A protein phosphotyrosine phosphatase distinct from alkaline phosphatase with activity against the insulin receptor

Rat liver plasma membranes were found to have a relatively high ratio of acid to alkaline phosphatase activity when compared to rabbit liver and human placental membranes, respectively. The rat liver plasma membranes contained PPTl phosphatase activity against the soluble autophosphorylated insulin receptor beta-subunit. The PPT phosphatase activity of the membranes, using 32P-histone 2b as a substrate, was inhibited by 100 microM Zn+2, insensitive to 10 mM EDTA, and displayed maximal activity at neutral pH. Dephosphorylation of the insulin receptor beta-subunit by rat liver membranes was inhibited by Zn+2, and stimulated by EDTA. These results prove that the plasma membrane of a physiologically relevant insulin target tissue contains a PPT phosphatase, distinct from alkaline phosphatase, which catalyzes the dephosphorylation of the insulin receptor beta-subunit.     

The origin of plasma alkaline phosphatase activity in mice and rats

Swiss albino mice displayed the highest activity of alkaline phosphatase at 4-6 weeks with a precipitous decline by 18 weeks of age to a value seen in the mature animal. Circulating activity of alkaline phosphatase was significantly higher in the rat than the mouse in the fed state. With fasting, enzyme activity declined in the rat yet increased in the mouse. The net result was significantly higher plasma alkaline phosphatase activity in the mouse than the rat after the 48 hr fast. L-Phenylalanine inhibition of plasma alkaline phosphatase was greater in plasma from the rat than the mouse in the fed state. Yet in the fed condition, L-homoarginine and L-p-bromotetramisole inhibited alkaline phosphatase activity in plasma from mice to a greater extent than in rats. Heat inactivation as well as urea denaturation of alkaline phosphatase was significantly faster with plasma of the mouse than the rat in the fed state. Thus, it appears that the alkaline phosphatase isoenzyme of skeletal origin contributes a greater proportion of the circulating activity in the fed Swiss albino mouse than occurs in the Sprague-Dawley rat in which the intestinal isoenzyme plays a greater role in the fed condition.     

pH-dependent conversion of liver-membranous alkaline phosphatase to a serum-soluble form by n-butanol extraction

Alkaline phosphatase released from rat liver plasma membrane under usual conditions was electrophoretically not identical with a soluble form in serum which was derived from the liver. The liver-membranous alkaline phosphatase, however, was converted to the serum-soluble form when the liver plasma membrane was treated with n-butanol under the acidic conditions lower than pH 6.5. Such pH-dependent conversion of the enzyme was not observed in plasma membrane of rat ascites hepatoma AH-130 cells. The converting activity for alkaline phosphatase was detected not only in plasma membrane but also in lysosomal membrane of rat liver.     

Detection of alkaline phosphatase activity after conventional isoelectric focusing by an indoxyl-tetrazolium salt technique

Alkaline phosphatase was solubilized from human and rat tissues using papain in the presence of TRITON X-100 and subjected to isoelectric focusing (IEF) in polyacrylamide or agarose gels. Up till now, usually 1- and 2-naphthylphosphates have been used as substrates in order to specifically stain molecular forms of this enzyme by the azo-dye technique. In this paper, the use of another histochemical substrate, 5-bromo-4-chloro-3-indoxyl phosphate, in combination with tetrazolium salts [McGadey, J. (1970) Histochemie 23, 180-184] is presented. After hydrolysis, the released indoxyl moieties reduce tetrazolium salts to insoluble formazans at the zones of alkaline phosphatase activity. Zymogrammes showing molecular forms of alkaline phosphatase from 20 rat organs and the application of this staining technique for the detection of alkaline phosphatase activity in non-dialyzed human plasma after IEF are presented.     

Induction of alkaline phosphatase by retinoic acid

Treatment of mammalian cells in culture with retinoic acid causes a time- and concentration-dependent increase of the specific activity of alkaline phosphatase. The increase reaches a factor of 15 and more and begins at a concentration of 10(-8)M retinoic acid. The induction is inhibited by cycloheximide or actinomycin D. The same isoenzyme of alkaline phosphatase is expressed in control and in retinoic acid-treated cells as demonstrated by the inhibitions by amino acids and peptides. The enzyme induction occurs in rat heart, skeletal muscle, brain, lung cells and HeLa cells. No induction was found in two lines of human melanoma cells. After treatment of cells with tunicamycin, the induction of alkaline phosphatase is detectable only in the homogenate and no longer detectable by histochemical methods. This shows that the glycosylation of the protein is an important step in the insertion of this enzyme into the plasma membrane.     

Acid and alkaline phosphatases activities in vascular smooth muscle: species differences and subcellular distribution

1. Acid and alkaline phosphatase activities were studied in rat and dog aortic muscle using p-nitrophenyl phosphate (p-NPP) as the substrate. Alkaline phosphatase activity was quite comparable to acid phosphatase activity in rat aortic microsomes as well as further purified plasma membranes, but considerably lower than acid phosphatase activity in dog aortic membranes. 2. Subcellular distribution of acid and alkaline phosphatase activities in these vascular muscles indicated that alkaline phosphatases and a large portion of acid phosphatase activities were primarily associated with plasma membranes and the distribution of acid phosphatase showed little resemblance to that of N-acetyl-beta-glucosaminidase, a lysosomal marker enzyme. 3. The rat aortic plasmalemmal acid and alkaline phosphatase activities responded very differently to magnesium, fluoride, vanadate and EDTA. The alkaline phosphatase was more susceptible to heat inactivation than acid phosphatase. 4. These results suggest that these two phosphatases are likely to be two different enzymes in the smooth muscle plasma membranes. The implication of the present findings is discussed in relation to the alteration of these phosphatases in hypertensive vascular diseases.     

The 180000 molecular weight plasma membrane insulin receptor substrate is a protein tyrosine phosphatase and is elevated in diabetic plasma membranes

Wheat germ agglutinin-purified non-diabetic and diabetic human placenta membranes were or were not depleted of EGF receptor with monoclonal anti-EGF receptor antibody B1D8, and subsequently phosphorylated. Phosphorylated insulin receptor beta-subunit was lower and pp180 was higher in diabetic placenta membranes than in non-diabetic membranes. Phosphorylated-beta-subunit was also lower in diabetic (streptozotocin-induced) rat liver whereas the amount of pp180 was dependent on membrane protein concentration. When rat liver tyrosine-phosphorylated proteins were incubated 30 min, 4 degrees C with EDTA-terminated 32P-phosphorylation reaction mixtures of wheat germ agglutinin-purified rat liver proteins, less phosphorylated proteins were immunoprecipitated with antiphosphotyrosine. The decrease in tyrosine-phosphorylated products suggested that pp180 was a protein tyrosine phosphatase. Taken together, the results suggest that diabetic plasma membranes contain more tyrosine phosphatase than non-diabetic membranes.     

Investigation of alkaline phosphatase activity in the serum of pregnant rats

An investigation was undertaken to determine if the placental alkaline phosphatase of the rat enters the maternal circulation and to study some of its characteristics. Unlike human, rat placental alkaline phosphatase was found to be heat labile and the alkaline phosphatase activity in the serum of both pregnant and non-pregnant rats was also found to be heat labile. Also unlike the human, the alkaline phosphatase activity in rat serum does not increase as pregnancy progresses to term. In an endeavour to establish if the rat placental enzyme is present in the serum of the pregnant rat, the characteristics of the enzyme in both placental extracts and serum of non-pregnant and 1-, 2- and 3-week pregnant rats were studied using the techniques of heat stability at 56°, gel filtration through Sephadex columns, disc gel electrophoresis, and L-phenylalanine inhibition. The presence of rat placental alkaline phosphatase in maternal serum could not be positively demonstrated by any of these procedures, suggesting that rat placental alkaline phosphatase does not enter the maternal serum.     

Tetrameric alkaline phosphatase from human liver is converted to dimers by phosphatidylinositol phospholipase C

Membrane-bound human liver alkaline phosphatase solubilized by a non-ionic detergent, Nonidet P-40 (NP-40), has the molecular mass of a tetramer. It can be converted to a dimeric form by treatment with a phosphatidylinositol phospholipase C (PI-PLC) obtained from Bacillus cereus. When human liver plasma membranes were directly treated with PI-PLC, the released alkaline phosphatase was dimeric. Thus, phosphatidylinositol may help maintain the tetrameric quaternary structure of alkaline phosphatase and aid its binding to human liver plasma membranes.     

Neurofilament-L is a protein phosphatase-1-binding protein associated with neuronal plasma membrane and post-synaptic density

Far Westerns with digoxigenin-conjugated protein phosphatase-1 (PP1) catalytic subunit identified PP1-binding proteins in extracts from bovine, rat, and human brain. A major 70-kDa PP1-binding protein was purified from bovine brain cortex plasma membranes, using affinity chromatography on the immobilized phosphatase inhibitor, microcystin-LR. Mixed peptide sequencing following cyanogen bromide digestion identified the 70-kDa membrane-bound PP1-binding protein as bovine neurofilament-L (NF-L). NF-L was the major PP1-binding protein in purified preparations of bovine spinal cord neurofilaments and the cytoskeletal compartment known as post-synaptic density, purified from rat brain cortex. Bovine neurofilaments, at nanomolar concentrations, inhibited the phosphorylase phosphatase activity of rabbit skeletal muscle PP1 catalytic subunit but not the activity of PP2A, another major serine/threonine phosphatase. PP1 binding to bovine NF-L was mapped to the head region. This was confirmed by both binding and inhibition of PP1 by recombinant human NF-L fragments. Together, these studies indicate that NF-L fulfills many of the biochemical criteria established for a PP1-targeting subunit and suggest that NF-L may target the functions of PP1 in membranes and cytoskeleton of mammalian neurons.     

Characterization of the pyridoxal 5'-phosphate and pyridoxamine 5'-phosphate hydrolase activity in rat liver. Identity with alkaline phosphatase.

The tissue content of pyridoxal 5'-phosphate is controlled principally by the protein binding of this coenzyme and its hydrolysis by a cellular phosphatase. The present study identifies this enzyme and its intracellular location in rat liver. Pyridoxal-P is not hydrolyzed by the acid phosphatase of intact lysosomes. At pH 7.4 and 9.0, the subcellular distribution of pyridoxal-P phosphatase activity is similar to the for p-nitrophenyl-P, and the major portion of both activities is found in the plasma membrane fraction. The ratio of specific activities for pyridoxal-P and p-nitrophenyl-P hydrolysis remains relatively constant during the isolation of plasma membranes. These activities also behave concordantly with respect to pH rate profile, pH-Km profile, and response to chelating agents, Zn2+, Mg2+, and inhibitors. Kinetic studies indicate that pyridoxal-P binds to same enzyme sites as beta-glycerophosphate and phosphorylcholine. The data strongly favor alkaline phosphatase as the enzyme which functions in the control of pyridoxal-P and pyridoxamine-P metabolism in rat liver. Alkaline phosphatase was solubilized from isolated plasma membranes. The kinetic properties of the enzyme are not markedly altered by its dissociation from the membrane matrix. However, there are significant differences in its behavior toward Mg2+ which suggest a structural role for Mg2+ in liver alkaline phosphatase.     

Rat liver canalicular membrane vesicles. Isolation and topological characterization

Canalicular plasma membranes were isolated from rat liver homogenates using nitrogen cavitation and calcium precipitation methods. Compared with homogenates, the membranes were enriched 55- to 56-fold in gamma-glutamyltransferase, aminopeptidase M, and alkaline phosphatase activities and showed very low enrichment in markers of other membranes. By electron microscopy, the membrane preparation contained neither junctional complexes nor contaminating organelles and consisted exclusively of vesicles. The presence of vesicles was also evident from the osmotic sensitivity of D-[6-3H]glucose uptake into the membrane preparation. Antisera obtained from rabbits immunized with highly purified rat kidney gamma-glutamyltransferase inhibited the transferase activity of intact or Triton X-100-solubilized membranes by 45-55%. Treatment of vesicles with anti-gamma-glutamyltransferase antisera and anti-rabbit IgG antisera increased the apparent density of the membranes during sucrose density gradient centrifugation. gamma-Glutamyltransferase and aminopeptidase M activities were selectively removed from the vesicles by limited proteolysis with papain without changing the intravesicular space or alkaline phosphatase activity of the membranes. Specific binding of anti-gamma-glutamyltransferase antibody to the outer surface of isolated hepatocytes was observed as measured by the antisera and 125I-labeled protein A; binding followed saturation kinetics with respect to antibody concentration. These data indicate that the isolated canalicular membrane vesicles are exclusively oriented right-side-out and that gamma-glutamyltransferase and aminopeptidase M are located on the luminal side of rat liver canalicular plasma membranes.     

Dimeric nature and amino acid compositions of homogeneous canine prostatic human liver and rat liver acid phosphatase isoenzymes. Specificity and pH-dependence of the canine enzyme.

Two isoenzymes of rat liver acid phosphatase (orthophosphoric-monoester phosphohydrolase (acid optimum) EC 3.1.3.2) have been purified to homogeneity, at least one of these for the first time. Both of the rat liver isoenzymes have identical specific activities towards p-nitrophenyl phosphate. Molecular weights of the native enzymes are 92 000 for rat liver isoenzyme I and 93 000 for isoenzyme II, while the subunit molecular weights are 51 000 and 52 000 respectively. Data on substrate specificity and pH dependence are presented for the homogeneous canine prostatic enzyme, which is also isolated as a dimeric enzyme of (native) molecular weight 89 000. Carbohydrate analysis data are presented for canine prostatic acid phosphatase and it is further noted that both isoenzymes of rat liver acid phosphatase are also glycoproteins. The amino acid compositions of the two rat liver isoenzymes are presented together with those of the similar dimeric acid phosphatase of human liver and of canine prostate. Comparison of these results with published data for the amino acid composition of human prostatic acid phosphatase shows substantial similarities. However, significant differences are seen in the amino acid composition of rat liver acid phosphatase isoenzyme I as compared to a previous literature report. Most notably, 17 histidine residues are found per mol of isoenzyme I and 18 for isoenzyme II.     

Isolation and sequencing of a cDNA clone encoding acid phosphatase in rat liver lysosomes

A full length cDNA for acid phosphatase in rat liver lysosomes was isolated and sequenced. The predicted amino acid sequence comprises 423 residues (48,332 Da). A putative signal peptide of 30 residues is followed by the NH2-terminal sequence of lysosomal acid phosphatase (45,096 Da). The deduced NH2-terminal 18-residue sequence is identical with that determined directly for acid phosphatases purified from the rat liver lysosomal membranes. The primary structure deduced for acid phosphatase contains 9 potential N-glycosylation sites and a hydrophobic region which could function as a transmembrane domain. It exhibits 89% and 67% sequence similarities in amino acids and nucleic acids, respectively, to human lysosomal acid phosphatase. The amino acid sequence of the putative transmembrane segment shows a complete similarity to that of the human enzyme. Northern blot hybridization analysis identified a single species of acid phosphatase mRNA (2.2 kbp in length) in rat liver.     

The autorelease of alkaline phosphatase from the plasma membrane during the incubation of cultured liver cell homogenates

When a rat hepatoma cell (R-Y121B) homogenate was incubated at 37 degrees C, 30-70% of the total alkaline phosphatase was released into the supernatant fluid from the precipitate fractions. The release reached a plateau level after 10 h of incubation at 37 degrees C. The optimum pH value for the release was 7.4. Alkaline phosphatase activity increased during the incubation of the cell homogenates, but this increase was independent of the enzyme release. Serum increased not only alkaline phosphatase activity in the cultured cells but also enzyme release in their homogenates. In addition, we examined a rat liver homogenate and the following 11 cell lines: 3 hepatoma cell lines, including the R-Y121B cell line, 4 liver cell lines, 2 human urinary bladder carcinoma cell lines, a kidney cell line, and a mouse adrenal tumor cell line. Only in the cultured liver cell line and hepatoma cell lines, 30-60% of the total enzyme was released into the soluble fraction from the precipitate fractions; the release was not observed in the other cell lines, nor in the rat liver homogenate. The release of alkaline phosphatase took place in both heat-stable and heat-labile alkaline phosphatases. Alkaline phosphatase, extracted from cell homogenates, showed two bands during polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. The mobilities of the two bands changed inversely with or without sodium dodecyl sulfate. In general, the alkaline phosphatase which showed slow mobility with sodium dodecyl sulfate was more readily released from the plasma membrane.(ABSTRACT TRUNCATED AT 250 WORDS)     

Insulin induces activation of kinase FA in membranes and thereby promotes activation of ATP.Mg-dependent phosphatase in adipocytes

Exposure of rat adipocytes to physiological concentrations of insulin resulted in a time- and concentration-dependent activation-translocation of kinase FA (an activating factor of ATP.Mg-dependent protein phosphatase) in plasma membranes and the subsequent activation of ATP.Mg-dependent protein phosphatase in the cytosol. The insulin-induced activation of membrane-associated kinase FA and cytosolic ATP.Mg-dependent protein phosphatase occurred very rapidly, reaching the maximal activity levels within 3 min. Moreover, the insulin effect is transient; the insulin-stimulated FA activity in membranes and ATP.Mg-dependent phosphatase activity in the cytosol returned to control levels within 30 min. It is concluded that insulin may induce the activation of kinase FA in membranes and thereby promotes the activation of ATP.Mg-dependent multifunctional protein phosphatase in the cytosol of rat adipocytes in order to mediate some of its intracellular effects through the dephosphorylation reactions. The release of factor FA from plasma membranes may represent one of the transmembrane signalling mechanisms for insulin actions.     

Electrophoretic characterization of hepatic alkaline phosphatase released by phosphatidylinositol-specific phospholipase C. A comparison with liver membrane and serum-soluble forms.

Alkaline phosphatase was solubilized from plasma membrane of rat liver with butanol-ol, bile acids or sodium deoxycholate, and electrophoretically compared with a soluble form in serum which was derived from the liver. The three enzyme preparations from the plasma membrane migrated at the same position on polyacrylamide-gel electrophoresis in the presence of either Triton X-100 or sodium dodecyl sulphate. The mobility of them, however, was distinctly different from that of the serum-soluble form of the liver-derived alkaline phosphatase. On the other hand, phosphatidylinositol-specific phospholipase C isolated from Bacillus cereus was used to release alkaline phosphatase from plasma membrane. The released alkaline phosphatase was demonstrated to have the same mobility as the serum-soluble form on polyacrylamide-gel electrophoresis in the presence or absence of detergents. The phospholipase C also converted the butan-1-ol-extracted membrane form into the serum-soluble form. The results suggest that release of alkaline phosphatase from the liver into serum is not simply caused by a detergent effect of bile salts, but involves an enzymic hydrolysis of phosphatidylinositol, with which alkaline phosphatase may strongly interact in the membrane.     

Hepatic alkaline phosphatase isoenzymes: isolation, characterization and differential alteration.

Although it is generally believed that hepatic alkaline phosphatase is localized to liver plasma membranes, 63% is present in the cytosol fraction after ultracentrifugation of rat liver homogenates. Divalent cation requirements, heat inactivation, pH optima, Km and chemical inhibition characteristics of partially purified alkaline phosphatase enzymes prepared from membrane and cytosol fractions suggested different structural forms. Furthermore, bile duct obstruction and ethinyl estradiol administration preferentially increased membrane-bound alkaline phosphatase activity, while cytosol activity was unaltered. In contrast, phenobarbital treatment decreased membrane-bound alkaline phosphatase and increased cytosol activity. These studies support the presence of two forms of hepatic alkaline phosphatase in rat liver which are regulated by different control mechanisms.     

Regional and Subcellular Distribution in Mammalian Brain of the Enzymes Producing Adenosine

The activities of 5'-nucleotidase, 2'-nucleotidase, alkaline phosphatase, and acid phosphatase were measured in rat and autopsied human brains. The four phosphatases in the rat brain showed little change in activity after death. The activities of adenosine-producing enzymes were compared in various parts of rat and human brains. When phosphatase activity was measured at pH 7.5, 5'-nucleotidase showed the highest activity in the most parts of the brain. The activity of 2'-nucleotidase and that of nonspecific phosphatase were almost the same at pH 7.5. However, higher phosphatase activity was observed in all parts of the brain when nonspecific phosphatase activity was measured at pH 10.0 or 5.5. High specific activity of 5'-nucleotidase in the brain was detected in the membranous components, especially in the synaptic membranes. The activity of 2'-nucleotidase was distributed in the soluble and synaptosomal fractions. The highest activity of both alkaline and acid phosphatases was recovered in the crude mitochondrial fraction, with the highest specific activity in the microsomal fraction. Phosphatase activity was distributed widely in the rat brain. The activity of 5'-nucleotidase was high in the medulla oblongata, thalamus, and hippocampus, but low in the peripheral nerve, spinal cord, and occipital lobe. The activity of 2'-nucleotidase was high in the vermis and frontal lobe. The highest acid and alkaline phosphatase activities were detected in the frontal lobe and in the olfactory bulb, respectively. The distribution of the four phosphatases in the autopsied human brain was similar to that in the rat brain. The highest 5'-nucleotidase activity was observed in the temporal lobe and thalamus.(ABSTRACT TRUNCATED AT 250 WORDS)     

Prostatic acid phosphatase degrades lysophosphatidic acid in seminal plasma

Lysophosphatidic acid (LPA) is a lipid mediator with multiple biological activities and is detected in various biological fluids, including human seminal plasma. Due to its cell proliferation stimulatory and anti-apoptotic activities, LPA has been implicated in the progression of some cancers such as ovarian cancer and prostate cancer. Here, we show that prostatic acid phosphatase, which is a non-specific phosphatase and which has been implicated in the progression of prostate cancer, inactivates LPA in human seminal plasma. Human seminal plasma contains both an LPA-synthetic enzyme, lysoPLD, which converts lysophospholipids to LPA and is responsible for LPA production in serum, and its major substrate, lysophosphatidylcholine. In serum, LPA accumulated during incubation at 37 degrees C. However, in seminal plasma, LPA did not accumulate. This discrepancy is explained by the presence of a strong LPA-degrading activity. Incubation of LPA with seminal plasma resulted in the disappearance of LPA and an accompanying accumulation of monoglyceride showing that LPA is degraded by phosphatase activity present in the seminal plasma. When seminal plasma was incubated in the presence of a phosphatase inhibitor, sodium orthovanadate, LPA accumulated, indicating that LPA is produced and degraded in the fluid. Biochemical characterization of the LPA-phosphatase activity identified two phosphatase activities in human seminal plasma. By Western blotting analysis in combination with several column chromatographies, the major activity was revealed to be identical to prostatic acid phosphatase. The present study demonstrates active LPA metabolism in seminal plasma and indicates the possible role of LPA signaling in male sexual organs including prostate cancer.