Partial purification and some properties of human liver alkaline phosphatase

Alkaline phosphatase isozymes in insects and comparison with mammalian enzyme

Studies of insect alkaline phosphatases (ALPs) are reviewed, including general insect isozyme papers from earlier periods. Results of biochemical and genetic investigations of the silkworm midgut ALPs are described. The membrane-bound (m-ALP) and soluble form (s-ALP) are controlled by distinct genes on the same chromosome. These isozymes were different in tissue localization, antigenicity, stability under alkaline conditions and sugar chains. Compared with mammalian ALPs, silkworm ALPs represented specificity in the monomeric structure, tissue localization and inhibition by amino acids. The amino acid sequence deduced from cDNA sequence of silkworm m-ALP showed 42.7-44.6% homology to three human types of ALP. Comparison of the amino acid sequences in functionally important parts of various ALP isozymes showed a significant conservation. Physiological roles of ALPs were discussed and the significance of the study in temporal and spatial regulations of both silkworm ALP genes was pointed out. In addition, the evolutionary relationship among various genes was discussed.

Sugar-chain heterogeneity of human alkaline phosphatases: differences between normal and tumour-associated isozymes

The sugar-chain heterogeneity of alkaline phosphatases (ALPs) from various human organs was investigated by using the serial lectin affinity technique. This technique revealed a possible structure of the sugar chain(s) of ALP isozymes and clarified a difference in affinity on the lectin column not only among three genetically different isozymes (liver/bone/kidney, intestinal and placental types) but also among liver, bone, and kidney ALPs. Lectin-binding profiles of ALPs in these human organs closely resembled those in the corresponding organs of the rat, as reported previously, suggesting that heterogeneities in sugar chains of ALPs have a specificity for the respective organs rather than being species-specific. Lectin-binding profiles of tumour-produced placental and liver ALPs were significantly different from those of ALPs in the respective normal organs. However, the two altered ALPs exhibited similar lectin-binding affinities. Isoelectric focusing analysis showed essentially no difference in protein charge between the normal and tumor-produced ALPs. Moreover, tumour-produced ALPs had the same N-terminal amino acid sequence and peptide mapping as normal ALPs. From these results, it is possible to suggest that organ-specific sugar chains in ALP isozymes are changed into those peculiar to tumours in association with malignant transformation.

A possible mechanism of induction and translocation into blood stream of rat alkaline phosphatase activity by bile duct ligation

We investigated the effects of bile duct ligation on alkaline phosphatase (ALP) activities in liver, calvarium, duodenum, and ileum in rats and its possible mechanism of action. ALP isozyme activities in the ligated rats were significantly elevated in the liver and duodenum, while those in the ileum and calvarium were markedly decreased. The ALP isozyme activity elevated by the ligation was obviously suppressed by prior administration of indomethacin, an inhibitor of prostaglandin synthesis. Moreover, phorbol ester also elevated the ALP activity as well as the phosphatase level in the ligated rat. However, other drugs, such as an inhibitor of protein kinase C and calmodulin, showed different effects: calmodulin stimulated an 11.0-, 1.3-, or 1.5-fold increase in ALP activity in the ileum, duodenum, or calvarium, respectively; whereas the hepatic enzyme activity was not affected. The induction by calmodulin was markedly different from that by the ligation. Moreover, imipramine, an inhibitor of protein kinase C, had little effect. These results suggest that prostaglandin is a possible ALP inducer in ligated rats, probably working by elevating the cAMP level. On the other hand, the ligation induced simultaneously de novo synthesis of the membranous and soluble ALP isozymes; and the release rate of the soluble enzyme was greater than that of the membranous isozymes, indicating that the soluble enzyme might be a main source of the induced serum ALP. Lectin affinity chromatography indicated that the soluble enzyme or induced serum enzyme may contain more fucose than that of the membranous one, suggesting that the sugar moiety in the ALP molecule may relate to the clearance of ALP from or its release into the circulation.

Different lectin affinities in rat alkaline phosphatase isozymes: multiple forms of the isozyme isolated by heterogeneities of sugar moieties

Differences among rat alkaline phosphatases from various organs were established by using the serial lectin affinity technique. Elution profiles of isozymes with various lectin columns were significantly different from each other, and it was possible to distinguish between isozymes by this technique. It has been shown by many workers that a high-mannose-type and/or hybrid-type sugar chain is contained in the fraction bound strongly to concanavalin A-Sepharose. The duodenal alkaline phosphatase had a low content of this fraction, although the content of this fraction obtained from duodenal explants was increased markedly when explants were cultured with swainsonine, which is an inhibitor of alpha-mannosidase II, and this leads to the accumulation of high-mannose-type and hybrid-type sugar chains in the pathway of sugar chain processing. From the present results, it is suggested that differences in the elution profiles of isozymes may be due to the structural differences of sugar chains in alkaline phosphatases.

Changes of intestinal alkaline phosphatase produced by cholecalciferol or 1,25-dihydroxyvitamin D3 in vitamin D-deficient chicks

Treatment with cholecalciferol or 1,25-dihydroxyvitamin D3 (1,25(OH)2D3) increases activity and changes electrophoretic mobility of alkaline phosphatase (alkPase) from duodenal brush border of vitamin D-deprived chicks. Three of the four molecular forms of the enzyme show reduced velocity of migration 9 h after 1,25(OH)2D3 or 24 h after vitamin D3. This change is reversed about 48 h later, when mobility of those bands is higher than that of controls. Incubation of enzyme preparations with exogenous neuraminidase produces the same electrophoretic modifications observed during the early stage, indicating that they are due to desialylation. Cholecalciferol or 1,25(OH)2D3 increase sialidase activity of duodenal brush border. This increment precedes that of alkPase and could account for the initial desialylation and moderate rise of alkPase. Cycloheximide markedly reduces alkPase in rachitic chicks and blocks the increase of the enzyme activity produced by vitamin D3, but does not modify the rise of sialidase or the reduction of alkPase electrophoretic mobility. The bimodal response of alkPase to 1,25(OH)2D3 or cholecalciferol comprises two different mechanisms: during a first stage, epigenetic modifications of preexisting enzyme can be triggered by the increased Ca2+ levels; in a second phase, there is activation of enzyme synthesis.

Partial purification of alkaline phosphatase from bovine polymorphonuclear neutrophils and some properties

Alkaline phosphatase was purified from bovine polymorphonuclear neutrophils by butanol extraction and a combination of ion exchange, gel filtration and affinity chromatography. The enzyme was partially purified 2300-fold with a 4.7% yield and a sp. act. of 206 units/mg of protein. Polyacrylamide gel electrophoresis in sodium dodecyl sulfate indicated a single activity band with the mol. wt of 165,000. The pH optima for the enzyme were 10.0 with p-nitrophenylphosphate and phenylphosphate and were 9.0 when beta-glycerophosphate, AMP and ADP were used. The enzyme was activated by Mg2+, Mn2+, Co2+ and Ni2+ but was inhibited by Zn2+. The enzyme was inhibited by EDTA and the EDTA-inactivated enzyme was reactivated by Mg2+, Mn2+ and Co2+ but not Zn2+.

Multiple forms of alkaline phosphatases in human liver tissue

Alkaline phosphatases (AP) extracted in the presence of n-butanol from human liver are separated by affinity chromatography on phenylsepharose Cl-4B into two fractions named APII and APIIII. By repeated chromatography, APII was purified to a single enzyme entity with a specific activity of 1,684 kU/g protein. APIIII was purified to a specific activity of 535 kU/g protein. It consisted of only APIIII enzyme activity, but still contained gamma-glutamyltransferase activity. These two forms of AP are different in chromatographic and electrophoretic behaviour, APIIII being a larger molecule than APII. APII and APIIII are very similar in enzyme kinetic behavior, such as substrate activity, thermolability and sensitivity to different inhibitors. It is concluded from these experiments that multiple forms of AP in liver bear identical active centres, the difference is due to a modification of protein residue. It is possible that both are modified forms of one enzyme. Both are different from the AP isoenzyme that appears in serum in cholestatic patients.

The role of the liver in clearance of glycoproteins from the general circulation, with special reference to intestinal alkaline phosphatase

Glycoproteins represent a wide variety of macromolecules with important physiological functions. Characteristic variations in carbohydrate composition and plasma concentration of these proteins may occur during pathological conditions. Steady-state plasma concentrations are determined by release from normal or diseased tissues and simultaneous clearance from the general circulation. The liver occupies a central position in the production but also clearance and catabolism of such glycoproteins. A number of specialized receptor-mediated transport processes for different types of glycoproteins in this organ is reviewed. Membrane recognition is generally followed by absorptive endocytosis and vesicle transport to lysosomes, Golgi system and/or bile canaliculis. The charge of the protein, the nature of the terminal sugar residue or complex formation with other glycoproteins may determine the extent of uptake in the various cell types of the liver. By means of these transport processes the liver is able to remove potentially dangerous macromolecules such as denatured proteins, aggressive enzymes and immunocomplexes from the general circulation. Drugs can bind to some of these proteins or may interact with the hepatic transport or catabolism processes. Special attention is paid to the hepatic clearance of asialoglycoproteins with terminal galactose groups. Intestinal alkaline phosphatase is used as a model compound to characterize the pharmacokinetic profiles of hepatic uptake and biliary excretion in the rat in vivo and isolated perfused rat livers. Histochemical and electron-microscopic studies demonstrated a galactose-specific, receptor-mediated endocytotic process, mainly but not exclusively localized in centrolobular hepatocytes. Drug interactions with these processes will be the subject of further investigations.

A monoclonal antibody that reacts with nonallelic enzyme glycoproteins

One of six monoclonal antibodies raised against purified human placental alkaline phosphatase cross-reacts with the adult and fetal forms of intestinal alkaline phosphatase. The placental and intestinal enzymes are nonallelic. A new electrophoretic titration procedure was used to assess the relative reactivities of the different enzymes with the antibody. The placental enzyme was the most reactive. However, the adult intestinal enzyme showed greater reactivity than the fetal enzyme. The determinants to which the antibody binds on these three forms of alkaline phosphatase presumably differ in their detailed molecular configurations.

Biochemistry of alkaline phosphatase isoenzymes

The review discusses the similarities and differences between the common isoenzymatic forms of ALP. Methods for separating, measuring, and purifying the isoenzymes on the basis of these differing properties are described. The evidence is reviewed for the existence of different genes coding for different isoenzymes, and the current state of knowledge is surveyed concerning the location, development, function, and regulation of the isoenzymes. Finally, some unusual forms of ALP which may appear in the circulation are described.

Multiple forms of human intestinal alkaline phosphatase: chemical and enzymatic properties, and circulating clearances of the fast- and slow-moving enzymes

Two forms of alkaline phosphatase (orthophosphoric monoester phosphohydrolase (alkaline optimum, EC 3.1.3.1) have been purified from human small intestine by column chromatography on DEAE-cellulose and tyraminyl derivative affinity gel, and by preparative disc gel electrophoresis. Intestinal phosphatases were electrophoretically separated into two components, fast- and slow-moving enzymes, with apparent molecular weights of 140000 and 168000 and with subunit weights of 68000 and 80000, respectively. Analyses of carbohydrate and amino acid revealed marked differences in the two enzymes. Enzymatic properties and affinities for an anti-blood group antibody were also found to differ. Papain digestion released a hydrophobic small peptide from the slow-moving enzyme and its enzymatic properties resembled those of the fast-moving enzyme. Circulating clearance (T1/2) of the slow- and fast-moving enzymes from adult intestine was found to be 7.5 h and 1.3 h, respectively; that of fetal intestinal enzyme was 2.8 h. Sialidase, sialidase/beta-galactosidase, or sialidase/beta-galactosidase/N-acetyl-beta-glucosaminidase treatment of the fetal enzyme reduced the value to about 40 min. Further, digestion with alpha-fucosidase, alpha-mannosidase or both restored it to nearly the original level. Organ distribution of injected 125I-labelled enzymes indicates that the desialylated hepatic enzyme was selectively distributed in liver, while the degalactosylated intestinal enzyme was incorporated into liver lymph fluid, and small intestine. These results suggest that the pathway of circulating clearance of alkaline phosphatase has several routes.

Inhibition of alkaline phosphatase by bismuth

The interaction of alkaline phosphatase (EC 3.1.3.1) with bismuth was studied. Among the tested alkaline phosphatases, bismuth was found to be the most effective inhibitor of the placental enzyme. Partial denaturation of the placental enzyme by papain digestion had little effect, if any, on the inhibition. Bismuth inhibition of the placental enzyme activity was more progressive with mixed glycosidase treatment than with sialidase treatment. The pH activity profile of the mixed glycosidase-treated placental enzyme was clearly shifted in the presence of bismuth. The mixed glycosidase-treated placental enzyme/bismuth mixture was more heat labile than the non-treated placental enzyme. Based on the results of kinetic studies, the inhibition mechanism of the placental enzyme by bismuth was shown to be of the competitive type, and the Ki value and Hill coefficient of the mixed glycosidase-treated placental enzyme was found to be 92 mu mol/l and 2.25, respectively. L-Phenylalanine does not interfere with the inhibitory effect of bismuth on alkaline phosphatase. Inorganic phosphate, on the other hand, appears to disturb bismuth bindings.

A monoclonal antibody to intestinal alkaline phosphatase made against D98/AH-2 (HeLa) cells

A monoclonal antibody (AAP1) to human intestinal alkaline phosphatase (ALP) was produced by immunizing a mouse with D98/AH-2 (HeLa) cells, which produce the enzyme ectopically. The antibody, which did not inhibit enzyme activity using p-nitrophenyl phosphate as the substrate, was of the IgG2A class and did not show complement-dependent cytotoxicity. In trace binding assays AAP1 bound only to cells that expressed an intestinal-like form of human ALP, including some human intraspecific (D98/AG-2 x human lymphocyte or fibroblast) hybrids. Immunoprecipitation of immune complexes from cell-free extracts of D98/AG-2 cells, using protein A containing S. aureus and AAP1 antibody, resulted in precipitation of all the ALP activity. The precipitated material had a subunit molecular weight of 80,000 daltons, as estimated by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulphate. In non-denaturing conditions, AAP1 antibody prevented the migration of ALP activity into the gel when cell-free extracts were made from human adult or fetal intestine, or D98/AH-2 cells. Similarly, AAP1 could be used to precipitate ALP activity from these extracts but not from extracts of human liver, kidney or placenta.

Purification and properties of a phosphorylase (phosphoprotein) phosphatase associated with an alkaline phosphatase of Mr 35000 from bovine adrenal cortex

A metal-ion-independent, nonspecific phosphoprotein phosphatase (Mr = 35000) which represents the major phosphorylase phosphatase activity in bovine adrenal cortex has been purified to apparent homogeneity. An alkaline phosphatase activity (p-nitrophenyl phosphate as a substrate) of the same molecular weight, which requires both a metal ion (Mg2+ greater than Mn2+ greater than Co2+) and a sulfhydryl compound for activity, has been found to co-purify with the phosphoprotein phosphatase throughout the purification procedures. Characterization of the phosphoprotein and the alkaline phosphatase activities with respect to their catalytic properties, substrate and metal ion specificities, relationship with large molecular forms of the enzymes and responses to various effectors has been carried out. The results indicate that the phosphoprotein phosphatase can be converted by pyrophosphoryl compounds (e.g. PPi and ATP) to a metal-ion-dependent form which, subsequently, can be reactivated by Co2+ greater than Mn2+ but not by Mg2+ or Zn2+. The results also indicate that, although the phosphoprotein and the alkaline phosphatase activities are closely associated, they exhibit distinct physical and catalytic properties. Discussions concerning whether these two activities represent two different forms of the same protein or two different yet very similar polypeptide chains have been presented.

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 novel alkaline phosphatase, a minor component of normal liver phosphatases

A novel alkaline phosphatase differing from the so-called liver-specific isoenzyme was found in four out of twenty-four normal adult livers. Although the mobility of this enzyme was the same as that of so-called liver-specific alkaline phosphatase on the polyacrylamide gel electrophoretogram, its mobility was not altered following neuraminidase treatment, while that of the liver-specific enzyme was affected by the same treatment. Both enzymes also differed in other enzymatic and immunologic properties. The enzyme, however, resembled the so-called intestinal alkaline phosphatase in many enzymatic and immunologic properties. Thus, the inhibition patterns by amino acids, EDTA and inorganic phosphate, the pH optima, KM values for phenyl phosphate and reactivity with anti-intestinal alkaline phosphatase antibody were quite similar for both enzymes. Differences in the properties of this enzyme and intestinal alkaline phosphatase were in sensitivity to denaturation by treatment with heat and urea and to inhibition by Levamisole. The possible origin of the enzyme in normal liver and its relationship to the Kasahara isoenzyme and fetal intestine-type in hepatoma is discussed.

Contrast manifestation of alkaline phosphatase and 5'-nucleotidase in plasma membranes isolated from rat liver and ascites hepatoma

1. Plasma membranes were isolated from ascites hepatoma AH-130 and rat livers with or without partial hepatectomy or bile duct ligation. Reciprocal manifestations of two marker enzymes for plasma membranes were observed in these membrane preparations; alkaline phosphatase activity was found much higher in the hepatoma membrane than in any preparations of the liver membranes, whereas 5'-nucleotidase activity was much lower in the former than in the latter. 2. Effects of lectins and anti-plasma membrane antiserum on these two marker enzymes were examined. The results showed that about 50% of apparent activity of 5'-nucleotidase found in the hepatoma membrane was exhibited by alkaline phosphatase. 3. Localizations of alkaline phosphatase and 5'-nucleotidase in polyacrylamide gels after electrophoresis were demonstrated using 5'-AMP and 5-Br, 4-Cl-indoxylphosphate as substrate. There was a difference in electrophoretic mobility between the alkaline phosphatase of the hepatoma and that of the liver.

Inhibition of alkaline phosphatase by sialic acid

The interaction of human organ alkaline phosphatases (orthophosphoric-monoester phosphohydrolases (alkaline optimum), EC 3.1.3.1) with sugars was studied. Hexosamines, N-acetylneuraminic acid (NANA or sialic acid), N-acetylmuramic acid and N-acetylglycolylneuraminic acid inhibited human organ alkaline phosphatase activities. Of these, sialic acid was the most effective inhibitor. The pH profiles for the enzymes in the absence and presence of sialic acid were similar. The sialic acid - enzyme complex was more heat stable than the free enzyme between 20 and 45 degrees C. Lineweaver-Burk plots of 1/v versus 1/S at various concentrations of sialic acid showed intersecting straight lines indicating that the mechanism of inhibition was a mixed type. The Ki value obtained from the plots of 1/v versus the square of sialic acid concentration was 0.07 mM for the hepatic, sialidase-treated hepatic, and intestinal alkaline phosphatases. The respective Hill coefficients varied somewhat with the alkaline phosphatase isoenzyme. Hyperbolic curves were obtained when the percentage of remaining activity was plotted against the substrate concentration at different concentrations of sialic acid. The Hill coefficient was lowered in the presence of sialic acid. The sialidase-treated hepatic enzymes used gave the most effective conversion. Partial denaturation of the enzyme with urea, or pronase digestion had a little if any effect on the sialic acid inhibition with constant time.

Partial purification of human intestinal alkaline phosphatase with affinity chromotography. Some properties and interaction of concanavalin A with alkaline phosphatase

1. Alkaline phosphatase (orthophosphoric-monoester phosphohydrolase (alkaline optimum), EC 3.1.3.1) from human intestine was purified with concanavalin A-Sepharose and tyraminyl derivative-Sepharose affinity chromatography. The enzyme obtained with these techniques had a specific activity of approx. 513.2 mumol p-nitrophenylphosphate hydrolyzed per min per mg of protein at pH 10.0. 2. The highly purified enzyme showed one major enzymatically active band and a possible minor enzymatically active band on acrylamide gel and cellogel electrophoresis, and the two fraction types showed identical antigenicity. 3. The highly purified intestinal enzyme was compared with the purified hepatic enzyme: the saccharide content of each showed a marked difference. 4. The interaction of alkaline phosphatase with concanavalin A, a carbohydrate-binding protein, was studied. Concanavalin A showed an organ-specific behavior to alkaline phosphatase isoenzyme, i.e., the effect on the enzyme activity, and the optimum pH of the activity. 5. The concanavalin A and alkaline phosphatase complex showed a protective effect against heat denaturation and inactivation of proteinase digestion. There was no difference in stability between the intestinal enzyme and the hepatic enzyme. 6. Alkaline phosphatase preparations from human intestine and human liver can bind with concanavalin A; these interactions of concanavalin A; these interactions of concanavalin A with the enzyme occurred reversibly when alpha-methyl-D-mannoside was added. 7. The double reciprocal plots of 1/v vs. 1/s at higher concentrations of concanavalin A showed that the mechanism of inhibition was "mixed type". From the results of Dixon plots, the inhibition constant (Ki) was calculated to the 0.025 muM for human intestinal enzyme. 8. The effect of concanavalin A on L-phenylalanine inhibition of the intestinal alkaline phosphatase indicates that concanavalin A does not interfere with L-phenylalanine binding, but its effect on L-homoarginine inhibition of the hepatic enzyme seems to show that concanavalin A interfered with L-homoarginine binding.