Purification and kinetic mechanism of rat liver glycogen synthase

Comparative characterization of human and rat liver glycogen synthase

Glycogen synthase from human liver was studied, and its properties were compared with those of rat liver glycogen synthase. The rat and human liver glycogen synthases were similar in their pH profile, in their kinetic constants for the substrate UDP-glucose and the activator glucose 6-phosphate, and in their elution profiles from Q-Sepharose. The apparent molecular weight of the human synthase subunit was 80,000-85,000 by gel electrophoresis, which is similar to that of the rat enzyme. In addition, antibodies to rat liver glycogen synthase recognized human liver glycogen synthase, indicating that the enzymes of these two species share antigenic determinants. However, there were significant differences between the two enzymes. In particular, the total activity of the human enzyme was higher than that of the rat. The human enzyme, purified to near homogeneity, had a specific activity of 40 U/mg protein compared with 20 U/mg protein for the rat enzyme. The active forms of the rat enzyme had greater thermal stability than those of the human enzyme, but the human enzyme was more stable on storage in various buffers. Last, amino acid analysis indicated differences between the enzymes of the two species. Since glycogen synthase is an important enzyme in liver glycogen synthesis, the characterization of this enzyme in the human will help provide insight regarding human liver glycogen synthesis.

Regulation of glycogen synthesis in the liver

The glycogen synthase-mediated reaction is rate-limiting for glycogen synthesis in the liver. Glycogen synthase has been purified essentially to homogeneity and has been shown to be a dimer composed of identical subunits. It is regulated by a phosphorylation-dephosphorylation mechanism, catalyzed by kinases and a phosphatase. The subunits of synthase D, the most phosphorylated form, each contain approximately 17 phosphates. The subunits of synthase I, the least phosphorylated form, each contain 14 phosphates. Thus, during the transition between these two forms, a net of three phosphoryl groups is added or removed. In synthase D, six of the phosphates are alkali-labile. In synthase I, three of the phosphates are alkali-labile. Therefore, all of the phosphorylation sites important in the interconversion of these two forms are alkali-labile (attached to serine or threonine residues). In short-term experiments using isolated hepatocytes, [32P]phosphate was only incorporated into the alkali-labile sites and the phosphate in these sites was shown to turn over rapidly. Glucose addition, which is known to reduce the proportion of synthase in the D form when assayed kinetically, also reduced the [32P]phosphate content. Glucagon addition, which increases the proportion of synthase in the D form, increased it. These changes do not appear to be site-specific. Ingestion or administration of fructose, or galactose, as well as glucose, result in a shift in synthase equilibrium in favor of the less phosphorylated forms. Possible mechanisms by which synthase phosphatase activity may be increased after ingestion of glucose or fructose, and thus shift the equilibrium in favor of the less phosphorylated forms, are discussed. The mechanism by which galactose may stimulate the phosphatase reaction is completely unknown.

Control of glycogen synthase phosphorylation in isolated rat hepatocytes by epinephrine, vasopressin and glucagon

Isolated rat hepatocytes were incubated in a medium containing 0.1 mM [32P]phosphate (0.1 mCi/ml) before exposure to epinephrine, glucagon or vasopressin. 32P-labeled glycogen synthase was purified from extracts of control or hormone-treated cells by the use of specific antibodies raised to rabbit skeletal muscle glycogen synthase. Analysis of the immunoprecipitates by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate indicated that a single 32P-labeled polypeptide, apparent Mr 88000, was removed specifically by the antibodies and corresponded to glycogen synthase. Similar electrophoretic analysis of CNBr fragments prepared from the immunoprecipitate revealed that 32P was distributed between two fragments, of apparent Mr 14000 (CB-1) and 28000 (CB-2). Epinephrine, vasopressin or glucagon increased the 32P content of the glycogen synthase subunit. CB-2 phosphorylation was increased by all three hormones while CB-1 was most affected by epinephrine and vasopressin. These effects correlated with a decrease in glycogen synthase activity. From studies using rat liver glycogen synthase, purified by conventional methods and phosphorylated in vitro by individual protein kinases, it was found that electrophoretically similar CNBr fragments could be obtained. However, neither cyclic-AMP-dependent protein kinase nor three different Ca2+-dependent enzymes (phosphorylase kinase, calmodulin-dependent protein kinase, and protein kinase C) were effective in phosphorylating CB-2. The protein kinases most effective towards CB-2 were the Ca2+ and cyclic-nucleotide-independent enzymes casein kinase II (PC0.7) and FA/GSK-3. The results demonstrate that rat liver glycogen synthase undergoes multiple phosphorylation in whole cells and that stimulation of cells by glycogenolytic hormones can modify the phosphorylation of at least two distinct sites in the enzyme. The specificity of the hormones, however, cannot be explained simply by the direct action of any known protein kinase dependent on cyclic nucleotide or Ca2+. Therefore, either control of other protein kinases, such as FA/GSK-3, is involved or phosphatase activity is regulated, or both.

Identification of an Mr 77,000 - 80,000 product of in vitro translation of rat liver mRNA using antibody to glycogen synthase

Rabbit antibody to rat liver glycogen synthase has been used to identify a product of Mr 77,000 - 80,000 from in vitro translation of rat liver mRNA. A comparison of various protease inhibitors on the relative molecular weight of rat liver glycogen synthase suggest that higher molecular weight enzyme forms could arise from incomplete hydrolysis of glycogen before enzyme isolation and enzyme subunit Mr determinations.

The initiation of glycogen biosynthesis in rat heart

A rat heart extract synthesizes glycogen-like material from UDP-glucose in the absence of added primer. Most of this material is precipitable by dilute trichloroacetic acid, in contrast to glycogen synthesized in presence of added glycogen primer. It is postulated that the endogenous initiation of glycogen synthesis occurs by apposition of glucose residues to a protein and that the material so synthesized in vitro corresponds to the protein-bound glycogen reported to exist in rat heart. The ability to label the putative protein primer in vitro with [14C]glucose should assist the isolation of the primer and the elucidation of the nature of the association between the carbohydrate and protein moeities.

Comparison of the liver glycogen synthase from normal and streptozotocin-induced diabetic rats

Glycogen synthase in the liver extracts of short-term (3 days) streptozotocin-induced diabetic rats is poorly activated by the endogenous synthase phosphatase as well as phosphatase(s) from the liver extracts of normal animals. However, synthase in the liver extracts of diabetic rats is readily activated by the 35,000 Mr rabbit liver protein phosphatase (H. Brandt, F.L. Capulong, and E. Y. C. Lee (J. Biol. Chem. 250, 8038-8044 (1975)). The purified synthases from normal and diabetic animals respond differently after incubations with three different phosphatases. Both normal and diabetic synthase are activated by the 35,000 Mr protein phosphatase; however, the total activity of diabetic, but not the normal, synthase is significantly increased. Normal, but not the diabetic, synthase is activated by a synthase phosphatase from normal rats; this activation is accompanied by an increase in total synthase activity. Incubation of the diabetic synthase with calf intestinal alkaline phosphatase results in a reduction of the total synthase activity, whereas synthase activity of the normal is not significantly affected. The reduction in total activity of the diabetic synthase by treatment with alkaline phosphatase was prevented by prior dephosphorylation with 35,000 Mr rabbit liver protein phosphatase. In addition to their differences in responses to different phosphatases, the normal and diabetic synthases are also different in their molecular weights as determined by sucrose density gradient centrifugation (154,000 +/- 17,000 (n = 6) for the normal and 185,000 +/- 15,000 (n = 8) for the diabetic synthase) and their kinetic properties.

Kinetic mechanism of rabbit muscle glycogen synthase I

The kinetic mechanism of rabbit muscle glycogen synthase I was investigated by determining isotope-exchange rates at chemical equilibrium between uridine diphosphoglucose (UDPG) and glycogen and between UDPG and uridine 5'-diphosphate (UDP). The rates were followed simultaneously by use of UDPG labeled with 14C in the glucose moiety and with 3H in the uracil group. They were found to be independent of the concentrations of glycogen and the UDPG-UDP pair, averaging 6 X 10(-9) mol min-1 mg-1, with a ratio of UDPG-glycogen exchange to UDPG-UDP exchange of 0.85-0.95. The conclusion is that glycogen synthase has a rapid equilibrium random bi bi mechanism. The previously reported slow activation of glycogen-free synthase in the presence of glycogen was examined kinetically. The activation rate appears to be independent of glycogen concentration over a wide range, while the maximum activation is related to the third or fourth root of the glycogen concentration. This suggest that the slow bimolecular reaction mechanism proposed for human polymorphonuclear leucocyte glycogen synthase I [Sølling, H., & Esmann, V. (1977) Eur. J. Biochem. 81, 129] does not apply to rabbit muscle synthase I. The rate of exchange of glycogen molecules in the complex between glycogen and rabbit muscle synthase I under conditions where the enzyme is catalytically active was estimated by a novel method. The enzyme-glycogen complex was treated with [glucose-14C]UDPG and glycogen of different molecular weight. The distribution of isotope between the two forms of glycogen was determined after their separation by agarose gel chromatography. A rate constant of 0.3 min-1 was estimated for the exchange. It can be calculated, on the basis of the specific activity of the enzyme (20 mumol min-1 mg-1) and its action pattern, that hundreds of individual chains in the glycogen molecule must be available to the enzyme during the average lifetime of the complex. A mechanism is proposed for this process.

Biosynthesis of glycogen in Neurospora crassa. Purification and properties of the UDPglucose:glycogen 4-alpha-glucosyltransferase

The Neurospora crassa glycogen synthase (UDPglucose:glycogen 4-alpha-glucosyltransferase, EC 2.4.1.11) was purified to electrophoretic homogeneity by a procedure involving ultracentrifugation, DEAE-cellulose column chromatography, (NH4)2SO4 fractionation and 3-aminopropyl-Sepharose column chromatography. The final purified enzyme preparation was almost entirely dependent on glucose-6-P and had a specific activity of 6.9 units per mg of protein. The subunit molecular weight of the glycogen synthase was determined by electrophoresis in sodium dodecyl sulfate-polyacrylamide gel to be 88 000--90 000. The native enzyme was shown to have a molecular weight of 270 000 as determined by sucrose density gradient centrifugation. Thus, the glucose-6-P-dependent form of the N. crassa glycogen synthase can exist as trimer of the subunit. Limited proteolysis with trypsin or chymotrypsin converted the glucose-6-P-dependent form of the enzyme into an apparent glucose-6-P-independent form. The enzyme was shown to catalyze transfer of glucose from UDPglucose to glycogen as well as to its phosphorylase limit dextrin, but not to its beta-amylase limit dextrin. Moreover, glucose, maltose and maltotriose were not active as acceptors.

Properties of beta-glucan synthetase from Saccharomyces cerevisiae

Properties of beta-glucan synthetase from S. cerevisiae were studied. The enzyme exhibited optimal activity at pH 6.7 and 24 C. Km for UDP-glucose was 0.12 mM. Addition of Mg++ or Mn++ stimulated its activity by 60% and 21% respectively. High concentrations of EDTA and hydroxyquinoline were inhibitory. Glucan synthetase was fully active in cell-free extracts. Small concentrations of trypsin or subtilopeptidase A from Bacillus subtilis, caused only a slight increase in glucosyl transferase activity, but larger concentrations destroyed beta-glucan synthetase. Acid proteases were neither stimulatory nor destructive. Thus it seems unlikely that beta-glucan synthetase exists in a zymogen form. Glucan synthetase was unstable. It was inactivated more rapidly at 28 C than at 0 C. The presence of substrate, beta-glucan or the protease inhibitors PMSF, Antipain or Pepstatin A did not protect beta-glucan synthetase from inactivation. Glucan synthetase was not stimulated by addition of cellobiose or beta-glucans. The synthesis of beta-glucans was competitively inhibited by UDP (Ki = 0.45 mM). Glucono-delta-lactone, a known inhibitor of beta-glucosidases was a strong non-competitive inhibitor of beta-glucan synthetase.

Purification and steady state kinetic mechanism of glycogen synthase-D from human polymorpho-nuclear leukocytes

The authors' work on the purification and steady state kinetic investigation of the enzyme glycogen synthase D (UDP-glucose: glycogen 4-alpha-glucosyl-transferase, EC 2.4.1.11) from human polymorphonuclear leukocytes is reviewed. The main features of the kinetic mechanism for catalysis of the reaction interconversion of the quaternary enzyme-substrate-activator complexes. The anions interact exclusively with the G-6-P binding site of the enzyme. The dissociation constants for the enzyme-modifier complexes are determined, and a kinetic mechanism for the action of the anions is proposed, leading to activation or inhibition, depending on the concentration of G-6-P.