Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.3.1 (alkaline phosphatase)
 47,916 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Many proteins of eukaryotic cells are anchored to membranes by covalent linkage to glycosyl-phosphatidylinositol (GPI). These proteins lack a transmembrane domain, have no cytoplasmic tail, and are, therefore, located exclusively on the extracellular side of the plasma membrane. GPI-anchored proteins form a diverse family of molecules that includes membrane-associated enzymes, adhesion molecules, activation antigens, differentiation markers, protozoan coat components, and other miscellaneous glycoproteins. In the kidney, several GPI-anchored proteins have been identified, including uromodulin (Tamm-Horsfall glycoprotein), carbonic anhydrase type IV, alkaline phosphatase, Thy-1, BP-3, aminopeptidase P, and dipeptidylpeptidase. GPI-anchored proteins can be released from membranes with specific phospholipases and can be recovered from the detergent-insoluble pellet after Triton X-114 treatment of membranes. All GPI-anchored proteins are initially synthesized with a transmembrane anchor, but after translocation across the membrane of the endoplasmic reticulum, the ecto-domain of the protein is cleaved and covalently linked to a preformed GPI anchor by a specific transamidase enzyme. Although it remains obscure why so many proteins are endowed with a GPI anchor, the presence of a GPI anchor does confer some functional characteristics to proteins: (1) it is a strong apical targeting signal in polarized epithelial cells; (2) GPI-anchored proteins do not cluster into clathrin-coated pits but instead are concentrated into specialized lipid domains in the membrane, including so-called smooth pinocytotic vesicles, or caveoli; (3) GPI-anchored proteins can act as activation antigens in the immune system; (4) when the GPI anchor is cleaved by PI-phospholipase C or PI-phospholipase D, second messengers for signal transduction may be generated; (5) the GPI anchor can modulate antigen presentation by major histocompatibility complex molecules. Finally, at least one human disease, paroxysmal nocturnal hemoglobinuria, is a result of defective GPI anchor addition to plasma membrane proteins.
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PMID:Glycosyl-phosphatidylinositol-anchored membrane proteins. 145 Mar 66

Human intestinal alkaline phosphatase (IAP) can be released by the enterocyte into duodenal fluid as a mixture of three isoforms. A proportion of the enzyme is associated with triple-layered membrane vesicles (vesicular IAP). Although, occasionally, free hydrophilic IAP dimers are present, the remaining enzyme usually consists of a mixture of hydrophobic IAP dimers and more complex hydrophobic IAP structures of larger size, both entities being identified as "intestinal variant" alkaline phosphatase (VAR IAP). The hydrophobicity of VAR IAP stems exclusively from its attached glycosyl-phosphatidylinositol (GPI) anchor. Both vesicular IAP and VAR IAP are converted to hydrophilic enzyme upon removal of the GPI tail by phospholipase D (PLD) present in duodenal fluid. The IAP released into the vascular bed consists mainly of VAR IAP; vesicular IAP is absent. The enzyme characteristics of VAR IAP partially purified from duodenal fluid and from serum are identical. In plasma, VAR IAP appears to associate with (lipo)protein complexes and is thus protected from further degradation by plasma PLD. Such complex formation may explain why, in the serum of a healthy reference population, VAR IAP was more abundant than hydrophilic dimeric IAP.
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PMID:Differential release of human intestinal alkaline phosphatase in duodenal fluid and serum. 145 94

Partially purified high-molecular-weight alkaline phosphatase from serum was compared with two other forms of the enzyme from the human liver, enzyme in native plasma membranes and purified alkaline phosphatase as a hydrophilic dimer. In a high-molecular-weight form from serum and plasma membranes, and when treated with 1% (v/v) Triton X-100, alkaline phosphatase showed a major band on gradient gel electrophoresis with a mobility equivalent to 400 kD. Nondetergent-treated material from both sources did not enter the gel and was in the voided volume of a gel permeation column. Stimulation of catalytic activity by four different phospholipids and by albumin yielded similar results for high-molecular-weight alkaline phosphatase and for the enzyme in plasma membranes, but these were different from the hydrophilic form. Inhibitors of alkaline phosphatase had similar effects on all forms. Of the three forms of the enzyme, only the hydrophilic dimer did not become incorporated into liposomes or adsorb to octyl-Sepharose after solubilization with Triton X-100 and removal of the detergent. Km (substrate concentration to give half maximal velocity) values with p-nitrophenylphosphate and heat and sodium dodecyl sulfate stabilities were similar for all forms. In the high-molecular-weight form from serum and in plasma membranes, alkaline phosphatase and 5'-nucleotidase showed similar rates of release by phosphatidylinositol phospholipase C. Three preparations of phospholipase D failed to release alkaline phosphatase from either the high-molecular-weight form or from plasma membranes. Based on these similarities, it is probable that the complex of high-molecular-weight alkaline phosphatase in serum most often originates from fragments of hepatic plasma membranes.
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PMID:High-molecular-weight alkaline phosphatase in serum has properties similar to the enzyme in plasma membranes of the liver. 183 14

Mammalian serum and plasma contain high levels of glycosylphosphatidylinositol-specific phospholipase D (GPI-PLD). Previous studies with crude serum or partially purified GPI-PLD have shown that this enzyme is capable of degrading the GPI anchor of several purified detergent-solubilized cell surface proteins yet is unable to act on GPI-anchored proteins located in intact cells. Treatment of intact ROS17/2.8, WISH or HeLa cells (or membrane fractions prepared from them) with GPI-PLD purified from bovine serum by immunoaffinity chromatography gave no detectable release of alkaline phosphatase into the medium. However, when membranes were treated with GPI-PLD in the presence of 0.1% Nonidet P-40 substantial GPI anchor degradation (as measured by Triton X-114 phase separation) was observed. The mechanism of this stimulatory effect of detergent was further investigated using [3H]myristate-labelled variant surface glycoprotein and human placental alkaline phosphatase reconstituted into phospholipid vesicles. As with the cell membranes the reconstituted substrates exhibited marked resistance to the action of purified GPI-PLD which could be overcome by the inclusion of Nonidet P-40. Similar results were obtained when crude bovine serum was used as the source of GPI-PLD. These data indicate that the resistance of cell membranes to the action of GPI-PLD is not entirely due to the action of serum or membrane-associated inhibitory factors. A more likely explanation is that, in common with many other eukaryotic phospholipases, the action of GPI-PLD is restricted by the physical state of the phospholipid bilayer in which the substrates are embedded. These data may account for the ability of endothelial and blood cells to retain GPI-anchored proteins on their surfaces in spite of the high levels of GPI-PLD present in plasma.
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PMID:Factors affecting the ability of glycosylphosphatidylinositol-specific phospholipase D to degrade the membrane anchors of cell surface proteins. 183 78

Increasing interest in receptor-regulated phospholipase C and phospholipase D hydrolysis of cellular phosphatidylcholine motivates the development of a sensitive and simple assay for the water-soluble hydrolytic products of these reactions, phosphocholine and choline respectively. Choline was partially purified from the methanol/water upper phase of a Bligh & Dyer extract by ion-pair extraction using sodium tetraphenylboron, and the mass of choline was determined by a radioenzymic assay using choline kinase and [32P]ATP. After removal of choline from the upper phase, the mass of residual phosphocholine was determined by converting it into choline by using alkaline phosphatase, followed by radioactive phosphorylation. In addition to excellent sensitivity (5 pmol for choline and 10 pmol for phosphocholine), these assays demonstrated little mutual interference (phosphocholine----choline = 0%; choline----phosphocholine = 5%), were extremely reproducible (average S.E.M. of 3.5% for choline and 2.9% for phosphocholine), and were simple to perform with instrumentation typically available in most laboratories. In addition, the ability to apply the extraction technique to the upper phase of Bligh & Dyer extracts permitted simple analysis not only of choline and phosphocholine, but also of phosphatidylcholine and lipid products of phospholipase C and phospholipase D activity (1,2-diacylglycerol and phosphatidic acid respectively) from the same cell or tissue sample.
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PMID:Isolation and enzymic assay of choline and phosphocholine present in cell extracts with picomole sensitivity. 211 61

Two alternative procedures are described for the quantitative determination of phosphatidylcholine in a flow-injection system utilizing immobilized enzymes. Phospholipase C from Bacillus cereus and phospholipase D from cabbage were covalently bound to the surface of controlled-pore glass beads and the enzyme-derivatized beads were packed in small columns. In the first procedure, the phospholipase C column was connected with a second column containing coimmobilized alkaline phosphatase and choline oxidase. In the alternative procedure, the column packed with immobilized phospholipase D was connected with a column packed with immobilized choline oxidase. The hydrogen peroxide produced through the action of choline oxidase in both flow-injection systems was detected amperometrically. Both procedures are suitable for an accurate and rapid quantitation of phosphatidylcholine. The sensitivity of the method based on phospholipase C and alkaline phosphatase is higher than that using phospholipase D. Quantitation of phosphatidylcholine at the nanomole level can be easily obtained using the first method.
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PMID:Determination of phosphatidylcholine in a flow injection system using immobilized enzyme reactors. 220 Mar 5

1. We determined the organ of origin and possible mechanism of translocation into the circulation of alkaline phosphatase (ALPase) in the diabetic rat. 2. Experimental diabetes was induced by injection of streptozotocin, resulting in a 8.2-fold elevation in serum ALPase activity. In this case, the major ALPase isozyme detected in serum was intestinal ALPase. 3. In in vitro experimental systems, ALPase was readily released from the duodenal plasma membrane by bacterial phosphatidylinositol-specific-phospholipase C (PI-PLase C) but little if any was released from the ileal membrane. 4. Serum and ileal ALPases were identical in terms of molecular size, whereas duodenal ALPase clearly differed from the serum enzyme. 5. Based on an investigation of the sugar moiety, more of the fraction having higher concanavalin A affinity was found in serum ALPase than with in the case of either of the intestinal ALPases. Serum and intestinal ALPases also differed slightly regarding isoelectric points. 6. Consequently, these data suggest that the serum ALPase of the diabetic rat is derived from ileal ALPase, and it is unlikely that the appearance of ALPase in the circulation is simply the result of solubilization by the action of PI-PLase C or phospholipase D.
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PMID:Translocation of intestinal alkaline phosphatase in streptozotocin-induced diabetic rats. 225 56

A fraction of intestinal alkaline phosphatase (IAP) is secreted into blood. To study this process, enzyme secretion was examined in a fetal (IRD-98) and a differentiated (Caco-2) intestinal cell line. Tissue-unspecific alkaline phosphatase (AP) activity in the IRD-98 cells increased 20-fold after addition of 1.5 mM sodium butyrate and 40 mM NaCl, but no AP activity was secreted into the medium. In contrast, newly synthesized IAP in Caco-2 cells was secreted into the medium. AP secretion increased with time and was inhibited by monensin. Medium AP was still partially bound to membranes as assessed by Triton X-114 phase separation and could be released by the addition of serum. Analysis by sodium dodecyl sulfate polyacrylamide gels and by isoelectric focussing showed that secreted AP gave a pattern similar to that of the AP released from membranes by phospholipase D treatment. When Caco-2 cells were grown on filters, AP activity was found in both basolateral (75%) and luminal (25%) media. These data demonstrate that the secretion of a particulate AP with extracellular release from the membrane can account for the appearance of the intestinal isozyme in both the serum and the lumen.
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PMID:Intestinal alkaline phosphatase is secreted bidirectionally from villous enterocytes. 254 40

Binding of two monoclonal anti-liposome antibodies to the surface of cultured murine peritoneal macrophages was investigated by indirect immunofluorescence and enzyme-linked immunosorbent assay. Neither antibody bound to cultures of freshly explanted, nonadherent macrophages, but immunoreactivity was observed following cell adherence to tissue culture plastic. Fluorescent microscopic evaluation revealed heterogeneity in staining patterns of the antibodies on adherent cells. Binding both to viable and fixed adherent macrophages was observed even after a 10,000-fold dilution of antibody. Treatment of adherent macrophage cultures with trypsin increased antibody binding. Further treatment of trypsinized-macrophages with alkaline phosphatase or neuraminidase did not affect antibody binding, but phospholipase D and, to a greater extent, phospholipase C resulted in a marked decrease in cellular binding. The data indicate that antibodies produced against liposomes appear to bind to surface phospholipids of macrophages, but binding can be influenced by the physiological state of the macrophage and overlying cell surface proteins.
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PMID:Antibodies to phospholipids and liposomes: binding of antibodies to cells. 282 Apr 89

Alkaline phosphatase in a wide range of tissues has been shown to be anchored in the membrane by a specific interaction with the polar head group of phosphatidylinositol. It has previously been suggested that the production of low Mr alkaline phosphatase during the commonly used butanol extraction procedure may result from the activation of an endogenous phosphoinositide-specific phospholipase C which removes the 1,2-diacylglycerol responsible for membrane anchoring. This conversion process was investigated in greater detail with human placenta used as the source of alkaline phosphatase. Mr and hydrophobicity of the alkaline phosphatase were determined by gel filtration on TSK-250 and partitioning in Triton X-114, respectively. Alkaline phosphatase extracted from human placental particulate fraction with butanol at pH 5.4 or released by incubation with Staphylococcus aureus phosphatidylinositol-specific phospholipase C produced a form of alkaline phosphatase of Mr approx. 170,000 and relatively low hydrophobicity. By contrast, the butanol extract prepared at pH 8.3 was an aggregated form of Mr approx. 600,000 and was relatively hydrophobic. The effect of a variety of inhibitors and activators on the amount of low Mr alkaline phosphatase produced during butanol extraction revealed that it was a Ca2+- and thiol-dependent process. Proteinase inhibitors had no effect. [3H]Phosphatidylinositol hydrolysis by the particulate fraction, unlike low Mr alkaline phosphatase production, was relatively sensitive to heat inactivation, indicating that the phosphoinositide-specific phospholipases C from cytosol and lysosomes were unlikely to be responsible for conversion. A butanol-stimulated activity which removed the [3H]myristic acid from the variant surface glycoprotein ( [3H]mfVSG) of Trypanosoma brucei was detectable in the human placental particulate fraction. Since this activity was acid active, Ca2+- and thiol-dependent and relatively heat stable, it may be the same as that responsible for production of low Mr alkaline phosphatase. The only 3H-labelled product identified was phosphatidic acid, suggesting that the [3H]mfVSG-cleaving activity is a phospholipase D. These data strongly support the proposal that production of low Mr alkaline phosphatase during butanol extraction is an autolytic process occurring as the result of an endogenous phospholipase. However, they also suggest that the lysosomal and cytosolic phosphoinositide-specific phospholipases C that have previously been described in many mammalian tissues are not responsible for this process.
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PMID:Conversion of human placental alkaline phosphatase from a high Mr form to a low Mr form during butanol extraction. An investigation of the role of endogenous phosphoinositide-specific phospholipases. 302 77


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