Dephosphorylation of purine mononucleotides by alkaline phosphatases. Substrate specificity and inhibition patterns.

Three purine mononucleotides, adenosine-, inosine- and guanosine monophosphate, were used as substrates at pH 7.4 and at 10.4 for three alkaline phosphatases (orthophosphoric-monoester phosphohydrolase (acid optimum), EC 3.1.3.1) containing similar phosphate-binding serine groups at their esteratic sites. Substrate specificity was found for the enzymes from calf intestine and bovine liver. Alkaline phosphatase from Escherichia coli was nonspecific. A substrate-dependent and pronounced inhibition with the purine analogue 1,3-dimethyl xanthine was found for the enzymes from intestine and liver, but not for alkaline phosphatase from E. coli. A substrate-independent and pronounced inhibition was found for all three enzymes with the phosphomonoester p-nitrophenol phosphate as the inhibitor. Alkaline phosphatases may play an important role in the regulation of the intracellular content of purine mononucleotides.     

Purification and characterization of alkaline phosphatase from rat kidney.

Alkaline phosphatase [EC 3.1.3.1.] was purified about 250-fold from rat kidney, and its enzymological properties were studied. Kidney homogenate was extracted with n-butanol, passed through Sephadex G-200 and chromatographed on a DEAE-cellulose column. The peak from the DEAE-cellulose column was subjected to isoelectric focusing, and the alkaline phosphatase activity was separated into two peaks. The molecular weights of alkaline phosphatase in these peaks were 4.8.X10(4) and 1.0X10(5), as determined by SDS-polyacrylamide gel electrophoresis. Anti-serum against alkaline phosphatase from rat kidney was prepared, and was shown to neutralize the activity from kidney, liver or bone, but not that from intestine.     

Cytochemical detection and cytofluorimetric analysis of alkaline phosphatase in continuous lines of thymic lymphomas induced in mice by a radiation leukemia virus

Alkaline phosphatase was studied in cell lines established from Radiation Leukemia Virus induced thymic lymphomas of C57BL/Ka mice. The cytochemical staining techniques and flow cytofluorimetry analysis described by Dolbeare et al. (J. Histochem. Cytochem., 1980, 28, 419-426) were used. The alkaline phosphatase found in lymphoma cells was heat labile and L-homoarginine. L-phenylalanine and p-bromotetramisole sensitive and is probably similar to the isoenzyme present in mouse placenta, kidney and liver. Very little alkaline phosphatase activity was detected in normal thymus of adult mice, suggesting that the method used in the paper could be helpful for studying the emergence of the first neoplastic cells during the leukemogenic process.     

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)     

Size and stability to sodium dodecyl sulfate of alkaline phosphatases from their three established human genes

Subunit molecular weights of human alkaline phosphatases (orthophosphoric-monoester phosphohydrolases (alkaline optimum), EC 3.1.3.1) determined by polyacrylamide gel electrophoresis in sodium dodecyl sulfate (SDS) were dependent upon acrylamide concentration, a reflection of their glycoprotein nature. Molecular weights at a concentration of 7% (w/w) or greater were 68300, 80800 and 79400 for the enzymes from placenta, liver and mucosa of small intestine, respectively. All enzymes were dimers, the respective native Mr values determined by gradient gel electrophoresis being 138000, 186000 and 180000. None of the molecular weights was altered by desialylation. Stability of the catalytic activity of the purified enzymes to SDS varied and was very dependent on pH. SDS at 1% (w/v) rapidly denatured both native and desialylated alkaline phosphatase from placenta at pH 7.5 but had little effect on these at pH 10.3. Compared with placenta, the native enzyme from liver had greater stability at pH 7.5 and both native and desialylated forms had lower stability at pH 10.3. The enzyme from intestinal mucosa was sharply different from the other two isoenzymes: SDS had little effect at pH 7.5 but very rapidly denatured the enzyme at pH 10.3. The size of alkaline phosphatases and their stability to SDS can be used to identify gene products and to recognize heterodimers formed between products of more than one gene.     

Purification and characterization of alkaline phosphatase in cultured rat liver cells.

Alkaline phosphatase has been purified from cultured rat liver cells by butanol extraction, column chromatography on DEAE-cellulose and on Sephadex G-200, and preparative polyacrylamide gel electrophoresis. By electrophoresis on polyacrylamide, the purified enzyme was resolved into two active forms. Both forms have similar molecular weights of around 200,000. The subunit size was found to be 50,000 by SDS-polyacrylamide gel electrophoresis. These results suggest that alkaline phosphatase purified from cultured rat liver cells has a tetrameric structure. The optimum pH was found to be approximately 10.4, using p-nitrophenylphosphate as a substrate in a carbonate buffer system. The apparent Km was estimated to be 2.4 mM, using p-nitrophenylphosphate in carbonate buffer, pH 10.4.     

Characterization of two different alkaline phosphatases in mouse teratoma: Partial purification,electrophoretic, and histochemical studies

Alkaline phosphatase (E.C.3.1.3.1.) has been used as a marker for embryonal carcinoma cells which constitute the multipotential stem cells of the mouse teratoma. Studies by other investigators based on kinetics of thermal inactivation and L-phenylalanine inhibition have shown that the alkaline phosphatase of the teratoma differs from the mouse intestinal and liver isozymes, but resembles the isozymes of kidney and placenta. Since functional characterization of nonpurified enzymes is not the most accurate means for distinguishing different molecular forms of an enzyme, we have partially purified the enzymes from the ascitic (embryoid body) and solid tumor forms of the OTT-6050 teratoma line, and utilized the technique of electrophoresis in polyacrylamide gels to compare the teratoma enzyme with isozymes from kidney and placenta. Covalent ³²PO₄-labeling of the alkaline phosphatases and polyacrylamide gel electrophoresis in sodium dodecylsulfate was also used to compare the subunit molecular weights of the enzymes. The results indicate that the mouse teratoma enzyme is distinct from the kidney and placental isozymes. Since histochemical studies have localized the enzyme to the stem cell population of the teratoma, the results imply that stem cell alkaline phosphatase is a distinct isozyme. The embryoid bodies contain a second alkaline phosphatase which may correspond to the placental isozyme. This enzyme may be attributed to the outer cell layer of embryoid bodies of the ascitic tumor, since this cell type histochemically demonstrates alkaline phosphatase activity.     

Purification and characterization of alkaline phosphatase from plasma membranes of rat ascites hepatoma.

Alkaline phosphatase was purified from plasma membranes of rat ascites hepatoma AH-130, the homogenate of which had 50-fold higher specific activity than that found in the liver homogenate. The presence of Triton X-100, 0.5%, was essential to avoid its aggregation and to stabilize its activity. The purified enzyme, a glycoprotien, was homogeneous in polyacrylamide gel electrophoresis. Polyacrylamide gel electrophoresis in sodium dodecyl sulfate indicated a protein molecular weight of 140,000. The addition of beta-mercaptoethanol caused the dissociation of the alkaline phosphatase into two subunits of identical molecular weight, 72,000. Isoelectric focusing revealed that the pI of this enzyme is 4.7. The pH optimum for the purified enzyme was 10.5 or higher with p-nitrophenylphosphate, and slightly lower pH values (pH 9.5--10.2) were obtained when other substrates were used. Of the substrates tested, p-nitrophenylphosphate (Km-0.3 mM) was most rapidly hydrolyzed. Vmax values of other substrates relative to that of p-nitrophenylphosphate were as follows; beta-glycerophosphate, 76%; 5'-TMP, 82%; 5'-AMP, 62%; 5'-IMP, 43%; glucose-6-phosphate, 39%; ADP, 36% and ATP, 15%. More than 90% of the activity of the purified enzyme was irreversibly lost when it was heated at 55 degrees C for 30 min, or exposed either to 10 mM beta-mercaptoethanol for 10 min to 3 M urea for 30 min, or to an acidic pH below pH 5.0 for 2 h. Of the effects by divalent cations, Mg2+ activated the enzyme by 20% whereas Zn2+ strongly inhibited it by 95% at 0.5 mM. EDTA at higher than 1 mM inactivated the enzyme irreversibly, although the effect of EDTA at lower than 0.1 mM was reversible by the addition of divalent cations, particularly by Mg2+. The enzyme was most strongly inhibited by L-histidine among the amino acids tested, and also strongly inhibited by imidazole. These results suggest that alkaline phosphatase of rat hepatoma AH-130 is very similar to that of rat liver in most of the properties reported so far.     

Release of alkaline phosphodiesterase I from rat kidney plasma membrane produced by the phosphatidylinositol-specific phospholipase C of Bacillus thuringiensis

The release of plasma-membrane-bound enzymes by phosphatidylinositol-specific phospholipase C obtained from Bacillus thuringiensis was investigated. Among the ectoenzymes of plasma membrane tested, alkaline phosphodiesterase I was released markedly from rat kidney cortex slices, in addition to alkaline phosphatase and 5'-nucleotidase. Other membrane-bound enzymes; alanine aminopeptidase, leucine aminopeptidase, dipeptidyl peptidase, leucine aminopeptidase, dipeptidyl peptidase IV, esterase and gamma-glutamyl transpeptidase could not be liberated from the treated slices. Alkaline phosphodiesterase I was released linearly from rat kidney slices with the concentration of phosphatidylinositol-specific phospholipase C, but little enzyme was released from rat liver slices. Alkaline phosphodiesterase I separated from kidney tissue with n-butanol still retained phosphatidylinositol and was transformed into a lower molecular weight form by phosphatidylinositol-specific phospholipase C. This suggests an important function for phosphatidylinositol in the binding of alkaline phosphodiesterase I to the plasma membrane of rat kidney cells. The alkaline phosphodiesterase I released from rat kidney had a molecular weight of about 240,000 and an isoelectric point (pI) of 5.4. The enzyme hydrolyzed the phosphodiester linkage of p-nitrophenyl-thymidine 5'-monophosphate at pH 8.9 and had a Km value of 0.3 mM. The enzyme was activated by Mg2+ and Ca2+, but was inhibited by EDTA. Strong inhibition took place on the addition of adenosine 5'-phosphosulfate or the nucleotide pyrophosphates, i.e., UDP-galactose and alpha, beta-methylene ATP.     

A comparative study of alkaline phosphatases among human placenta, bovine milk, hepatopancreases of shrimp Penaeus monodon (Crustacea: Decapoda) and clam Meretrix lusoria (Bivalvia: Veneidae): to obtain an alkaline phosphatase with improved characteristics as a reporter

1. Alkaline phosphatases were purified from human placenta, bovine milk, shrimp and clam with a final spec. act. of 67,000, 32,000, 22,000 and 15,000 U/mg of protein respectively. 2. The alkaline phosphatase from Meretrix lusoria is unique with its thermostability at 65 degrees C for 30 min; whereas the remaining enzymes studied, including the human placental alkaline phosphatase, are inactivated and have negligible activities. 3. The alkaline phosphatase from Penaeus monodon can be differentiated by its pH optimum at 9.0; the remaining enzymes studied have their optimal pH at 10.0. 4. The alkaline phosphatases from shrimp and clam are proposed to be applied as "reporters" in the study of mammalian cells.     

An in vitro production of bone specific alkaline phosphatase

Induced alkaline phosphatase has been extracted from osteosarcoma cells grown in tissue culture medium. The extracted enzyme has been purified. Using electrophoresis, inhibition studies, and thermolability, the enzyme was categorized as alkaline phosphatase of osseous origin. Antibodies to this enzyme were reacted against alkaline phosphatase extracted from cadaveric bone, liver, intestine, kidney and fresh placenta. The antibodies were specific against alkaline phosphatase of osseous origin only. No cross-reaction occurred with the enzyme extracted from other sources. The data derived from these studies indicate that alkaline phosphatase of bone is a specific enzyme of osseous tissue. Furthermore, the enzyme has specific antigenic and other properties which distinguish it from alkaline phosphatases from other sources. A model for in vitro production of a specific alkaline phosphatase of bone is presented.     

Synthesis of first trimester placental alkaline phosphatase in cultured human term placental cells

Alkaline phosphatase activity in human placental cells transformed by a tsA mutant of simian virus 40 (SV40) can be greatly induced by growing these cells at 40 degrees C, the temperature at which the tsA transformants regain their nontransformed phenotype. The induction of alkaline phosphatase in these cells requires the synthesis of both RNA and protein. The induced alkaline phosphatase from a SV40 tsA30 mutant-transformed term placental cell line (TPA30-1) was purified, characterized, and compared with alkaline phosphatase from term placenta and first trimester placenta. The form of alkaline phosphatase found in TPA30-1 cells differs from the phosphatase of term placenta in physiochemical and immunological properties. The TPA30-1 phosphatase is, however, indistinguishable from the alkaline phosphatase of human first trimester placenta by several criteria, including electrophoretic mobility, apparent molecular weight (Mr = 165,000), size of monomeric subunit (Mr = 77,000), heat lability, and sensitivity to inhibition by amino acids and EDTA. In addition, alkaline phosphatase from both TPA30-1 cells and first trimester placenta can be inactivated by antiserum to liver alkaline phosphatase but not by antiserum to term placental alkaline phosphatase. The induction of first trimester phosphatase in cells derived from term placenta provides a system for the study of alkaline phosphatase gene regulation in human placenta.     

Control of the production and partial characterization of repressible extracellular 5'-nucleotidase and alkaline phosphatase in Neurospora crass.

A new species of orthophosphate repressible extracellular 5'-nucleotidase (5'-ribonucleotide phosphohydrolase, EC 3.1.3.5) was found to be released into mycelial culture media when a wild type strain of Neurospora crassa was grown on limiting amounts of phosphate. The production of 5'-nucleotidase and extracellular acid and alkaline phosphatase was inhibited by the addition of rifampicin when it was added at the later stage of mycelial growth, but not when it was added at a very early stage. The 5'-nucleotidase and extracellular alkaline phosphatase were partially purified and characterized. pH optimum of the former was 6.8 and that of the latter was higher than 10.0. The 5'-nucleotidase activity was inhibited by ethylenediaminetetraacetate (EDTA) and ZnCl2 at pH 6.8 and stimulated by MnCl2 and CoCl2 at pH 4.0. Alkaline phosphatase activity was stimulated by EDTA, MgCl2, CoCl2 and MnCl2. 5'-nucleotidase activity was stimulated by EDTA, MgCl2, CoCl2 and MnCl2. 5'-nucleotidase hydrolyzed various 5'-nucletides but not 3'-nucleotides or other various phosphomono- and diester compounds. Alkaline phosphatase hydrolyzed all the phosphomonoester compounds tested. Mutants, nuc-1 and nuc-2, which were originally isolated by the inability to utilize RNA or DNA as a sole source of phosphate, were unable to produce 5'-nucleotidase or six other repressible enzymes reported previously. These mutants showed no or significantly reduced growth on orthophosphate-free nucleotide media depending on the number of conidia inoculated, mainly because of loss of ability to produce these repressible extracellular phosphatases.     

Ectoenzyme release from rat liver and kidney by phosphatidylinositol-specific phospholipase C

Ectoenzyme release from rat liver and kidney by phosphatidylinositol (PI)-specific phospholipase C of Bacillus thuringiensis was studied. Alkaline phosphatase and 5'-nucleotidase were released from rat kidney slices to extents of up to 60% and 30%, respectively. Release of alkaline phosphatase was observed at lower amounts of PI-specific phospholipase C than that of 5'-nucleotidase. Both enzymes were more easily released from microsomal fractions or free cells. From kidney cells, alkaline phosphatase was released without cell lysis, and more than 80% release of alkaline phosphatase was observed at 3.8% hydrolysis of PI. Isoelectric focusing profiles of alkaline phosphatase released by PI-specific phospholipase C were significantly different from the control in the cases of both rat liver and kidney. Lubrol-solubilized alkaline phosphatase was eluted at the void volume of a Toyopearl HW-55 column, while the enzyme obtained by further treatment with PI-specific phospholipase C was eluted in the lower-molecular-weight region corresponding to 100,000-110,000 daltons. Furthermore, Lubrol-solubilized phosphatase became more thermostable on treatment with PI-specific phospholipase C.     

Alkaline phosphatase isozymes of Xenopus laevis embryos and tissues.

Alkaline phosphatase was obtained by treating embryos of Xenopus laevis with n-butanol at different developmental stages from gastrula to tadpole; the enzyme was also obtained from adult kidney, liver, and intestinal mucosa. Purification was carried out by gel filtration and polyacrylamide gel electrophoresis. The enzyme activity is chromatographically spearated into two peaks, with molecular weights of approximately 200,000 and 400,000. Alternatively, two groups may be characterized on the basis of their electrophoretic mobilities, which correspond to the different molecular weight classes. Effects of pH, temperature, inhibitors, and substrate concentration were studied. The kinetic and physical properties of the two alkaline phosphatase isozymes are similar, and are comparable to the properties reported for this enzyme from other vertebrates. Alkaline phosphatase activity increased sharply at the gastrula stage and reached a plateau at the late tailbud stage. During this period there was an 18-fold increase in activity.     

Comparison of human alkaline phosphatase isoenzymes. Structural evidence for three protein classes.

The structural relationships among human alkaline phosphatase isoenzymes from placenta, bone, kidney, liver and intestine were investigated by using three criteria. 1. Immunochemical characterization by using monospecific antisera prepared against either the placental isoenzyme or the liver isoenzyme distinguishes two antigenic groups: bone, kidney and liver isoenzymes cross-react with anti-(liver isoenzyme) serum, and the intestinal and placental isoenzymes cross-react with the anti-(placental isoenzyme) antiserum. 2. High-resolution two-dimensional electrophoresis of the 32P-labelled denatured subunits of each enzyme distinguishes three groups of alkaline phosphatase: (a) the liver, bone and kidney isoenzymes, each with a unique isoelectric point in the native form, can be converted into a single form by treatment with neuraminidase; (b) the placental isoenzyme, whose position also shifts after removal of sialic acid; and (c) the intestinal isoenzyme, which is distinct from all other phosphatases and is unaffected by neuraminidase digestion. 3. Finally, we compare the primary structure of each enzyme by partial proteolytic-peptide 'mapping' in dodecyl sulphate/polyacrylamide gels. These results confirm the primary structural identity of liver and kidney isoenzymes and the non-identity of the placental and intestinal forms. These data provide direct experimental support for the existence of at least three alkaline phosphatase genes.     

An infrared study of the thermal and pH stabilities of the GPI-alkaline phosphatase from bovine intestine

Alkaline phosphatase (EC 3.1.3.1) from bovine intestine mucosa (BIAP) is a homodimeric metalloenzyme, which hydrolyses nonspecifically phosphate monoesters at alkaline pH with release of inorganic phosphate and alcohol. BIAP is either soluble (sBIAP) or membrane-anchored by a glycosylphosphatidylinositol moiety (GPI-BIAP). This anchor might have some contribution in the stabilization of the GPI-linked protein structure. Our purpose was to study the role of the anchor by using two parameters, the enzymatic activity and the protein conformation, which was analyzed by using FTIR spectroscopy. We determined that the two forms of BIAP show some similarities with the previously described structure of alkaline phosphatase isolated from Escherichia coli and human placenta. Meanwhile GPI-BIAP and sBIAP exhibit similar specific activities, the presence of the anchor increases the thermal and pH stabilities of the enzyme activity and conformation.     

Formaldehyde-chloral hydrate as a fixative for mouse tissues for localisation of acid and alkaline phosphatases

Summary Acid and alkaline phosphatase were demonstrated in mouse liver, kidney, thymus and heart sections fixed for 24 hours in a formol chloral hydrate solution and stained using naphthol-AS-phosphate as substrate and Red-violet-LB as the coupling agent. The substrate pH for acid and alkaline phosphatase was 5.4 and 8.2 respectively. The staining time was 75 minutes.     

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.     

Purification and characterization of a repressible alkaline phosphatase from Thermus aquaticus.

A repressible alkaline phosphatase has been isolated from the extreme bacterial thermophile, Thermus aquaticus. The enzyme can be derepressed more than 1,000-fold by starving the cells for phosphate. In derepressed cells, nearly 6% of the total protein in a cell-free enzyme preparation is alkaline phosphatase. The enzyme was purified to homogeneity as judged by disc acrylamide electrophoresis and sodium dodecyl sulfate electrophoresis. By sucrose gradient centrifugation it was established that the enzyme has an approximate molecular weight of 143,000 and consists of three subunits, each with a molecular weight of 51,000. Tris buffer stimulates the activity of the enzyme, which has a pH optimum of 9.2. The enzyme has a broad temperature range with an optimum of 75-80 degrees. The enzyme catalyzes the hydrolysis of a wide variety of phosphorylated compounds as do many of the mesophilic alkaline phosphatases. The Michaelis constant(Km) for the enzyme is 8.0 X 10(-4) M. Amino acid analysis of the protein revealed little in the amino acid composition to separate it from other mesophilic enzymes which have been previously studied.