for substrates in intact cells, we have probed the substrate primary sequence requirements of protein kinase C using synthetic peptides corresponding to sites of phosphorylation from four of the known physiological substrates. We have also identified the acetylated N-terminal serine of chick muscle lactate dehydrogenase as an in vitro site of phosphorylation for this protein kinase. These comparative studies have demonstrated that, in vivo, the enzyme exhibits a preference for one basic residue C-terminal to the phosphorylatable residue, as in the sequence: Ser/Thr-Xaa-Lys/Arg, where Xaa is usually an uncharged residue. Additional basic residues, both N and C-terminal to the target amino acid, enhance the Vmax and Km parameters of phosphorylation. None of the peptides based on physiological phosphorylation sites of protein kinase C was an efficient substrate of cAMP-dependent protein kinase, emphasizing the distinct site-recognition selectivities of these two pleiotropic protein kinases. The favorable kinetic parameters of several of the synthetic peptides, coupled with their selectivity for phosphorylation by protein kinase C, will facilitate the assay of this enzyme in the presence of other protein kinases in tissue and cell extracts.

Heparin-activated protein kinase from rabbit muscle: relationship to enzymes of the glycogen synthase kinase-3 category

A heparin-activated protein kinase has been previously identified in rabbit skeletal muscle extracts (Z. Ahmad et al. (1985) FEBS Lett. 179, 96-100). Further study has indicated that this enzyme phosphorylates rabbit muscle glycogen synthase in the same tryptic peptide(s) as the protein kinase FA/GSK-3 (glycogen synthase kinase-3) and is able to activate the ATP-Mg2+-dependent protein phosphatase. These results indicate similarities in properties between the two protein kinases. Exposure of the heparin-activated enzyme to trypsin resulted in loss of heparin activation, from 3-fold to 1.3-fold. One hypothesis suggested by this result is that the enzyme FA/GSK-3 could be a derivative of the heparin-activated enzyme that has lost heparin sensitivity. The conceptual importance of this hypothesis is that it may provide a clue to the mode of regulation of this important class of protein kinases.

Regulation of hepatic glycogen phosphorylase and glycogen synthase by calcium and diacylglycerol

Incubation of rat hepatocytes with angiotensin II (1 nM) produced a time-dependent accumulation of 1, 2-diacylglycerol and inactivation of glycogen synthase with maximum effects at 10 min. The level of diacylglycerol then gradually declined and the activity of glycogen synthase I returned to control values at 30 min. In contrast, angiotensin II caused an increase in cytosolic Ca2+ and an activation of glycogen phosphorylase which were rapid and transient, reaching maximum values in less than 2 min and then returning to control levels at 15 min. There were excellent correlations between the changes in glycogen synthase I and diacylglycerol levels and between the changes in phosphorylase alpha and cytosolic Ca2+ in these time-course studies. However, there was no correlation between the changes in diacylglycerol and phosphorylase alpha or between the changes in cytosolic Ca2+ and glycogen synthase I. Norepinephrine also caused a slow increase in diacylglycerol and inactivation of glycogen synthase, and a rapid increase in cytosolic free Ca2+ and activation of glycogen phosphorylase. Addition of an alpha1-adrenergic blocker (prazosin or phentolamine) caused rapid decreases in cytosolic free Ca2+ and phosphorylase alpha, but only slowly reversed the inactivation of synthase and accumulation of diacylglycerol. The dose-response curves for norepinephrine and prazosin on glycogen synthase were well correlated with those on diacylglycerol. It is proposed that in liver cells, Ca2+-mobilizing hormones regulate phosphorylase a through a Ca2+-dependent mechanism and inactivate glycogen synthase through the generation of diacylglycerol, at least in part. The data provide additional support for the view that protein kinase C may be important in the regulation of glycogen synthase in liver.

Studies and perspectives of protein kinase C

Protein kinase C, an enzyme that is activated by the receptor-mediated hydrolysis of inositol phospholipids, relays information in the form of a variety of extracellular signals across the membrane to regulate many Ca2+-dependent processes. At an early phase of cellular responses, the enzyme appears to have a dual effect, providing positive forward as well as negative feedback controls over various steps of its own and other signaling pathways, such as the receptors that are coupled to inositol phospholipid hydrolysis and those of some growth factors. In biological systems, a positive signal is frequently followed by immediate negative feedback regulation. Such a novel role of this protein kinase system seems to give a logical basis for clarifying the biochemical mechanism of signal transduction, and to add a new dimension essential to our understanding of cell-to-cell communication.

Purified pyruvate kinases type M2 from unfertilized hen's egg are substrates of protein kinase C

To characterize pyruvate kinase isoenzymes from cells with the capability to proliferate, this enzyme was purified from yolk and vitelline membrane of unfertilized hen's egg. Pyruvate kinase type M2 from vitelline membrane was obtained in a homogeneous form after a 1150-fold purification to a specific enzymatic activity of 450 mumol X min-1 X mg-1. It was saturated half-maximally with phosphoenolpyruvate at KPPrv0.5 = 0.36 mM phosphoenolpyruvate and was activity by fructose 1,6-bisphosphate and L-serine at suboptimal substrate concentrations. After 11 000-fold purification to a specific enzymatic activity of 60 mumol X min-1 X mg-1, the pyruvate kinase isoenzymes type M2 (KPPrv0.5 = 0.32 mM) and M1 (KPPrv0.5 = 0.04 mM) were obtained from the yolk substance. Kinetic differences were noted between the pyruvate kinase type-M2 isoenzymes from vitelline membrane and yolk. A comparison of the amino acid composition of the purified pyruvate kinase isoenzymes from hen's egg revealed that all isoenzymes were related to pyruvate kinase type M1 from chicken breast muscle. The M2-type isoenzyme from vitelline membrane was related to the M2-type isoenzyme from chicken tumors, but was not related to the M2-type pyruvate kinase from chicken lung or liver. Protein kinase C from chicken oviduct phosphorylated in vitro both pyruvate kinase M2 isoenzymes from the unfertilized hen's egg preferably at serine and less at threonine residues. Pyruvate kinase type M1 from egg yolk was a weak substrate of protein kinase C. An activation of pyruvate kinase type M2 from vitelline membrane was observed at suboptimal concentrations of phosphoenolpyruvate under the conditions of phosphorylation, in the presence of phosphatidylserine.

Protein kinase C: properties and possible role in cellular division and differentiation

Protein kinase C was first described some eight years ago. Recent results indicate that this kinase may have a crucial role in signal transduction for substances involved in cellular differentiation and division. Protein kinase C is activated by attachment to plasma membranes, in the presence of calcium and diacylglycerol. The activator is produced in the membrane following the signal-induced breakdown of phosphoinositides. Tumor promoters, such as phorbol ester, can substitute for diacylglycerol. The recent findings that: tyrosine kinases might be involved in the phosphoinositide turnover and, phosphorylation of growth factor receptors by protein kinase C regulates some of their functions, indicate more and more clearly that this kinase is involved in the control of cell growth division and differentiation. Purification procedures, properties and mechanisms of regulation will be summarized and discussed.

Multisite phosphorylation of glycogen synthase from rabbit skeletal muscle. Identification of the sites phosphorylated by casein kinase-I

A casein kinase was highly purified from rabbit skeletal muscle whose substrate specificity and enzymatic properties were virtually identical to those of casein kinase-I from rabbit reticulocytes. Prolonged incubation of glycogen synthase with high concentrations of skeletal muscle casein kinase-I and Mg-ATP resulted in the incorporation of greater than 6 mol phosphate/mol subunit and decreased the activity ratio (+/- glucose-6P) from 0.8 to less than 0.02. The sites phosphorylated by casein kinase-I were all located in the N and C-terminal cyanogen bromide peptides, termed CB-1 and CB-2. At an incorporation of 6 mol phosphate/mol subunit, approximately equal to 2 mol/mol was present in CB-1 and approximately equal to 4 mol/mol in CB-2. Within CB-1, casein kinase-I phosphorylated the serines that were 3, 7 and 10 residues from the N-terminus of glycogen synthase, with minor phosphorylation at threonine-5. Within CB-2, approximately equal to 90% of the phosphate incorporated was located between residues 28 and 53, and at least five of the seven serine residues in this region were phosphorylated. The remaining 10% of phosphate incorporated into CB-2 was located between residues 98 and 123, mainly at a serine residue(s). Two of the major sites labelled by casein kinase-I (serine-3 and serine-10 of CB-1) are not phosphorylated by any other protein kinase. This will enable the role of casein kinase-I as a glycogen synthase kinase in vivo to be evaluated.

Acute effects of tumor-promoting phorbol esters on hepatic intermediary metabolism

In hepatocytes isolated from meal-fed rats, phorbol 12-myristate 13-acetate as well as phorbol 12,13-didecanoate stimulated de novo fatty acid synthesis in a dose-dependent manner. Moreover, phorbol 12-myristate 13-acetate inhibited ketogenesis from exogenous oleate, but slightly enhanced oleate esterification. The stimulation of esterification was more pronounced with endogenously synthesized fatty acids. In hepatocytes from 24h-starved rats a moderate stimulation of gluconeogenesis and ureogenesis was observed with glutamine as substrate. It is concluded that tumor-promoting phorbol esters mimic the short-term effects of insulin on hepatic fatty acid metabolism.

Inositol trisphosphate and diacylglycerol as intracellular second messengers in liver

Receptor occupation by a variety of Ca2+-mobilizing hormones, such as alpha 1-adrenergic agents, vasopressin and angiotensin II, causes a rapid phosphodiesterase-mediated hydrolysis of phosphatidylinositol-4,5-bisphosphate in the plasma membrane with the production of the water soluble compound myo-inositol-1,4,5-trisphosphate (IP3) and the lipophilic molecule 1,2-diacylglycerol (DG). This review summarizes the recent evidence obtained in the liver that defines the roles of these products as intracellular messengers of hormone action. Intracellular Ca2+ mobilization is mediated by IP3, which releases Ca2+ from a subpopulation of the endoplasmic reticulum, resulting in a rapid increase of the cytosolic free Ca2+ concentration ( [Ca2+]i). Further effects of receptor occupancy are inhibition of the plasma membrane Ca2+-ATPase, despite net Ca2+ efflux, and an increased permeability of the plasma membrane to extracellular Ca2+. The activation of the phospholipid-dependent protein kinase C by DG does not alter Ca2+ fluxes across the plasma membrane. In contrast to some secretory cells, a synergism between protein kinase C activation and increased [Ca2+]i is not observed in liver. Activation of protein kinase C profoundly inhibits the response to alpha 1-adrenergic agonists, with only minimal effects on the vasopressin response. It is concluded that in liver the two inositol-lipid messenger systems, IP3 and DG, exert their effects by essentially separate pathways.