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.     

Characterization of alkaline phosphatase in canine serum

On the basis of carbohydrate structure, normal dog serum contains three basic types of serum alkaline phosphatase (SAP) corresponding to (1) highly branched complex (non-concanavalin A-binding), (2) complex, or (3) high-mannose (both concanavalin A-binding) oligosaccharide structures. Subsequent binding experiments with monoclonal antibody to intestinal alkaline phosphatase (AP) and bromotetramisole inhibition studies clearly indicated the presence of intestinal-like SAP. Concanavalin A (Con-A) binding characteristics suggested the presence of a bone-like SAP. Con-A-binding and isoelectric focusing results revealed the presence of two (type Ib and IIb) major SAP isoenzymes thought to be of hepatic origin. SAP isoenzymes appear to be modified when compared to tissue AP, particularly in regard to molecular size and, in some cases, carbohydrate structure.     

In vitro inhibition of alkaline phosphatase activities from intestine, bone, liver, and kidney by phenobarbital.

A kinetic study of the inhibition of several alkaline phosphatase (AP isoenzyme activities by phenobarbital was carried out using p-nitrophenylphosphate (10 mM) as a substrate at pH 9.8 in a 300-mM Hepes buffer. AP from bovine kidney, calf intestine, bovine liver, and rat bone was used. Over a phenobarbital concentration range of 20-400 mM, all these isoenzymes were inhibited in an uncompetitive manner with a Ki of 200 mM for intestinal AP, and in a linear mixed-type manner for all the other isoenzymes tested. The Ki values were 10, 40 and 55 mM for kidney, bone and liver AP, respectively. The use of 15 mM carbonate-bicarbonate or 400 mM diethanolamine buffer did not modify the degree of inhibition of intestinal AP activity. Dixon plots of the reciprocal of reaction velocity versus inhibitor concentration either at different substrate concentration or at different DEA concentration indicate uncompetitive inhibition for the intestinal enzyme. This in vitro inhibitory effect of phenobarbital is in contrast to its in vivo stimulating action on AP. However, in the whole animal, the effects of phenobarbital administration probably represent the sum of multiple effects.     

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.     

Characterisation of rat and human tissue alkaline phosphatase isoforms by high-performance liquid chromatography and agarose gel electrophoresis

Alkaline phosphatase (ALP) exists as several isoenzymes and many isoforms present in tissues and serum. The objective of this study was to separate tissue ALP forms in rats and humans and characterise their properties. The materials for the investigation were intestinal, bone, and liver tissue of rats and commercially available human preparations of tissue ALP. Two methods of separation were used: high-performance liquid chromatography (HPLC) and agarose gel electrophoresis. Using HPLC in the rat tissues, two ALP isoforms in the intestine, one in the bone, and three in the liver were identified. In humans three intestinal, two bone, and one liver isoform were resolved. Electrophoresis showed two ALP activity bands in rat intestine, one wide band in the bone, and three bands in the liver. ALP of human tissues was visualised as a single wide band, with a different mobility observed for each organ. In both species the presence of a form with properties characteristic of the bone isoform of the tissue-nonspecific isoenzyme was observed in the intestine. HPLC offers a higher resolution than electrophoresis with respect to tissue ALP fractions in rats and in humans, but electrophoresis visualises high-molecular-mass insoluble enzyme forms.     

Dimeric nature and amino acid compositions of homogeneous canine prostatic human liver and rat liver acid phosphatase isoenzymes. Specificity and pH-dependence of the canine enzyme.

Two isoenzymes of rat liver acid phosphatase (orthophosphoric-monoester phosphohydrolase (acid optimum) EC 3.1.3.2) have been purified to homogeneity, at least one of these for the first time. Both of the rat liver isoenzymes have identical specific activities towards p-nitrophenyl phosphate. Molecular weights of the native enzymes are 92 000 for rat liver isoenzyme I and 93 000 for isoenzyme II, while the subunit molecular weights are 51 000 and 52 000 respectively. Data on substrate specificity and pH dependence are presented for the homogeneous canine prostatic enzyme, which is also isolated as a dimeric enzyme of (native) molecular weight 89 000. Carbohydrate analysis data are presented for canine prostatic acid phosphatase and it is further noted that both isoenzymes of rat liver acid phosphatase are also glycoproteins. The amino acid compositions of the two rat liver isoenzymes are presented together with those of the similar dimeric acid phosphatase of human liver and of canine prostate. Comparison of these results with published data for the amino acid composition of human prostatic acid phosphatase shows substantial similarities. However, significant differences are seen in the amino acid composition of rat liver acid phosphatase isoenzyme I as compared to a previous literature report. Most notably, 17 histidine residues are found per mol of isoenzyme I and 18 for isoenzyme II.     

Arginase isoforms in frog and lizard tissues

Isoforms of arginase in the liver and kidney tissues of the ureotelic frog (Rana tigerina) and uricotelic lizard (Calotes versicolor) were fractionated by DEAE-cellulose chromatography (pH 8.3). Four molecular forms, designated as A'1, A2, A3 and A4 based on the KCl concentration required for their elution from the ion-exchange column, were detected in lizard liver, while only two forms were found in lizard kidney (A3 and A4) and frog liver and kidney (A2 and A3). No major differences were found in the pH optimum, substrate affinity and molecular weight of the isoenzymes. The isoforms in lizard tissues were either totally unaffected or only partially immunoprecipitated by antibodies raised against rat liver and beef liver arginases, but those in frog tissues were significantly activated by the two antibodies. While the physiological importance of the presence of four isoforms in lizard liver remains enigmatic, different sets of isoenzymes were present in the liver of the two ureotelic vertebrates, rat and frog. Hence, it appeared that a given mode of nitrotelism was not associated with a specific set of isoenzymes. Also, the data were not consistent with the generally held view that a basic isoform of arginase served as a component of the urea cycle in liver and a neutral/slightly acidic form functions in the synthesis of proline, glutamate and polyamines in extra-hepatic tissues. The isoforms appeared to show considerable functional overlap.     

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.     

On the role and fate of LPS-dephosphorylating activity in the rat liver

Gut-derived lipopolysaccharide (LPS) plays a role in the pathogenesis of liver diseases like fibrosis. The enzyme alkaline phosphatase (AP) is present in, among others, the intestinal wall and liver and has been previously shown to dephosphorylate LPS. Therefore, we investigated the effect of LPS on hepatic AP expression and the effect of AP on LPS-induced hepatocyte responses. LPS-dephosphorylating activity was expressed at the hepatocyte canalicular membrane in normal and fibrotic animals. In addition to this, fibrotic animals also displayed high LPS-dephosphorylating activity around bile ducts. The enzyme was shown to dephosphorylate LPS from several bacterial species. LPS itself rapidly enhanced the intrahepatic mRNA levels for this enzyme within 2 h by a factor of seven. Furthermore, in vitro and in vivo studies showed that exogenous intestinal AP quickly bound to the asialoglycoprotein receptor on hepatocytes. This intestinal isoform significantly attenuated LPS-induced hepatic tumor necrosis factor-alpha and nitric oxide (nitrite and nitrate) responses in vitro. The enzyme also reduced LPS-induced hepatic glycogenolysis in vivo. This study shows that LPS enhances AP expression in hepatocytes and that intestinal AP is rapidly taken up by these same cells, leading to an attenuation of LPS-induced responses in vivo. Gut-derived LPS-dephosphorylating activity or enzyme upregulation within hepatocytes by LPS may therefore be a protective mechanism within the liver.     

Phosphofructokinase D from the epithelial cells of rat small intestine.

Phosphofructokinase from the epithelial cells of rat small intestine was characterized with respect to isoenzyme type in a comparison of its properties with those of the skeletal-muscle, brain and major liver isoenzymes by using five different techniques, namely electrophoresis on cellulose acetate and in polyacrylamide gels, chromatography on DEAE-cellulose, (NH4)2SO4 precipitation and immunotitration. When precautions were taken to inhibit the formation of active proteolytic artifacts by the action of endogenous proteinases, each technique revealed that rat intestinal mucosa contains only a single form of phosphofructokinase. The mucosal isoenzyme was found to be very similar to, although not identical with, the major liver isoenzyme and to be quite distinct from the skeletal-muscle isoenzyme when studied by the techniques of cellulose acetate electrophoresis, chromatography on DEAE-cellulose and immunotitration, whereas the converse was true when studied by the techniques of (NH4)2SO4 precipitation and polyacrylamide-gel electrophoresis. The mucosal isoenzyme was distinct from the brain isoenzyme when studied by each of the five techniques. Tsai & Kemp [(1973) J. Biol. Chem. 248, 785-792] reported that animal tissues contain three principal isoenzymes of phosphofructokinase, type A found as the sole isoenzyme in skeletal muscle, type B found as the major isoenzyme in liver and type C found as a significant isoenzyme in brain. Phosphofructokinase from mucosa is distinct from each of these isoenzymes. Following the nomenclature of Tsai & Kemp (1973), the isoenzyme from the mucosa of rat intestinal epithelial cells is designated phosphofructokinase D. The mucosal and liver isoenzymes behave so similarly with respect to their charge and immunological characteristics, on which the typing of isoenzymes is conventionally based, that it is likely that some tissues reported to contain the liver isoenzyme contain instead the mucosal isoenzyme.     

Induction of a Peroxisomal Malate Dehydrogenase Isoform in Liver of Starved Rats

The influence of starvation on malate dehydrogenase (MDH) in rat liver was investigated. Native electrophoresis revealed two MDH isoforms in non-starved rats and three isoenzymes in starved rats. After sucrose density gradient centrifugation of cell organelles from liver, MDH activity was detected in the mitochondrial and cytosolic fractions from non-starved rats. However, additional activity was found in the peroxisomal fraction from starved rats. The latter was identified as the electrophoretically new isoform in starved animals. The three isoforms of malate dehydrogenase from hepatocytes were separated and partially purified by chromatography on DEAE-Toyopearl. Several kinetic and regulatory properties of the three isoforms were rather similar. It is suggested that the newly expressed isoform of MDH operates in the glyoxylate cycle of liver peroxisomes of food-starved animals.     

Distribution of secreted aspartyl proteinases using a polymerase chain reaction assay withSAP specific primers inCandida albicans isolates

Secreted aspartyl proteinase (Sap) distribution among different C. albicans isolates was determined using SAP-specific primers in polymerase chain reaction (PCR) assay. SAP1, SAP2, and SAP3 were detected in 13 of 40 (32.5%), SAP4 in 38/40 (95%), SAP5 were detected in 30/40 (75%), SAP6 in 23/40 (57.5%) of C. albicans strains isolated from blood cultures. SAP1-SAP3 were detected in 37 of 40 (92.5%), SAP4 were detected in 3/40 (7.5%), SAP5 in 3/40 (7.5%), SAP6 in 5/40 (12.5%) of C. albicans strains isolated from vaginal swab cultures. Sap1, Sap2 and Sap3 isoenzymes were found to be related to the vaginopathic potential of C. albicans; Sap4, Sap5 and Sap6 isoenzymes were found to be correlated with systemic infections.     

Expression of the rat liver haptoglobin gene is mediated by isoforms of C/EBPalpha, -beta and -delta proteins

CCAAT/enhancer binding proteins (C/EBP) alpha, -beta and -delta play an important role in mediating I interleukin-6 (IL-6) dependent expression of acute-phase protein (APP) genes in liver during acute-phase (AP) response. Based on the presence of type IL-6 responsive element (IL-6 RE) in the rat haptoglobin (Hp) gene promoter we assumed that some C/EBPalpha, -beta and/or -delta isoforms could mediate the expression of this gene during turpentine-induced AP response. By Western immunoblot and Northern blot assays, we found that turpentine treatment of rats led to a coordinate induction of C/EBPbeta and -delta as well as repression of C/EBPalpha isoforms pool levels in rat liver nuclear extracts (NEs) which was preceded by an adequate alteration of their mRNAs expression in liver. Consequently, results of DNA affinity chromatography revealed that affinity of certain C/EBPalpha isoforms to bind the type I IL-6 RE within the rat Hp gene promoter decreased whereas affinities of certain C/EBPbeta isoforms and C/EBPdelta were increased and induced, respectively. Our data suggest that turpentine-induced alterations of C/EBPalpha, -beta and -delta pool levels and DNA-binding activities can be regarded as an integral part of activation of the Hp gene expression in the course of AP response.     

Purification and characterization of glutathione transferases from the sea bass (Dicentrarchus labrax) liver

Two forms of glutathione transferase were purified from liver cytosol of the sea bass (Dicentrarchus labrax) by GSH-Sepharose affinity chromatography followed by chromatofocusing. The major enzyme (DL-GST-6.7; 75% of total activity bound to the column) has a pI value of 6.7 and is composed of two subunits of apparent molecular mass 26.5 kDa. The minor enzyme (DL-GST-8.2; 25% of total activity bound to the column) has a pI value of 8.2 and is composed of two subunits of molecular mass 23.5 kDa. Both isoenzymes appear to have blocked N-terminal. The purified proteins were characterized with respect to substrate specificity, CD spectra, TNS binding properties (with 2-toluidinylnaphthalene 6-sulfonate), and immunological reactivity. Partial internal amino acid sequence was also determined for each isoenzyme. The results obtained suggest that DL-GST-6.7 and DL-GST8.2 are novel GSTs belonging, respectively, to theta and alpha classes.     

Two human ACAT2 mRNA variants produced by alternative splicing and coding for novel isoenzymes

Acyl coenzyme A：cholesterol acyltransferase 2 （ACAT2） plays an important role in cholesterol absorption. Human ACAT2 is highly expressed in small intestine and fetal liver, but its expression is greatly diminished in adult liver. The full-length human ACAT2 mRNA encodes a protein, designated ACAT2a, with 522 amino acids. We have previously reported the organization of the human ACAT2 gene and the differentiation-dependent promoter activity in intestinal Caco-2 cells. In the current work, two human ACAT2 mRNA variants produced by alternative splicing are cloned and predicted to encode two novel ACAT2 isoforms, named ACAT2b and ACAT2c, with 502 and 379 amino acids, respectively. These mRNA variants differ from ACAT2a mRNA by lack of the exon 4 （ACAT2b mRNA） and exons 4-5 plus 8-9-10 （ACAT2c mRNA）. Significantly, comparable amounts of the alternatively spliced ACAT2 mRNA variants were detected by RT- PCR, and Western blot analysis confirmed the presence of their corresponding proteins in human liver and intestine cells. Furthermore, phosphorylation and enzymatic activity analyses demonstrated that the novel isoenzymes ACAT2b and ACAT2c lacked the phosphorylatable site SLLD, and their enzymatic activities reduced to 25%-35% of that of ACAT2a. These evidences indicate that alternative splicing produces two human ACAT2 mRNA variants that encode the novel ACAT2 isoenzymes. Our findings might help to understand the regulation of the ACAT2 gene expression under certain physiological and pathological conditions.     

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.     

Modulation of human Caco-2 intestinal epithelial cell phenotype by protein kinase C inhibitors

Protein kinase C (PKC) isoforms are altered in colon tumors and upon exposure of intestinal mucosa to nutrients. We evaluated the effects of the PKC inhibitors staurosporine and calphostin C on human Caco-2 intestinal epithelial proliferation, motility, and differentiation. Motility was quantitated by monolayer expansion and the brush border enzymes dipeptidyl dipeptidase (DPDD) and alkaline phosphatase (AP) by synthetic substrate digestion. Staurosporine (0.03-1.0 ng/ml) and calphostin C (10^-12M-10^-4 M) dose-dependently inhibited monolayer expansion and AP but stimulated DPDD. Proliferation was also inhibited but the effects of each inhibitor on motility, AP, and DPDD were preserved after mitomycin C proliferative blockade, suggesting that these effects were proliferation-independent. PKC inhibitors independently inhibit motility, AP and proliferation in human intestinal Caco-2 epithelial cells, but selectively stimulate the small intestinal differentiation marker DPDD. PKC may regulate small intestinal epithelial differentiation.