Characterization and localization of alkaline phosphatase in canine seminal plasma and gonadal tissues

Alkaline phosphatase (AP) is a useful indicator of the presence of the sperm-rich (2nd) fraction in the canine ejaculate. Two AP isoenzymes originating from separate genes have been identified in the dog: tissue nonspecific (TNS) and intestinal. Bone, liver, and corticosteroid-induced AP are different isoforms of the TNS and intestinal isoenzymes. Using gel electrophoresis and levamisole inhibition assays, it was determined that seminal plasma AP (SAP) is a unique isoform of canine TNS AP whose glycosylation is distinct from either of the TNS AP isoforms commonly found in canine serum. Using immunocytochemistry, SAP activity was localized to the epididymal and seminiferous tubular epithelium. The ability to distinguish SAP from bone AP, liver AP and corticosteroid-induced AP could be beneficial to the practitioner in determining the quality of a semen sample.     

Some properties and immunological relationship of acid phosphatases from gramineae

Two acid phosphatases have been found in crude extracts of seeds, coleoptiles and leaves of various grass species by means of crossed immunoelectrophoresis.The enzymes, cross-reacting with antibodies raised against proteins of Poa pratensis seeds differ in their binding to con A. The use of affinity chromatography on con A-Sepharose has separated the acid phosphatases into two fractions: the non-binding (acid phosphatase A) and the con A-binding (acid phosphatase B). The con A-binding acid phosphatase B from all tissues was further purified by gel filtration on Biogel P-100 and hydrophobic interaction chromatography on phenyl-Sepharose. Two isoenzymes: acid phosphatase B₁ and B₂ were obtained. The isoenzymes are glycoproteins containing D-mannose or D-glucose in their carbohydrate moiety. They retained the enzyme activity after binding in macromolecular complex with antibodies or con A. The purified acid phosphatases from all tissues cross-react with monospecific antibodies raised against P. pratensis seeds acid phosphatase B₁ indicating the antigenic relationship between the enzymes of various grass species.     

The preparation of monoclonal antibodies to human bone and liver alkaline phosphatase and their use in immunoaffinity purification and in studying these enzymes when present in serum.

1. Liver and bone alkaline phosphatase isoenzymes were solubilized with the zwitterionic detergent sulphobetaine 14, and purified to homogeneity by using a monoclonal antibody previously raised against a partially-purified preparation of the liver isoenzyme. Both purified isoenzymes had a specific activity in the range 1100-1400 mumol/min per mg of protein with a subunit Mr of 80,000 determined by SDS/polyacrylamide gel electrophoresis. Butanol extraction instead of detergent solubilization, before immunoaffinity purification of the liver enzyme, resulted in the same specific activity and subunit Mr. The native Mr of the sulphobetaine 14-solubilized enzyme was consistent with the enzyme being a dimer of two identical subunits and was higher than that of the butanol-extracted enzyme, presumably due to the binding of the detergent micelle. 2. Pure bone and liver alkaline phosphatase were used to raise further antibodies to the two isoenzymes. Altogether, 27 antibody-producing cell lines were cloned from 12 mice. Several of these antibodies showed a greater than 2-fold preference for bone alkaline phosphatase in the binding assay used for screening. No antibodies showing a preference for liver alkaline phosphatase were successfully cloned. None of the antibodies showed significant cross-reaction with placental or intestinal alkaline phosphatase. Epitope analysis of the 27 antibodies using liver alkaline phosphatase as antigen gave rise to six groupings, with four antibodies unclassified. The six major epitope groups were also observed using bone alkaline phosphatase as antigen. 3. Serum from patients with cholestasis contains soluble and particulate forms of alkaline phosphatase. The soluble serum enzyme had the same size and charge as butanol-extracted liver enzyme on native polyacrylamide-gel electrophoresis. Cellulose acetate electrophoresis separated the soluble and particulate serum alkaline phosphatases as slow- and fast-moving forms respectively. In the presence of sulphobetaine 14 all the serum enzyme migrated as the slow-moving form on cellulose acetate electrophoresis. Monoclonal anti-(alkaline phosphatase) immunoadsorbents did not bind the particulate form of alkaline phosphatase in cholestatic serum but bound the soluble form. In the presence of sulphobetaine 14 all the cholestatic serum alkaline phosphatase bound to the immunoadsorbents. 4. The electrophoretic and immunological data are consistent with both particulate and soluble forms of alkaline phosphatase in cholestatic serum being derived from the hepatocyte membrane.     

Further characterization of serum alkaline phosphatase from male and female beagle dogs

Alkaline phosphatase (AP) from the sera of both male and female beagle dogs was partially purified and then analyzed for the presence of AP isoenzymes having intestinal or osseous characteristics as detected by bromotetramisole inhibition or wheat germ lectin agarose electrophoresis, respectively. The sera from both sexes were similar in regard to the presence of AP isoenzymes with intestinal (16 vs. 20%) or osseous (19 vs. 23%) characteristics, but serum AP from the male had a greater sialic acid content and only the male serum contained a detectable constitutive acidic (pI = 3.4) AP isoenzyme. This was similar to a serum AP isoenzyme previously found elevated in the sera of dogs afflicted with hyperadrenocorticalism or of dogs treated with certain corticosteroids.     

The function of carbohydrate moiety and alteration of carbohydrate composition in human alkaline phosphatase isoenzymes

The relationship between the structure and function of alkaline phosphatase (orthoposphoric monoester phosphohydrolase (alkaline optimum), EC 3.1.3.1) isoenzymes is under investigation in a number of laboratories. The present study deals with the effects of glycosidase digestion on the alkaline phosphatase isoenzymes. Changes in physicochemcial properties, activity, affinity for various lectins and blood group antisera, carbohydrate composition and biological half-life were investigated. The desialylated hepatic enzyme was shown to be more heat labile and more sensitive to protease digestion in the presence of 0.5% sodium dodecyl sulfate than native hepatic enzyme. Helix contents of the native and desialated hepatic enzyme were calculated to be 39.0 and 30.8%, respectively, and apparent molecular weights 175,000 and 167,000, respectively. Intestinal enzyme preparations treated with alpha-mannosidase, exo-N-acetyl-Dglucosaminidase and endo-N-acetyl-D-glucosaminidase-D displayed a decrease in enzyme activity. Among these, the alpha-mannosidase-treated enzyme activity was the most clearly reduction. The maximum activity of the alpha-mannosidase-treated intestinal enzyme was observed to change from 40 mM Mg2+ to 5--10 mM Mg2+.     

A difference in the regulation of mRNA expression between the phenotypic and the embryonic alkaline phosphatase genes in human cancer cells

The steady-state levels of mRNAs encoding alkaline phosphatase isoenzymes were examined in two human breast carcinoma cell lines. MDA-MB-157 cells expressed the phenotypic breast alkaline phosphatase and BT20 cells expressed the nonphenotypic placental alkaline phosphatase isoenzyme, frequently reexpressed in neoplasms. Dexamethasone (DEX), which elicits a general effect on phosphatase expression, and 1,25-dihydroxy vitamin D3 (1,25(OH)2D3), a promoter of cell differentiation that correspondingly effects embryonic phosphatase expression, were chosen as perturbing agents for these experiments. RNA blot analysis showed a single RNA species of approximately 2.6 kb under all treatment conditions in BT20 cells and a single RNA species of 2.6 kb under each condition in MDA-MB-157 cells. The results showed that the expression of both the AP isoenzyme mRNA phenotypic of breast produced by MDA-MB-157 cells and the embryonic alkaline phosphatase isoenzyme (PLAP) mRNA produced by BT20 cells was increased by treatment with DEX. By comparison 1,25(OH)2D3 caused an increase in the tissue-unspecific AP mRNA in the MDA-MB-157 cells, but caused a decrease in PLAP mRNA levels in BT20 cells. The level of each isoenzyme mRNA species is altered by either hormone in a dose- and time-dependent manner in both cell lines. In BT20 cells, treatment with cycloheximide showed that ongoing protein synthesis is not required to potentiate the PLAP mRNA response to DEX, but is required for the action of 1,25(OH)2D3. However, protein synthesis is required for the action of both hormones in the MDA-MB-157 cells which make the breast phenotypic AP. These data demonstrate that the DEX- and 1,25(OH)2D3-regulated expression of both of these alkaline phosphatase isoenzymes occurs via a complex mechanism involving control of mRNA abundance, not translational control of constant message levels.     

Nuclear AP4A-binding activity of sea urchin embryos changes in relation to the initiation of S phase

The AP4A-binding activity of sea urchin embryos was studied using radioactively labelled diadenosine 5',5"'-P1,P4-tetraphosphate (Ap4A). Among various subcellular components that can bind [3H]AP4A, nuclei alone showed the highly specific Ap4A-binding activity which was not influenced by the presence of AP4A, AP5A and GP4G. The addition of an excess amount of ATP only slightly reduced the binding of [3H]AP4A to the nuclei. It was found that AP4A binds to the residual proteinaceous structure of nuclei which was resistant to the extraction with 2 M NaCl. The nuclear AP4A-binding activity fluctuated cyclically during each cell cycle, with a transient increase at the beginning of S phase followed by an abrupt decrease within 10 min. When the initiation of S phase was blocked, the increase in the AP4A-binding activity was also prevented. It seems that the binding of AP4A to the nuclear structural protein is involved in the initiation of S phase.     

A study of the selective inhibition by urea of neutrophil alkaline phosphatase isoenzymes

The kinetics of neutrophil alkaline phosphatase (AP) inactivation by urea were examined. In standardized conditions (molarity and pH of buffer, magnesium chloride and urea concentration), monitoring of the enzymatic reaction allows identification of neutrophil AP isoenzymes. This study confirms the heterogeneity of AP in normal human neutrophils.     

The 1.9 A crystal structure of heat-labile shrimp alkaline phosphatase

Alkaline phosphatases are non-specific phosphomonoesterases that are distributed widely in species ranging from bacteria to man. This study has concentrated on the tissue-nonspecific alkaline phosphatase from arctic shrimps (shrimp alkaline phosphatase, SAP). Originating from a cold-active species, SAP is thermolabile and is used widely in vitro, e.g. to dephosphorylate DNA or dNTPs, since it can be inactivated by a short rise in temperature. Since alkaline phosphatases are zinc-containing enzymes, a multiwavelength anomalous dispersion (MAD) experiment was performed on the zinc K edge, which led to the determination of the structure to a resolution of 1.9 A. Anomalous data clearly showed the presence of a zinc triad in the active site, whereas alkaline phosphatases usually contain two zinc and one magnesium ion per monomer. SAP shares the core, an extended beta-sheet flanked by alpha-helices, and a metal triad with the currently known alkaline phosphatase structures (Escherichia coli structures and a human placental structure). Although SAP lacks some features specific for the mammalian enzyme, their backbones are very similar and may therefore be typical for other higher organisms. Furthermore, SAP possesses a striking feature that the other structures lack: surface potential representations show that the enzyme's net charge of -80 is distributed such that the surface is predominantly negatively charged, except for the positively charged active site. The negatively charged substrate must therefore be directed strongly towards the active site. It is generally accepted that optimization of the electrostatics is one of the characteristics related to cold-adaptation. SAP demonstrates this principle very clearly.     

Alkaline phosphatase isoenzymes in human kidney and urine,immunohistochemical, immunological and biochemical characterization

Summary Human kidney contains two antigenetically distinct isoenzymes of alkaline phosphatase (AP): a liver type and an intestinal type. The intestinal type AP is a minor component (1%–4%) of the total AP activity: it is found only in the cytoplasm. Both isoenzymes are located, found by an immunohistochemical technique, in the proximal convoluted tubules. This histochemical result eliminates the possibility that the low intestinal AP content in the kidney might only originate from blood vessels, where the intestinal isoenzyme was also found. The renal isoenzymes contribute to urinary AP. Intestinal type AP in urine of healthy persons, 10%–40% of the total AP activity, was found after high speed centrifugation predominantly in the supernatant (100,000 g), the liver type mainly in the sediment. Biochemical characterization revealed that intestinal type AP in kidney and urine are identical and differ from the isoenzyme of intestinal mucosa only slightly in their electrophoretic mobility.     

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.     

The primary structure of human tissue amyloid P component from a patient with primary idiopathic amyloidosis

The amino acid sequence of human tissue amyloid P component (AP) extracted by a modified method from the spleen of a patient with primary idiopathic amyloidosis was determined. AP is a glycoprotein composed of a pair of noncovalently bound pentameric discs with a subunit size of 23-25 kDa. Each subunit consists of 204 residues, a single disulfide bridge linking Cys 36 to Cys 95, and a carbohydrate moiety attached to Asn 32. The precursor of AP is the serum amyloid protein (SAP). The primary structure of AP presented here differs from the amino acid sequence of SAP previously reported, but is identical to the amino acid sequence of mature SAP deduced from the nucleotide sequence of complementary DNA clones. It shares 52% homology with the amended sequence of human C-reactive protein, an acute phase protein, and 68% homology with the Syrian hamster "female protein," another acute phase protein whose response is modulated by sex steroids. AP/SAP, C-reactive protein, and female protein belong to a family of plasma proteins called pentraxins and their considerable sequence homology is probably the result of gene duplication. Neither the physiological function of AP nor its possible pathological role in amyloidosis are yet known.     

Influence of Mg2+ ions on the activity measurement of isoenzymes of alkaline phosphatase

The activity of alkaline phosphatase isoenzymes from liver, bone and small intestine is differently influenced by Mg2+. The stimulation of isoenzymes from liver and bone is higher by Mg2+ ions than in the case of isoenzymes from small intestine. An obligatory preincubation of the serum sample in a buffer-Mg2+ mixture is necessary to avoid difficulties which may arise in the kinetic determination of alkaline phosphatase activity under extreme conditions, i.e. low Mg2+ concentration in serum, the necessity of dilution of the sample or the high isoenzyme content from liver or bone in the serum.     

Rat alkaline phosphatase. II. Structural similarities between the osteosarcoma, bone, kidney, and placenta isoenzymes

A mouse monoclonal antibody raised against rat osteosarcoma alkaline phosphatase (AP) was covalently coupled to protein A-Sepharose and used to purify this enzyme from preparations of rat osteosarcoma, calvaria, kidney, and placenta in a single-step procedure. The tissue-specific isoenzymes purified in this manner showed identity in the immunodiffusion reaction with a polyclonal anti-AP antibody, but differed in apparent molecular weight and degree of polydispersity on sodium dodecyl sulfate-polyacrylamide gels. Treatment with N-glycanase abolished these differences, yielding proteins with an apparent molecular weight of 52,000 Da and identical V8 protease digestion patterns. Alkaline phosphatase from these tissues showed no significant difference in amino acid composition and identity in the first 20 N-terminal amino acids. These findings provide structural evidence which supports the hypothesis that the tissue-specific alkaline phosphatase isoenzymes share a common protein sequence subject to different glycosylation pattern.     

Independent association of serum amyloid P component, protein S, and complement C4b with complement C4b-binding protein and subsequent association of the complex with membranes

C4b-binding protein (C4BP) is a large complex assembly of eight subunits that functions as an inhibitor of the complement cascade. A portion of the C4BP in serum exists as a complex with protein S. This study demonstrated that another protein, serum amyloid P component (SAP), also formed a calcium-dependent complex with C4BP. The C4BP.SAP complex was detected by several methods including light scattering intensity, gel filtration, and sucrose density gradient ultracentrifugation. This complex was of high affinity relative to serum levels of these proteins so that no dissociation was detected at 3% of serum protein concentrations. The C4BP.SAP complex was also detected in normal serum and the results suggested that there was virtually no free SAP or uncomplexed C4BP in normal serum. In addition to its complex with C4BP, SAP underwent other calcium-dependent associations such as binding to phospholipid vesicles and self-aggregation. Self-aggregation was highly cooperative with kinetics corresponding to a reaction that was 6th-order with respect to calcium and required about 1.5 mM calcium. In contrast, formation of the SAP.C4BP complex and interaction of SAP with membranes required only about 0.4 and 1.0 mM calcium, respectively. Thus, selection of the correct conditions allowed study of the SAP.C4BP interaction without interference from self-aggregation. All three of these interactions of SAP were mutually exclusive and the SAP. C4BP interaction appeared to be favored over self-aggregation or binding of SAP to phospholipids. It seems likely that the biologically dominant interaction for SAP is with C4BP. The SAP.C4BP complex interacted with protein S and these binding sites appeared to be entirely independent. Furthermore, SAP had little or no effect on the ability of C4BP to bind C4b. Finally, the entire complex of proteins (C4BP, SAP, protein S, and C4b) could associate with membranes in the presence of calcium. Membrane binding occurred through the protein S component. This rather complicated assemblage of proteins probably functions in a regulatory role for the complement cascade or other biological systems. It is possible that elevated levels of SAP or nonequivalent levels of SAP and C4BP could contribute to certain pathological conditions.     

Thermolabile alkaline phosphatase from Northern shrimp (Pandalus borealis): protein and cDNA sequence analyses

Sequence analysis of short fragments resulting from trypsin digestion of the thermolabile shrimp alkaline phosphatase (SAP) from Northern shrimp Pandalus borealis formed the basis for amplification of its encoding cDNA. The predicted protein sequence was recognized as containing the consensus alkaline phosphatase motif comprising the active site of this protein family. Protein sequence homology searches identified several eukaryote alkaline phosphatases with which the 475-amino acid SAP polypeptide revealed shares 45% amino acid sequence identity. Residues for potential metal binding seem to be conserved in these proteins. The predicted 54-kDa molecular mass of SAP is smaller than previously reported, but is consistent with our recent SDS-PAGE analysis of the native protein. Compared to its homologs, the shrimp enzyme has a surplus of negatively charged amino acids, while the relative number of prolines is lower and the frequency of aromatic residues is higher than in mesophilic counterparts.     

Plasma membrane homing of tissue nonspecific alkaline phosphatase under the influence of 3-hydrogenkwadaphnin, an antiproliferative agent from Dendrostellera lessertii

Several mammalian enzymes are anchored to the outer surface of the plasma membrane by a covalently attached glycosylphosphatidylinositol (GPI) structure. These include acetylcholinesterase, alkaline phosphatase (AP) and 5'-nucleotidase among other enzymes. Recently, it has been reported that these membrane enzymes can be released into the serum by the GPI-dependent phospholipase D under various medical disturbances such as cancer and/or by chemical and physical manipulation of the biological systems. Treatment of MCF-7 cells with two consecutive effective concentrations of 3-hydrogenkwadaphnin (3-HK, 3 nM) for 48 h enhanced membrane AP activity by almost 330% along with a 40% reduction in the AP activity of the cell culture medium. In addition, our data indicate that 3-HK is capable of inducing mainly the tissue-nonspecific alkaline phosphatase (TNAP) isoenzyme, along with enhancing its thermostability. These findings, besides establishing a correlation between the antiproliferative activity of 3-HK and the extent of plasma membrane AP activity, might assist in the development of new diagnostic tools for following cancer medical treatments.     

Stability of isoenzymes of alkaline phosphatase in various buffer systems.

The stability of isoenzymes of alkaline phosphatase from liver, bones and small intestine was compared after addition to inactivated serum in the buffer systems: glycine, 2-amino-2-methyl-1-propanol, diethanolamine and 2-amino-2-methyl-1,3-propandiol at 37 degrees C. The mentioned isoenzymes were inactivated to different extents in glycine and 2-amino-2-methyl-1-propanol buffers. In diethanolamine and 2-amino-2-methyl-1,3-propandiol buffers sufficient stability of isoenzymes is obtained so that only these buffers are suitable for activity determinations of alkaline phosphatase at 37 degrees C.     

Evidence for glycosylphosphatidylinositol anchoring of intralumenal alkaline phosphatase of the calf intestine.

1. Considerable amounts of intestinal alkaline phosphatase (AP) were found intralumenally in all animal species investigated, i.e. calf, pig, goat, rat, mouse, guinea pig, hen and carp. The ratios between the total activity of AP found intralumenally and the total intestinal activity vary considerably. Calves and pigs show the highest, i.e. 0.77 and 0.44, respectively, while rodents have much lower ratios. Only 20-34% of the intralumenal alkaline phosphatase (IAP) of the calf and pig is soluble and not within the sediment after centrifugation at 135,000 x g for 60 min. whereas the IAP of rodents is soluble in the range of 60-72% of the total IAP. 2. For the IAP of the mucosa and chyme of calf, all criteria were found which are generally used, indicating a glycosylphosphatidylinositol (GlcPtdIns) anchor as proved by strong hydrophobicity using Triton X-114 phase partitioning, phenyl-Sepharose binding and enzyme aggregation, and the susceptibility to phosphatidylinositol-specific phospholipase C (PtdIns-PLC) and papain digestion. 3. More than 80% of the mucosa alkaline phosphatase (MAP) of the proximal part of the intestine and of the particulate fraction of IAP exhibit these criteria indicating the presence of the GlcPtdIns-anchor structure, whereas the anchor content of the soluble intralumenal enzyme decreases from the pylorus to the ileocecal junction. 4. MAP partially purified to a specific activity of 1747 IU/mg retains the anchor structure. 5. The results presented indicate that the release of large amounts of AP into the chyme is realized without splitting the GlcPtdIns anchor. The possible intralumenal function of this form of AP is discussed.     

Bone alkaline phosphatase in Paget's disease.

The measurement of bone proteins and peptides and their derived products has been very useful in the diagnosis and management of patients with skeletal disease. This group of assays includes alkaline phosphatase (AP) and bone Gla protein (BGP). We here describe the comparison of a new immunoassay that is specific for bone alkaline phosphatase (BAP) to measurements of total alkaline phosphatase (TAP) and BGP in Paget's disease. In our studies, we demonstrated that BAP was increased in the serum of patients with Paget's disease. Comparisons with the other measurements revealed that BAP correlated better with total AP (r = 0.92) than with BGP (r = 0.51); the lowest correlation occurred between BGP and total AP (r = 0.26). In patients with liver disease, the BAP was indistinguishable from normal whereas the TAP was elevated. These studies indicate that BAP assesses different aspects of bone cell function than BGP in Paget's disease. This discordancy also exists between BGP and total serum AP activity. BAP measurements by immunoassay offer a novel method of assessing skeletal status. Thus, the information that measurement of different bone-specific proteins provides should be separately useful in assessing the skeleton for a variety of metabolic bone diseases.