Purification and characterization of a protein inhibitor from rat liver that inhibits type 1 protein phosphatase when 3-hydroxy-3-methylglutaryl CoA reductase is the substrate

A protein inhibitor of HMG-CoA reductase phosphatase activity from rat liver was purified to homogeneity. The protein was purified 4,000-fold with an overall yield of 4%. The purified protein had a molecular mass of 31 kDa. This spontaneously active protein is thermostable and acid-resistant. The protein inhibitor is phosphorylated by glycogen synthase kinase-3 and cAMP-dependent protein kinase without change in its inhibitory activity. The inhibition caused by this inhibitor on phosphatases 1 and 2A is similar to that of inhibitor-2 from rabbit skeletal muscle using hydroxymethylglutaryl-CoA reductase as substrate. The regulation properties of this inhibitor towards phosphatase 1 together with another protein inhibitor of phosphatase 2A in cholesterol metabolism are discussed.     

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 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.     

The MgATP-dependent protein phosphatase and protein phosphatase 1 have identical substrate specificities

The MgATP-dependent phosphorylase phosphatase was found to have a broad substrate specificity. Its activity against all phosphoproteins tested was dependent upon preincubation with the activating factor FA and MgATP. The enzyme dephosphorylated and inactivated phosphorylase kinase and inhibitor 1, and dephosphorylated and activated glycogen synthase and acetyl-CoA carboxylase. Glycogen synthase was dephosphorylated at similar rates whether it had been phosphorylated by cyclic-AMP-dependent protein kinase, phosphorylase kinase or glycogen synthase kinase 3. The enzyme also catalysed the dephosphorylation of ATP citrate lyase, initiation factor eIF-2, and troponin I. The properties of the MgATP-dependent protein phosphatase from either dog liver or rabbit skeletal muscle showed a remarkable similarity to highly purified preparations of protein phosphatase 1 from rabbit skeletal muscle. The relative activities of the two enzymes against all phosphoproteins tested was very similar. Both enzymes dephosphorylated the beta-subunit of phosphorylase kinase 40-fold faster than the alpha-subunit, and both enzymes were inhibited by identical concentrations of the two proteins termed inhibitor 1 and inhibitor 2, which inhibit protein phosphatase 1 specifically. These results demonstrate that the MgATP-dependent protein phosphatase is a type-1 protein phosphatase, and is distinct from type-2 protein phosphatases which dephosphorylate the alpha-subunit of phosphorylase kinase and are unaffected by inhibitor 1 and inhibitor 2. The possibility that the MgATP-dependent protein phosphatase is an inactive form of protein phosphatase 1 and that both proteins share the same catalytic subunit is discussed.     

Characterization of GSK-M, a glycogen synthase kinase from rat skeletal muscle

A form of glycogen synthase kinase designated GSK-M3 was purified 4000-fold from rat skeletal muscle by phosphocellulose, Affi-Gel blue, Sephacryl S-300 and carboxymethyl-Sephadex column chromatography. Separation of GSK-M from the catalytic subunit of the cAMP-dependent protein kinase was facilitated by converting the catalytic subunit to the holoenzyme form by addition of the regulatory subunit prior to the gel filtration step. GSK-M had an apparent Mr 62,000 (based on gel filtration), an apparent Km of 11 microM for ATP, and an apparent Km of 4 microM for rat skeletal muscle glycogen synthase. The kinase had very little activity with 0.2 mM GTP as the phosphate donor. Kinase activity was not affected by the addition of cyclic nucleotides, EGTA, heparin, glucose 6-P, glycogen, or the heat-stable inhibitor of cAMP-dependent protein kinase. Phosphorylation of glycogen synthase from rat skeletal muscle by GSK-M reduced the activity ratio (activity in the absence of Glc-6-P/activity in the presence of Glc-6-P X 100) from 90 to 25% when approximately 1.2 mol of phosphate was incorporated per mole of glycogen synthase subunit. Phosphopeptide maps of glycogen synthase obtained after digestion with CNBr or trypsin showed that this kinase phosphorylated glycogen synthase in serine residues found in the peptides containing the sites known as site 2, which is located in the N-terminal CNBr peptide, and site 3, which is located in the C-terminal CNBr peptide of glycogen synthase. In addition to phosphorylating glycogen synthase, GSK-M phosphorylated inhibitor 2 and activated ATP-Mg-dependent protein phosphatase. Activation of the protein phosphatase by GSK-M was dependent on ATP and was virtually absent when ATP was replaced with GTP. GSK-M had minimal activity toward phosphorylase b, casein, phosvitin, and mixed histones. These data indicate that GSK-M, a major form of glycogen synthase kinase from rat skeletal muscle, differs from the known glycogen synthase kinases isolated from rabbit skeletal muscle.     

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.     

Characterisation of a reconstituted Mg-ATP-dependent protein phosphatase

Homogenous preparations of the catalytic subunit of protein phosphatase-1 and inhibitor-2 can be combined to produce an inactive enzyme that consists of a 1:1 complex between these two proteins. This species is indistinguishable from the Mg-ATP-dependent protein phosphatase in that preincubation with glycogen synthase kinase-3 and Mg-ATP is required to generate activity. Activation results from the phosphorylation of inhibitor-2. The molar concentrations of protein phosphatase-1 and inhibitor-2 in rabbit skeletal muscle (0.25-0.5 microM) are similar. Incubation of the reconstituted Mg-ATP-dependent protein phosphatase with chymotrypsin is accompanied by limited proteolysis of inhibitor-2 and the loss of its phosphorylation site(s). This species can be activated by glycogen synthase kinase-3 and Mg-ATP provided that inhibitor-2 is added. This exogenous inhibitor-2 appears to displace the fragments of inhibitor-2 from the enzyme that were generated by chymotryptic digestion. These experiments may explain the report [Yang, S.D., Vandenheede, J.R. and Merlevede, W. (1981) J. Biol. Chem. 256, 10231-10234] that inhibitor-2 can function as an 'activator' as well as an inhibitor of the Mg-ATP-dependent protein phosphatase. Incubation of the catalytic subunit of protein phosphatase-1 with sodium fluoride or sodium pyrophosphate converted the enzyme to an inactive form that could be partially reactivated by manganese ions, but not by glycogen synthase kinase-3 and Mg-ATP. Conversely, the reconstituted Mg-ATP-dependent protein phosphatase could only be activated by glycogen synthase kinase-3 and Mg-ATP, and not by manganese ions. It is concluded that the conversion of protein phosphatase-1 to a manganese-ion dependent form is a quite separate phenomenon from the formation of the Mg-ATP-dependent protein phosphatase. Inhibitor-2 can inactivate protein phosphatase-1 by a second mechanism that is not reversed by preincubation with glycogen synthase kinase-3 and Mg-ATP. This occurs at higher concentrations of inhibitor-2 than those required to form the Mg-ATP-dependent protein phosphatase, and appears to result from the binding of inhibitor-2 to a distinct site on the enzyme.     

Inhibitors of protein phosphatase-1. Inhibitor-1 of bovine adipose tissue and a dopamine- and cAMP-regulated phosphoprotein of bovine brain are identical

Protein phosphatase inhibitor-1 was purified from bovine adipose tissue. The protein had an apparent molecular mass of 32 kDa by SDS/PAGE and a Stokes' radius of 3.4 nm. It was phosphorylated by cAMP-dependent protein kinase on a threonyl residue; this phosphorylation was necessary for inhibition of protein phosphatase-1. Bovine adipose tissue inhibitor-1 was compared directly with rabbit skeletal muscle inhibitor-1 and with a 32000-Mr, dopamine- and cAMP-regulated phosphoprotein from bovine brain (DARPP-32), also an inhibitor of protein phosphatase-1. By the following biochemical and immunochemical criteria, bovine adipose tissue inhibitor-1 was found to be very similar and possibly identical to DARPP-32 and was clearly distinct from skeletal muscle inhibitor-1: molecular mass by SDS/PAGE; Stokes' radii; phosphorylation on threonine residues; Staphylococcus-aureus-V8-protease-generated peptide patterns analyzed by SDS/PAGE; tryptic phosphopeptide maps analysed by two-dimensional thin-layer electrophoresis/chromatography; elution on reverse-phase HPLC; chymotryptic peptide maps as analysed by reverse-phase HPLC; amino acid composition; antibody recognition by immunoprecipitation and immunoblotting; effect of cyanogen bromide cleavage on protein phosphatase inhibitor activity. Based on these results we conclude that bovine brain and adipose tissue contain an identical phosphoprotein inhibitor of protein phosphatase-1 (DARPP-32), which is distinct from that of skeletal muscle (inhibitor-1).     

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.     

Identification of a third form of protein phosphatase 1 in rabbit skeletal muscle that is associated with myosin

A third form of protein phosphatase 1 has been identified in skeletal muscle which is distinct from the species composed of the catalytic subunit complexed to the glycogen-binding subunit (protein phosphatase 1G) or inhibitor-2 (protein phosphatase 1I). The third form has an apparent molecular mass of 110 kDa, is not immunoprecipitated by antibody prepared against the glycogen-binding subunit, does not interact with glycogen and is devoid of inhibitor-2. It is tightly bound to myosin and is therefore termed protein phosphatase 1M.     

The catalytic subunits of protein phosphatase-1 and protein phosphatase 2A are distinct gene products

Three forms of protein phosphatase-1 were isolated from rabbit skeletal muscle that had Mr values of 37 000, 34 000 and 33 000 determined by sodium dodecyl sulphate (SDS) gel electrophoresis. Each species dephosphorylated the beta-subunit of phosphorylase kinase very much faster than the alpha-subunit, was inhibited by inhibitors 1 and 2 with equal potency, and was converted to a form dependent on glycogen synthase kinase-3 and Mg-ATP for activity by incubation with inhibitor-2. Digestion with cyanogen bromide or Staphylococcus aureus proteinase followed by SDS gel electrophoresis showed a very similar pattern of cleavage products for all three forms. The Mr-37 000 and Mr-34 000 species were converted to the Mr-33 000 form by incubation with chymotrypsin. It is concluded that the Mr-33 000 and Mr-34 000 forms are derived from the Mr-37 000 component by limited proteolysis. Conversion of the Mr-37 000 to the Mr-33 000 form was accompanied by a two-fold increase in activity, indicating that an Mr-4000 fragment at one end of the polypeptide is an inhibitory domain that decreases enzyme activity. The catalytic subunit of protein phosphatase 2A from rabbit skeletal muscle had an Mr of 36 000 determined by SDS gel electrophoresis and its specific activity (3 kU/mg) was much lower than that of the Mr-37 000 (15-20 kU/mg) or Mr-33/34 000 (40-50 kU/mg) forms of protein phosphatase-1. It dephosphorylated the alpha-subunit of phosphorylase kinase 4-5-fold faster than the beta-subunit, was unaffected by inhibitor-1 or inhibitor-2, and preincubation with the latter protein did not result in the production of a glycogen synthase kinase-3 and Mg-ATP-dependent form of the enzyme. Digestion with chymotrypsin did not alter the electrophoretic mobility of protein phosphatase 2A under conditions that caused quantitative conversion of the Mr-37 000 form of protein phosphatase-1 to the Mr-33 000 species. Digestion with cyanogen bromide or S. aureus proteinase, followed by SDS gel electrophoresis, showed a quite different pattern of cleavage products to those observed with protein phosphatase 1. Antibody to protein phosphatase-2A raised in sheep did not cross-react with any of the forms of protein phosphatase-1, as judged by immunoelectrophoretic and immunotitration experiments. It is concluded that protein phosphatase-1 and protein phosphatase-2A are distinct gene products.     

Specificity of a protein phosphatase inhibitor from rabbit skeletal muscle.

A hear-stable protein, which is a specific inhibitor of protein phosphatase-III, was purified 700-fold from skeletal muscle by a procedure that involved heat-treatment at 95 degrees C, chromatography on DEAE-cellulose and gel filtration on Sephadex G-100. The final step completely resolved the protein phosphatase inhibitor from the protein inhibitor of cyclic AMP-dependent protein kinase. The phosphorylase phosphatase, beta-phosphorylase kinase phosphatase, glycogen synthase phosphatase-1 and glycogen synthase phosphatase-2 activities of protein phosphatase-III [Antoniw, J. F., Nimmo, H. G., Yeaman, S. J. & Cohen, P.(1977) Biochem.J. 162, 423-433] were inhibited in a very similar manner by the protein phosphatase inhibitor and at least 95% inhibition was observed at high concentrations of inhibitor. The two forms of protein phosphatase-III, termed IIIA and IIIB, were equally susceptible to the protein phosphatase inhibitor. The protein phosphatase inhibitor was at least 200 times less effective in inhibiting the activity of protein phosphatase-I and protein phosphatase-II. The high degree of specificity of the inhibitor for protein phosphatase-III was used to show that 90% of the phosphorylase phosphatase and glycogen synthase phosphatase activities measured in muscle extracts are catalysed by protein phosphatase-III. Protein phosphatase-III was tightly associated with the protein-glycogen complex that can be isolated from skeletal muscle, whereas the protein phosphatase inhibitor and protein phosphatase-II were not. The results provide further evidence that the enzyme that catalyses the dephosphorylation of the alpha-subunit of phosphorylase kinase (protein phosphatase-II) and the enzyme that catalyses the dephosphorylation of the beta-subunit of phosphorylase kinase (protein phosphatase-III) are distinct. The results suggest that the protein phosphatase inhibitor may be a useful probe for differentiating different classes of protein phosphatases in mammalian cells.     

Protein phosphatase activity is controlled by an inhibitor phosphoprotein in tick salivary glands

Protein phosphatase activity in tick salivary glands was inhibited by heat-stable protein(s) from tick salivary glands as well as by an inhibitor protein from rabbit skeletal muscle. Inhibitor activity was increased after phosphorylation of inhibitor proteins with the catalytic subunit (C) of cyclic AMP-dependent protein kinase and ATP. C inhibited protein phosphatase activity of the partially purified enzyme, while purified cyclic AMP-dependent protein kinase inhibitor protein prevented inhibition of tick salivary gland protein phosphatase by C suggesting that the inhibitor phosphoprotein coelutes with the partially purified enzyme. A soluble heat-stable protein with a molecular weight of approx. 26 kDa was phosphorylated by C, suggesting that a protein phosphatase inhibitor protein similar to inhibitor-1 in mammalian tissue, is present in tick salivary glands.     

Isolation and partial characterization of a protein with HMG-CoA reductase phosphatase activity associated with rat liver microsomal membranes.

Several rat liver HMG-CoA-reductase (HMG-CoA-Rd) phosphatase activities have been shown to be associated with the endoplasmic reticulum. These activities were not due to glycogen contamination, as judged not only from different patterns of solubilization of the microsomal membranes and the glycogen pellet but also by differential centrifugation behavior under standard conditions and in a sucrose gradient. We present evidence that at least three forms of protein phosphatase are associated with microsomal membranes: a polycation-stimulated type 2A phosphatase, a type 2C phosphatase, and a non-2A, non-2B, non-2C phosphatase. This last HMG-CoA-Rd phosphatase activity corresponding to an 85 kDa protein was partially purified by several chromatographic procedures. The IC50 value for the inhibition of the HMG-CoA-Rd phosphatase by I-2 was 10-fold higher than for the inhibition of the purified type 1 catalytic subunit from rabbit skeletal muscle. The microsomal HMG-CoA-Rd phosphatase activity was slightly affected by the protein inhibitor that inhibits type 2A activity when HMG-CoA reductase is the substrate. The HMG-CoA-Rd phosphatase activity is spontaneously active and it is not reactivated in the presence of Mg2+ or polycations. The holoenzyme does not contain the inhibitor-2 and it is not reactivated by incubation with ATP and glycogen synthase kinase-3. Proteolytic treatment of the enzyme yielded a polypeptide fragment of low Mr (37 kDa) with reduced activity. A model of holoenzymatic HMG-CoA-Rd phosphatase and its relation to the microsomal membranes is presented.     

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.     

Rabbit muscle glycogen-bound phosphoprotein phosphatases: substrate specificities and effects of inhibitor-1

A phosphoprotein phosphatase which has an apparent molecular weight of 240,000 was partially purified (500-fold) from the glycogen-protein complex of rabbit skeletal muscle. The enzyme exhibited broad substrate specificity as it dephosphorylated phosphorylase, phosphohistones, glycogen synthase, phosphorylase kinase, regulatory subunit of cAMP-dependent protein kinase, and phosphatase inhibitor 1. The phosphatase showed high specificity towards dephosphorylation of the beta-subunit of phosphorylase kinase and site 2 of glycogen synthase. With the latter substrate, the presence of phosphate in sites 1a and 1b decreased the apparent Vmax, perhaps by inhibiting the dephosphorylation of site 2. The phosphorylated form of inhibitor 1 did not significantly inhibit this high-molecular-weight phosphatase. However, an inhibitor 1-sensitive phosphatase activity could be derived from this preparation by limited trypsinization. Furthermore, greater than 70% of the phosphatase activity in skeletal muscle extracts and in the glycogen-protein complex was insensitive to inhibitor 1. Limited trypsinization of each fraction obtained from the phosphatase purification increased the total activity (1.5- to 2-fold) and converted the enzyme into a form which was inhibited by inhibitor 1. The results suggest that inhibitor 1-sensitive phosphatase may be a proteolyzed enzyme.     

Apparent activation of the MgATP-dependent protein phosphatase by pp60v-src. Identification of an activity like that of glycogen synthase kinase 3 in immunoaffinity purified pp60v-src preparations

Immunoaffinity purified pp60v-src was found to activate the MgATP-dependent protein phosphatase in the presence of MgATP. Although preliminary evidence suggested that phosphorylation of the inhibitor-2 subunit on tyrosine residues was responsible for the activation, preincubation of the pp60v-src preparation at 41 degrees C resulted in a rapid loss of its protein kinase activities towards both casein and inhibitor-2 while its ability to activate the protein phosphatase complex was relatively insensitive to this treatment. This result demonstrated that pp60v-src was not responsible for activation of the MgATP-dependent protein phosphatase. A protein kinase activity which phosphorylated glycogen synthase on serine residues was detected in the pp60v-src preparation. The protein kinase was active in the presence of inhibitors of phosphorylase kinase, glycogen synthase kinase 5/casein kinase II, and cAMP-dependent protein kinase. It is, therefore, likely that activation of the MgATP-dependent protein phosphatase resulted from the presence of a glycogen synthase kinase 3 like activity in the pp60v-src preparation. Our results illustrate the importance of applying multiple criteria to link the phosphorylation of a protein with an observed change in its activity.     

The control of protein phosphatase-1 by targetting subunits. The major myosin phosphatase in avian smooth muscle is a novel form of protein phosphatase-1.

The major protein phosphatase that dephosphorylates smooth-muscle myosin was purified from chicken gizzard myofibrils and shown to be composed of three subunits with apparent molecular masses of 130, 37 and 20 kDa, the most likely structure being a heterotrimer. The 37-kDa component was the catalytic subunit, while the 130-kDa and 20-kDa components formed a regulatory complex that enhanced catalytic subunit activity towards heavy meromyosin or the isolated myosin P light chain from smooth muscle and suppressed its activity towards phosphorylase, phosphorylase kinase and glycogen synthase. The catalytic subunit was identified as the beta isoform of protein phosphatase-1 (PP1) and the 130-kDa subunit as the PP1-binding component. The distinctive properties of smooth and skeletal muscle myosin phosphatases are explained by interaction of PP1 beta with different proteins and (in conjunction with earlier analysis of the glycogen-associated phosphatase) establish that the specificity and subcellular location of PP1 is determined by its interaction with a number of specific targetting subunits.     

Identification of a glycogen synthase phosphatase from yeast Saccharomyces cerevisiae as protein phosphatase 2A.

A glycogen synthase phosphatase was purified from the yeast Saccharomyces cerevisiae. The purified yeast phosphatase displayed one major protein band which coincided with phosphatase activity on nondenaturing polyacrylamide gel electrophoresis. This phosphatase had a molecular mass of about 160,000 Da determined by gel filtration and was comprised of three subunits, termed A, B, and C. The subunit molecular weights estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis were 60,000 (A), 53,000 (B), and 37,000 (C), indicating that this yeast glycogen synthase phosphatase is a heterotrimer. On ethanol treatment, the enzyme was dissociated to an active species with a molecular weight of 37,000 estimated by gel filtration. The yeast phosphatase dephosphorylated yeast glycogen synthase, rabbit muscle glycogen phosphorylase, casein, and the alpha subunit of rabbit muscle phosphorylase kinase, was not sensitive to heat-stable protein phosphatase inhibitor 2, and was inhibited 90% by 1 nM okadaic acid. Dephosphorylation of glycogen synthase, phosphorylase, and phosphorylase kinase by this yeast enzyme could be stimulated by histone H1 and polylysines. Divalent cations (Mg2+ and Ca2+) and chelators (EDTA and EGTA) had no effect on dephosphorylation of glycogen synthase or phosphorylase while Mn2+ stimulated enzyme activity by approximately 50%. The specific activity and kinetics for phosphorylase resembled those of mammalian phosphatase 2A. An antibody against a synthetic peptide corresponding to the carboxyl terminus of the catalytic subunit of rabbit skeletal muscle protein phosphatase 2A reacted with subunit C of purified yeast phosphatase on immunoblots, whereas the analogous peptide antibody against phosphatase 1 did not. These data show that this yeast glycogen synthase phosphatase has structural and catalytic similarity to protein phosphatase 2A found in mammalian tissues.     

Phosphorylase phosphatase from skeletal muscle membranes

Microsomes containing 12-15 U/mg phosphorylase phosphatase were obtained from skeletal muscle glycogen particles following glycogen digestion and differential centrifugation. The phosphatase associated with the membranes is in an inhibited state; dilution induces dissociation and deinhibition of the enzyme. Phosphatase-depleted membranes can rebind purified phosphatase catalytic subunit but not the complex between catalytic subunit and inhibitor 2. Binding involves a receptor, deduced from saturation phenomena, which is responsible for inhibition of the bound enzyme and which is a protein, since trypsin treatment releases all bound enzyme and prevents rebinding. The phosphatase extracted from the membranes is of type 1 and is a mixture of complexes, the major ones displaying a Mr of 300,000 and 70,000. From these complexes the 35-kDa catalytic subunit can be obtained either by trypsin treatment or by acetone precipitation. Purification to homogeneity involves chromatography on polylysine and FPLC chromatography on Mono Q and Polyanion SI columns. The purified enzyme exhibits a specific activity of 26,800 U/mg (27,900 U/mg after trypsin treatment) and consists of a major protein of 38 kDa (SDS gel electrophoresis). A minor component of 33 kDa, which may represent either a proteolytic product or an isozyme, can be separated. Both 38-kDa and 33-kDa catalytic subunits form a 70-kDa inactive complex with inhibitor 2 and upon incubation of the complexes the catalytic subunit is slowly converted to the inactive conformation which can then be reactivated by either the kinase FA or trypsin and Mn2+. Alternatively the inactive catalytic subunit is reactivated by Mn2+ alone once it has been isolated by FPLC chromatography on SI. The observation that the same catalytic subunit is present at various cell locations (namely cytosol, glycogen particles and microsomes), though in different conformations, is in favour of the hypothesis that displacement of the catalytic subunit from one cell site to the other may represent a new mechanism for phosphatase regulation in skeletal muscle.