Multiple molecular forms of phosphoprotein phosphatase. III. Phosphorylase phosphatase and phosphohistone phosphatase of rabbit liver.

1. Phosphoprotein phosphatase (phosphoprotein phosphohydrolase EC 3.1.3.16) in the soluble fraction of rabbit liver which catalyzes the dephosphorylation of muscle phosphorylase a and phosphohistone (P-histone) was resolved into three active fractions by NaCl gradient elution from a DEAE-cellulose column (Fraction I, 11 and III in order of elution). They have different relative reaction rates for the two substrates and different degrees of stimulation by Mn-2+. Apparent Km values of Fraction I, II and III were 15, 20 and 16 muM for phosphorylase a, and 6.9, 5.3 and 4.4 muM for P-histone, respectively (with Mn-2+ in the assay mixture). 2. On sucrose density gradient centrifugation Fraction I and II were revealed to contain a major peak (7.0 S and 7.8 S, respectively) and a minor peak (4.0 S) of activity, while Fraction III contained only one peak (5.8 S). Freezing and thawing in the presence of 0.2 M mercaptoethanol dissociated all three fractions into subunits of similar molecular size (3.4 S), with concomitant enhancement of phosphorylase phosphatase activity. The Km values all became essentially the same (20 muM for phosphorylase a and 16 muM for P-histone). 3. The phosphorylase phosphatase and P-histone phosphatase activities could not be separated with any of the procedures described. Competition between the two phosphoprotein substrates was observed with some of the fractions.?     

Myosin light-chain phosphatase.

1. A method for the isolation of a new enzyme, myosin light-chain phosphatase, from rabbit white skeletal muscle by using a Sepharose-phosphorylated myosin light-chain affinity column is described. 2. The enzyme migrated as a single component on electrophoresis in sodium dodecyl sulphate/polyacrylamide gel at pH7.0, with apparent mol.wt. 70000. 3. The enzyme was highly specific for the phosphorylated P-light chain of myosin, had pH optima at 6.5 and 8.0 and was not inhibited by NaF. 4. A Ca2+-sensitive 'ATPase' (adenosine triphosphatase) system consisting of myosin light-chain kinase, myosin light-chain phosphatase and the P-light chain is described. 5. Evidence is presented for a phosphoryl exchange between Pi, phosphorylated P-light chain and myosin light-chain phosphatase. 6. Heavy meromyosin prepared by chymotryptic digestion can be phosphorylated by myosin light-chain kinase. 7. The ATPase activities of myosin and heavy meromyosin, in the presence and absence of F-actin, were not significantly changed (+/- 10%) by phosphorylation of the P-light chain.     

Native and latent forms of liver phosphorylase phosphatase. The non-identity of native phosphorylase phosphatase and synthase phosphatase.

The directly measurable (native) phosphorylase phosphatase present in a fresh mouse liver extract is bound to particulate glycogen and is not inhibited by heat-stable inhibitors. Treatment of the extract with trypsin or ethanol at room temperature caused a more than 10-fold increase in phosphorylase phosphatase activity. This increased activity stems from the activation of completely inactive (latent) enzyme, the major part of which is present in the high-speed supernatant. The trypsin-revealed activity can be completely blocked by heat-stable inhibitors. Treatment of the animal with glucocorticoids increases, and fasting decreases the activity of the native phosphorylase phosphatase. The level of latent enzyme, however, is unaffected by these treatments. The major portion of synthase phosphatase in the fresh liver extract is bound to glycogen. This enzyme is inhibited by the heat-stable inhibitor-2 and inactivated by trypsin or ethanol as well as by several treatments that have little effect on phosphorylase phosphatase. Upon DEAE-cellulose chromatography at 0 degrees C of a fresh liver extract, phosphorylase phosphatase and synthase phosphatase were resolved as separate, single peaks. If the preparation was not kept at 0 degrees C during the entire procedure, two peaks of each enzyme were observed. Under these conditions the first peak of phosphorylase phosphatase and of synthase phosphatase coincided. From these findings it is concluded that synthase phosphatase and phosphorylase phosphatase, in their native form, are distinct enzymes.     

Phosphoprotein phosphatase associated with rat liver plasma membrane. Properties of phosphorylase phosphatase and phosphohistone phosphatase

Plasma membrane isolated from rat liver contained activities of phosphoprotein phosphatase dephosphorylating [32P]phosphorylase a or [32P]phosphohistone. The properties of the membrane-bound phosphatase were examined using these exogenous substrates. The optimal reaction rate was at pH near neutrality. At concentrations as low as 0.1-1.0 mM, Mg2+ or Mn2+ slightly stimulated the activity for phosphorylase a or phosphohistone, respectively; at higher concentrations, they were inhibitory with both substrates. Co2+ was inhibitory with both substrates, while Ca2+ had no significant effect. The phosphatase activities were inhibited by ATP, ADP, or AMP; the extents of inhibition were in opposite order with the two substrates. Phosphorylase phosphatase activity was strongly inhibited by KF or Pi. Phosphorylase phosphatase activity could be completely solubilized by incubating the membrane with 0.5 M NaCl or trypsin, and this was associated with several-fold activation. While Vmax values were increased, Km values for phosphorylase a were not much affected by these treatments. Unlike the soluble phosphatase, freezing in the presence of mercaptoethanol or by precipitation with ethanol failed to activate or to solubilize the membrane-bound phosphatase. The molecular weights of the NaCl-and the trypsin-solubilized phosphatase were estimated on gel filtration to be about 42,000 and 32,000, respectively. The present results indicate that the phosphoprotein phosphatase associated with liver plasma membrane shares several properties in common with phosphatases from other sources reported, and that, like those in the soluble fraction, it may be bound to some inhibitory proteins.     

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.     

Phosphoglycolate phosphatase. Purification and properties.

Phosphoglycolate phosphatase (EC 3.1.3.18) was purified 1500-fold from field-grown tobacco leaves by acetone fractionation, DEAE-cellulose and molecular sieve chromatography, and preparative polyacrylamide gel electrophoresis. Preparations were judged 90 to 95% homogeneous by chromatography on DEAE-cellulose, polyacrylamide gel electrophoresis, and by isoelectric focusing. The highest specific activity obtained was 468 mumol of phosphate released/min/mg of protein. The native protein has a molecular weight of 80,500 by Ferguson plot analysis and 86,300 by sedimentation velocity on sucrose density gradients. Sodium dodecyl sulfate-polyacrylamide gels gave a molecular weight of 20,700, indicating the P-glycolate phosphatase is a tetramer with identical or near identical subunits. The enzyme, freshly purified or in crude homogenates, had a pI of 3.8 to 3.9 pH units by isoelectric focusing. Phosphosphoglycolate phosphatase from spinach leaves has a molecular weight of 93,000 and, unlike the enzyme from tobacco leaves, it is extremely unstable after DEAE-cellulose chromatography and is inactivated by lipase (EC 3.1.1.3). The phosphatase from both plants was stabilized by the addition of citrate or isocitrate in the buffers. Ribose 5-phosphate is a competitive inhibitor of phosphoglycolate phosphatase at physiological concentration, while other phosphate esters of the photosynthetic carbon cycle were without effect.     

Characterization of KB cell alkaline phosphatase. Evidence of similarity to placental alkaline phosphatase.

The alkaline phosphatase from KB cells was purified, characterized, and compared to placental alkaline phosphatase, which it resembles immunologically. Two nonidentical nonomeric subunits of the KB phosphatase were found. The two subunits, which have apparent molecular weights of 64,000 and 72,000, can be separated on polyacrylamide gels containing sodium dodecyl sulfate. The Mr = 64,000 KB subunit appears to be identical in protein structure to the monomer of placental alkaline phosphatase. The Mr = 72,000 KB subunit, while differing in the NH2-terminal amino acid, appears also to be very similar to the placental alkaline phosphatase monomer. Both KB phosphatase subunits bind (32P)phosphate, and bind to Sepharose-bound anti-placental alkaline phosphatase. Native KB phosphatase is identical to the placental isozyme in isoelectric point, pH optimum, and inhibition by amino acids, and has a very similar peptide map. The data presented support the hypothesis that the Mr = 64,000 KB phosphatase subunit may the the same gene product as the monomer of placental alkaline phosphatase. This paper strengthens the evidence that the gene for this fetal protein, normally repressed in all cells but placenta, is derepressed in the KB cell line. In addition, this paper presents the first structural evidence that there are two different subunit proteins comprising the placental-like alkaline phosphatase from a human tumor cell line.     

Identification of the adipocyte acid phosphatase as a PAO-sensitive tyrosyl phosphatase.

We have partially purified an 18-kDa cytoplasmic protein from 3T3-L1 cells, which dephosphorylates pNPP and the phosphorylated adipocyte lipid binding protein (ALBP), and have identified it by virtue of kinetic and immunological criteria as an acid phosphatase (EC 3.1.3.2). The cytoplasmic acid phosphatase was inactivated by phenylarsine oxide (PAO) (Kinact = 10 microM), and the inactivation could be reversed by the dithiol, 2,3-dimercaptopropanol (Kreact = 23 microM), but not the monothiol, 2-mercaptoethanol. Cloning of the human adipocyte acid phosphatase revealed that two isoforms exist, termed HAAP alpha and HAAP beta (human adipocyte acid phosphatase), which are distinguished by a 34-amino acid isoform-specific domain. Sequence analysis shows HAAP alpha and HAAP beta share 74% and 90% identity with the bovine liver acid phosphatase, respectively, and 99% identity with both isoenzymes of the human red cell acid phosphatase but no sequence similarity to the protein tyrosine phosphatases (EC 3.1.3.48). HAAP beta has been cloned into Escherichia coli, expressed, and purified as a glutathione S-transferase fusion protein. Recombinant HAAP beta was shown to dephosphorylate pNPP and phosphoALBP and to be inactivated by PAO and inhibited by vanadate (Ki = 17 microM). These results describe the adipocyte acid phosphatase as a cytoplasmic enzyme containing conformationally vicinal cysteine residues with properties that suggest it may dephosphorylate tyrosyl phosphorylated cellular proteins.     

Conversion of a phosphoseryl/threonyl phosphatase into a phosphotyrosyl phosphatase.

By use of the autophosphorylated epidermal-growth-factor receptor and the synthetic peptide RRLIE-DAEY(P)AARG, representing an autophosphorylation site of the transforming protein of Rous-sarcoma virus, it is demonstrated that the phosphotyrosyl phosphatase activity of the polycation-stimulated phosphatases is substantially increased by an enzyme-directed effect of ATP or PPi. Concomitant with this increase in phosphotyrosyl phosphatase activity, the phosphorylase phosphatase activity is decreased, thus dramatically changing the substrate specificity of these enzymes. The dephosphorylation of four different phosphotyrosyl sites of the epidermal-growth-factor receptor is neither consecutive nor at random, but a preferred dephosphorylation of the P1 site over the P3 greater than P2 greater than P4 sites is observed. This phosphatase activity represents a substantial fraction of the total phosphotyrosyl phosphatase activity in the post-mitochondrial supernatant of Xenopus laevis oocytes.     

Phosphotyrosyl-specific protein phosphatase activity of a bovine skeletal acid phosphatase isoenzyme. Comparison with the phosphotyrosyl protein phosphatase activity of skeletal alkaline phosphatase

A partially purified bovine cortical bone acid phosphatase, which shared similar characteristics with a class of acid phosphatase known as tartrate-resistant acid phosphatase, was found to dephosphorylate phosphotyrosine and phosphotyrosyl proteins, with little activity toward other phosphoamino acids or phosphoseryl histones. The pH optimum was about 5.5 with p-nitrophenyl phosphate as substrate but was about 6.0 with phosphotyrosine and about 7.0 with phosphotyrosyl histones. The apparent Km values for phosphotyrosyl histones (at pH 7.0) and phosphotyrosine (at pH 5.5) were about 300 nM phosphate group and 0.6 mM, respectively, The p-nitrophenyl phosphatase, phosphotyrosine phosphatase, and phosphotyrosyl protein phosphatase activities appear to be a single protein since these activities could not be separated by Sephacryl S-200, CM-Sepharose, or cellulose phosphate chromatographies, he ratio of these activities remained relatively constant throughout the purification procedure, each of these activities exhibited similar thermal stabilities and similar sensitivities to various effectors, and phosphotyrosine and p-nitrophenyl phosphate appeared to be alternative substrates for the acid phosphatase. Skeletal alkaline phosphatase was also capable of dephosphorylating phosphotyrosyl histones at pH 7.0, but the activity of that enzyme was about 20 times greater at pH 9.0 than at pH 7.0. Furthermore, the affinity of skeletal alkaline phosphatase for phosphotyrosyl proteins was low (estimated to be 0.2-0.4 mM), and its protein phosphatase activity was not specific for phosphotyrosyl proteins, since it also dephosphorylated phosphoseryl histones. In summary, these data suggested that skeletal acid phosphatase, rather than skeletal alkaline phosphatase, may act as phosphotyrosyl protein phosphatase under physiologically relevant conditions.     

Pulmonary phosphatidic acid phosphatase. Properties of membrane-bound phosphatidate-dependent phosphatidic acid phosphatase in rat lung.

1. The membrane-bound phosphatidate-dependent phosphatidic acid phosphatase activity of rat lung has been investigated in cytosol and microsomal fractions using as a substrate [32P]phosphatidate bound to heat inactivated rat liver microsomes. Both activities demonstrated broad pH optima with a maximum of 7.4--8 for the cytosol and a maximum of 6.5--7.5 with microsomal preparations. 2. At low concentrations (0--5 mM) Mg2+ produced a slight stimulation of the cytosol activity but at higher concentrations an inhibition was observed. Low concentrations (1.0--2.0 mM) of EDTA abolished the cytosol activity and reduced the microsomal activity to half. In both cases, the addition of Mg2+ in the presence of EDTA resulted in an activity which was more than 2-fold greater than that observed in the absence of chelator or divalent cation. 3. The cytosol activity was relatively resistant to the addition of ionic and nonionic detergents. In general, the addition of a number of phosphate esters increased rather than decreased the release of 32Pi, indicating a relative specificity for phosphate groups associated with a hydrophobic environment. The addition of aqueous dispersions of phosphatidate, lysophosphatidic acid or phosphatidylglycerophosphate markedly reduced the hydrolysis of membrane-bound [32P]phosphatidate. The cytosol activity was slightly inhibited by the addition of phosphatidylcholine. 4. In an attempt to estimate the relative contributions of the cytosol and microsomal activities in vivo, these activities were assayed using [32P]phosphatidate endogenously generated on rat lung microsomes. With the 32P-labelled microsomes, the hydrolysis remained linear over the 45 min of the experiment. Addition of high speed supernatant produced a rapid release of 32Pi during the first 10 min followed by a more gradual release similar to that oberved with the microsomes alone. The cytosol activity remained greater than the microsomal activity at all times studied. 5. When [14C]phosphatidate-labelled microsomes were incubated in the presence of nonradioactive CDPcholine, the addition of cytosol markedly stimulated the incorporation of radioactivity into phosphatidylcholine. This observation suggests that the phosphatidic acid phosphatase activity associated with the cytosol has a role in phosphatidylcholine (and presumably surfactant) biosynthesis in rat lung.     

Leukocyte alkaline phosphatase in malignancies.

The leukocyte alklaine phosphatase (LAP) levels were determined in 183 patients with malignant diseases and 71 normal controls. The median LAP scores were 64 units (range 0 to 290) for the patients and 55 (range 2 to 158) for the controls, respectively, and no significant difference could be established. When analyzed according to primary malignancy, only in patients with Hodgkin's disease (n = 14) was the median value higher than normal (p less than 0.001). In patients with distant metastases (n = 48), higher LAP levels were demonstrated (M = 76, range 21 to 290) as compared to patients with no evidence of metastases (M = 53, range 0 to 229), (p less than 0.01). Thus, LAP activity has very limited value in the diagnosis of malignancies. Its elevation in the presence of malignant disease might, however, indicate metastases.     

Soybean root nodule acid phosphatase.

Acid phosphatases are ubiquitous enzymes that exhibit activity against a variety of substrates in vitro, although little is known about their intracellular function. In this study, we report the isolation, characterization, and partial sequence of the major acid phosphatase from soybean (Glycine max L.) root nodules. The phosphatase was purified predominantly as a heterodimer with subunits of 28 and 31 kD; homodimers of both subunits were also observed and exhibited phosphatase activity. In addition to the general phosphatase substrate, p-nitrophenyl phosphate, the heterodimeric form of the enzyme readily hydrolyzed 5'-nucleotides, flavin mononucleotide, and O-phospho-L-Tyr. Low or negligible activity was observed with ATP or polyphosphate. Purified nodule acid phosphatase was stimulated by magnesium, inhibited by calcium and EDTA, and competitively inhibited by cGMP and cAMP with apparent Ki values of 7 and 12 microM, respectively. Partial N-terminal and internal sequencing of the nodule acid phosphatase revealed homology to the soybean vegetative storage proteins. There was a 17-fold increase in enzyme activity and a noticeable increase in protein levels detected by immunoblotting methods during nodule development. Both of these parameters were low in young nodules and reached a peak in mature, functional nodules, suggesting that this enzyme is important for efficient nodule metabolism.