Acid phosphatase from liver of the frog Rana esculenta, separation and partial characterization of multiple forms.

1. Acid phosphatase (AcPase) from liver of the frog, Rana esculenta has been isolated and purified. The enzyme is heterogeneous, showing 4 activity zones on disc electrophoresis. The AcPase was separated into 3 peaks on DEAE-cellulose. Peak A corresponding to the electrophoretic AcPase IV represents an extensively purified enzyme form. 2. The separated enzyme forms are change isomers with a molecular weight of about 33,000. They differ markedly in substrate requirements and sensitivity towards activators and inhibitors. All of them are highly activated by dithiothreitol, show a rather restricted substrate specificity, and marked activity against ATP.     

Immunolocalization of an Acid Phosphatase from Pearl Oyster (<Emphasis Type="Italic">Pinctada fucata</Emphasis>) and Its In Vitro Effects on Calcium Carbonate Crystal Formation

Distribution of an acid phosphatase, AcPase I, from pearl oyster (Pinctada fucata) in different tissues was investigated via enzyme activity determination and immunohistochemistry. Positive reactions were observed in sections of digestive gland, base of gill filaments, and epithelia of the outer side of the middle fold and the inner side of the outer fold, which indicated AcPase I might participate in processes besides immune defense, such as calcium metabolism or shell formation. Its effects on CaCO₃ crystal formation were studied in vitro. Results revealed that AcPase I inhibited CaCO₃ precipitation in a dose-dependent manner and had no affinity for calcium. CaCO₃ crystals induced by AcPase I exhibited a cluster needle-like morphology, which proved to be aragonite. The morphology and size of the aragonites varied with different concentrations of AcPase I. Our observations described here may provide important clues to further understanding of the correlations between mineralization and immune defense in the oyster.     

The high molecular weight and the low molecular weight acid phosphatases of the frog liver and their phosphotyrosine activity

1. Two molecular weight classes of non-specific acid phosphatases (AcPases) (3.1.3.2) are present in the frog (Rana esculenta) liver: a higher molecular weight (HMW) of Mr 140,560 and a lower molecular weight (LMW) of Mr 38,180 enzyme. 2. The LMW AcPase was described earlier and the HMW AcPase of optimum pH 4.8 is shown to be a L(+)-tartrate sensitive, thermolabile, dimeric glycoenzyme slightly activated by DTT. 3. The HMW and the LMW AcPases exhibit activity for phosphotyrosine which showed similar sensitivity to various effectors as the p-nitrophenyl phosphatase activity; however, both enzymes differed substantially in this respect suggesting that they might be involved in different metabolic steps.     

Histochemical studies of acid and alkaline phosphatases in rat tooth germs with undecalcified resin-embedded specimens.

A novel technique for the histochemical demonstration of acid phosphatase (AcPase) and alkaline phosphatase (AkPase) in hard tissues has been proposed. Fresh, unfixed, undecalcified samples of rat tooth germs and surrounding structures were embedded in LR Gold resin at -20 degrees C. Sections of 2 microns were taken and subsequently processed for enzyme histochemistry. AkPase reaction product appeared as strong linear staining outlining cell boundaries and was present in the enamel organ, dental pulp, and osteoblast cells. Tartrate-resistant AcPase staining was seen exclusively in the osteoclasts of developing alveolar bone. Our results demonstrated that the use of unfixed, undecalcified LR Gold resin-embedded specimens for histochemistry is a novel technique which may be of value for certain studies when decalcification of specimens is undesirable. The technique appears to give good preservation of enzyme activity combined with the ability to prepare sections with excellent morphological detail.     

Extralysosomal localisation of acid phosphatase in the rat kidney

 There is strong evidence that acid phosphatase (AcPase) plays an important role in the catabolism of the glomerular basement membrane (GBM) and the removal of macromolecular debris resulting from ultrafiltration. Recent enzyme histochemical investigations provide new evidence of the antithrombotic and anti-inflammatory function of ADPase and on the distribution of AcPase in mouse kidney tubule cells. By means of 3 mM cerium as the trapping agent and 1 mM p-nitrophenyl phosphate as the substrate, extralysosomal AcPase could be demonstrated at the ultrastructural level. Following a mild perfusion fixation (2% formaldehyde + 0.07% glutaraldehyde), an effective postfixation and short enzyme incubations (20 min) with microwave irradiation, highly specific enzyme histochemical reaction product and reasonable structural preservation were obtained. Extralysosomal, membrane-bound AcPase was observed along the endoplasmic reticulum, the trans-Golgi cisternae, the nuclear envelope, basal infoldings of the proximal and distal tubular cells and on glomerular profiles, e.g. cell membranes of podocytes, endothelium and basement membrane. Large amounts of extralysosomal AcPase were observed in the basement membrane of glomeruli, in contrast to no AcPase activity in the tubular and mesangial basement membrane. The observed difference in AcPase activity in the tubular epithelial basement membrane and the GBM supports the idea that AcPase in GBM specifically serves in the clearance of macromolecular debris to facilitate ultrafiltration. In the GBM a laminar distribution is observed, suggesting that both epithelial and endothelial cells are involved in the production of AcPase. Accepted: 16 September 1997     

Amino acid composition and immunochemical properties of AcPase III and AcPase IV representing glycoforms of the lower molecular weight, tartrate-resistant acid phosphatase of the frog liver.

1. Amino acid composition and immunological properties of the frog liver LMW AcPase forms: AcPase III and IV were examined. 2. AcPase III and IV show nearly identical amino acid composition and close immunological similarity. 3. These results indicate protein identity of both the enzyme forms and together with our previous data [Kubicz A., Szalewicz A. and Chrambach A., Int. J. Biochem. 23, 413-419 (1991)] demonstrate that generation of AcPase III and IV is a modification of the same enzyme protein by glycosylation processes. 4. Differences in immunoreactivity between AcPase III and IV were observed and discussed to be due to their altered conformations.     

Multiple forms of acid phosphatase and their differential secretion during stalk formation under submerged monolayer incubation of Dictyostelium discoideum

The electrophoretic pattern of intracellular and secreted acid phosphatases (AcPases) in Dictyostelium discoideum was examined during incubation of the cells as a submerged monolayer. Three distinct forms of the enzyme were observed in the cell during differentiation; one was detected throughout development (AcPase 1), whereas the others including AcPase 2 were stage-specific. AcPase 1 was released in the medium predominantly in early development and AcPase 2, a prestalk specific form, was secreted during stalk formation. When cells were incubated under conditions where stalk cells did not form, only AcPase 1 was recognized both in the cell and in the medium.     

The 35 kDa acid metallophosphatase of the frog Rana esculenta liver: studies on its cellular localization and protein phosphatase activity

The cellular localization of the 35 kDa, low molecular mass acid metallophosphatase (LMW AcPase) from the frog (Rana esculenta) liver and its activity towards P-Ser and P-Tyr phosphorylated peptides were studied. This enzyme was localized to the cytoplasm of hepatocytes but did not appear in other cells of liver tissue (endothelium, macrophages, blood cells). This LMW AcPase does not display activity towards (32)P-phosphorylase a under conditions standard for the enzymes of PPP family. Proteins containing P-Ser: rabbit (32)P-phosphorylasea and phosvitin are hydrolysed only at acidic pH and are poor substrates for this enzyme. The frog AcPase is not inhibited by okadaic acid and F(-) ions, the Ser/Thr protein phosphatase inhibitors. Moreover, the frog enzyme does not cross-react with specific antisera directed against N-terminal fragment of human PP2A and C-terminal conserved fragment of the eukaryotic PP2A catalytic subunits. These results exclude LMW AcPase from belonging to Ser/Thr protein phosphatases: PP1c or PP2Ac. In addition to P-Tyr, this enzyme hydrolyses efficiently at acidic pH P-Tyr phosphorylated peptides (hirudin and gastrin fragments). K(m) value for the hirudin fragment (7.55 +/- 1.59 x 10(-6) M) is 2-3 orders of magnitude lower in comparison with other substrates tested. The enzyme is inhibited competitively by typical inhibitors of protein tyrosine phosphatases (PTPases): sodium orthovanadate, molybdate and tungstate. These results may suggest that the LMW AcPase of frog liver can act as PTPase in vivo. A different cellular localization and different response to inhibition by tetrahedral oxyanions (molybdate, vanadate and tungstate) provide further evidence that LMW AcPase of frog liver is distinct from the mammalian tartrate-resistant acid phosphatases.     

The lower molecular weight acid phosphatase from the frog liver: isolation of homogeneous AcPase III and IV representing glycoforms with different bioactivity

1. AcPase III and AcPase IV, the major enzyme forms of the LMW AcPase of the frog (Rana esculenta) liver were resolved and purified to homogeneity. 2. AcPase III and IV showed a single protein band on SDS-PAGE corresponding to a mol. wt (Mr) of about 35,000. The Mr of the native enzyme forms were 33,200 (gel electrophoresis) and 38,200 +/- 5000 (gel filtration). This indicates that they are monomeric proteins sharing the same protein molecule. 3. AcPase III and IV differ essentially in thermostability and the activating effect of ConA binding. 4. AcPase III and IV are considerably activated with DTT but they differed markedly by the extent of this activation and the accompanying changes of their pH-activity curves. 5. It is suggested that the frog liver LMW AcPase represents a set of glycoforms whose different bioactivity is determined by the redox states of their essential cysteine residues.     

Isolation and characterization of a homogeneous acid phosphatase from catfish liver

A homogeneous, tartrate-inhibitable acid phosphatase (AcPase) was obtained from the liver of channel catfish (Ictalurus punctatus) by the use of Affi Gel-10-coupled aminohexyltartramic acid affinity chromatography. The enzyme has a molecular weight of 82,500 and is a dimer consisting of two apparently equivalent subunits with subunit weights of 35,000 +/- 3000. Amino acid composition data are presented and compared with those of mammalian acid phosphatases. Data suggest that the enzyme is a metalloacid phosphatase. Catfish liver AcPase exhibits two molecular forms with pI 5.66 and 5.37 which were separated by chromatofocusing. A spontaneous conversion of the less acidic form to a more acidic form was observed and this conversion was accompanied by a decreased sensitivity towards tartrate inhibition.     

Phagosome-lysosome interactions related to erythrophagocytosis in Kupffer cells of fetal rat liver

Kupffer cells of fetal rat liver were examined by ultrastructural cytochemical methods to reveal acid phosphatase (AcPase) activity in lysosomes. Elongated cisternae, 940-1150 A in width containing AcPase reaction product, were identified in these cells. These cisternae were sometimes in continuity with phagosomes containing engulfed erythrocytes. Observations suggest that such cisternae may partly encircle these phagosomes. The relationships of these cisternae to GERL (Golgi Endoplasmic Reticulum Lysosomes) is discussed.     

Two subfamilies of plant purple acid phosphatases

The cDNA sequences of two purple acid phosphatases (previously purified AcPase1 and putative AcPase2) from yellow lupin ( Lupinus luteus L) have been determined. AcPase1 mRNA is 1755 nt in length, including a single open reading frame of 1434 nt that encodes 477 amino acid residues (EMBL accession number AJ458943 ). The AcPase2 mRNA is a 170-nt molecule, including a single open reading frame of 1392 nt that encodes 463 amino acid residues (EMBL accession number AJ505579 ). Both sequences were compared with known purple acid phosphatases (PAPs). The analysis of all known PAP sequences showed that they are divided into two subfamilies. The characteristic feature of the first subfamily containing AcPase1 is the lack of cysteine residues in the C-terminal region of the polypeptide around position 350. AcPase2 belongs to the second subfamily which contains a disulphide bridge formed of cysteines present around position 350. A possible relationship between structure and substrate specificity in these two PAP subfamilies is presented. Expression of AcPase1 and AcPase2 shows that the first enzyme is produced in the early stage of germination (its mRNA in polyadenylated form is present already in dry seeds), whereas the second phosphatase is produced mainly in the roots of mature plants. The early expression of AcPase1 was confirmed by a comparative analysis of a cotranslational N-glycosylation of AcPase1 and diphosphonucleotide phosphatase/phosphodiesterase ( PPD1 ) known to be expressed in the final stage of germination.     

Immunological characterization of human acid phosphatase gene products

The immunological cross-reactivity of heterogeneous acid phosphatase isozymes from different human tissues has been studied using monospecific antisera prepared against four homogeneous acid phosphatases. The enzyme characterized as tartrate-inhibitable, prostatic acid phosphatase is also found to be present in leukocytes, kidney, spleen, and placenta. The tartrate-inhibitable (liver) lysosomal enzyme is also found in kidney, fibroblasts, brain, placenta, and spleen, but it is not detectable in erythrocytes and prostate. In several tissues, 10–20% of the tartrate-inhibitable enzyme is not precipitated by any of the antisera used; an exceptionally high amount (54%) of such an enzyme is present in human brain. Antiserum against a low molecular weight tartrate-resistant liver enzyme (14 kDa) does not cross-react with the erythrocyte enzyme. (10–20 kDa). All other tissues except placenta, prostate, and fibroblast cells show a cross-reactivity with the 14-kDa acid phosphatase antiserum. Thus, the low molecular weight human liver acid phosphatase is distinct from the erythrocyte enzyme, and there are also at least three different tartrate-inhibitable acid phosphatases in human tissues. Chromosomal assignments have been made for only two of the (at least) five acid phosphatases that are present in adult human tissues.This study was supported by DHHS Research Grant GM 27003 from the U.S. National Institute of General Medical Sciences and by Grant SFB-104 from the Deutsche Forschungsgemeinschaft.     

Studies on the oligosaccharide heterogeneity of the isoelectric forms of the lower molecular weight acid phosphatase of frog liver

1. The lower molecular weight, heterogeneous acid phosphatase (AcPase) from the frog liver (Rana esculenta) containing AcPase I, II, III and IV was separated into enzymatically active components by isoelectric focusing in an immobilized pH gradient. 2. The blotted enzyme bands were characterized by their different binding patterns obtained with the lectins concanavalin A, wheat germ agglutinin (WGA), Lens culinaris hemagglutinin (LcH) and peanut agglutinin (PNA). 3. In situ neuraminidase treatment reduced the staining intensity of some WGA-bands and increased that of PNA-bands. 4. The finding that AcPases I, II, III and IV differ in their carbohydrate chain composition, together with previous results showing different bioactivities of AcPases III and IV, indicates a correlation between the glycosylation state of enzyme forms and their physiological action.     

Acetylcholinesterases.

Acetylcholinesterase (E.C.3.1.1.7) is a widely distributed enzyme, particularly in excitable tissues such as muscle, nerve, and electric organs but also found in erythrocytes and snake venoms. The function of the enzyme at postsynaptic sites in excitable tissues is considered to be termination of synaptic transmission via the hydrolytic inactivation of acetylcholine. The functional role of the enzyme at extrajunctional sites of excitable tissues, in nerve endings and in the erythrocyte has not been established. In the past five or six years substantial progress has been made in terms of our understanding of acetylcholinesterases (AChE) particularly with regard to their molecular characterization, their subunit structure and their immunological properties. These advances have been due in part to successful purification of enzymes from various tissues by the application of affinity chromatography techniques. In addition, some progress has been made regarding physiological aspects of the development and regulation of AChE in excitable tissues. This review will focus on these aspects of AChE by reference to work utilizing the enzyme from the following sources: electric tissue of the eel, $\text{Electrophorus electricus}$, or electric fish, $\text{Torpedo}$, species; mammalian and avian skeletal muscle; neural tissues, particularly mammalian brain; and the mammalian erythrocyte. For more comprehensive reviews of AChE readers are referred to the following references (1, 2).     

Purification and some properties of a Mg2+-activated acid phosphatase from rat testis

• 1.1. The acid phosphatase (AcPase, EC 3.1.3.2) IV from rat testicular tissue was purified to apparent homogeneity.
• 2.2. The enzyme displays a native molecular weight of 70 kDa determined on gel permeation chromatography on a Sephadex G-100 column and 68 kDa using linear 5–20% sucrose density gradient centrifugation. The subunit molecular weight on SDS-PAGE analysis is 67 kDa, suggesting that the enzyme is a monomeric protein.
• 3.3. The enzyme does not bind to Concanavaline A-Sepharose 4B column, indicating that it is not a glycoprotein.
• 4.4. The rat testis AcPase IV is a metal activated enzyme in which Mg²⁺ is the metal activating agent with a K_a, = 0.88 × 10⁻³ M. The Michaelis constant for p-nitrophenylphosphate, in the presence of saturating concentrations of Mg²⁺ ions, is 0.23 × 10⁻³ M.
• 5.5. The enzyme preferentially hydrolizes p-nitrophenylphosphate, phenylphosphate and ATP.

     

Properties of inorganic pyrophosphatase of pig scapula cartilage.

The properties of a highly purified inorganic pyrophosphatase (pyrophosphate phosphohydrolase; EC 3.6.1.1) from pig scapula cartilage were studied. The enzyme had a molecular weight of 66 000 and a pH optimum of 7-8. It was markedly activated by magnesium, but not, or only to a much smaller degree, by other metal ions. PP1 was the only substrate found and had a Km value of 11 muM. The enzyme was not inhibited by phosphate and other inhibitors of alkaline phosphatase such as CN- minus, amino acids and theophylline; it was slightly inhibited by tartrate, formaldehyde and ammonium molybdate and strongly inhibited by F- minus, Ca2+ and other metal ions. The properties of the enzyme in the presence of concentrations of PP1 present in plasma (3.5 muM) were similar to those found at higher (2 mM) concentrations of PP1. The diphosphonates ethane-1-hydroxy-1,1-diphosphonate and dichloromethylenediphosphonate inhibited the enzyme in the presence of low PP1 concentrations. The characteristics of this enzyme are therefore similar to pyrophosphatases from other sources, such as from yeast and erythrocytes, and do not support a specific role of this enzyme in the calcification process.     

An Inhibition and Kinetic Study of Acid Phosphatase in Paramecium caudatum and Paramecium tetraurelia1

ABSTRACT. Inhibition, inactivation, pH, and kinetic studies using both homogenates and purified lysosomal fractions of Paramecium caudalum and of P. tetraurelia were carried out to examine the lysosomal acid phosphatase (AcPase) and its relationship to p-nitrophenylphosphatase (pNPPase), glucose-6-phosphatase (G6Pase), and 5′-nucleotidase (AMPase). The results generally support the idea that Paramecium cells contain a distinct lysosomal AcPase with a broad substrate specificity. The hydrolysis of glucose-6-phosphate (G6P) and adenosine 5′-monophosphate (AMP) was shown to be due to this enzyme, suggesting that true G6Pase and AMPase may be lacking in these two species; however, some hydrolysis of AMP at pH 7.5 catalyzed by an unknown soluble enzyme distinct from alkaline phosphatase and Na⁺-K⁺-ATPase was observed. Since the hydrolysis of p-nitrophenylphosphate (pNPP) at acid pH was also shown to be due to AcPase alone, pNPPase could be used as a rapid assay for Paramecium AcPase. At an alkaline pH, however, this activity was catalyzed by an alkaline phosphatase located in the cytosol fraction. P. caudatum AcPase was shown to have kinetic properties similar to those of purified rat liver and human prostatic AcPase and to have relative substrate affinities in the order of G6P < β-glycerophosphate < pNPP < AMP. These different substrate affinities might account for the observed differences in the inhibition of the four lysosomal activities by NaF, L(+)-tartrate, and molybdate, all of which inhibited the hydrolysis of G6P, β-glycerophosphate, and pNPP competitively, but which exhibited a noncompetitive inhibition of a mixed type with the hydrolysis of AMP.     

Characterization of the type of carbohydrate chains of the higher molecular weight (140 kDa) acid phosphatase of the frog liver

• 1.1. The higher molecular weight, (HMW, M_r 140 kDa) acid phosphatase (AcPase) of the frog liver (Rana esculenta) was separated into enzymatically active components by isoelectric focusing in an immobilized pH gradient and their carbohydrate chains were analyzed by specific lectin binding after native blotting.
• 2.2. The lectin-binding patterns obtained with ConA, WGA, LcH and PNA as well as with WGA and PNA after desialylation indicate that the frog liver HMW AcPase contains predominantly N-linked complex and/or hybride type carbohydrate chains with terminal sialic acid and fucose residues; O-glycosylated enzyme components with free and sialic acid substituted Gal-GalNAc sequences were also detected.

     

Purification and properties of glutathione peroxidase from human placenta.

Glutathione peroxidase (glutathione--H2O2 oxidoreductase; EC 1.11.1.9) was purified to homogeneity from human placenta by using (NH4)2SO4 precipitation, ion-exchange chromatography, Sephadex gel filtration and preparative polyacrylamide-disc-gel electrophoresis. Glutathione peroxidase from human placenta is a tetramer, having 4g-atoms of selenium/mol of protein. The molecular weight of the enzyme is about 85000 with a subunit size of about 22,000. Kinetic properties of the enzyme are described. On incubation with cyanide, glutathione peroxidase is completely and irreversibly inactivated and selenium is released as a low-molecular-weight fragment. Reduced glutathione, beta-mercaptoethanol and dithiothreitol protect the enzyme from inactivation by cyanide and the release of selenium. Properties of human placental glutathione peroxidase are similar to those of isoenzyme A reported earlier by us from human erythrocytes. The presence of isoenzyme, B, reported earlier by us in human erythrocytes, was not detected in placenta. Also selenium-independent glutathione peroxidase (isoenzyme II), which is specific for cumene hydroperoxide, was not present in human placenta.