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.     

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.     

Studies of the heterogeneity of carp liver acid phosphatases: acid phosphatase--I. Subunit structure and carbohydrate composition

The three molecular forms of the carp liver acid phosphatase (AcPase) were shown to be dimeric proteins, two of them differing in molecular weights. An activating effect of ConA binding on the AcPases has been observed. AcPase I and AcPase II showed a mol. wt of 122,500 and of 58,884 +/- 3000 for their subunits. It is assumed that AcPase I is a sialylated derivative of AcPase II. AcPase III has a mol. wt of 93,132 and the two subunits of 46,556 +/- 4000. A homogeneous AcPase I was obtained and its carbohydrate composition is presented.     

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.     

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.     

Catfish liver acid phosphatases: differently glycosylated enzyme molecules with altered kinetic properties

Two forms of catfish liver acid phosphatase (AcPase I and II) were separated and purified to homogeneity and their carbohydrate compositions and some biochemical properties were studied. Evidence is given that AcPase I and II are differently glycosylated forms of the same enzyme. The enzyme forms differ significantly in the size and the composition of their carbohydrate components, sensitivity towards sulfhydryl-blocking and protecting reagents, sensitivity to ferric and ferrous ions, thermostability and ability to hydrolyze some nucleotides. The more highly glycosylated form is more sensitive to thermal denaturation. AcPase I and II behave differently towards ascorbate and changes in its concentration and it is suggested that the concentration of reducing modifiers may regulate AcPase activity at the cellular level. It is hypothesized that the differing extents of glycosylation influence the structure of the enzyme forms. This is expressed in altered conformations of two enzyme forms and results in a different exposure of the essential cysteine residues.     

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.     

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.     

Acid phosphatases in mammalian tissues. Evidence for the existence of a 57 kDa Zn(2+)-dependent acid phosphatase form.

1. A comparative study of multiple forms of acid phosphatase (AcPase) in various organs of mammals was carried out. 2. These studies indicated that the high-molecular weight AcPase is preferentially expressed by tissues which undergo cell proliferation such as epithelial tissues; on the contrary, the low-molecular weight enzyme seems to be characteristic of highly differentiated tissues such as nervous, muscle and blood erythrocytes. 3. The existence of a new AcPase activated by Zn2+ ions was observed in all tissues studied with the exception of erythrocytes. 4. The enzyme shows a molecular weight of 57 kDa, is insensitive to NaF, hydrolyzes p-nitro-phenylphosphate and o-c-phenylphosphate; ATP, a-naphthyl-phosphate and beta-glycerolphosphate are also dephosphorylated.     

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.

     

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 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.     

Spontaneous conversion of carp liver AcPase I and some properties of its asialo-form

Evidence is given for a spontaneous conversion of AcPase I to a more basic form due to autolytic loss of sialic acid. To investigate whether the presence of sialic acid in the enzyme molecule is of any physiological significance some physico-chemical properties of an enzymatically obtained asialo-AcPase I were studied. It has been shown that the asialo-form retained the properties of the native enzyme in respect to thermostability and pH-stability but modified slightly the hydrolytic activities of some phosphorylated compounds, and this might be of significance under physiological conditions.     

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.     

Isolation from rat liver of a peroxisomal enzyme which converts molecular form 1 of biliverdin reductase into molecular form 3

Cobaltous chloride induced in rat liver an enzyme which converted biliverdin reductase molecular form 1 into the molecular form 3. This conversion involves the oxidation of two sulfhydryl groups of form 1 giving rise to a disulfide bond in form 3. The converting enzyme was isolated from the liver peroxisomal fraction (which was devoid of biliverdin reductase activity), and was absent in liver peroxisomes of control rats. The enzyme was solubilized by treatment of the peroxisomes with 0.1% sodium deoxycholate, and partially purified by DEAE-cellulose and Sephadex G-100 filtration. It is a NAD⁺ dependent enzyme which was inactivated by trypsing and heat treatments. It did not oxidize either reduced glutathione or cysteine. The converting enzyme had a molecular weight of about 54,000 daltons. The oxidation of biliverdin reductase molecular form 1 mediated by the converting enzyme did not affect the latter's molecular weight or activity.     

Multiplicity of bovine liver GM1 ganglioside beta-galactosidase

The multiplicity of bovine liver acid beta-galactosidase was investigated. Acid beta-galactosidase activity was measured in the presence of glucono-delta-lactone, which inhibited the neutral beta-galactosidase activity but not the acid beta-galactosidase activity in bovine liver. Three forms of acid beta-galactosidase were separated by Sephadex G-200 gel filtration and the elution pattern of the 4-methylumbelliferyl-beta-galactosidase activity coincided with that of the GM1-beta-galactosidase activity. These forms were relatively stable under acidic conditions (pH 4.5), but the two high molecular weight forms were inclined to dissociate into the low molecular weight form under neutral conditions (pH 7.0). The three forms of the enzyme showed similar pH-optima and apparent Michaelis constants for GM1 ganglioside.     

Ultrastructural localization of lysosomal enzymes in the egg cortex of Brachydanio

The localization of acid phosphatase (E.C. 3.1.3.2), inorganic trimetaphosphatase (E.C. 3.6.1.2), and aryl sulfatase (E.C. 3.1.6.1) in the cortex of unactivated and activated eggs of Brachydanio was examined by ultrastructural cytochemistry. Using a lead capture method, activity for all three acid hydrolases was demonstrated in organelles of the cortex before and after egg activation. Acid phosphatase (AcPase) reaction product was consistently present in primary lysosomes, secondary lysosomes, multivesicular bodies, and yolk bodies. AcPase activity was absent from mitochondria, profiles of the endoplasmic reticulum, coated pits of exocytosed cortical granules, and coated vesicles. Although most cortical granules of the mature, unactivated egg were unreactive for this enzyme, a few showed AcPase reaction product. It is not clear whether the AcPase-positive granules might be an immature form of cortical granules or a subpopulation of these organelles with lysosomal properties. Most cisternae of the Golgi apparatus did not stain for AcPase; however, reaction product was occasionally localized in a single cisterna as well as several small vesicles at the inner face of the Golgi. The intensity of the reaction product and the pattern of distribution of trimetaphosphatase (Tm-Pase) activity was very similar to that of AcPase. However, TmPase was never observed in cortical granules. Cortices of unactivated and activated eggs showed less overall aryl sulfatase (ArSase) activity when compared with AcPase and TmPase. The presence of ArSase reaction product in lysosomes and multivesicular bodies confirmed the acid hydrolytic nature of these organelles. AcPase and TmPase, and to a lesser extent ArSase, are adequate markers of a cortical lysosomal system in the danio egg.(ABSTRACT TRUNCATED AT 250 WORDS)     

Forms and intracellular distribution of alpha-D-mannosidases in murine liver and spleen

1. The intracellular distribution of alpha-D-mannosidase in homogenates of murine liver and spleen was investigated by differential and gradient density centrifugation. 2. In both tissues an enzyme with a neutral pH optimum was found in the cytosol together with an alpha-D-mannosidase with optimal activity between pH 5.5 and 6.0 which was also partially membrane-bound. 3. In liver the acidic alpha-D-mannosidase was obtained almost entirely in a particulate form distributed equally between a heterogeneous low density region and heavy density lysosomes. 4. The lysosomal form of the liver enzyme was purified to electrophoretic homogeneity and shown to be a glycoprotein composed of four identical subunits of molecular weight 65 kDa. 5. Antibody raised against the purified liver alpha-D-mannosidase immunoprecipitated a polypeptide from spleen which had the same molecular size. This acidic enzyme was the predominant type of alpha-D-mannosidase in spleen, but in contrast to liver, it was obtained mainly in a cytosoluble form, the remaining activity being present in the heterogeneous light density compartment. 6. Although both tissues contain the same molecular form of the acidic alpha-D-mannosidase, in murine spleen this enzyme does not appear to be associated with stable heavy density lysosomes.     

The interrelation between high- and low-molecular-weight forms of GM1-beta-galactosidase purified from porcine spleen

1) Two forms of acid beta-galactosidase [EC 3.1.23] with different molecular weights catalyzing the hydrolysis of GM1-ganglioside and p-nitrophenyl-beta-D-galactoside were separated and purified from porcine spleen. 2) The apparent molecular weights were 400,000-600,000 and 70,000-74,000 for the high (termed Am form) and low (termed A1 form) molecular weight forms, respectively. 3) On examination by sodium dodecyl sulfate (SDS)/polyacrylamide gel electrophoresis, both forms of the enzyme had a common protein band of molecular weight 63,000, and the Am form showed three additional protein bands with molecular weights of 31,000, 21,000, and 20,000. 4) Both forms of the enzyme had similar catalytic functions with regard to pH-optimum, Km, substrate specificity and sensitivity to substrate analogues and other substances such as detergents, bovine serum albumin (BSA) and NaCl. 5) Both forms of the enzyme were fairly stable upon preincubation at 45 degrees C at acidic pH (pH 4.5), but lost their activities at neutral pH (pH 7.0). 6) The A1 form was a monomer at neutral pH (pH 7.0) and formed a dimer at acidic pH (pH 4.5). However, most of the Am form could not be converted to a dimeric form on gel filtration at acidic pH.     

Purification and some properties of tartrate-sensitive acid phosphatase from rabbit kidney cortex.

Two forms of tartrate-sensitive acid phosphatases (EC 3.1.3.2) were purified from rabbit kidney cortex by a multiple-column-chromatography method. The basic form constituted 90% of the enzyme and migrated as a single band of protein on polyacrylamide-gel electrophoresis. The proteins contaminating the acidic form did not exceed 5% of the total protein. The specific activity towards p-nitrophenyl phosphate was 12 mumol/min per mg for the basic form and 0.7 mumol/min per mg for the acidic form. The basic form of the enzyme differs from the acidic form in its heat-stability, Km values, inhibition rates by tartrate and fluoride and substrate specificities. Relative to p-nitrophenyl phosphate hydrolysis rate, the acidic form hydrolysed a variety of physiological monophosphate esters, whereas the basic form hydrolysed only CMP and phosphoenolpyruvate. Bacterial neuraminidases had no effect on the activity and mobility of the acidic form on polyacrylamide-gel electrophoresis. Both forms have the same molecular weight (101000 +/- 4000) and are probably composed of two identical subunits. The question whether the two forms of the enzyme are different proteins or whether one is a modified form of the other is discussed.