Cortisol modification of HeLa 65 alkaline phosphatase. Decreased phosphate content of the induced enzyme.

Alkaline phosphatase activity of HeLa cells is increased 5-20-fold during growth in medium with cortisol. The increase in enzyme activity is due to an enhanced catalytic efficiency rather than an increase in alkaline phosphatase protein in induced cells. In the present study the chemical composition of control and induced forms of alkaline phosphatase were investigated to determine the enzyme modification that may be responsible for the increased catalytic activity. HeLa alkaline phosphatase is a phosphoprotein and the induced form of the enzyme has approximately one-half of the phosphate residues associated with control enzyme. The decrease in phosphate residues of the enzyme apparently alters its catalytic activity. Other chemical components of purified alkaline phosphatase from control and induced cells are similar; these include sialic acid, hexosamine and sulfhydryl residues.     

Physico-chemical properties of alkaline phosphatase from the seal small intestine

Alkaline phosphatase of the Greenland seal was purified to homogeneity, using immobilized concanavalin A. The specific activity of the enzyme is 1200-1500 mu/mg protein. The molecular mass of alkaline phosphatase as determined by electrophoresis performed under non-denaturating conditions is 260 kD, whereas that determined in the presence of beta-mercaptoethanol and SDS is 70 kD, which points to the tetrameric type of the seal alkaline phosphatase molecule. Using the atomic adsorption method, it was demonstrated that the phosphatase molecule contains four zinc atoms. Some physico-chemical parameters of seal alkaline phosphatase (pH-dependence, effects of temperature and cations on the enzyme activity, pI, thermal stability) were determined.     

Purification and characterization of intestinal alkaline phosphatase from harp seal

1. Alkaline phosphatase (EC 3.1.3.1.) from harp seal (Phagophilus groenlandicus) has been purified by concanavalin A-Sepharose chromatography to homogeneity with a specific activity of 1200-1500 units/mg of protein. 2. The mol. wt of the enzyme and its subunits were estimated as 260,000 and 70,000, respectively. By chromatofocusing the isoelectric point of this enzyme is 5.5. 3. With p-nitrophenylphosphate, pH-optimum and KM for the enzyme are 9.8 and 0.9 mM, respectively. 4. The enzyme was strongly inhibited by Sn4+, Fe3+ and Zn2+, whereas Mg2+ and Mn2+ were effective activators of the enzyme. Seal alkaline phosphatase was slightly inhibited by high concentrations of Ca2+ and Cr3+. 5. The enzyme activity reached a maximum at 55-60 degrees C. It was shown that the heat stability of seal and calf intestinal alkaline phosphatases were equal at 37 and 56 degrees C.     

Improved activity and stability of alkaline phosphatases from psychrophilic and mesophilic organisms by chemically modifying aliphatic or amino groups using tetracarboxy-benzophenone derivatives.

The activity-stability-structure relationship of the cold-active alkaline phosphatase from Red Arctic shrimp, Pandalus borealis (SAP) was studied by chemically modifying aliphatic (C-H) or amino (NH2) groups using benzophenone tetracarboxylic derivatives in either a light (UV-A) or dark reaction. The response of the cold-adapted enzyme was compared to a similarly modified calf alkaline phosphatase (CAP). MALDI-TOF-MS was used to determine the extent and nature of the modifications in both SAP and CAP. On average 2 to 4 amino acid residues were linked to a BP-modifier, with up to 18 to 21 amino acids modified in a smaller portion of the material. The effect of the modifications on kinetic and thermodynamic properties varied with the enzyme and type of modification. The aliphatic-group modified SAP demonstrated typical characteristics of a mesophilic enzyme, consistent with an activity-stability trade-off where gain in thermostability was attained at the expense of decreased activity. In contrast, the activity of the amino-group modified SAP attained an even more psychrophilic character with respect to its kinetic (increase in kcat and Km) and thermodynamic (reduction in deltaH#) properties. Interestingly, the amino-group modified SAP also acquired higher thermostability, thus demonstrating that both activity and stability can be simultaneously enhanced using chemical modification. The study demonstrates the applicability of benzophenone chemical modification for improving the thermal properties of enzymes from psychrophiles and mesophiles.     

Isolation of tau-phosphohistidine from a phosphoryl-enzyme intermediate of human prostatic acid phosphatase.

The carbethoxylation of prostatic acid phosphatase (orthophosphoric-monoester phosphohydrolase (acid optimum), EC 3.1.3.2) was accompanied by modification of histidine residues and the inactivation of the enzyme. These findings are consistent with photoinactivation experiments described earlier (Rybarska, J. and Ostrowski, W (1974) Acta Biochim, Polon. 21, 377--390). Prostatic acid phosphatase was phosphorylated at alkaline pH using p-nitrophenyl [32P]phosphate as substrate. Phosphoryl enzyme is stable in alkaline solutions and undergoes dephosphorylation at acidic pH. After hydrolysis of phosphoryl enzyme in strong alkaline solution, a single phosphoryl amino acid was isolated from hydrolyzate and identified as the tau-phosphohistidine.     

The role of Zn(II) in calf intestinal alkaline phosphatase studied by the influence of chelating agents and chemical modification of histidine residues.

Alkaline phosphatase from calf intestine (orthophosphoric-monoester phosphohydrolase (alkaline optimum), EC 3.1.3.1) is reversibly inhibited at pH 8.0 by incubation with chelating agents. Complete reactivation may be achieved by stoichiometric addition of Zn2+. Atomic absorption spectrometry was used to demonstrate the linear correlation between Zn2+ content and degree of reactivation. The reversibly inhibited enzyme contained 1 Zn2+ per subunit whereas 2 Zn2+ were found in both the reactivated and the native enzyme. At more alkaline pH-values, inactivation by chelating agents becomes irreversible; under such conditions the inactivated alkaline phosphatase still contains 1 Zn2+ per subunit. The conformational changes resulting from the loss of Zn2+ and leading to irreversible inactivation were investigated by optical rotatory dispersion, immunological techniques, and ultraviolet and fluorescence spectroscopy. Azocoupling of the alkaline phosphatase with diazonium-1-H-tetrazole and Zn2+ content measurement of azocoupled enzyme probes indicated that 2 histidine residues per subunit are involved in binding of the catalytically important Zn2+.     

Preparation and use of monoclonal antibodies against seal alkaline phosphatase]

Monoclonal antibodies (termed as APP.1 and related to subclass IgG1) against seal alkaline phosphatase, have been obtained. APP.1 did not influence the enzymatic activity of alkaline phosphatase. The dissociation constant for the APP.1 interaction with Greenland seal alkaline phosphatase was equal to 8.5 x 10(-10) M. It was found that APP.1 interact with intestinal isoenzymes of common and fur seal, calf and deer alkaline phosphatases. An APP.1 complex with seal alkaline phosphatase was obtained and successfully applied in immunoenzymatic analysis. The use of this complex made it possible to diminish the limit of detectability of antibodies against peptide fragments of HIV-1 and HIV-2 proteins. Moreover, this complex allowed the identification of cytokeratin-8 and vimentin in human kidney slices and embryonic fibroblast-like cells, respectively.     

Cloning of cold-active alkaline phosphatase gene of a psychrophile,Shewanella sp., and expression of the recombinant enzyme

A psychrophilic alkaline phosphatase (EC 3.1.3.1) from Shewanella sp. is a cold-active enzyme that has high catalytic activity at low temperature [Ishida et al. (1998) Biosci. Biotechnol. Biochem., 62, 2246-2250]. Here, we identified the nucleotide sequence of a gene encoding the enzyme after cloning with the polymerase chain reaction (PCR) and inverted PCR techniques. The deduced amino acid sequence of the enzyme contained conserved amino acids found among mesophilic alkaline phosphatases and showed some structural characteristics including a high content of hydrophobic amino acid residues and the lack of single alpha-helix compared with the alkaline phosphatase of Escherichia coli, which were possibly efficient for catalytic reaction at low temperatures. The recombinant enzyme expressed in E. coli was purified to homogeneity with the molecular mass of 41 kDa. The recombinant enzyme had a specific activity of 1,500 units/mg and had high catalytic activity at low temperatures.     

Acylation and carbamylation of equine muscle carbonic anhydrase (CA-III) upon reaction with p-nitrophenyl esters and carbamoyl phosphate

Equine muscle carbonic anhydrase (CA-III) behaves like ubiquitin in undergoing extensive acylation of N epsilon-lysine residues upon reacting with p-nitrophenyl esters. The enzyme undergoes extensive carbamoylation of lysine residues when reacted with carbamoyl phosphate. The modification of from 6 to 7 lysine residues results in the production of a series of more anodic electrophoretic components. The derivatization of the lysine residues leads to a marked decrease in the enzyme's ability to hydrate CO2. The equine CA-III possesses both acid and alkaline phosphatase activities in contrast to the rabbit which possesses only the former type.     

Translation of rat intestinal RNA yields two alkaline phosphatases.

After translation of total rat intestinal RNA, immunoprecipitation using monospecific antiserum against rat intestinal alkaline phosphatase yielded two polypeptides in the adult duodenum and jejunum (molecular masses 62 and 65 kDa). Immunoprecipitation of both bands was blocked by a single purified alkaline phosphatase. In the adult ileum and in the entire small intestine of suckling pups, only the 62 kDa translation product was found. After fat feeding, translated alkaline phosphatase increased by an amount proportionate to the increase in enzyme activity previously seen in the serum. A small fraction of nascent alkaline phosphatase was translocated into microsomal vesicles, producing peptides of 65 and 69 kDa. Tunicamycin-treated membranes demonstrated a different signal peptide for each translation product. N-Terminal sequencing of the translation products showed leucine residues at similar positions, but overlap with the mature protein sequence was not demonstrated. On the basis of these data, we propose the presence of two mRNAs encoding alkaline phosphatase in the rat intestine.     

Monoclonal antibody to alkaline phosphatase from the intestinal mucosa of the harp seal, Phoca groenlandica.

1. Hybridoma secreting a monoclonal antibody APP.1 to the harp seal alkaline phosphatase (A1Ph) was obtained by fusing murine myeloma Sp 2/0 cells with the splenocytes of BALB/c mice immunized with purified isozyme K. 2. The antibody has no effect on the enzyme activity and shows a high affinity for harp seal A1Ph (KD = 8.5 x 10(-10) M). The antibody has similar affinities for the AlPh of harp seal, fur seal, common seal and deer. 3. The antibody APP.1 was coupled to Sepharose and employed in chromatographic purification of the harp seal intestinal AlPh. Alkaline phosphatase isolated on this immunosorbent has a spec. act. of 20,800 units per mg of protein. 4. The antibody-enzyme complex gives an excellent immunocytochemical labeling of tissue sections, cell cultures and smears.     

Hybrids of chemical derivatives of Escherichia coli alkaline phosphatase.

The activities of hybrid dimers of alkaline phosphatase containing two chemically modified subunits have been investigated. One hybrid species was prepared by dissociation and reconstitution of a mixture of two variants produced by chemical modification of the native enzyme with succinic anhydride and tetranitromethane, respectively. The succinyl-nitrotyrosyl hybrid was separated from the other members of the hybrid set by DEAE-Sephadex chromatography and then converted to a succinyl-aminotyrosyl hybrid by reduction of the modified tyrosine residues with sodium dithionite. A comparison of the activities of these two hybrids with the activities of the succinyl, nitrotyrosyl and aminotyrosyl derivatives has shown that either the subunits of alkaline phosphatase function independently or if the subunits turnover alternately in a reciprocating mechanism, then the intrinsic activity of each subunit must be strongly dependent on its partner subunit.     

Characterization of monosaccharides in human placental alkaline phosphatase by gas—liquid chromatography

Gas—liquid chromatography of hydrolysates of highly purified human placental alkaline phosphatase (orthophosphoric-monoester phosphohydrolase, EC 3.1.3.1) demonstrated the presence of monosaccharide residues, mannose, galactose, glucose and fucose. This enzyme, therefore, is a sialoglycoprotein.     

Alkaline inorganic pyrophosphatase activity of mammalian-cell alkaline phosphatase

Alkaline phosphatase prepared from mammalian cell cultures was found to have alkaline inorganic pyrophosphatase activity. Both of these activities appear to be associated with a single protein, as demonstrated by: (1) concomitant purification of alkaline phosphatase and alkaline inorganic pyrophosphatase; (2) proportional precipitation of alkaline phosphatase and inorganic pyrophosphatase activities by titrating constant amounts of an enzyme preparation with increasing concentration of antibody; (3) immune electrophoresis, which showed that precipitin bands that have alkaline phosphatase activity also have pyrophosphatase activity; (4) inhibition of pyrophosphatase activity by cysteine, an inhibitor of alkaline phosphatase activity; (5) similar subcellular localization of the two enzyme activities as demonstrated by histochemical methods; (6) hormonal and substrate induction of alkaline phosphatase activity in mammalian cell cultures, which produced a nearly parallel rise in inorganic pyrophosphatase activity.     

The active-site and amino-terminal amino acid sequence of bovine intestinal alkaline phosphatase

The active site of bovine intestinal alkaline phosphatase (orthophosphoric-monoester phosphohydrolase (alkaline optimum), EC 3.1.3.1) was labeled with [32P]Pi, a radioactive CNBr peptide was isolated and the amino acid sequence was determined. The sequence of the active-site peptide has limited homology (26%) with the active-site sequence of Escherichia coli alkaline phosphatase except for the ten residues immediately flanking the active-site serine (70%). A possible amino acid sequence deduced from the amino acid composition of an active-site tryptic peptide from human placental alkaline phosphatase is very similar to the bovine intestinal active-site sequence. The amino-terminal sequence of bovine intestinal alkaline phosphatase is homologous (69%) with the human placental enzyme but not with the E. coli phosphatase.     

Lactoperoxidase-125I localization of salt-extractable alkaline phosphatase on the cytoplasmic membrane of Bacillus licheniformis.

Previous histochemical and biochemical localizations of alkaline phosphatase in Bacillus licheniformis MC14 have shown that the membrane-associated form of the enzyme is located on the inner surface of the cytoplasmic membrane, and soluble forms are located in the periplasmic space and in the growth medium. The distribution of salt-extractable alkaline phosphatase on the surfaces of the cytoplasmic membrane of B. licheniformis MC14 was determined by using lactoperoxidase-125I labeling techniques. Cells harvested during rapid alkaline phosphatase production were converted to protoplasts or lysed protoplasts and labeled. Analysis of the data obtained indicated that 30% of the salt-extractable, membrane-associated alkaline phosphatase was located on the outer surface of the cytoplasmic membrane, whereas 70% of the membrane-associated enzyme was localized on the inner surface. Controls for protoplast integrity (release of tritiated thymidine or examination of cytoplasmic proteins for label content) indicated excellent protoplast stability. Controls indicated that chemical labeling was not a factor in the apparent distribution of alkaline phosphatase on the membrane. These results support the previously reported histochemical localization of alkaline phosphatase on the membrane inner surface. The presence of alkaline phosphatase on the membrane outer surface is reasonable, considering the soluble forms of the enzyme found in the periplasmic region and in the culture medium.     

I-cell disease: deficiency of extracellular hydrolase phosphorylation

The content of ³²P-phosphorylated residues of purified extracellular N-acetyl-β-hexosaminidase obtained from the fibroblasts of I-cell disease patients was compared to that of control cells hydrolase. The analyses indicated a 60-fold decrease of the radioactivity per unit enzyme activity in the hydrolase synthesized by the patient's fibroblasts compared to the normal enzyme. Electrofocusing demonstrated again a marked decrease in the ³²P-content of the I-cell hydrolase while the control enzyme showed the presence of radioactivity in both isozymes, namely hexosaminidase A and hexosaminidase B. Most of the radioactivity could be removed from the hydrolase following incubation with alkaline phosphatase, thus indicating its phosphoester linkage.Since phosphorylated sugar residues on lysosomal enzymes function as recognition marker for their transport to the lysosomal compartment and for their specific uptake by fibroblasts, the deficiency of phosphorylated residues on the I-cell hydrolase explains the low intracellular and high extracellular lysosomal enzyme levels observed in this disease.     

Ontogeny of pituitary cell-types and the hypothalamo-hypophysial relationship during early development of chum salmon,Oncorhynchus keta

Tissue non-specific alkaline phosphatase is a membrane-bound glycoprotein enzyme which is characterized by its phosphohydrolytic, protein phosphatase, and phosphotransferase activities. This enzyme is distributed virtually in all mammalian tissues, particularly during embryonic development. Its expression is stagespecific and can be demonstrated in the developing embryo as early as the 2-cell stage. It has been suggested that tissue non-specific alkaline phosphatase might play a role in tissue formation. In the study reported here, a genetransfer approach was employed to investigate possible roles for this enzyme by inserting the cDNA for rat tissue non-specific alkaline phosphatase into CHO and LLC-PK1 cells. Permanently transfected cell-lines expressing varying levels of alkaline phosphatase were estblished. The data showed that functional enzyme was expressed in the transfected cells. Cell spreading and attachment were enhanced in transfected CHO cells expressing high levels of tissue non-specific alkaline phosphatase but not in the LLC-PK1 cells. Further, in CHO cells, proliferation was shown to be inversely proportional to the level of the tissue non-specific alkaline phosphatase expression. Homotypic cell association was demonstrated in both alkaline phosphatase-positive and alkaline phosphatase-negative cells in both CHO and LLC-PK1 celllines. Taken together, these findings suggest that in addition to a role in mineralization of bone, tissue nonspecific alkaline phosphatase might also play a role in other cell activities, including those related to differentiation, such as cell-cell or cell-substrate interaction and proliferation.     

A heat-stable alkaline phosphatase from Penaeus japonicus Bate (Crustacea: Decapoda): a phosphatidylinositol-glycan anchored membrane protein

1. A heat-stable alkaline phosphatase was purified from Penaeus japonicus, with a final specific activity of 21,280 U/mg of protein. 2. In polyacrylamide-gel electrophoresis under non-denaturing conditions, the purified shrimp alkaline phosphatase was found to have an identical molecular size and surface charge as the human placental enzyme. 3. By using SDS-PAGE, the monomers of shrimp alkaline phosphatase were discovered to have a Mr 55,000 but those of human placental enzyme with a Mr 70,000. Deglycosylation decreases the Mr values of the subunits to 33,000 for shrimp alkaline phosphatase. 4. The purified alkaline phosphatase from shrimp was recovered with both the attachment sites for sialic acids and phosphatidylinositol. 5. The shrimp alkaline phosphatase has an isoelectric point (pI) of 7.6 and the human placental enzyme has a pI of 4.8.