Differentiation of human adult and fetal intestinal alkaline phosphatases with monoclonal antibodies

Two forms of intestinal alkaline phosphatase have been recognized in humans. They are very similar in a number of biochemical and immunologic characteristics, but the exact genetic relationship between them remains unclear. To further study this problem, six monoclonal antibodies and a polyclonal rabbit antiserum to human fetal intestinal alkaline phosphatase have been produced. All of the monoclonal antibodies and the rabbit antiserum crossreact with adult intestinal alkaline phosphatase and with the intestinal-like alkaline phosphatase found in D98/AH-2 human tissue-culture cells. Four of the monoclonal antibodies and the rabbit antiserum crossreact with placental alkaline phosphatase, while none of the antibodies or the antiserum recognize liver or kidney alkaline phosphatase. Four of the monoclonal antibodies can distinguish between adult and fetal intestinal alkaline phosphatase in electrophoretic titration-binding studies, with the relative binding of adult enzyme being significantly greater than that of the fetal enzyme in each case. One of these antibodies, which also reacts with placental alkaline phosphatase, can distinguish the type 3 allelic variant of the placental enzyme from types 1 and 2. This indicates that the antibody detects a structural difference in the protein moiety of one of the allelic forms of the enzyme. These data suggest that adult and fetal intestinal alkaline phosphatases represent structurally distinct proteins, either encoded for by different genes or produced by differential processing of a common precursor molecule determined by a single gene.     

A possible new locus of alkaline phosphatase expressed in human testis

Summary Human testes contain trace amounts of heat-stable placental-like alkaline phosphatase. Using a recently described allotype-specific monoclonal antibody (F₁₁) toward placental alkaline phosphatase (PLAP), we show that the frequencies of reactivity of the testis enzymes differ greatly from those of the placental phenotypes. By means of the enzyme inhibitors L-Phe, L-Phe-gly-gly, L-Leu, and L-Leu-gly-gly, the testis enzyme can be clearly distinguished in all cases from the placental enzyme. These results argue that the testis enzyme is not a product of the placental gene and suggest the possible existence of a new locus of alkaline phosphatase.     

Immunoelectron microscopic analysis of the binding of monoclonal antibodies to molecular variants of human placental alkaline phosphatase

Three monoclonal antibodies with distinct antigenic specificities were examined by electron microscopy for their binding to three common genetic variants (SS, FS, and FF) of human placental alkaline phosphatase. In the reaction with the monoclonal antibody H5, all three variants of human placental alkaline phosphatase preferentially formed circular immune complexes composed of two antibodies and two enzyme molecules. In separate reactions with the F11 and B2 monoclonal antibodies, the SS variant formed circular complexes and the FS variant formed Y-shaped complexes composed of one antibody and two enzyme molecules, whereas the FF variant scarcely reacted. These results confirm immunochemical data showing that H5 binds to both S and F subunits with similar affinities, whereas F11 and B2 bind the S subunit with markedly higher affinity than they do the F subunit. Furthermore, the formation of circular complexes in the reaction of the mixture of the two antibodies, F11 and B2, with FS molecules suggests that these two antibodies bind to different sites on the S subunit. Therefore, the F and S subunits differ from one another at more than one site. This is the first indication that alleles of human placental alkaline phosphatase may result from more than just single point mutations in the gene encoding them.     

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.     

Identification of a butanol-extractable human placenta-specific antigen with alkaline phosphatase activity.

N-Butanol extracts of whole-term placenta from different individuals were prepared, and used as immunogens to raise heterologous hyperimmune sera in rabbits. Upon immunoelectrophoresis the anti-placenta antisera could recognize at least six antigenic components in the placental extract even after they had been completely absorbed with pooled male serum proteins. However, the antisera so absorbed, designated (-PMS) antisera, could still react strongly with several normal adult tissue extracts including kidney. Systematic and quantitative absorptions of the (-PMS) antisera were thus further carried out with individual butanol extracts of normal adult liver, lung, intestine, stomach, kidney, bone, pancreas, spleen, heart, cerebrum, cerebellum, breast, and packed red cells, as well as a composite extract containing equal amounts of each of the 13 adult tissue extracts. Of the six antigenic components in the placental extracts reacting with the (-PMS) antisera the only one which retained its reactivity with the antisera throughout exhaustive absorptions was associated with alkaline phosphatase activity. This immunologic and enzymologic identity was confirmed with homogeneous placental alkaline phosphatase. Extracts from each of three placentae injected into three pairs of rabbits all produced an identical antibody reaction with the unique determinant(s) of placental alkaline phosphatase. The same identity of precipitin reaction was also found with extracts of 14 other placentae against each of these antisera. It thus firmly establishes that placental alkaline phosphatase is a characteristic placenta-specific fetal protein.     

Investigation of alkaline phosphatase activity in the serum of pregnant rats

An investigation was undertaken to determine if the placental alkaline phosphatase of the rat enters the maternal circulation and to study some of its characteristics. Unlike human, rat placental alkaline phosphatase was found to be heat labile and the alkaline phosphatase activity in the serum of both pregnant and non-pregnant rats was also found to be heat labile. Also unlike the human, the alkaline phosphatase activity in rat serum does not increase as pregnancy progresses to term. In an endeavour to establish if the rat placental enzyme is present in the serum of the pregnant rat, the characteristics of the enzyme in both placental extracts and serum of non-pregnant and 1-, 2- and 3-week pregnant rats were studied using the techniques of heat stability at 56°, gel filtration through Sephadex columns, disc gel electrophoresis, and L-phenylalanine inhibition. The presence of rat placental alkaline phosphatase in maternal serum could not be positively demonstrated by any of these procedures, suggesting that rat placental alkaline phosphatase does not enter the maternal serum.     

Phage displayed antibodies to heat stable alkaline phosphatase: framework region as a determinant of specificity

Human antibodies against specific targets of tumor cells are the most desirable molecules for possible immunotherapy. They could be developed by using the combinatorial antibody library displayed on a phage. We selected four human antibody fragments (scFv) binding to the oncoplacental antigen Heat Stable Alkaline Phosphatase (HSAP, the placental isozyme of alkaline phosphatase) from a synthetic human antibody library. Characterization of these scFvs showed they bound HSAP with moderate affinity but did not have isozyme specificity, as determined by binding to cell lines exhibiting differential expression of isozymes of alkaline phosphatase. The V(H) sequences of two of these scFvs were similar and although both bound to HSAP only one was cross-reactive with albumin. The sequences revealed a difference in the framework region (FR1) of these antibodies, indicating a role for this region in the determination of specificity. This is also significant considering that the heavy chains generated the diversity of the synthetic library used in this study, and only a single light chain showing binding to BSA was used for the entire library.     

Evidence for an enhanced de novo synthesis of alkaline phosphatase in cholestatic rat liver using immunotitration and precursor incorporation techniques.

An antikidney phosphatase serum was produced. This showed a cross-reaction with liver phosphatase and precipitated the latter enzyme specifically in the double antibody method. An U-[14C] protein hydrolysate was injected intraperitoneally into rats, which had previously undergone bile duct ligation. Liver alkaline phosphatase was partially purified and immunoprecipitated. By determination of phosphatase labelling the extent of de novo synthesis of the phosphatase protein was evaluated. Comparing livers from control and cholestatic rats, it could be shown that 12 h after beginning of cholestasis the de novo synthesis of alkaline phosphatase was increased up to 4-fold and that is remained at a 2-fold increased level for at least 2 days.     

Expression in non-lymphoid cells of mouse recombinant immunoglobulin directed against the tumour marker human placental alkaline phosphatase

From a mouse hybridoma cell line secreting a monoclonal antibody directed against the tumour marker human placental alkaline phosphatase, mRNA coding for the H and L chains of this antibody was isolated and cloned as cDNA. Sequence analysis of the H and L chain cDNAs confirmed the IgG2b,kappa subtype previously established. Recloning the H and L chain cDNA information into SV40-based vectors enabled us to obtain expression of functional immunoglobulin upon cotransfection into COS or CHO dhfr- cells. This illustrates that non-lymphoid cells also have the capacity to assemble active immunoglobulins.     

Quantitation of peroxidase-antibody binding to membrane fragments using column chromatography.

A method which can be used to measure the amount of peroxidase antibody which is specifically bound to placental alkaline phosphatase in membrane fragments is described. The technique uses Sepharose 4B chromatography to separate membrane fragments containing bound peroxidase-antibody from unbound peroxidase-antibody. Specificity is demonstrated by nonbinding to rabbit placental membranes, by a strict correlation between membrane-associated phosphatase and bound peroxidase-antibody, and by preventing binding using pure enzyme. The general utility of this method for membrane antigens is discussed.     

Placental alkaline phophatase in benign and malignant endometrium

Summary The presence of placental alkaline phosphatase has been demonstrated immunohistochemically using a monoclonal antibody, in frozen sections of human endometrium. The enzyme is present in glandular epithelium, but is found most commonly in the surface epithelial layer throughout the menstrual cycle. It has also been demonstrated in malignant endometrial epithelium in eight out of twelve patients.     

Development of an enzyme-linked immunosorbent assay of thromboxane B2 using a monoclonal antibody

An inhibition enzyme-linked immunosorbent assay (ELISA) was developed using a monoclonal antibody against thromboxane B2 (TXB2). As a specific antigen, the bovine serum albumin conjugate of TXB2 was adsorbed onto polystyrene microtiter plates. The sensitivity of the monoclonal antibody was compared by means of three different enzyme conjugates, all commercially available. The detection limit with immunoglobulin conjugates of alkaline phosphatase and horseradish peroxidase was 0.04 ng of TXB2 per sample. The use of horseradish peroxidase coupled with an avidin-biotin complex allowed a tenfold increase in sensitivity to 0.0045 ng of TXB2 per sample. The suitability of the assay was checked with TXB2-containing human serum and urine samples, which yielded unchanged standard curves. Recovery experiments had an accuracy of r = 0.960 and r = 0.987. Validity was confirmed by a good correlation between radioimmunoassay and ELISA (r = 0.949). Results of an inhibition experiment with platelet-rich plasma in the presence and absence of ibuprofen demonstrated the practical applicability of this method.     

Radioimmunotherapy trials in germ testicular carcinoma: a phase I study

Two patients with germ cell testicular cancer were submitted to radioimmunotherapy (RIT) by using the monoclonal antibody 131I-radiolabelled (MoAb) H17E2, raised against placental alkaline phosphatase (PLAP). Both patients had been previously treated with repeated chemotherapy regimens assisted by autologous bone marrow transplant (ABMT), that, in the end were unsuccessful, thus necessitating further experimental treatment. RIT was well tolerated and the targeting of multiple neoplastic lesions was satisfactory. Nevertheless, the clinical results of treatment were minimal owing to the extension of the tumour. The data obtained suggest the possibility of applying this form of treatment in patients with minimal residual disease after previous traditional chemotherapy regimens.     

Immunohistochemical characterization of purple acid phosphatase-containing leucocytes in the human placenta

Summary A tartrate-resistant acid phosphatase activity was detected in the human placenta. This enzyme displayed immunological properties similar to those of the group of purple acid phosphatases that can be demonstrated with a rabbit polyclonal antibody against bovine spleen purple acid phosphatase. The placental enzyme was mainly localized immunohistochemically to neutrophil granulocytes of the maternal blood between the placental villi and within foetal capillaries using the bovine spleen antibody and the commercial monoclonal antibody M1 directed against an antigen found on mature granulocytes. A minor activity was detected in decidual cells and the syncytiotrophoblast. The presence of purple acid phosphatase in placental granulocytes may be related to special immunological conditions of pregnancy.     

Immunosensor for Mycobacterium tuberculosis on screen-printed carbon electrodes

In this work, two methods have been compared to produce enzymatic voltammetric immunosensors for the determination of Mycobacterium tuberculosis antigens (Ag360 and Ag231), using a pre-oxidised screen-printed carbon electrode (SPCE) as a signal transduction element. The enzyme alkaline phosphatase (AP) was used in combination with the substrate 3-indoxyl phosphate (3-IP). In one design, the immune complexes between M. tuberculosis antigens and monoclonal antibodies against M. tuberculosis were formed out of the electrode surface. Then, the immune complexes were captured by biotinylated rabbit anti-M. tuberculosis antibodies, immobilised on the streptavidin modified SPCEs through the streptavidin:biotin reaction. Finally, an alkaline phosphatase (AP) labelled rabbit IgG anti-mouse immunoglobulin G was used as a detector antibody. In the other design, the M. tuberculosis antigens were captured by monoclonal antibodies against M. tuberculosis, which were immobilised on the electrode surface through the reaction with rabbit IgG passively adsorbed on the SPCEs. The biotinylated rabbit anti-M. tuberculosis antibodies were used with an alkaline phosphatase labelled streptavidin as detector antibodies. The best results for M. tuberculosis antigen determination were obtained using the immunosensor on the streptavidin modified SPCEs and the immune complexes between antigen Ag231 and monoclonal antibodies MabF184-3, with a detection limit of 1.0 ng/ml. The immunosensor was also applied to Ag231 spiked proteic matrices.     

Human trophoblast glycoproteins defined by monoclonal antibody 1D2

A cell surface antigen has been defined by a monoclonal antibody 1D2, raised following immunisation with lectin-purified syncytiotrophoblast glycoproteins. 1D2 was nonreactive with any one of 8 common trophoblast proteins in immunodot. Analysis of nonreduced western blots of syncytiotrophoblast microvillous plasma membrane (StMPM) protein indicated that mAb 1D2 was reactive with a series of sialylated proteins with molecular weights of 16-22 kilodaltons. Immunoprecipitates of radiolabelled StMPM protein contained molecules that co-migrated with placental alkaline phosphatase in addition to those identified by western blotting. This set of human trophoblast molecules has not been previously identified by monoclonal antibodies; the antigenicity is widely distributed in human tissues.     

Kinetic determination of alkaline phosphatase activity based on hydrolytic cleavage of the P-F bond in monofluorophosphate and fluoride ion-selective electrode

Alkaline phosphatase catalyzes the hydrolytic cleavage of the P-F bond in monofluorophosphate with the subsequent release of fluoride ions. A kinetic potentiometric method is described in which a fluoride ion-selective electrode is used for the sensitive and selective measurement of the released F- for the determination of alkaline phosphatase activity. It is shown that monofluorophosphate can be used as an alternative substrate for alkaline phosphatase. The reaction demonstrates a well-defined correlation with the hydrolysis of the P-O bond in 4-nitrophenyl phosphate. The serum alkaline phosphatase was determined in human serum samples by the potentiometric technique, and the results obtained compared well with a standard spectrophotometric method.     

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.     

Simultaneous demonstration of lectin-binding sites and antigens detected by monoclonal antibodies in a parallelized double-staining technique: a highly discriminative and quickly developing technique for frozen sections

A sensitive immunoenzymatic double-staining technique is presented for the simultaneous visualization of lectin-binding sites and antigenic structures detected by monoclonal antibodies. The lectin is demonstrated by an extended unlabeled peroxidase-antiperoxidase (PAP) technique and the monoclonal antibody by an alkaline phosphatase-antialkaline phosphatase (APAAP) method, which corresponds to the standard PAP technique. 3-amino-9-ethylcarbazole (AEC) and fast blue BB salt serve as substrates for the peroxidase and the alkaline phosphatase, respectively. The antisera and the enzyme complexes raised in different animals enable the performance of three parallel incubation steps. The staining procedure requires three and a half hours altogether. This method proved to be highly discriminative and rather insensitive to interference by various artifacts.     

Discrimination of human placental alkaline phosphatase allelic variants by monoclonal antibodies.

Eighteen monoclonal antibodies were produced by the mouse hybridoma method using purified placental alkaline phosphatase (ALP) as antigen. The ability of the various antibodies to discriminate among allelic variants of the enzyme was tested using a large panel of placental ALPs that had been typed electrophoretically. The panel included sets of samples of each of the six common polymorphic phenotypes as well as a series of rare variants. The reactivity of each antibody with each placental ALP (binding ratio) was determined relative to a single standard placental ALP (type 1) in a quantitative binding assay. The findings for six of the antibodies have already been reported. The results on the other 12 antibodies are presented here, and the combined data on the total series of 18 antibodies are analyzed and discussed. Six of the 18 antibodies showed significantly reduced binding to one or another of the products of the three common alleles. In three cases, the discrimination was reflected by essentially "all-or-none" binding reactions. In the other three cases, the binding differences were less marked but could be demonstrated by quantitative comparisons of the binding ratios. Quantitative binding ratio comparisons also enabled heterozygotes to be differentiated from homozygotes in each case. Some of the antibodies showed reduced binding with certain of the rare variant ALP electrophoretic phenotypes. It is estimated that at a minimum this unselected series of 18 antibodies is directed to at least nine different antigenic determinants on the surface of the placental ALP molecule. The results illustrate the power of monoclonal antibodies to discriminate among allelic variants of enzymes.