Properties of mouse alpha-galactosidase.

alpha-Galactosidase has been examined in various murine tissues using the substrate 4-methylumbelliferyl-alpha-galactoside. Mouse liver appears to contain a single major form of the enzyme, as judged by chromatography and electrophoresis. The enzmye was purified 467-fold with a yield of about 40% by a method involving chromatography on Concanavalin A-Sepharose. It has maximal activity at pH 4.2, a Km value of 1.4 mM, and energy of activation of 16 400 cal/mol, and a molecular weight of 150 000 at pH 5.2. It is inhibited at high concentrations of myoinositol and appears to contain N-acetylneuraminic acid. In these characteristics it resembles human alpha-galactosidase A. The enzyme from various tissues differs in electrophoretic mobility. After treatment with neuraminidase, however, the enzyme from all tissues comigrates as a single band of activity. By this criterion the alpha-galactosidase of liver is most heavily sialylated and that from kidney the least. As estimated by gel filtration, the enzyme from liver and kidney exists as species of molecular weight 320 000, 150 000 and 70 000, depending upon pH and ionic strength. This appears to be the result of aggregation of the enzyme, since the forms are interconvertible and under some conditions a single molecular weight species is observed. The liver enzyme is primarily lysosomal, while the kidney enzyme is distributed approximately equally between lysosomal and microsomal fractions.     

Separation and properties of β-galactosidase, β-glucosidase, β-glucuronidase and n-acetyl-β-glucosaminidase from rat kidney

1. The activities of β-galactosidase, β-glucosidase, β-glucuronidase and N-acetyl-β-glucosaminidase from rat kidney have been compared when 4-methylumbelliferyl glycosides are used as substrates. 2. Separation by gel electrophoresis at pH7·0 indicated slow- and fast-moving components of rat-kidney β-galactosidase. 3. The fast-moving component is also associated with the total β-glucosidase activity and inhibition experiments indicate that a single enzyme species is responsible for both activities. 4. DEAE-cellulose chromatography and filtration on Sephadex gels suggests that the β-glucosidase component is a small acidic molecule, of molecular weight approx. 40000–50000, with optimum pH5·5–6·0 for β-galactosidase and β-glucosidase activities. 5. The major β-galactosidase component has low electrophoretic mobility, a calculated molecular weight of 80000 and optimum pH3·7.     

A sialidase complex from chicken liver: Characterization of a multienzyme complex with β-galactosidase and carboxypeptidase

Mammalian lysosomal sialidase exists as an enzyme complex with β-galactosidase and carboxypeptidase, so-called “protective protein.” In this article, we report that chicken sialidase also occurs as a complex with β-galactosidase and protective protein. The purified sialidase complex had a molecular weight > 700 kDa on gel filtration and showed four protein components of 76, 65, 54 and 48 kDa on SDS-PAGE under nonreducing conditions. N-Terminal sequences of the 65- and 48-kDa proteins were homologous to human lysosomal β-galactosidase and protective protein precursor, respectively. The purified sialidase complex also had carboxypeptidase activity. Both sialidase and carboxypeptidase activities were precipitated together by an antibody against chicken β-galactosidase. The complex reversibly dissociated into 120-kDa β-galactosidase dimer and 100-kDa carboxypeptidase dimer at pH 7.5, but the sialidase irreversibly inactivated during the depolymerization. These findings indicate that chicken sialidase exists as a multienzyme complex, by which the sialidase activity appears to be stabilized.     

Cloning and expression of the gene encoding <Emphasis Type="BoldItalic">Streptomyces coelicolor</Emphasis> A3(2) α-galactosidase belonging to family 36

The α-galactosidase gene of Streptomyces coelicolor A3(2) was cloned, expressed in Escherichia coli and characterized. It consisted of 1497 nucleotides encoding a protein of 499 amino acids with a predicted molecular weight of 57,385. The observed homology between the deduced amino acid sequences of the enzyme and α-galactosidase from Thermus thermophilus was over 40%. The α-galactosidase gene was assigned to family 36 of the glycosyl hydrolases. The enzyme purified from recombinant E. coli showed optimal activity at 40 °C and pH 7. The enzyme hydrolyzed p-nitrophenyl-α-D-galactopyroside, raffinose, stachyose but not melibiose and galactomanno-oligosaccharides, indicating that this enzyme recognizes not only the galactose moiety but also other substrates.     

Rat-kidney lysosomes: isolation and properties

1. The activities of lysosomal enzymes in the cortexes and medullas and the principal subcellular fractions of rat kidney were measured. 2. A method is described for the isolation of rat-kidney lysosomes and a detailed analysis of the enzymic composition of the lysosomes is reported. Enzyme analysis of the other principal subcellular fractions is included for comparison. 3. Studies of the distribution of α-glucosidase showed that the lysosomal fraction contained only 10% of the total enzyme activity. The microsomal fraction contained most of the particulate α-glucosidase. Lysozyme was concentrated mainly in the lysosomal fraction with only small amounts present in the microsomal fraction. Lysosomal α-glucosidase had optimum pH5 whereas the microsomal form had optimum pH6. Both lysosomal and microsomal lysozyme had optimum pH6·2. 4. The stability of lysosomal suspensions was studied. Incubation at 37° and pH7 resulted in first an increased availability of enzymes without parallel release of enzyme. This was followed by a second stage during which the availability of enzymes was closely related to the release of enzymes. These changes were closely paralleled by changes in light-scattering properties of lysosomes. 5. The latent nature of the α-glucosidase and lysozyme of intact kidney lysosomes was demonstrated by their graded and parallel release with other typical lysosomal enzymes. 6. Isolated lysosomes were unstable at pH values lower than 5, most stable at pH6–7 and less stable at pH 8–9. Lysosomes were not disrupted when the osmolarity of the suspending medium was decreased from 0·6m to 0·25m. 7. The discussion compares the properties and composition of kidney lysosomes, liver lysosomes and the granules of macrophages. 8. The possible origin of the lysozyme in kidney lysosomes by reabsorption of the lysozyme in blood is discussed.     

Comparative Biochemistry of a Cytosolic Artiodactyl Glycosidase

Artiodactyls possess abundant neutral glycosidase activity in liver, kidney and intestine. This enzyme is cytosolic and displays a more neutral pH optimum, more acidic isoelectric point and broader substrate range than the corresponding acidic β-galactosidases. The neutral glycosidases were more thermolabile than the respective acidic β-galactosidases and displayed a relative molecular mass approximating 60 kDa. This isozyme appeared to be a minor species in both rat and dog liver. The porcine enzyme was studied in more detail. Porcine neutral glycosidase activity was detected in 45-day gestational fetuses in both liver and kidney but not brain. Fetal kidney activities were about half those observed in adult kidney extracts. Porcine neutral glycosidase was immunologically distinct from acidic β-galactosidase and was immunologically similar to the corresponding isozymes from deer, ovine and bovine liver. Porcine neutral glycosidase was moderately inhibited by d-galactonic acid γ-lactone and strongly inhibited by d-gluconic acid δ-lactone; however, acidic β-galactosidase was not inhibited by the δ-lactone. Inhibition by the γ-lactone was competitive for both enzymes. 4-Methylumbelliferyl-β-d-galactoside, -glucoside and -xyloside competed for the same active site. A polymorphism for fast- and slow-migrating isozymes of porcine neutral glycosidase was observed, which appeared to be under genetic control.     

Expression and Characterization of Glycosylated and Catalytically Active Recombinant Human α-Galactosidase A Produced in Pichia pastoris

Fabry disease is an X-linked inborn error of glycolipid metabolism caused by deficiency of the lysosomal enzyme α-galactosidase A. This enzyme is responsible for the hydrolysis of terminal α-galactoside linkages in various glycolipids. An improved method of production of recombinant α-galactosidase A for use in humans is needed in order to develop new approaches for enzyme therapy. Human α-galactosidase A for use in enzyme therapy has previously been obtained from human sources and from recombinant clones derived from human cells, CHO cells, and insect cells. In this report we describe the construction of clones of the methylotrophic yeast Pichia pastoris that produce recombinant human α-galactosidase A. Recombinant human α-galactosidase A is secreted by these Pichia clones and the level of production is more than 30-fold greater than that of previously used methods. Production was optimized using variations in temperature, pH, cDNA copy number, and other variables using shake flasks and a bioreactor. Expression of the human enzyme increased with increasing cDNA copy number at 25°C, but not at the standard growth temperature of 30°C. The recombinant α-galactosidase A was purified to homogeneity using ion exchange (POROS 20 CM, POROS 20 HQ) and hydrophobic (Toso-ether, Toso-butyl) chromatography with a BioCAD HPLC Workstation. Purified recombinant α-galactosidase A was taken up by fibroblasts derived from Fabry disease patients and normal enzyme levels could be restored under these conditions. Analysis of the carbohydrate present on the recombinant enzyme indicated the predominant presence of N-linked high-mannose structures rather than complex carbohydrates.     

Localization and some properties of lysosomal dipeptidases in rat liver

1. 1. The rates of hydrolysis of 26 synthetic depeptides by extracts from highly purified lysosomal fractions from rat liver at pH 5.0 and by whole liver homogenates at pH 7.4 have been determined. Extracts from the lysosomal fractions hydrolysed most peptides at a lower rate per mg protein than the homogenates, and some peptides not at all.

2. 2. Properties of two dipeptidases present in the extracts from the lysosomal fractions, splitting Ile-Glu and Leu-Gly, respectively, were studied in greater detail. The enzyme that hydrolysed Ile-Glu was strongly activated by dithiothreitol, showed optimal activity at pH 4.5 and had a molecular weight of about 120 000. Leu-Gly dipeptidase did apparently not contain an essential thiol group and had a molecular weight of approx. 90 000. It showed maximal activity at pH 6.5.

3. 3. After differential centrifugation of liver homogenates, Ile-Glu and Leu-Gly-splitting activities were determined in the fractions, under the optimal conditions mentioned above. The Ile-Glu-hydrolysing enzyme activity showed about the same distribution as the lysosomal marker enzyme acid phosphatase. Leu-Gly-splitting activity, however, was largely present in the cytosol fraction, with only a small peak in the lysosomal fraction. We obtained evidence that the activities present in the lysosomal fraction and in the cytosol fraction were due to different enzymes, and that one of these enzymes was localized exclusively in lysosomes.

4. 4. It is concluded that some dipeptides originating from intralysosomal proteolysis might be split by lysosomal dipeptidases, whereas others are probably hydrolysed only in the extra-lysosomal compartment of the cell.

Lysosomal enzyme changes in growing and regressing mammary tumours

Rat mammary tumours induced by 7,12-dimethylbenz[a]anthracene can undergo repeated growth and regression during successive pregnancies. In a 10-day period after birth about half of the tumours regressed 50% or more. The concentrations of the lysosomal enzymes increased in regressing mammary tumours to the following multiples of the initial values: β-glucuronidase, 7·7; β-galactosidase, 3·9; cathepsin, 2·9; acid ribonuclease, 2·1; arylsulphatase A, 1·5; acid phosphatase, 1·4. In contrast, several non-lysosomal enzymes failed to increase. Activities in the post-partum uterus increased to the following multiples of the initial values: β-glucuronidase, 5·8; cathepsin, 5·5; acid ribonuclease, 4·3; β-galactosidase, 2·2; acid phosphatase, 1·8. Arylsulphatase A in the post-partum uterus decreased significantly, suggesting a non-lysosomal distribution or a special function related to pregnancy. No other significant changes were observed in the lysosomal or non-lysosomal enzymes in the hormone-independent liver or hormone-dependent normal mammary gland. The ratio of free to bound arylsulphatase A and acid ribonuclease decreased slightly 1–3 days after birth because of problems in homogenizing the tumours. At days 4–8, however, there was a dramatic increase in the ratio of the free to bound activities. The results can be explained in terms of the lysosomal theory of intracellular digestion.     

Purification and Partial Characterization of Potato (Solanum tuberosum) Invertase and Its Endogenous Proteinaceous Inhibitor

Invertase plays an important role in the hydrolysis of sucrose in higher plants, especially in the storage organs. In potato (Solanum tuberosum) tubers, and in some other plant tissues, the enzyme seems to be controlled by interaction with an endogenous proteinaceous inhibitor. An acid invertase from potato tubers (variety russet) was purified 1560-fold to electrophoretic homogeneity by consecutive use of concanvalin A-Sepharose 4B affinity chromatography, DEAE-Sephadex A-50-120 chromatography, Sephadex G-150 chromatography, and DEAE-Sephadex A-50-120 chromatography. The enzyme contained 10.9% carbohydrate, had an apparent molecular weight of 60,000 by gel filtration, and was composed of two identical molecular weight subunits (M_r 30,000). The enzyme had a K_m for sucrose of 16 millimolar at pH 4.70 and was most stable and had maximum activity around pH 5. The endogenous inhibitor was purified 610-fold to homogeneity by consecutive treatment at pH 1 to 1.5 at 37°C for 1 hour, (NH₄)₂SO₄ fractionation, Sephadex G-100 chromatography, DEAE-Sephadex G-50-120 chromatography, and hydroxylapatite chromatography. The inhibitor appears to be a single polypeptide (M_r 17,000) without glyco groups. The purified inhibitor was stable over the pH range of 2 to 7 when incubated at 37°C for 1 hour.     

Neurochemical abnormality in I-cell disease: chemical analysis and a possible importance of beta-galactosidase deficiency.

Sphingolipid composition in both gray and white matter of a patient with I-cell disease was normal except for the higher proportion.of G_MI-ganglioside in gray and white matter. In the patient's liver and kidney there was a significant accumulation of ceramide dihexoside and ceramide trihexoside and of sulphatide in kidney. Non-lipid hexosamine and sialic acid concentration in brain was increased 1.2-1.5 times above normal. Recovery of myelin from I-cell's white matter was 80-100%, suggesting that demyelination, if present, is minimal. Myelin lipid and myelin specific glycoprotein patterns were normal. Except for β-galactosidase activity the activity of other brain lysosomal enzymes were within the normal range. This finding was similar to that of Hurler's syndrome. Only β-galactosidase activity was reduced to less than 10% of normal in the patient's brain. To examine the possible metabolic significance of β-galactosidase deficiency in I-cell disease the physical characteristics of this enzyme, isolated from tissues from I-cell, Hurler and control patients, were compared using isoelectric focusing, Con A-Sepharose and Sephadex G-150 chromatography. The isoelectric point and the binding affinity of I-cell β-galactosidase with Con A-Sepharose was comparable to normal. However, the isoenzyme patterns of brain and liver I-cell β-galactosidase with Sephadex G-150 gel filtration revealed decreased acid β-galactosidase. Effects of the addition of sodium chloride on each fraction of β-galactosidase isoenzymes isolated from I-cell tissues were markedly different from controls, whereas the pH optimum of these enzymes were similar to normal. These enzyme characteristics in I-cell tissues were different from normal and Hurler's syndrome. These findings suggest that β-galactosidase deficiency in I-cell disease is a more specific phenomenon rather than secondary inhibition as found in the mucopolysaccharidoses and thus may have an important role for the pathogenesis of brain damage and disease occurrence.     

Effects of thiol protease inhibitors on intracellular degradation of exogenous β-galactosidase in cultured human skin fibroblasts

The effects of low molecular weight (LMW) protease inhibitors of microbial origin were evaluated on the intracellular degradation of β-galactosidase purified from Aspergillus oryzae and taken up by cultured human skin fibroblasts with β-galactosidase deficiency. Only thiol protease inhibitors showed an effect to increase the enzyme activity. E-64, a specific inhibitor of thiol proteases, prolonged 3-fold a half life of the exogenous β-galactosidase and when the enzyme was supplied as liposomes, the half life was prolonged 9-fold in these cells. The role of thiol proteases in the degradation of enzyme molecules was discussed.     

Purification and properties of bovine liver lysosomal adenosine 5'-phosphosulphate sulphohydrolase. A non-specific enzyme with pyrophosphatase and phosphodiesterase activities.

Bovine liver lysosomal adenosine 5'-phosphosulphate sulphohydrolase (EC 3.6.2.1) was purified to apparent homogeneity. The molecular weight of the enzyme was 53 000 by sodium dodecyl sulphate polyacrylamide gel electrophoresis and 56 000 by BioGel P-150 gel filtration. The substrate specificity of the enzyme was studied. The several substrates towards which the enzyme preparation showed high activity were used to establish that a single enzyme was responsible for the different activities. This multiple specificity provides a possible explanation of the physiological role of lysosomal adenosine 5'-phosphosulphate sulphohydrolase.     

Purification of rabbit kidney cytokinase and a comparison of its properties with human urokinase

1. The cytokinase (tissue activator of plasminogen) content of several mammalian tissues was evaluated by a quantitative casein hydrolysis method. 2. An alkaline (pH10·5) extraction of cytokinase from rabbit kidney lysosome–microsome fraction, followed by chromatography on DEAE-cellulose at pH7·6 with stepwise or linear increase in concentration of phosphate buffer, gave an 86-fold purification of the enzyme. The purified material was non-proteolytic against casein and heated fibrin and was freeze-dried without significant loss of activity or solubility. 3. Cytokinase is a protein with E^0·1%_1cm.=0·87 at 280mμ, and does not possess sufficient hexose or sialic acid to be classified as a glycoprotein. It has S_20,w 2·9–3·1s and molecular weight 50000 when measured on a calibrated Sephadex G-100 column. It has an isoelectric point between pH8 and pH9, and is maximally active and stable at pH8·5. It is inactivated by heat at 78°. 4. Cytokinase and human urokinase have the same K_m value and are inhibited in a partially competitive manner by -aminohexanoic acid and aminomethylcyclohexanecarboxylic acid. They are also inhibited by cysteine and arginine, but are unaffected by iodoacetamide and p-chloromercuribenzoate. 5. On the basis of this and other evidence it is suggested that rabbit kidney cytokinase and human urokinase are similar, if not identical, enzymes.     

Rat tripeptidyl peptidase I: molecular cloning, functional expression, tissue localization and enzymatic characterization

We purified tripeptidyl peptidase I (TPP I) to homogeneity from a rat kidney lysosomal fraction and determined its physicochemical properties, including its molecular weight, substrate specificity and partial amino acid sequence. The molecular weight of the enzyme was calculated to be 280,000 and 290,000 by non-denaturing PAGE and gel filtration, respectively, and to be 43 000 and 46 000 on SDS-PAGE in the absence and presence of beta-ME, respectively. These findings suggest that the enzyme is composed of six identical subunits. The Km, Vmax, kcat and kcat/Km values of TPP I at optimal pH (pH 4.0) were 680 microM, 3.7 micromol x mg(-1) x min(-1), 33.1 s(-1) and 4.87 x 10(4) s(-1) x M(-1) for Ala-Ala-Phe-MCA, respectively. TPP I was significantly inhibited by PCMBS and HgCl2, and moderately by DFP. These findings also suggest that TPP I is an exotype serine peptidase that is regulated by SH reagent. TPP I released the tripeptide Arg-Val-Tyr from angiotensin III more rapidly than from Ala-Ala-Phe-MCA, and also released Gly-Asn-Leu from neuromedin B with the same velocity as from Ala-Ala-Phe-MCA. Angiotensin III and neuromedin B have recently been found to be good natural substrates for lysosomal TPP I. Furthermore, we determined the rat liver cDNA structure and deduced the amino acid sequence. The cDNA, designated as lambdaRTI-1, is composed of 2485 bp and encodes 563 amino acids in the coding region. By Northern blot analysis, the order for TPP I mRNA expression was kidney > or = liver > heart > brain > lung > spleen > skeletal muscle and testis. In parallel experiments, the TPP I antigen was detected in various rat tissues by immunohistochemical staining.     

beta-Galactosidases in Ripening Tomatoes

Tomatoes (Lycopersicon esculentum L.) contained a high level of β-galactosidase activity which was due to three forms of the enzyme. During tomato ripening, the sum of their activities remained relatively constant, but the levels of the individual forms of β-galactosidase changed markedly. The three enzymes were separated by a combination of chromatography of DEAE-Sephadex A-50 and Sephadex G-100. During ripening of tomatoes, β-galactosidases I and III levels decreased but the β-galactosidase II level increased more than 3-fold. The three enzymes were optimally active near pH 4, and all were inhibited by galactose and galactonolactone. However, the enzymes differed in molecular weight, K_m value with p-nitrophenyl-β-galactoside, and stability with respect to pH and temperature. β-Galactosidase II was the only enzyme capable of hydrolyzing a polysaccharide that was isolated from tomatoes and that consisted primarily of β-1, 4-linked galactose. The ability of β-galactosidase II to degrade the galactan and the increase in its activity during tomato ripening suggest a possible role for this enzyme in tomato softening.     

Purification and properties of spinach leaf debranching enzyme

Starch debranching enzyme was purified from intact spinach (Spinacia oleracea L. cv Vital) chloroplasts and from a spinach leaf extract using affinity chromatography on Sepharose 6B-bound cycloheptaamylose (Schardinger β-dextrin). The enzyme from both sources was homogeneous upon sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Spinach leaf debranching enzyme appears to consist of a single polypeptide chain, since the molecular weight of the native protein (110,000 daltons) was not changed by treatment with sodium dodecyl sulfate. Only one spinach leaf debranching enzyme band could be detected after electrophoresis of a leaf extract on amylopectin-containing polyacrylamide gel, the retardation factor of which coincided with that of the single band seen with the chloroplast enzyme. The purified enzyme exhibited strong pullulanase activity, the specific activity being 69 units per milligram protein with pullulan and 22 units per milligram protein with amylopectin. Cycloheptaamylose is a potent competitive inhibitor of spinach leaf debranching enzyme. The pH optimum of the enzyme was found to be 5.5. The purified enzyme is rather unstable at both 20° and 0°C. Part of the activity lost under storage or at a suboptimal pH could immediately be restored by the addition of thiols. The reactivatable protein, being of the same molecular weight as the native enzyme, exhibited a somewhat altered electrophoretic mobility resulting in one or two minor bands on a zymogram.     

Production and Purification of Extracellular D-Xylose Isomerase from an Alkaliphilic, Thermophilic Bacillus sp.

An alkaliphilic, thermophilic Bacillus sp. (NCIM 59) produced extracellular xylose isomerase at pH 10 and 50°C by using xylose or wheat bran as the carbon source. The distribution of xylose isomerase as a function of growth in comparison with distributions of extra- and intracellular marker enzymes such as xylanase and β-galactosidase revealed that xylose isomerase was truly secreted as an extracellular enzyme and was not released because of sporulation or lysis. The enzyme was purified to homogeneity by ammonium sulfate precipitation followed by gel filtration, preparative polyacrylamide gel electrophoresis, and ion-exchange chromatography. The molecular weight of xylose isomerase was estimated to be 160,000 by gel filtration and 50,000 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, indicating the presence of three subunits. The enzyme is most active at pH 8.0 and with incubation at 85°C for 20 min. Divalent metal ions Mg²⁺, Co²⁺, and Mn²⁺ were required for maximum activity of the enzyme. The K_m values for D-xylose and D-glucose at 80°C and pH 7.5 were 6.66 and 142 mM, respectively, while K_cat values were 2.3 × 10² s^-1 and 0.5 × 10² s^-1, respectively.     

Carnitine synthesis and uptake into cells are stimulated by fasting in pigs as a model of nonproliferating species

In rodents, fasting increases the carnitine concentration in the liver by an up-regulation of enzymes of hepatic carnitine synthesis and novel organic cation transporter (OCTN) 2, mediated by activation of peroxisome proliferator-activated receptor (PPAR) α. This study was performed to investigate whether such effects occur also in pigs which like humans, as nonproliferating species, have a lower expression of PPARα and are less responsive to treatment with PPARα agonists than rodents. An experiment with 20 pigs was performed, which were either fed a diet ad-libitum or fasted for 24 h. Fasted pigs had higher relative mRNA concentrations of the PPARα target genes carnitine palmitoyltransferase 1 and acyl-CoA oxidase in liver, heart, kidney, and small intestinal mucosa than control pigs, indicative of PPARα activation in these tissues (P<.05). Fasted pigs had a higher activity of γ-butyrobetaine dioxygenase (BBD), enzyme that catalyses the last step of carnitine biosynthesis in liver and kidney, and higher relative mRNA concentrations of OCTN2, the most important carnitine transporter, in liver, kidney, skeletal muscle, and small intestinal mucosa than control pigs (P<.05). Fasted pigs moreover had higher concentrations of free and total carnitine in liver and kidney than control pigs (P<.05). This study shows for the first time that fasting increases the activity of BBD in liver and kidney and up-regulates the expression of OCTN2 in various tissues of pigs, probably mediated by PPARα activation. It is concluded that nonproliferating species are also able to cover their increased demand for carnitine during fasting by an increased carnitine synthesis and uptake into cells.     

Immunological characterization of human acid phosphatase gene products

The immunological cross-reactivity of heterogeneous acid phosphatase isozymes from different human tissues has been studied using monospecific antisera prepared against four homogeneous acid phosphatases. The enzyme characterized as tartrate-inhibitable, prostatic acid phosphatase is also found to be present in leukocytes, kidney, spleen, and placenta. The tartrate-inhibitable (liver) lysosomal enzyme is also found in kidney, fibroblasts, brain, placenta, and spleen, but it is not detectable in erythrocytes and prostate. In several tissues, 10–20% of the tartrate-inhibitable enzyme is not precipitated by any of the antisera used; an exceptionally high amount (54%) of such an enzyme is present in human brain. Antiserum against a low molecular weight tartrate-resistant liver enzyme (14 kDa) does not cross-react with the erythrocyte enzyme. (10–20 kDa). All other tissues except placenta, prostate, and fibroblast cells show a cross-reactivity with the 14-kDa acid phosphatase antiserum. Thus, the low molecular weight human liver acid phosphatase is distinct from the erythrocyte enzyme, and there are also at least three different tartrate-inhibitable acid phosphatases in human tissues. Chromosomal assignments have been made for only two of the (at least) five acid phosphatases that are present in adult human tissues.This study was supported by DHHS Research Grant GM 27003 from the U.S. National Institute of General Medical Sciences and by Grant SFB-104 from the Deutsche Forschungsgemeinschaft.