A protein inhibitor of rabbit liver phosphorylase phosphatase.

Extracts of rabbit liver contain a heat-stable, non-dialysable inhibitor of phosphorylase phosphatase. The inhibitory activity is destroyed by trypsin treatment or by ethanol precipitation. The kinetics of the inhibition are non-competitive with respect to phosphorylase a. The inhibitory activity is polydisperse on gel permeation chromatography. The mechanism of the inhibition is due to a direct interaction of the protein inhibitor with the enzyme.     

The inhibitory effect of phosphorylase a on the activation of glycogen synthase depends on the type of synthase phosphatase.

The activity of glycogen synthase phosphatase in rat liver stems from the co-operation of two proteins, a cytosolic S-component and a glycogen-bound G-component. It is shown that both components possess synthase phosphatase activity. The G-component was partially purified from the enzyme-glycogen complex. Dissociative treatments, which increase the activity of phosphorylase phosphatase manyfold, substantially decrease the synthase phosphatase activity of the purified G-component. The specific inhibition of glycogen synthase phosphatase by phosphorylase a, originally observed in crude liver extracts, was investigated with purified liver synthase b and purified phosphorylase a. Synthase phosphatase is strongly inhibited, whether present in a dilute liver extract, in an isolated enzyme-glycogen complex, or as G-component purified therefrom. In contrast, the cytosolic S-component is insensitive to phosphorylase a. The activation of glycogen synthase in crude extracts of skeletal muscle is not affected by phosphorylase a from muscle or liver. Consequently we have studied the dephosphorylation of purified muscle glycogen synthase, previously phosphorylated with any of three protein kinases. Phosphorylase a strongly inhibits the dephosphorylation by the hepatic G-component, but not by the hepatic S-component or by a muscle extract. These observations show that the inhibitory effect of phosphorylase a on the activation of glycogen synthase depends on the type of synthase phosphatase.     

Regulation of synthase phosphatase and phosphorylase phosphatase in rat liver.

Using substrates purified from liver, the apparent Km values of synthase phosphatase ([UDPglucose--glycogen glucosyltransferase-D]phosphohydrolase, EC 3.1.3.42) and phosphorylase phosphatase (phosphorylase a phosphohydrolase, EC 3.1.3.17) were found to be 0.7 and 60 units/ml respectively. The maximal velocity of phosphorylase phosphatase was more than a 100 times that of synthase phosphatase. In adrenalectomized, fasted animals there was a complete loss of synthase phosphatase but only a slight decrease in phosphorylase phosphatase when activity was measured using endogenous substrates in a concentrated liver extract. When assayed under optimal conditions with purified substrates, both activities were present but had decreased to very low levels. Mixing experiments indicated that synthase D present in the extract of adrenalectomized fasted animals was altered such that it was no longer a substrate for synthase phosphatase from normal rats. Phosphorylase a substrate on the other hand was unaltered and readily converted. When glucose was given in vivo, no change in percent of synthase in the I form was seen in adrenalectomized rats but the percent of phosphorylase in the a form was reduced. Precipitation of protein from an extract of normal fed rats with ethanol produced a large activation of phosphorylase phosphatase activity with no corresponding increase in synthase phosphatase activity. Despite the low phosphorylase phosphatase present in extracts of adrenalectomized fasted animals, ethanol precipitation increased activity to the same high level as obtained in the normal fed rats. Synthase phosphatase and phosphorylase phosphatase activities were also decreased in normal fasted, diabetic fed and fasted, and adrenalectomized fed rats. Both enzymes recovered in the same manner temporally after oral glucose administration to adrenalectomized, fasted rats. These results suggest an integrated regulatory mechanism for the two phosphatase.     

Evidence for the non-identity of proteins having synthase phosphatase, phosphorylase phosphatase and histone phosphatase activity in rat liver.

Synthase phosphatase, phosphorylase phosphatase and histone phosphatase in rat liver were measured using as substrates purified liver synthase D, phosphorylase alpha and 32P-labelled phosphorylated f1 histone, respectively. The three phosphatase enzymes had different sedimentation characteristics. Both synthase phosphatase and phosphorylase phosphatase were found to sediment with the microsomal fraction under our experimental conditions. Only 10% of histone phosphatase was in this fraction; the majority was in the cytosol. No change in histone phosphatase was observed in the adrenalectomized fasted rat whereas synthase phosphatase and phosphorylase phosphatase activities were decreased 5-10 fold. Fractionation of liver extract with ethanol produced a dissociation of the three phosphatase activities. When a partially purified fraction was put on a DEAE-cellulose column, synthase phosphatase and phosphorylase phosphatase both exhibited broad elution profiles but their activity peaks did not coincide. Histone phosphatase eluted as a single discrete peak. When the supernatant of CaCl2-treated microsomal fraction was put on a Sepharose 4B column, the majority of synthase phosphatase was found to elute with the larger molecular weight proteins whereas the majority of phosphorylase phosphatase eluted with the smaller species. Histone phosphatase migrated as a single peak and was of intermediate size. Synthase phosphorylase phosphatase by synthase D (Ki approximately 2 units/ml). The inhibition of synthase phosphatase by phosphorylase alpha was kinetically non-competitive with substrate. Histone phosphatase activity was not inhibited by synthase D or by phosphorylase alpha. The above results suggest that different proteins are involved in the dephosphorylation of synthase D, phosphorylase alpha and histone in the cell.     

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.     

Control of rat skeletal-muscle phosphorylase phosphatase activity by adrenaline.

Administration of adrenaline to an isolated rat hindlimb preparation rapidly decreased muscle phosphorylase phosphatase (EC 3.1.3.17) activity and increased heat-stable and trypsin-labile phosphatase inhibitor activity. This was associated with increased tissue cyclic AMP concentrations, phosphorylase (EC 2.4.1.1) activation and glycogen synthase (EC 2.4.1.11) inactivation.     

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 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).     

Histone H1-stimulated phosphorylase phosphatase from rabbit skeletal muscle

A major rabbit skeletal muscle phosphorylase phosphatase activity which is markedly stimulated by histone H1 has been resolved from inhibitor-sensitive phosphorylase phosphatase (type-1 phosphatase), glycogen synthase kinase 3-activated phosphatase, phosphatase heat-stable inhibitor proteins, and alkaline phosphatase activity by various purification techniques. Evidence is presented that this phosphatase is a high-molecular weight form of a type-2 phosphatase. Our data suggest that this phosphatase may be regulated by histone H1, protamine or analogous polycationic compounds.     

Glycogen synthase phosphatase of rat liver. Its separation from phosphorylase phosphatase on DE-52 columns.

Glycogen synthase D was prepared from rat liver by chromatographing the glycogen pellet on DE-52 columns. It was free of glycogen and phosphorylase and converted readily into synthase I upon incubation with glycogen synthase phosphatase. With this synthase D as substrate, the identity of rat liver glycogen synthase phosphatase was studied by means of DE-52 column chromatography. Under the conditions developed, synthase phosphatase emerged from the columns as a sharp, single peak, and phosphorylase phosphatase came off later. The two phosphatases were also different from each other in stability, synthase phosphatase being less stable than phosphorylase phosphatase.     

Liver phosphorylase phosphatase

Summary Recent progress in studies on the properties and regulation of liver phosphorylase phosphatase can be divided into four stages. First, isolation from multiple molecular forms of phosphorylase phosphatase, of a single form of catalytic subunit (Mr = 32 000-35 000) which is active toward phosphorylase a and also toward a variety of protein substrates phosphorylated by either cyclic AMP-dependent protein kinase or other protein kinases. This was achieved by rather drastic procedures such as treatment with 80% ethanol at room temperature, incubation with 6 M urea, freeze-thawing in the presence of 0.2 M mercaptoethanol, or digestion by trypsin. These treatments caused concomitantly large enhancement of phosphorylase phosphatase activity, and the hypothesis was proposed that an inactive form of phosphorylase phosphatase existed as complexes of a catalytic subunit and inhibitory proteins. Second, it was discovered that liver and muscle extracts contain trypsin-labile proteins which, after heating at 90 °C, inhibited the catalytic subunit of phosphorylase phosphatase. Two types of protein inhibitors were identified: inhibitor-I was phosphorylated and activated by cyclic AMP-dependent protein kinase, whereas inhibitor-2 was not phosphorylated. Although inhibitor-1 has been implicated in hormonal regulation of glycogen metabolism in skeletal muscle, a similar role of protein inhibitors in the regulation of phosphorylase phosphatase in the liver has not been demonstrated and the physiological role of the inhibitor is questionable.Third, it has been demonstrated that liver phosphorylase phosphatase is reversibly inactivated and regulated by glutathione disulfide (GSSG) at the catalytic subunit level. Liver phosphorylase phosphatase contains, per mole of catalytic subunit, two sulfhydryl groups, one of which reacts with GSSG to form mixed disulfide with consequent inactivation of the enzyme. The inactivated enzyme can be reactivated by glutathione(GSH) or other sulfhydryl compounds through a reverse reaction. Injection of GSSG into the portal vein of rabbits caused a rapid increase in phosphorylase-a activity in the liver, suggesting that GSSG is involved in regulation of phosphorylase activity in vivo.Finally, current evidence suggests that liver phosphorylase phosphatase exists in the native state in a high molecular weight form which consists of the catalytic subunit and other regulatory subunits. One such enzyme species could be a 260 000-dalton protein composed of three different types of subunit, termed , and , or a 160 000-dalton protein composed of and subunits. The a subunit (Mr = 35 000) appears to be identical to the multifunctional catalytic subunit, whereas the (Mr = 69 000) and (Mr = 58 000) subunits are catalytically inactive but can modify the catalytic a subunit. It seems likely that the substrate specificity and catalytic activity of the subunit is considerably altered when it is part of larger complexes with other regulatory subunits ( and ). It has also been suggested that in addition to the native form of phosphorylase phosphatase, liver contains a considerably large amount of latent phosphorylase phosphatase, the catalytic activity of which could be revealed only by treatment with trypsin or ethanol.     

Purification and properties of a protein inhibitor that inhibits phosphatase 2A activity when hydroxymethylglutaryl coenzyme A reductase is the substrate

A heat-stable protein inhibitor of the hydroxymethylglutaryl-CoA reductase phosphatase 2A activity has been identified and purified to homogeneity, as judged by polyacrylamide gel electrophoresis. The apparent molecular mass was 20,000 Da. The protein lost its inhibitory properties when incubated with trypsin or treated with ethanol. The inhibitor protein does not inhibit type 1 phosphatase when either phosphorylase or hydroxymethylglutaryl-CoA reductase is the substrate. In contrast, this protein inhibitor inhibits the rat liver type 2A phosphatase activity when hydroxymethylglutaryl-CoA reductase is the substrate but not when phosphorylase a is the substrate. The inhibitor protein is not activated by incubation with ATP and cyclic AMP-dependent protein kinase and it is not phosphorylated by glycogen synthase kinase-3. These results, together with those of the kinetic experiments, suggest that the reductase phosphatase inhibitor is distinct from protein phosphatase inhibitor-1 and inhibitor-2.     

Multiple forms of synthase D phosphatase and phosphorylase a phosphatase in liver and regulatory effects of metabolites on their activities

The smooth endoplasmic reticulum (ER) and cytosol fractions of liver homogenates exhibit phosphoprotein phosphatase activity towards glycogen synthase D and phosphorylase a. The following observations suggest that liver contains multiple forms of these phosphatases. Synthase phosphatase activity in either fraction was more readily inactivated by heating than phosphorylase phosphatase activity. Both synthase phosphatase and phosphorylase phosphatase activities in smooth ER were non-competitively inhibited by Mg2+, but were activated by this ion in the cytosol. Synthase phosphatase activities in cytosol and smooth ER were stimulated by a number of sugar phosphates, particularly glucose-1-phosphate, galactose-6-phosphate and fructose-6-phosphate. Erythrose-4-phosphate stimulated synthase phosphatase activity in the cytosol, but inhibited the microsomal enzyme. Phosphorylase phosphatase activities in either fraction were inhibited by most sugar phosphates. Adenosine mono-, di- and tri-phosphates inhibited phosphatase activities in both fractions. Low concentrations of AMP and ADP inhibited phosphorylase phosphatase activities to a greater extent than synthase phosphatase activities. Chromatography of the smooth ER fraction on DEAE-cellulose resulted in the separation of synthase phosphatase from phosphorylase phosphatase, as soluble proteins. The elution profile for the microsomal phosphatase was different from that for the cytosol enzymes. It is concluded that: both synthase phosphatase and phosphorylase phosphatase in liver have at least two isoenzyme forms; synthase phosphatase and phosphorylase phosphatase are separate enzymes; the different behaviour of microsomal and cytosol phosphatases towards divalent cations and sugar phosphates provides a potential mechanism for the differential regulation of these activities in liver.     

Purification, properties, and substrate specificities of phosphoprotein phosphatase(s) from rabbit liver.

The phosphoprotein phosphatase(s) acting on muscle phosphorylase a was purified from rabbit liver by acid precipitation, high speed centrifugation, chromatography on DEAE-Sephadex A-50, Sephadex G-75, and Sepharose-histone. Enzyme activity was recovered in the final step as two distinct peaks tentatively referred to as phosphoprotein phosphatases I and II. Each phosphatase showed a single broad band when examined by sodium dodecyl sulfate gel electrophoresis; the molecular weights derived by this method were approximately 30,500 for phosphoprotein phosphatase I and 34,000 for phosphoprotein phosphatase II. The s20, w value for each enzyme was 3.40. Using this value and values for the Stokes radii, the molecular weight for each enzyme was calculated to be 34,500. Both phosphatases, in addition to catalyzing the conversion of phosphorylase a to b, also catalyzed the dephosphorylation of glycogen synthase D, activated phosphorylase kinase, phosphorylated histone, phosphorylated casein, and the phosphorylated inhibitory component of troponin (TN-I). The relative activities of the phosphatases with respect to phosphorylase a, glycogen synthase D, histone, and casein remained essentially constant throughout the purification. The activities of both phosphatases with different substrates decreased in parallel when they were denatured by incubation at 55 degrees and 65 degrees. The Km values of phosphoprotein phosphatase I for phosphorylase a, histone, and casein were lower than the values obtained for phosphoprotein phosphatase II. With glycogen synthase D as substrate, each enzyme gave essentially the same Km value. Utilizing either enzyme, it was found that activity toward a given substrate was inhibited competitively by each of the alternative substrates. The results suggest that phosphoprotein phosphatases I and II are each active toward all of the substrates tested.     

High-affinity binding of glycogen-synthase phosphatase to glycogen particles in the liver. Role of glycogen in the inhibition of synthase phosphatase by phosphorylase a.

1. Post-mitochondrial supernatants were prepared from the livers of 24 h-fasted rats. Upon centrifugation at high speed, the major part of the glycogen-synthase phosphatase activity sedimented with the microsomal fraction. However, two approaches showed that the enzyme was associated with residual glycogen rather than with vesicles of the endoplasmic reticulum. Indeed, the activity was entirely solubilized when the remaining glycogen was degraded either by glucagon treatment in vivo or by alpha-amylolysis in vitro. No evidence could be found for an association of glycogen-synthase phosphatase with the smooth endoplasmic reticulum, as isolated with the use of discontinuous sucrose gradients. 2. After solubilization by glucagon treatment in vivo, synthase phosphatase could be transferred to glycogen particles with very high affinity. Half-maximal binding occurred at a glycogen concentration of about 0.25 mg/ml, whereas glycogen synthase and phosphorylase required 1.5-2 mg/ml. 3. In gel-filtered extracts prepared from glycogen-depleted livers, the activation of glycogen synthase was not inhibited at all by phosphorylase alpha. The inhibition was restored when the liver homogenates were prepared in a glycogen-containing buffer. The effect was half-maximal at a glycogen concentration of about 0.25 mg/ml, and virtually complete at 1 mg/ml. These findings explain long-standing observations that in fasted animals the liver contains appreciable amounts of both synthase and phosphorylase in the active form.     

Evidence for the coordinate control of activity of liver glycogen synthase and phosphorylase by a single protein phosphatase.

Homogeneous rabbit liver phosphorylase phosphatase (Brandt, H., Capulong, Z. L., and Lee, E. Y. C. (1975) J. Biol. Chem. 250, 8038-8044) also dephosphorylates glycogen synthase b. During purification, phosphorylase phosphatase and glycogen synthase phosphatase co-purified with a constant ratio of activities. The two activities co-migrated on disc gel electrophoresis. Both substrates competed with each other for the phosphatase, and both phosphatase activities were inhibited by lysine ethyl ester. It is concluded that liver phosphorylase phosphatase and glycogen synthase phosphatase have a common identity and that coordinate regulation of the phosphatase-catalyzed activation of glycogen synthase and inactivation of phosphorylase occurs in vivo. This provides a parallel and opposing mechanism to that mediated by adenosine 3':5'-monophosphate-dependent protein kinase, which coordinately inactivates glycogen synthase and, via phosphorylase kinase, activates phosphorylase. Maximal glycogen synthase phosphatase activity was observed near neutrality. Mg2+ and glucose-6-P activated the glycogen synthase phosphatase reaction and this activation was pH-dependent. The Km for glycogen synthase b was 0.12 muM.     

Chromatographic characteristics and subcellular localization of synthase phosphatase,phosphorylase phosphatase and histone phosphatase in human polymorphonuclear leukocytes

Summary Synthase phosphatase, phosphorylase phosphatase and histone phosphatase activity in a leukocyte homogenate were found to have different sedimentation charcteristics: both synthase phosphatase and phosphorylase phosphatase activity are associated with the microsomal fraction, while the majority of histone phosphatase activity (75–85%) was found in the cytosol. Synthase phosphatase, phosphorylase phosphatase and histone phosphatase activities accompanying the microsomal fraction are readily solubilized by 0.3% Triton X-100.When the solubilized microsomal enzymes were chromatographed on Sephadex G-200, the majority of synthase phosphatase, phosphorylase phosphatase and histone phosphatase activity migrated in single peaks corresponding to apparent molecular weights of 380 000, 250 000 and 68 000, respectively. A minor peak of 30 000, which had phosphatase activity against all three substrates was also obtained.Ethanol treatment resulted in solubilization and dissociation of the three phosphatase activities. It was found that although ethanol treatment resulted in a 4-fold increase of phosphorylase phosphatase activity, histone phosphatase activity was decreased (by 60%), while synthase phosphatase activity remained stable. Similar results were obtained when ethanol treatment was performed on the 17 000 × g supernatant.Chromatography of the ethanol-treated microsomes (or homogenate) on Sephadex G-200 showed that the phosphatase activity towards synthase D, phosphorylase a and phosphohistone coincided a M_r 30 000 species. Heat treatment of the M_r 30 000 peak resulted in dissociation of synthase phosphatase and phosphorylase phosphatase activity.Synthase phosphatase was inhibited by phosphorylase a in a kinetically non-competitive manner while histone phosphatase activity was notinhibited by synthase D (8.5 unit/ ml) orby phosphorylase a(12 unit/ ml).     

Multiple molecular forms of phosphorylase phosphatase associated with particulate glycogen and extracted from the cytosol of dog liver.

The glycogen pellet of dog liver extracts contains a phosphorylase phosphatase which has characteristics different from those of the phosphatases extracted from the cytosol. The phosphatase associated with glycogen is characterized by a M, of 51,000, a half maximal inhibition at 0.3 mM ATP (Hill coefficient : 2) and a Ki for Mg2+ of 1 mM. Treatment with urea or mercaptoethanol of the phosphatase associated with glycogen does not influence the activity, the Mr or the half maximal inhibition by ATP, but a decrease of the Hill coefficient for ATP is observed. A similar treatment of the phosphatases extracted from the high speed supernatant results in a decrease of the Mr of the spontaneously active form from 215,000 to 43,000, without an effect on the Ki for ATP (7 micronM), but accompanied by an increase in activity. The ATP-Mg dependent form of the phosphatase from the high speed supernatant (Mr : 138,000 ; Ka for ATP in the presence of 0.1 mM Mg2+ : 0.3 micronM), is denatured by urea or mercaptoethanol. The phosphatase associated with particulate glycogen cannot be found in the supernatant, nor the phosphorylase phosphatases present in the supernatant in the glycogen pellet. When all the glycogen is mobilized (starvation, glucagon) the phosphatase specifically associated with glycogen cannot be found as such in the cytosol. No activation of synthase beta can be detected neither with the phosphatases extracted from the cytosol nor with the enzyme released from the glycogen pellet.     

Liver protein phosphatases: studies of the presumptive native forms of phosphorylase phosphatase activity in liver extracts and their dissociation to a catalytic subunit of Mr 35,000.

Several aspects of the properties of phosphorylase phosphatase in crude rat liver extracts were investigated. Treatment of tissue extracts with either trypsin, ethanol, or urea was found to dissociate phosphorylase phosphatase activity to a form of M_r 35,000. The M_r 35,000 enzyme form was derived from three native enzyme forms. The major cytosolic form of phosphorylase phosphatase had a molecular weight of 260,000 as determined by gel filtration and was dissociated to a M_r 35,000 form by treatment with either ethanol or urea. Treatment of the M_r 260,000 form with trypsin led to its conversion to M_r 225,000 and a M_r 35,000 form. A minor cytosolic form of M_r 200,000 was also present. This minor activity was latent until activated by trypsin treatment and was converted to a M_r 35,000 form by such treatment. The third form was found to chromatograph as a form of molecular weight greater than 500,000 on gel filtration and, like the M_r 200,000 form, was only detected after activation with trypsin. Subsequent to this treatment, it too behaved as a M_r 35,000 enzyme. Although a single major enzyme form was present in the cytosol, multiple molecular weight forms could be generated in crude extracts simply by the use of vigorous mechanical homogenization procedures. This suggested that artifactual forms of enzyme may readily be produced, possibly by proteolytic cleavage of the native enzyme.