Lack of Types 1 and 2A Protein Serine(P)/Threonine(P) Phosphatase Activities in Chloroplasts

Protein phosphatase activity in crude leaf extracts and in purified intact chloroplasts of wheat (Triticum aestivum) and pea (Pisum sativum) was analyzed using exogenously supplied phosphoproteins or endogenous thylakoid proteins. Leaf extracts contain readily detectable amounts of protein phosphatase activity measured with either phosphohistone or phosphorylase a, substrates of mammalian protein phosphatases. No significant chloroplast protein phosphatase activity was detected using these exogenous phosphoproteins. The dephosphorylation of endogenous thylakoid light-harvesting chlorophyll a/b binding proteins in situ was inhibited by fluoride, but not by microcystin-LR or okadaic acid, diagnostic inhibitors of mammalian types 1 and 2A protein phosphatases. Additionally, no evidence for a pea chloroplast alkaline phosphatase activity was found using β-glycerolphosphate or 4-methylum-belliferyl phosphate as substrates. From these results, we conclude that phosphohistone and phosphorylase a are not useful substrates for chloroplast thylakoid protein phosphatase activity and that the chloroplast enzymes may not fit into one of the canonical classifications currently used for protein phosphatases.     

Modulation of rat liver hydroxymethylglutaryl-CoA reductase by protein phosphatases: purification of nonspecific hydroxymethylglutaryl-CoA reductase phosphatases

Four phosphoprotein phosphatases, with the ability to act upon hydroxymethylglutaryl (HMG)-CoA reductase, phosphorylase, and glycogen synthase have been purified from rat liver cytosol through a process that involves DEAE-cellulose, aminohexyl-Sepharose-4B, and Bio-Gel A 1.5 m chromatographies. Protein phosphatase II (Mr 180,000) was the major enzyme (68%) with a very broad substrate specificity, showing similar activity toward the three substrates. Phosphatases I1 (Mr 180,000) and I3 (Mr 250,000) accounted for only 12 and 15% of the total activity, respectively, and they were also able to dephosphorylate the three substrates. In contrast, phosphatase I2 (Mr 200,000) showed only phosphorylase phosphatase activity with insignificant dephosphorylating capacity toward HMG-CoA reductase and glycogen synthase. Upon ethanol treatment at room temperature, the Mr of all phosphatases changed; protein phosphatases I2, I3, and II were brought to an Mr of 35,000, while phosphatase I1 was reduced to an Mr of 69,000. Glycogen synthase phosphatase activity was decreased in all four phosphatases. There was also a decrease in phosphatase I1 activity toward HMG-CoA reductase and phosphorylase as substrates. The HMG-CoA reductase phosphatase and phosphorylase phosphatase activities of phosphatases I2, I3, and II were increased after ethanol treatment. Each protein phosphatase showed a different optimum pH, which changed depending on the substrate. The four phosphatases increased their activity in the presence of Mn2+ and Mg2+. In general, Mn2+ was a better activator than Mg2+, and phosphatase I1 showed a stronger dependency on these cations than any other phosphatase. Phosphorylase was a competitive substrate in the HMG-CoA reductase phosphatase and glycogen synthase phosphatase reactions of protein phosphatases I1, I3, and II. HMG-CoA reductase was also able to compete with phosphorylase and glycogen synthase for phosphatase activity. Glycogen synthase phosphatase activity presented less inhibition in the low-Mr forms. A comparison has been made with other protein phosphatases previously reported in the literature.     

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.     

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).     

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.     

Long term regulation of glycogen metabolizing enzymes by insulin in H4 hepatoma cells

Insulin alone at concentrations of less than 1 to 5 uU/ml increased the enzyme activities of glycogen synthase, synthase phosphatase, phosphorylase, and phosphorylase phosphatase in hepatoma H4 cells in culture in the presence and absence of serum. Increase in total and active forms of glycogen synthase and phosphorylase were observed. Cycloheximide blocked the action of insulin on glycogen synthase, glycogen synthase phosphatase and phosphorylase phosphatase. The enzymes with the exception of glycogen synthase phosphatase were expressed with greater hormonal sensitivity in the absence as compared to the presence of serum in terms of hormone concentration required and or time of onset.These results demonstrate that these glycogen metabolizing enzymes are under long term control by insulin, with glycogen synthase being the most sensitive of the enzymes studied to the action of the hormone.Supported by grants from NIH AM 14334 and AM 22125 (University of Virginia Diabetes Research and Training Center) and by a grant from Lilly Research Lab, and the March of Dimes     

Separation and identification of type 1 and type 2 protein phosphatases from rabbit reticulocyte lysates

Protein phosphatase type 1 and type 2 activities (designated PP-1 and PP-2, respectively) from rabbit reticulocyte lysates have been identified and characterized based on criteria previously established for similar activities in rabbit skeletal muscle and rabbit liver. These include (a) chromatographic separation on DEAE-cellulose, (b) substrate specificity toward glycogen phosphorylase a and the alpha- and beta-subunits of phosphorylase kinase, (c) differential sensitivity to the heat-stable protein phosphatase inhibitors-1 and -2, and (d) sensitivity to MgATP. When total lysate phosphatases are assayed in the presence of 1 mM MnCl2, protein phosphatase type 2 represents 84% of lysate phosphorylase phosphatase activity. However, when phosphatase assays are carried out with MgATP concentrations similar to those in the lysate, type 2 activity is diminished, and the levels of type 1 (41%) and type 2 (59%) phosphatase activities are comparable. A small proportion (6%) of total lysate phosphatase is tightly bound to the ribosomes, where type 1 phosphatase predominates. At least five species of protein phosphatases can be identified in lysates. These constitute two forms of protein phosphatase type 1, one of which (designated FC) is dependent on MgATP and a lysate activator protein FA; both FC and FA have been identified previously in skeletal muscle. Three species of protein phosphatase type 2 have been identified and designated PP-2B, PP-2A1, and PP-2A2 based on criteria recently established for rabbit skeletal muscle and rabbit liver phosphatases, which display similar phosphatase profiles. Lysate protein phosphatases types 1, FC, 2A1, and 2A2 can all act on phosphorylase a and the alpha- (type 2) or beta-(type 1) subunit of phosphorylase kinase. PP-2B, a Ca2+/calmodulin-dependent phosphatase, specifically dephosphorylates the alpha-subunit of phosphorylase kinase, but does not act on phosphorylase alpha. The heat-stable protein phosphatase inhibitor-2 from skeletal muscle completely blocks the activity of the two type 1 phosphatases (PP-1, FC), but has no effect on the three species of type 2 protein phosphatase. A preliminary assay of the two heat-stable phosphatase inhibitors in lysates indicates significant levels of inhibitor-2, but little or no detectable inhibitor-1.     

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).     

Distinction between substrate- and enzyme-directed effects of modifiers of rabbit liver phosphorylase a phosphatases

The natural substrate (phosphorylase a) and two alternative ones (phosphorylated histone and a tetradecapeptide consisting of residues 5-18 of rabbit skeletal muscle phosphorylase a) were used to distinguish the modes of action of some physiologically important effectors of four different molecular forms of rabbit liver phosphorlase a phosphatases. In general, glucose, caffeine, AMP, ADP, Pi, and glucose-1-P showed substrate-directed effects for the holophosphatase forms, since they usually did not affect the activity on histone phosphate and, with one slight exception (Pi), never affected the activity on the tetradecapeptide phosphate. ADP, Pi, and glucose-1-P did affect directly the relative mass (Mr) 35,000 phosphatase, in addition to an inhibition mediated via phosphorylase a. ATP exerted both substrate- and enzyme-directed effects for the Mr 35,000 phosphatase and phosphatases 1 and 2A2, but only a substrate-directed effect for phosphatase 2A1, suggesting that the gamma-subunit of the type 2 phosphatases may prevent ATP binding to the phosphatase. Mg2+ showed substrate-directed effects for phosphatases 1, 2A1, and 2A2, and an additional enzyme-directed effect for the Mr 35,000 phosphatase form. Furthermore, Mg2+ could not abolish ATP inhibition of the tetradecapeptide phosphatase activity, but significantly overcame ATP inhibition of the phosphorylase a phosphatase activity, thus suggesting that its ability to reverse the ATP effect is by a substrate-directed mechanism. The substrate-directed effects seen for the different ligands on the different phosphatase forms strongly indicate the significance of this form of control in the regulation of phosphorylase a phosphatase activities and may serve to narrow the otherwise broad substrate specificities of the major phosphorylase a phosphatase activities in mammalian tissues: phosphatases 1 and 2A.     

Identification of the phosphatase deinhibitor protein phosphatases in rabbit skeletal muscle.

In rabbit skeletal muscle the polycation-stimulated (PCS) protein phosphatases [Merlevede (1985) Adv. Protein Phosphatases 1, 1-18] are the only phosphatases displaying significant activity toward the deinhibitor protein. Among them, the PCSH protein phosphatase represents more than 80% of the measurable deinhibitor phosphatase activity associated with the PCS phosphatases. The deinhibitor phosphatase activity co-purifies with the PCSH phosphatase to apparent homogeneity. In the last purification step two forms of PCSH phosphatase were separated (PCSH1, containing 62, 55 and 34 kDa subunits, and PCSH2, containing 62 and 35 kDa subunits), both showing the same deinhibitor/phosphorylase phosphatase activity ratio. The activity of the PCSH phosphatase toward the deinhibitor is not stimulated by polycations such as protamine, histone H1 or polylysine, unlike the stimulation observed with phosphorylase as the substrate. The phosphorylase phosphatase activity of PCSH phosphatase is inhibited by ATP, PPi and Pi, whereas the deinhibitor phosphatase activity of the enzyme is much less sensitive to these agents.     

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.     

Rat liver glycogen metabolism in the perinatal period

The correlation between blood glucose levels, the concentration of glycogen, the activities of glycogen sythase and phosphorylase and their respective kinases and phosphatases was examined in liver of rat fetuses between day 18 of gestation and one day after birth. Between day 18 and 21 there is a rapid increase in the concentration of glycogen and in the activity of synthase a and a much slower increase in the activity of phosphorylase a. The activity of the respective kinases increased rapidly during this period and reached maximun on day 21. The activity of synthase phosphatase and phosphorylase phosphatase increased after day 18, to reach a maximum on day 19 and 20, respectively, but decreased again towards day 21. The possibility that the changes in glycogen concentration and enzyme activities were related to an effect of glucose of AMP on the respective phosphatases was considered. It was found that the Km of phosphatase for glucose in the prenatal period was 5–7 mM, as in the adult. Since the level of blood glucose during this period was constant (2.8 mM), an effect of glucose on phosphatase activity seems unlikely. AMP concentration increased between day 18 and 21 from 6–15 nmol/g. In view of the low level of phosphorylase a activity during this period, the increase in AMP concentration is not considered to be important in the regulation of glycogen breakdown at this time.Immediately after birth blood glucose levels dropped to 5 mg/dl. This was accompanied by a rapid decrease in glycogen concentration and in the activity of glycogen synthase and a rise in phosphorylase activity. Blood glucose levels returned to the initial level within 1 h after birth, whereas the changes in glycogen concentration and enzyme activities continued for at least 3 h after birth. On day 22 all parameters examined had reached the level found in adult rat liver.It is suggested that the rapid changes observed immediately after birth are due to an effect of hypoglycemia mediated by hormones and cannot be ascribed to direct effects of metabolites on the enzyme systems involved.     

Isolation and characterisation of an acid phosphatase interfering with phosphorylase determinations in crude extracts from yeast

In phosphorylase assays in crude yeast extracts with glucose-1-phosphate (G-1-P) as substrate, 25–30% of the P_i-liberating activity could not be inhibited by antibodies against yeast phosphorylase and were attributed to the action of phosphatases. During phosphorylase preparation from baker's yeast (Saccharomyces cerevisiae), a phosphatase, molecular weight 45000±5000, with high specificity for G-1-P, pH-optimum 5.6, was isolated which appeared to be responsible for the interference. It did not hydrolyze other glycolytic intermediates, pyrophosphate or adenylates. No activation by Mg²⁺ or inhibition by (+)-tartrate, and only 40% inhibition by 50 mM F^- were observed, 5,5 dithiobis-(nitrobenzoic acid) (10mM) inactivated the enzyme completely. Its affinity for G-1-P was very low (K _m=40 mM). Consequently, it mainly interfered with the phosphorylase assay in the amylose synthesizing reaction, in which high G-1-P-concentrations have to be used. For phosphorylase assays in crude extracts, measurement of the phosphorolytic activity is recommended, in which the concentration of G-1-P is kept sufficiently low.Abbreviations G-1-P Glucose-1-phosphate - (NbS)₂ 5,5 dithiobis-(2-nitrobenzoic acid) - SDS Sodium dodecylsulfate     

Purification and properties of polycation-stimulated phosphorylase phosphatases from rabbit skeletal muscle

Four types of polycation-stimulated (PCS) phosphorylase phosphatases have been isolated from rabbit skeletal muscle. They are called PCSH (390 kDa), PCSM (250 kDa), and PCSL (200 kDa) phosphatase according to the apparent molecular weight of the native enzymes in gel filtration. Two forms of PCSH phosphatase could be separated by Mono Q fast protein liquid chromatography: PCSH1 and PCSH2. In the absence of polycations, the specific activities of the PCSH1, PCSH2, PCSM, and PCSL phosphatase were 400, 680, 600, and 3000 units/mg, respectively, using phosphorylase a as a substrate. They all contain a 62-65- and a 35-kDa subunit, the latter being the catalytic subunit. In addition PCSH1 phosphatase contains a 55-kDa subunit and the PCSM phosphatase a 72-75-kDa subunit in a substoichiometric ratio. All the PCS phosphatases are insensitive to Ca2+ calmodulin, inhibitor-1, and modulator protein. They display a high specificity for the alpha-subunit of phosphorylase kinase and a broad substrate specificity. The PCSH1 and PCSH2 phosphatases, but not the catalytic subunit (PCSC phosphatase), show a high degree of specificity for the deinhibitor protein. During the purification the phosphorylase to inhibitor-1 phosphatase activity ratio (10:1) remained constant for the PCSH and PCSL enzymes but decreased for the PCSM phosphatase. The stimulation observed with low concentrations of polycations is enzyme directed. The different enzyme forms show a characteristic concentration optimum and degree of stimulation. At higher concentrations, polycations become inhibitory and a time-dependent deactivation of the phosphatases is observed.     

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.     

Isolation and expression of a maize type 1 protein phosphatase

The dephosphorylation of phosphoproteins by protein phosphatases represents an important mechanism for regulating specific cellular processes in eukaryotic cells. The aim of the present study was to examine the structural and biochemical characteristics of a specific class of protein Ser/Thr phosphatases (type 1 protein phosphatases) which have received very little attention in higher plants. A cDNA clone (ZmPP1) was isolated from a maize (Zea mays L.) cDNA library. The deduced amino acid sequence is 80% identical with a 292-amino acid core region of rabbit and yeast type 1 protein phosphatase catalytic subunit. Southern blot analysis indicates that ZmPP1 may belong to a family of related genes in maize. ZmPP1 RNA was present in all maize tissues examined, indicating that it may play a fundamental role in cellular homeostasis. To demonstrate that ZmPP1 encodes an active protein phosphatase and, in an effort to characterize this gene product biochemically, high levels of ZmPP1 were expressed in Escherichia coli. Active ZmPP1 enzyme dephosphorylates rabbit phosphorylase a and is strongly inhibited by okadaic acid and by the mammalian inhibitor-2. These data show that ZmPP1 is structurally and biochemically very similar to the corresponding enzyme in animal cells. These results also suggest that the function and regulation of the higher plant type 1 protein phosphatases may be similar to the mammalian protein phosphatases.     

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.     

Adenosine 5'-O(3-thiotriphosphate) in the control of phosphorylase activity

Rabbit muscle phosphorylase b (EC 2.4.1.1) is converted to a thio-analog of phosphorylase a by phosphorylase kinase, Mg²⁺ and adenosine 5′-O(3-thiotriphosphate)(ATPγS). Conversion proceeds at one-fifth the rate obtained with ATP though the extent of reaction and final level of activation of the enzyme are the same. However, the thiophosphorylase a produced is resistant to phosphorylase phosphatase and, therefore, behaves as a competitive inhibitor with a K_I of 3 μM, similar to the K_M obtained with normal phosphorylase a. ATPγS can also be utilized by protein kinase in the activation of phosphorylase kinase at a rate similar to that obtained with ATP. It is hydrolyzed at 5 to 10 times the normal rate by the sarcoplasmic reticulum ATPase. When added to a muscle glycogen-particulate complex in the presence of Ca²⁺ and Mg²⁺, ATPγS triggers an activation of phosphorylase with simultaneous inhibition of phosphorylase phosphatase as previously observed with ATP.     

Fluorescence labelling of phosphatase activity in digestive glands of carnivorous plants

Abstract: A new ELF (enzyme labelled fluorescence) assay was applied to detect phosphatase activity in glandular structures of 47 carnivorous plant species, especially Lentibulariaceae, in order to understand their digestive activities. We address the following questions: (1) Are phosphatases produced by the plants and/or by inhabitants of the traps? (2) Which type of hairs/glands is involved in the production of phosphatases? (3) Is this phosphatase production a common feature among carnivorous plants or is it restricted to evolutionarily advanced species? Our results showed activity of the phosphatases in glandular structures of the majority of the plants tested, both from the greenhouse and from sterile culture. In addition, extracellular phosphatases can also be produced by trap inhabitants. In Utricularia, activity of phosphatase was detected in internal glands of 27 species from both primitive and advanced sections and different ecological groups. Further positive reactions were found in Genlisea, Pinguicula, Aldrovanda, Dionaea, Drosera, Drosophyllum, Nepenthes, and Cephalotus. In Utricularia and Genlisea, enzymatic secretion was independent of stimulation by prey. Byblis and Roridula are usually considered as “proto‐carnivores”, lacking digestive enzymes. However, we found high activity of phosphatases in both species. Thus, they should be classified as true carnivores. We suggest that the inflorescence of Byblis and some Pinguicula species might also be an additional “carnivorous organ”, which can trap a prey, digest it, and finally absorb available nutrients.     

Separation of rabbit liver latent and spontaneously active phosphorylase phosphatases by chromatography on heparin-sepharose

Latent and spontaneously active forms of phosphorylase phosphatase were separated by heparin-Sepharose chromatography of rabbit liver extract. The latent enzyme had an absolute polycation (histone H1, polybrene) requirement for the activity assayed with phosphorylase a and phosphorylase kinase substrates. Ethanol treatment resulted in the activation of both phosphatases by dissociating of 150-180 kDa holoenzymes to 33-38 kDa catalytic subunits as judged by gel filtration. The latent and spontaneously active phosphatases were differentiated according to their abilities to dephosphorylate the alpha and the beta subunits of phosphorylase kinase and sensitivities to inhibition by inhibitor-2 or heparin, and were classified as type-2A and type-1 phosphatases, respectively.