Purification and partial characterization of protein phosphatases from rat thymus

Protein phosphatases assayed with phosphorylase alpha are present in the soluble and particulate fractions of rat thymocytes. Phosphorylase phosphatase activity in the cytosol fraction was resolved by heparin-Sepharose chromatography into type-1 and type-2A enzymes. Similarities between thymocyte and muscle or liver protein phosphatase-1 included preferential dephosphorylation of the beta subunit of phosphorylase kinase, inhibition by inhibitor-2 and retention by heparin-Sepharose. Similarities between thymocyte and muscle or liver protein phosphatase-2A included specificity for the alpha subunit of phosphorylase kinase, insensitivity to the action of inhibitor-2, lack of retention by heparin-Sepharose and stimulation by polycationic macromolecules such as polybrene, protamine and histone H1. Protein phosphatase-1 from the cytosol fraction of thymocytes had an apparent molecular mass of 120 kDa as determined by gel filtration. The phosphatase-2A separated from the cytosol of thymocytes may correspond to phosphatase-2A0, since it was completely inactive (latent) in the absence of polycation and had activity only in the presence of polycations. The apparent molecular mass of phosphatase-2A0 from thymocytes was 240 kDa as determined by gel filtration. The catalytic subunit of thymocyte type-1 protein phosphatase was purified with heparin-Sepharose chromatography followed by gel filtration and fast protein liquid chromatography on Mono Q column. The purified type-1 catalytic subunit exhibited a specific activity of 8.2 U/mg and consisted of a single protein of 35 kDa as judged by SDS-gel electrophoresis. The catalytic subunit of type-2A phosphatase from thymocytes appearing in the heparin-Sepharose flow-through fraction was further purified on protamine-Sepharose, followed by gel filtration. The specific activity of the type-2A catalytic subunit was 2.1 U/mg and consisted of a major protein of 34.5 kDa, as revealed by SDS-gel electrophoresis.     

Decreased activity and impaired hormonal control of protein phosphatases in rat livers with a deficiency of phosphorylase kinase.

1. Livers from gsd/gsd rats, which do not express phosphorylase kinase activity, also contain much less particulate type-1 protein phosphatases. In comparison with normal Wistar rats, the glycogen/microsomal fraction contained 75% less glycogen-synthase phosphatase and 60% less phosphorylase phosphatase activity. This was largely due to a lower amount of the type-1 catalytic subunit in the particulate fraction. In the cytosol, the synthase phosphatase activity was also 50% lower, but the phosphorylase phosphatase activity was equal. 2. Both Wistar rats and gsd/gsd rats responded to an intravenous injection of insulin plus glucose with an acute increase (by 30-40%) in the phosphorylase phosphatase activity in the liver cytosol. In contrast, administration of glucagon or vasopressin provoked a rapid fall (by about 25%) in the cytosolic phosphorylase phosphatase activity in Wistar rats, but no change occurred in gsd/gsd rats. 3. Phosphorylase kinase was partially purified from liver and subsequently activated. Addition of a physiological amount of the activated enzyme to a liver cytosol from Wistar rats decreased the V of the phosphorylase phosphatase reaction by half, whereas the non-activated kinase had no effect. The kinase preparations did not change the activity of glycogen-synthase phosphatase, which does not respond to glucagon or vasopressin. Furthermore, the phosphorylase phosphatase activity was not affected by addition of physiological concentrations of homogeneous phosphorylase kinase from skeletal muscle (activated or non-activated). 4. It appears therefore that phosphorylase kinase plays an essential role in the transduction of the effect of glucagon and vasopressin to phosphorylase phosphatase. However, this inhibitory effect either is specific for the hepatic phosphorylase kinase, or is mediated by an unidentified protein that is a specific substrate of phosphorylase kinase.     

Insulin-induced increases in the activity of the spontaneously active and ATP.Mg-dependent forms of phosphatase-1 in alloxan-diabetic rat liver

Liver supernatant from normal and alloxan-diabetic rats was fractionated by DEAE-cellulose chromatography and the separated phosphoprotein phosphatase fractions were assayed with [32P]histone f2b, [32P]phosphorylase a and [32P]phosphorylase kinase as substrates. In diabetic rat liver, one of the phosphatase fractions found in the normal liver was significantly reduced. This fraction was identified as a mixture of the spontaneously active form and the ATP . Mg-dependent form of phosphoprotein phosphatase-1 (Fc) based on sensitivity to inhibitor-2, substrate specificity, and the fact that it could be activated 42-70% by glycogen synthase kinase-3 in the presence of ATP . Mg. Further analysis of this fraction showed that liver cytosol from diabetic rats contained 62-79% lower spontaneously active phosphatase-1 activity and 40-51% lower combined spontaneously active and ATP . Mg-dependent protein phosphatase-1 (Fc) activity. Insulin administration increased the spontaneously active and the ATP . Mg-dependent protein phosphatase-1 activities approximately 45% and 36%, respectively, in alloxan-diabetic rats. These data imply that the lower levels of spontaneously active phosphatase-1 activity in diabetic rat liver cannot be explained by presuming phosphatase-1 to have been present as Fc, the inactive form. Moreover, insulin restored the total activity of the spontaneously active and activatable forms of phosphatase-1 to those present in normal liver implying that both forms of phosphatase-1 activity are under hormonal control.     

Distinct type-1 protein phosphatases are associated with hepatic glycogen and microsomes

The type-1 protein phosphatase associated with hepatic microsomes has been distinguished from the glycogen-bound enzyme in five ways. (1) The phosphorylase phosphatase/synthase phosphatase activity ratio of the microsomal enzyme (measured using muscle phosphorylase a and glycogen synthase (labelled in sites-3) as substrates) was 50-fold higher than that of the glycogen-bound enzyme. (2) The microsomal enzyme had a greater sensitivity to inhibitors-1 and 2. (3) Release of the catalytic subunit from the microsomal type-1 phosphatase by tryptic digestion was accompanied by a 2-fold increase in synthase phosphatase activity, whereas release of the catalytic subunit from the glycogen-bound enzyme decreased synthase phosphatase activity by 60%. (4) 95% of the synthase phosphatase activity was released from the microsomes with 0.3 M NaCl, whereas little activity could be released from the glycogen fraction with salt. (5) The type-1 phosphatase separated from glycogen by anion-exchange chromatography could be rebound to glycogen, whereas the microsomal enzyme (separated from the microsomes by the same procedure, or by extraction with NaCl) could not. These findings indicate that the synthase phosphatase activity of the microsomal enzyme is not explained by contamination with glycogen-bound enzyme. The microsomal and glycogen-associated enzymes may contain a common catalytic subunit complexed to microsomal and glycogen-binding subunits, respectively. Thiophosphorylase a was a potent inhibitor of the dephosphorylation of ribosomal protein S6, HMG-CoA reductase and glycogen synthase, by the glycogen-associated type-1 protein phosphatase. By contrast, thiophosphorylase a did not inhibit the dephosphorylation of S6 or HMG-CoA reductase by the microsomal enzyme, although the dephosphorylation of glycogen synthase was inhibited. The I50 for inhibition of synthase phosphatase activity by thiophosphorylase a catalysed by either the glycogen-associated or microsomal type-1 phosphatases, or for inhibition of S6 phosphatase activity catalysed by the glycogen-associated enzyme, was decreased 20-fold to 5-10 nM in the presence of glycogen. The results suggest that the physiologically relevant inhibitor of the glycogen-associated type-1 phosphatase is the phosphorylase a-glycogen complex, and that inhibition of the microsomal type-1 phosphatase by phosphorylase a is unlikely to play a role in the hormonal control of cholesterol or protein synthesis. Protein phosphatase-1 appears to be the principal S6 phosphatase in mammalian liver acting on the serine residues phosphorylated by cyclic AMP-dependent protein kinase.     

Effects of diabetes and glycogen on the distribution between soluble and particulate fractions of activities of enzymes involved in hepatic glycogen metabolism.

The large decreases in hepatic glycogen associated with alloxan diabetes in fed rats were accompanied by apparent decreases in total activities of glycogen synthase, phosphorylase, protein kinase and synthase phosphatase determined on 8000 × g supernatants of liver homogenates. Inclusion of 4% glycogen in the extraction buffer normalized total soluble activities of synthase in the diabetic. Whereas inclusion of 4% glycogen in the extraction buffer doubled total soluble phosphorylase, total activity remained lower in the diabetic than in the normal. Extraction and assay of soluble protein kinase were unaffected by added glycogen. When activities were determined on whole homogenates, total glycogen synthase activities were the same in normal and diabetic liver. Although the decreases in total activities of phosphorylase, kinase and phosphatase were less when determined on whole homogenates of livers from diabetic rats, the diabetes-related decreases in total activities remained significant. Therefore, it appears that while alloxan diabetes results in absolute decreases in total hepatic activities of phosphorylase, kinase and phosphatase, it may also result in redistribution of hepatic synthase and phosphorylase between soluble and particulate fractions, a phenomenon possibly related to tissue glycogen concentrations. Such a redistribution might be involved in the lack of control of hepatic glycogenesis observed in alloxan diabetic rats.     

Identification of protein phosphatases-1 and 2A and inhibitor-2 in oocytes of the starfish Asterias rubens and Marthasterias glacialis

Protein phosphatases present in the particulate and soluble fractions of oocytes of the starfish Asterias rubens and Marthasterias glacialis have been classified according to the criteria used for these enzymes from mammalian cells. The major protein phosphatase activity in the particulate fraction had very similar properties to protein phosphatase-1 from mammalian tissues, including preferential dephosphorylation of the beta subunit of phosphorylase kinase, sensitivity to inhibitor-1 and inhibitor-2, inhibition of phosphorylase phosphatase activity by protamine and heparin, and retention by heparin-Sepharose. The major protein phosphatase in the soluble fraction had very similar properties to mammalian protein phosphatase-2A, including preferential dephosphorylation of the alpha subunit of phosphorylase kinase, insensitivity to inhibitors-1 and 2, activation by protamine and heparin, and exclusion from heparin-Sepharose. An acid-stable and heat-stable protein was detected in the soluble fraction of starfish oocytes, whose properties were indistinguishable from those of inhibitor-2 from mammalian tissues. It inhibited protein phosphatase-1 specifically, and its apparent molecular mass on SDS polyacrylamide gels was 31 kDa. Furthermore, an inactive hybrid formed between the starfish oocyte inhibitor and the catalytic subunit of mammalian protein phosphatase-1 could be reactivated by preincubation with MgATP and mammalian glycogen synthase kinase-3. The remarkable similarities between starfish oocyte protein phosphatases and their mammalian counterparts are indicative of strict phylogenetic conservation of these enzymes. The results will facilitate further analysis of the role of protein phosphorylation in the control of starfish oocyte maturation by the hormone 1-methyladenine.     

The protein phosphatases involved in cellular regulation. Evidence that dephosphorylation of glycogen phosphorylase and glycogen synthase in the glycogen and microsomal fractions of rat liver are catalysed by the same enzyme: protein phosphatase-1

Glycogen synthase (labelled in sites-3) and glycogen phosphorylase from rabbit skeletal muscle were used as substrates to investigate the nature of the protein phosphatases that act on these proteins in the glycogen and microsomal fractions of rat liver. Under the assay conditions employed, glycogen synthase phosphatase and phosphorylase phosphatase activities in both subcellular fractions could be inhibited 80-90% by inhibitor-1 or inhibitor-2, and the concentrations required for half-maximal inhibition were similar. Glycogen synthase phosphatase and phosphorylase phosphatase activities coeluted from Sephadex G-100 as broad peaks, stretching from the void volume to an apparent molecular mass of about 50 kDa. Incubation with trypsin decreased the apparent molecular mass of both activities to about 35 kDa, and decreased their I50 for inhibitors-1 and -2 in an identical manner. After tryptic digestion, the I50 values for inhibitors-1 and -2 were very similar to those of the catalytic subunit of protein phosphatase-1 from rabbit skeletal muscle. The glycogen and microsomal fractions of rat liver dephosphorylated the beta-subunit of phosphorylase kinase much faster than the alpha-subunit and dephosphorylation of the beta-subunit was prevented by the same concentrations of inhibitor-1 and inhibitor-2 that were required to inhibit the dephosphorylation of phosphorylase. The same experiments performed with the glycogen plus microsomal fraction from rabbit skeletal muscle revealed that the properties of glycogen synthase phosphatase and phosphorylase phosphatase were very similar to the corresponding activities in the hepatic glycogen fraction, except that the two activities coeluted as sharp peaks near the void volume of Sephadex G-100 (before tryptic digestion). Tryptic digestion of the hepatic glycogen and microsomal fractions increased phosphorylase phosphatase about threefold, but decreased glycogen synthase phosphatase activity. Similar results were obtained with the glycogen plus microsomal fraction from rabbit skeletal muscle or the glycogen-bound form of protein phosphatase-1 purified to homogeneity from the same tissue. Therefore the divergent effects of trypsin on glycogen synthase phosphatase and phosphorylase phosphatase activities are an intrinsic property of protein phosphatase-1. It is concluded that the major protein phosphatase in both the glycogen and microsomal fractions of rat liver is a form of protein phosphatase-1, and that this enzyme accounts for virtually all the glycogen synthase phosphatase and phosphorylase phosphatase activity associated with these subcellular fractions.     

Characterization of glycogen-synthase phosphatase and phosphorylase phosphatase in subcellular liver fractions

Upon fractionation of a postmitochondrial supernatant from rat liver, the synthase phosphatase (EC 3.1.3.42) activity (assayed at high tissue concentrations) was largely recovered in the glycogen fraction and to a minor extent in the cytosol. In contrast, the phosphorylase phosphatase (EC 3.1.3.17) activity was approximately equally distributed between these two fractions, a lesser amount being recovered in the microsomal fraction. The phosphatase activities in the microsomal and glycogen fractions were almost completely inhibited by a preincubation with the modulator protein, a specific inhibitor of type-1 (ATP,Mg-dependent) protein phosphatases. In the cytosolic fraction, however, type-2A (polycation-stimulated) phosphatase(s) contributed significantly to the dephosphorylation of phosphorylase and of in vitro phosphorylated muscular synthase. Liver synthase b, used as substrate for the measurement of synthase phosphatase throughout this work, was only activated by modulator-sensitive phosphatases. Trypsin treatment of the subcellular fractions resulted in a dramatically increased (up to 1000-fold) sensitivity to modulator, a several-fold increase in phosphorylase phosphatase activity and a complete loss of synthase phosphatase activity. Similar changes occurred during dilution of the glycogen-bound enzyme. A preincubation with the deinhibitor protein, which is known to counteract the effects of inhibitor-1 and modulator, increased several-fold the phosphorylase phosphatase activity, but exclusively in the cytosolic and microsomal fractions. It did not affect the synthase phosphatase activity. Taken together, the results indicate the existence of distinct, multi-subunit type-1 phosphatases in the cytosolic, microsomal and glycogen fractions.     

The protein phosphatases involved in cellular regulation. 1. Classification and substrate specificities

The protein phosphatase activities involved in regulating the major pathways of intermediary metabolism can be explained by only four enzymes which can be conveniently divided into two classes, type-1 and type-2. Type-1 protein phosphatases dephosphorylate the beta-subunit of phosphorylase kinase and are potently inhibited by two thermostable proteins termed inhibitor-1 and inhibitor-2, whereas type-2 protein phosphatases preferentially dephosphorylate the alpha-subunit of phosphorylase kinase and are insensitive to inhibitor-1 and inhibitor-2. The substrate specificities of the four enzymes, namely protein phosphatase-1 (type-1) and protein phosphatases 2A, 2B and 2C (type-2) have been investigated. Eight different protein kinases were used to phosphorylate 13 different substrate proteins on a minimum of 20 different serine and threonine residues. These substrates include proteins involved in the regulation of glycogen metabolism, glycolysis, fatty acid synthesis, cholesterol synthesis, protein synthesis and muscle contraction. The studies demonstrate that protein phosphatase-1 and protein phosphatase 2A have very broad substrate specificities. The major differences, apart from the site specificity for phosphorylase kinase, are the much higher myosin light chain phosphatase and ATP-citrate lyase phosphatase activities of protein phosphatase-2A. Protein phosphatase-2C (an Mg2+-dependent enzyme) also has a broad specificity, but can be distinguished from protein phosphatase-2A by its extremely low phosphorylase phosphatase and histone H1 phosphatase activities, and its slow dephosphorylation of sites (3a + 3b + 3c) on glycogen synthase relative to site-2 of glycogen synthase. It has extremely high hydroxymethylglutaryl-CoA (HMG-CoA) reductase phosphatase and HMG-CoA reductase kinase phosphatase activity. Protein phosphatase-2B (a Ca2+-calmodulin-dependent enzyme) is the most specific phosphatase and only dephosphorylated three of the substrates (the alpha-subunit of phosphorylase kinase, inhibitor-1 and myosin light chains) at a significant rate. It is specifically inhibited by the phenathiazine drug, trifluoperazine. Examination of the amino acid sequences around each phosphorylation site does not support the idea that protein phosphatase specificity is determined by the primary structure in the immediate vicinity of the phosphorylation site.     

The protein phosphatases involved in cellular regulation. 1. Modulation of protein phosphatases-1 and 2A by histone H1, protamine, polylysine and heparin

The phosphorylase phosphatases in rat and rabbit liver cytosol that are markedly stimulated by histone H1, protamine and polylysine were identified as protein phosphatases-2A0, 2A1 and 2A2 by anion-exchange chromatography, gel-filtration and immunotitration experiments. Histone H1 and protamine also stimulated the dephosphorylation of phosphorylase kinase, glycogen synthase, fructose-1,6-bisphosphatase, pyruvate kinase, acetyl-CoA carboxylase and phenylalanine hydroxylase by phosphatases-2A1 and 2A2, and with several of these substrates activation was even more striking (20-100-fold) than that observed with phosphorylase (approximately 5-fold). Activation by basic polypeptides did not involve dissociation of these phosphatases to the free catalytic subunit. The dephosphorylation of phosphorylase by protein phosphatase-1 was suppressed by basic polypeptides, protamine and polylysine being the most potent inhibitors. However, the dephosphorylation of glycogen synthase, pyruvate kinase and acetyl-CoA carboxylase were markedly stimulated by histone H1 and protamine (2-13-fold). Consequently, with the appropriate substrates, protein phosphatase-1 can also be regarded as a basic-polypeptide-activated protein phosphatase. Heparin stimulated (1.5-2-fold) the dephosphorylation of phosphorylase by phosphatases-2A0 and 2A1, provided that Mn2+ was present, but phosphatase-2A2 and the free catalytic subunit of phosphatase-2A were unaffected. Heparin, in conjunction with Mn2+, also stimulated (1.5-fold) the dephosphorylation of glycogen synthase (labelled in sites 3 abc), phosphorylase kinase and phenylalanine hydroxylase by phosphatase-2A1, but not by phosphatase-2A2. By contrast, the dephosphorylation of phosphorylase and phosphorylase kinase by protein phosphatase-1 was inhibited by heparin. However, dephosphorylation of glycogen synthase and pyruvate kinase by phosphatase-1 was stimulated by this mucopolysaccharide. The studies demonstrate that basic proteins can be used to distinguish protein phosphatase-1 from protein phosphatase-2A, but only if phosphorylase is employed as substrate. Optimal differentiation of the two phosphatases is observed at 30 micrograms/ml protamine or at heparin concentrations greater than 150 microM.     

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).     

Activation and inactivation of glycogen phosphorylase isoenzymes purified from diabetic rat heart

1. Hearts of diabetic rats gradually accumulate glycogen, although the activities of glycogen synthase and glycogen phosphorylase are altered in favor of a depletion of glycogen. 2. Phosphorylase in diabetic hearts has been reported to be even more activated in response to adrenaline than controls. 3. The situation is further complicated by the fact that in rat heart two isoenzymes of phosphorylase are present. Therefore we have studied the properties of phosphorylases purified from diabetic rat heart in more detail. 4. This investigation revealed that compared to controls: (A) the amount of enzyme protein which could be isolated from diabetic animals is drastically lower; (B) the affinities towards glycogen and inorganic phosphate are decreased; (C) the activation by phosphorylase kinase is delayed; and (D) the inactivation by protein phosphatase-1 is accelerated. 5. We conclude that all of the reported changes in diabetes might contribute to a phosphorylase system less able to catalyze glycogen breakdown effectively.     

The protein phosphatases involved in cellular regulation. Purification and characterisation of the glycogen-bound form of protein phosphatase-1 from rabbit skeletal muscle

A type-1 protein phosphatase (protein phosphatase-1G) was purified to homogeneity from the glycogen-protein particle of rabbit skeletal muscle. Approximately 3 mg of enzyme were isolated within 4 days from 5000 g of muscle. Protein phosphatase-1G had a molecular mass of 137 kDa and was composed of two subunits G (103 kDa) and C (37 kDa) in a 1:1 molar ratio. The subunits could be dissociated by incubation in the presence of 2 M NaCl, separated by gel-filtration on Sephadex G-100, and recombined at low ionic strength. The C component was the catalytic subunit, and was identical to the 37-kDa type-1 protein phosphatase catalytic subunit (protein phosphatase-1C) isolated from ethanol-treated muscle extracts, as judged by peptide mapping. The G component was the glycogen-binding subunit. It was very asymmetric, extremely sensitive to proteolytic degradation, and failed to silver stain on SDS/polyacrylamide gels. Protein phosphatase-1G was inhibited by inhibitor-1 and inhibitor-2, but unlike protein phosphatase-1C, the rate of inactivation was critically dependent on the ionic strength, temperature and time of preincubation with the inhibitor protein. At near physiological temperature and ionic strength, protein phosphatase-1G was inactivated very rapidly by inhibitor-1. Protein phosphatase-1G interacted with inhibitor-2 (I-2) to form an inactive species, with the structure GCI-2. This form could be activated by preincubation with Mg-ATP and glycogen synthase kinase-3. The G subunit could be phosphorylated on a serine residue(s) by cyclic-AMP-dependent protein kinase, but not by phosphorylase kinase or glycogen synthase kinase-3. Phosphorylation was rapid and stoichiometric, and increased the rate of inactivation of protein phosphatase-1G by inhibitor-1. The relationship of the G subunit to the 'deinhibitor protein' is discussed.     

The modulator protein dissociates the catalytic subunit of hepatic protein phosphatase G from glycogen.

1. The phosphorylase phosphatase and glycogen-synthase phosphatase activities associated with the glycogen particles from rat liver were progressively inhibited by incubation with modulator protein. However, the phosphorylase phosphatase activity of the catalytic subunit was entirely recovered after destruction of the modulator and the regulatory subunit(s) by trypsin. 2. Inhibition of protein phosphatase G by modulator was associated with a translocation of the phosphorylase phosphatase activity (measured after incubation with trypsin) from glycogen to the soluble fraction. The degree of inhibition of phosphatase G corresponded closely to the extent to which the phosphorylase phosphatase activity was released from the glycogen particles. Incubation of glycogen-free protein phosphatase G with modulator did not change the affinity of the enzyme for added glycogen, but decreased the amount of phosphatase that could be bound to glycogen. 3. The phosphorylase phosphatase activity that was released from the glycogen particles by modulator migrated on gel filtration as a complex (Mr 106,000) of the catalytic subunit with modulator. Phosphorylase phosphatase activity could be transferred from glycogen-bound protein phosphatase G to modulator that was covalently bound to Sepharose. After elution from the column, the enzyme was identified as the free catalytic subunit (Mr 37,000).     

Phosphorylation of the glycogen-binding subunit of protein phosphatase-1G by cyclic-AMP-dependent protein kinase promotes translocation of the phosphatase from glycogen to cytosol in rabbit skeletal muscle

The glycogen-bound form of protein phosphatase-1 (termed protein phosphatase-1G) is composed of the catalytic (C) subunit complexed to a glycogen-binding (G) subunit that anchors the enzyme to glycogen [Str?lfors et al. (1985) Eur. J. Biochem. 149, 295-303]. Incubation of purified protein phosphatase-1G with cyclic-AMP-dependent protein kinase and MgATP, which leads to stoichiometric phosphorylation of the G-subunit [Caudwell et al. (1986) FEBS Lett. 194, 85-90], was found to promote the release of the phosphatase from glycogen; similar observations were made using glycogen-protein particle preparations. An intravenous injection of adrenaline decreased protein phosphatase-1 activity associated with the glycogen-protein particles by 50% with a corresponding increase in the amount present in the cytosol. By contrast, adrenaline did not affect the distribution of glycogen synthase or glycogen phosphorylase which remained entirely bound to glycogen in these experiments. The specific release of protein phosphatase-1 from glycogen may facilitate its inactivation by inhibitor-1 in the cytosol, thereby preventing dephosphorylation of the glycogen metabolising enzymes. Translocation of protein phosphatase-1 may represent a novel mechanism for the activation of glycogenolysis and inhibition of glycogen synthesis by adrenaline.     

The effect of streptozotocin-induced diabetes and of insulin supplementation on glycogen metabolism in rat liver.

The effects of streptozotocin-induced diabetes and of insulin supplementation to diabetic rats on glycogen-metabolizing enzymes in liver were determined. The results were compared with those from control animals. The activities of glycogenolytic enzymes, i.e. phosphorylase (both a and b), phosphorylase kinase and protein kinase (in the presence or in the absence of cyclic AMP), were significantly decreased in the diabetic animals. The enzyme activities were restored to control values by insulin therapy. Glycogen synthase (I-form) activity, similarly decreased in the diabetic animals, was also restored to control values after the administration of insulin. The increase in glycogen synthase(I-form) activity after insulin treatment was associated with a concomitant increase in phosphoprotein phosphatase activity. The increase in phosphatase activity was due to (i) a change in the activity of the enzyme itself and (ii) a decrease in a heat stable protein inhibitor of the phosphatase activity.     

Effect of Diabetes on Glycogen Metabolism in Rat Retina

Glucose is the main fuel for energy metabolism in retina. The regulatory mechanisms that maintain glucose homeostasis in retina could include hormonal action. Retinopathy is one of the chemical manifestations of long-standing diabetes mellitus. In order to better understand the effect of hyperglycemia in retina, we studied glycogen content as well as glycogen synthase and phosphorylase activities in both normal and streptozotocin-induced diabetic rat retina and compared them with other tissues. Glycogen levels in normal rat retina are low (46 +/- 4.0 nmol glucosyl residues/mg protein). However, high specific activity of glycogen synthase was found in retina, indicating a substantial capacity for glycogen synthesis. In diabetic rats, glycogen synthase activity increased between 50% and 100% in retina, brain cortex and liver of diabetic rats, but only retina exhibited an increase in glycogen content. Although, total and phosphorylated glycogen synthase levels were similar in normal and diabetic retina, activation of glycogen synthase by glucose-6-P was remarkable increased. Glycogen phosphorylase activity decreased 50% in the liver of diabetic animals; it was not modified in the other tissues examined. We conclude that the increase in glycogen levels in diabetic retina was due to alterations in glycogen synthase regulation.     

Comparison of the substrate specificities of protein phosphatases involved in the regulation of glycogen metabolism in rabbit skeletal muscle.

Muscle extracts were subjected to fractionation with ethanol, chromatography on DEAE-cellulose, precipitation with (NH4)2SO4 and gel filtration on Sephadex G-200. These fractions were assayed for protein phosphatase activities by using the following seven phosphoprotein substrates: phosphorylase a, glycogen synthase b1, glycogen synthase b2, phosphorylase kinase (phosphorylated in either the alpha-subunit or the beta-subunit), histone H1 and histone H2B. Three protein phosphatases with distinctive specificities were resolved by the final gel-filtration step and were termed I, II and III. Protein phosphatase-I, apparent mol.wt. 300000, was an active histone phosphatase, but it accounted for only 10-15% of the glycogen synthase phosphatase-1 and glycogen synthase phosphatase-2 activities and 2-3% of the phosphorylase kinase phosphatase and phosphorylase phosphatase activity recovered from the Sephadex G-200 column. Protein phosphatase-II, apparent mol.wt. 170000, possessed histone phosphatase activity similar to that of protein phosphatase-I. It possessed more than 95% of the activity towards the alpha-subunit of phosphorylase kinase that was recovered from Sephadex G-200. It accounted for 10-15% of the glycogen synthase phosphatase-1 and glycogen synthase phosphatase-2 activity, but less than 5% of the activity against the beta-subunit of phosphorylase kinase and 1-2% of the phosphorylase phosphatase activity recovered from Sephadex G-200. Protein phosphatase-III was the most active histone phosphatase. It possessed 95% of the phosphorylase phosphatase and beta-phosphorylase kinase phosphatase activities, and 75% of the glycogen synthase phosphatase-1 and glycogen synthase phosphatase-2 activities recovered from Sephadex G-200. It accounted for less than 5% of the alpha-phosphorylase kinase phosphatase activity. Protein phosphatase-III was sometimes eluted from Sephadex-G-200 as a species of apparent mol.wt. 75000(termed IIIA), sometimes as a species of mol.wt. 46000(termed IIIB) and sometimes as a mixture of both components. The substrate specificities of protein phosphatases-IIA and -IIB were identical. These findings, taken with the observation that phosphorylase phosphatase, beta-phosphorylase kinase phosphatase, glycogen synthase phosphatase-1 and glycogen synthase phosphatase-2 activities co-purified up to the Sephadex G-200 step, suggest that a single protein phosphatase (protein phosphatase-III) catalyses each of the dephosphorylation reactions that inhibit glycogenolysis or stimulate glycogen synthesis. This contention is further supported by results presented in the following paper [Cohen, P., Nimmo, G.A. & Antoniw, J.F. (1977) Biochem. J. 1628 435-444] which describes a heat-stable protein that is a specific inhibitor of protein phosphatase-III.     

Kinases and phosphatases of hepatic glycogen metabolism during fasted to refed transition in normal and streptozotocin-induced diabetic rats.

Normal and streptozotocin-induced diabetic rats were fasted for 24 hours and refed for 4 hours. Changes in the activities of glycogen metabolizing enzymes in liver were followed during this period. In normal rats, hepatic glycogen content increased gradually after the onset of food intake. The percent of active glycogen synthase increased to a peak value at 1h which coincided with a significant (P less than 0.02) increase in synthase phosphatase activity. Phosphorylase alpha and the percent of alpha increased significantly (P less than 0.01) after the meal which correlated with similar increases in cAMP-dependent protein kinase and phosphorylase kinase activities. Activation of enzymes involved in both synthesis and degradation of glycogen during fasted to refed transition indicate a probable substrate cycling. In diabetic livers, there was marked decrease in the activities of glycogen metabolizing enzymes and their levels did not alter significantly in response to the meal indicating a poor turnover of glycogen.     

Regulation of protein phosphatase-1G from rabbit skeletal muscle. 1. Phosphorylation by cAMP-dependent protein kinase at site 2 releases catalytic subunit from the glycogen-bound holoenzyme

The glycogen-associated form of protein phosphatase-1 (PP-1G) is a heterodimer comprising a 37-kDa catalytic (C) subunit and a 161-kDa glycogen-binding (G) subunit, the latter being phosphorylated by cAMP-dependent protein kinase at two serine residues (site 1 and site 2). Here the amino acid sequence surrounding site 2 has been determined and this phosphoserine shown to lie 19 residues C-terminal to site 1 in the primary structure. The sequence in this region is: (sequence; see text) At physiological ionic strength, phosphorylation of glycogen-bound PP-1G was found to release all the phosphatase activity from glycogen. The released activity was free C subunit, and not PP-1G, while the phospho-G subunit remained bound to glycogen. Dissociation reflected a greater than or equal to 4000-fold decrease in affinity of C subunit for G subunit and was readily reversed by dephosphorylation. Phosphorylation and dephosphorylation of site 2 was rate-limiting for dissociation and reassociation of C subunit. Release of C subunit was also induced by the binding of anti-site-1 Fab fragments to glycogen-bound PP-1G. At near physiological ionic strength, PP-1G and glycogen concentration, site 2 was autodephosphorylated by PP-1G with a t0.5 of 2.6 min at 30 degrees C, approximately 100-fold slower than the t0.5 for dephosphorylation of glycogen phosphorylase under the same conditions. Site 2 was a good substrate for all three type-2 phosphatases (2A, 2B and 2C) with t0.5 values less than those toward the alpha subunit of phosphorylase kinase. At the levels present in skeletal muscle, the type-2A and type-2B phosphatases are potentially capable of dephosphorylating site 2 in vivo within seconds. Site 1 was at least 10-fold less effective than site 2 as a substrate for all four phosphatases. In conjunction with information presented in the following paper in this issue of this journal, the results substantiate the hypothesis that PP-1 activity towards the glycogen-metabolising enzymes is regulated in vivo by reversible phosphorylation of a targetting subunit (G) that directs the C subunit to glycogen--protein particles. The efficient dephosphorylation of site 2 by the Ca2+/calmodulin-stimulated protein phosphatase (2B) provides a potential mechanism for regulating PP-1 activity in response to Ca2+, and represents an example of a protein phosphatase cascade.