Arylsulfatase a from normal human lung and lung tumors showed different patterns of microheterogeneity

Arylsulfatase A was purified from human lung to apparent homogeneity as determined by electrophoresis in the presence of sodium dodecyl sulfate. The enzyme from normal lung as well as that from lung adenocarcinoma showed considerable microheterogeneity when examined by isoelectric focussing, with an isoelectric point (pI) ranging from 5.1 to 4.6. The tumor enzyme was more heterogeneous and contained more acidic components than the normal lung enzyme. The cause of the charge heterogeneity was examined by treatment with exogenous hydrolases. Upon treatment with sialidase, phosphatase or endo-beta-N-acetylglucosaminidase H (endoglycosidase H), the acidic enzyme forms shifted to an alkaline region on isoelectric focussing gels. Combined treatment of the arylsulfatase A with endoglycosidase H and sialidase resulted in complete loss of the most acidic components to give the less acidic components with pI 5.1, 5.0, and 4.9. These results strongly suggest that the charge heterogeneity of arylsulfatase A is due not only to sialylation but also to phosphorylation at the carbohydrate moiety of the enzyme, and the extent of substitution by acidic groups is markedly increased in the tumor enzyme.     

Lysosomal arylsulfatases A and B from horse blood leukocytes: purification and physico-chemical properties

Lysosomal arylsulfatases A and B (aryl-sulfate sulfohydrolases, EC 3.1.6.1) from horse leukocytes were purified about 680-fold and 70-fold, respectively, starting from a crude extract of the azurophil and specific granules of leukocytes, by affinity, ion exchange, and gel filtration chromatography. Purified arylsulfatase A displayed anomalous kinetics, a pH optimum at 5.2, an isoelectric point at 4.3, and a Km value for p-nitrocatechol sulfate (pNCS) of 0.37 mM. This enzyme was found to exist in two association states depending on pH: a high molecular weight form at pH 5.0 and a low molecular weight form at pH 7.5. Arylsulfatase B displayed normal kinetics, a pH optimum at 5.8, two isoelectric points at pH 8.6 and 8.9, and a Km value for pNCS of 3.38 mM. The thermostability of the two enzymes was different: arylsulfatase B was found to be more stable than arylsulfatase A. Arylsulfatase A was inhibited by sulfate, sulfite, silver, magnesium, manganese and calcium ions and arylsulfatase B by chloride, sulfate, sulfite and silver ions.     

Murine liver arylsulfatase B processing influenced by region on chromosome 17

SM/J liver arylsulfatase B has a more rapid electrophoretic mobility and occurs as a series of more acidic isozymes following electrofocusing in narrow pH gradients than the liver enzyme from C57BL/6J mice. The SM/J and C57BL/6J electrofocusing patterns were both converted to a single isozyme with similar isoelectric points by pretreatment with neuraminidase, suggesting that the SM/J and C57BL/6J isozymes differed with respect to their sialic acid content. Arylsulfatase B electrofocusing and thermostability phenotypes segregated independently among progeny of SM/J×C57BL/6J crosses, suggesting that the electrofocusing phenotypes were not determined by different alleles at As-1, the putative structural locus for arylsulfatase B. Comparison of the joint segregation of hepatic acid phosphatase electrophoretic patterns and liver arylsulfatase B electrofocusing profiles revealed that the electrofocusing profiles may be determined by a region on chromosome 17 near or identical to Apl. Kidney, brain, and spleen arylsulfatase B electrofocusing patterns did not appear to differ between SM/J and C57BL/6J mice.This research was supported in part by Biomedical Sciences Research Support Grant RR-07030, by NIGMS Grant 1-RO1GM27707-01, and by Grant 1–570 from the National Foundation/March of Dimes.     

Phosphorylation and sulfation of arylsulfatase A accompanies biosynthesis of the enzyme in normal and carcinoma cell lines

Arylsulfatase A (arylsulfate sulfohydrolase, EC 3.1.6.1), a mammalian lysosomal enzyme, is initially synthesized as a 69, 67 and 64 kDa precursor polypeptide in a prostate carcinoma cell line PC-3SF12, in HeLa cells and in a normal human embryonic lung cell line WI-38, respectively. These precursor polypeptides are secreted into the medium or processed to mature enzymes of apparent molecular mass 66, 64 or 62 kDa in PC-3SF12, HeLa or WI-38 cells, respectively. The precursor and mature polypeptides in WI-38 cells are phosphorylated, and the phosphate is lost upon treatment with endo-beta-hexosaminidase H. Arylsulfatase A is also shown to be sulfated in WI-38 cells. The presence of castanospermine, an inhibitor of sulfation of the second N-acetylglucosamine residue of the chitobiose core, does not reduce the extent of sulfation of arylsulfatase A, suggesting that either terminal sugars or the protein is sulfated. Sulfation may have a protective function similar to that of terminal sialic acid residues in glycoproteins. Although the subcellular location of arylsulfatase A is identical in PC-3SF12 and in WI-38 cells, pulse-chase experiments indicate that arylsulfatase A protein has a slower turnover in the prostate carcinoma cell line than it does in the normal human lung cell line. The differences in the apparent molecular weights of arylsulfatase A in the normal and carcinoma cell lines are shown to be due to variations in the carbohydrate content of the enzyme. The apparent molecular mass of the polypeptide chain obtained after endo-beta-hexosaminidase H treatment is 59 kDa, a value which is identical for all three cell lines studied here. These results suggest the possibility of an enhanced activity of terminal glucosyltransferase enzymes in carcinoma cell lines and in tumor tissues. Arylsulfatase A may be a useful marker for studying transformation-related processes in human cell lines.     

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.     

Microheterogeneity of arylsulfatase a: Treatment with hydrolytic enzymes

Cerebroside sulfatase also known as arylsulfatase A from human liver displays six microheteromer bands upon narrow pH range isoelectric focusing. Sialic acid residues only partially account for this enzyme multiplicity since neuraminidase treatment reduces the number of bands to three. Uptake studies with cultured fibroblasts strongly suggest arylsulfatase A has covalently bound mannose 6-phosphate residues. However, treatment with alkaline phosphatase and a battery of glycohydrolases failed to reduce the number of enzyme charge forms below three. These results imply that the neuraminidase-resistant charge microheterogeneity is not due to structures associated with the carbohydrate moiety of arylsulfatase A.     

Purification and properties of arylsulfatase B from high- and low-activity mouse strains

Arylsulfatase B (arylsulfate sulfohydrolase; EC 3.1.6.1) activities in C57BL/6J, SWR/J, and A/J mouse liver approximate a 5:3:1 ratio. Each enzyme was purified to apparent homogeneity, and the properties of the three purified enzymes were compared. The purified enzyme behaved as a monomer with an apparent molecular weight of 50,000. The purified enzyme catalyzed the hydrolysis of p-nitrocatechol sulfate (pNCS), 4-methylumbelliferyl sulfate (4MUS), and chondroitin-4-sulfate (C4S) heptasaccharide. Purified SWR/J arylsulfatase B possessed a higher relative electrophoretic mobility at pH 4.0 than the A/J and C57BL/6J isozymes, and the SWR/J enzyme was more thermostable than either the C57BL/6J or the A/J enzyme. No differences were observed among the three enzymes with respect to their Michaelis constants for 4MUS and pNCS, isoelectric points, responses to inhibitors, pH optima, or electrophoretic mobilities at pH 8.3. The relative in vivo rates of synthesis of C57BL/6J, A/J, and SWR/J arylsulfatase B were comparable.     

Phosphorylation of human lysosomal arylsulfatase B by cAMP-dependent protein kinase. Different sites of phosphorylation between normal and cancer tissues

We previously demonstrated that an acidic variant (B1) of lysosomal arylsulfatase B from transplanted human lung cancer is phosphorylated on its protein and carbohydrate moieties (Gasa, S., and Makita, A. (1983) J. Biol. Chem. 258, 5034-5039). The present study identifies that a cAMP-dependent protein kinase is responsible for phosphorylation of arylsulfatase B. The protein kinase activity toward the sulfatase was considerably higher in the transplanted lung cancer than in normal lung in the presence of cAMP. B enzyme purified from normal human liver was found to contain 0.6 mol/mol B enzyme, and protein kinase treatment added further 1.3 mol of Pi to give a single phosphopeptide (X). On the other hand, B1 enzyme purified from the transplanted human lung cancer which had been labeled in vivo with 32Pi revealed at least two phosphopeptides (X and Y). Assuming that the sulfatase from normal liver and lung cancer possesses the same number of available phosphorylation sites, phosphorylation of site X which was available only by deliberate phosphorylation of the native, ordinary B enzyme appears to be cancer-associated. Increasing phosphorylation of the sulfatase resulted in a maximum 50% elevation in arylsulfatase activity, followed by a decrease of the activity upon overphosphorylation, using an artificial substrate.     

Interaction of tumor and surrounding tissue of mice inoculated B16 melanoma variants in terms of enzyme activity

1. The interactions of B16-F1 and B16-F10 tumors with their surrounding tissues in terms of enzyme activities such as cathepsin B, hemoglobin(Hb)-hydrolase, acid phosphatase, beta-glucuronidase and plasminogen activator were investigated when said tumors proliferated locally and at secondary sites throughout the host's circulatory system. 2. In the case of B16-F1 and B16-F10 tumor cells proliferating under the skin, statistical differences were not detected between the enzyme activities of the skin surrounding the tumors and control skin, nor between B16-F1 and B16-F10 tumors, except for beta-glucuronidase. 3. In the case of B16-F1 and B16-F10 tumor cells metastasizing to lung, statistical differences were detected between numerous enzyme activities of the lung tissues surrounding the tumors and control lung tissue, and also between B16-F1 and B16-F10 tumors. 4. The activities of cathepsin B and acid phosphatase of lung tissue surrounding B16-F1 tumor were lower than those of the control lung. 5. beta-Glucuronidase activity of lung tissue surrounding B16-F10 tumor was higher than that of the control lung. 6. The activities of cathepsin B, Hb-hydrolase and beta-glucuronidase of the B16-F10 tumor were higher than those of the B16-F1 tumor. 7. Results indicate that metastasized B16 melanoma tumor cells interact with surrounding lung tissues, and that cathepsin B, Hb-hydrolase and beta-glucuronidase might play important roles in the metastasis of the malignant tumor.     

Phosphorylation on protein and carbohydrate moieties of a lysosomal arylsulfatase B variant in human lung cancer transplanted into athymic mice

Human lung cancer transplanted into athymic mice contains predominantly an acidic variant (designated B1) of lysosomal arylsulfatase B. B1 enzyme was suggested to be phosphorylated and sialylated (Gasa, S., Makita, A., Kameya, T., Kodama, T., Koide, T., Tsumuraya, M., and Komai, T. (1981) Eur. J. Biochem. 116, 497-503). In order to determine the localization of phosphate in B1 enzyme, we labeled in vivo the transplanted tumor with [32P]H3PO4 or [3H]glucosamine and purified B1 enzyme by immunoprecipitation. Bio-Gel chromatography of the labeled B1 enzyme treated with endoglycosidase H demonstrated that both the excluded and included materials were labeled with 32P and 3H. From acid hydrolysate of the excluded materials, phosphorylated serine and threonine were detected. Protein phosphorylation of arylsulfatase was confirmed by in vitro labeling experiments with [gamma-32P]ATP. By incubation of the tumor homogenate with ATP followed by isolation of the enzymes, B1 enzyme had a significant amount of radioactivity, whereas the B enzyme had little; by exogenous protein kinase, partially purified B enzyme was phosphorylated 35 times more than B1 enzyme. Acid hydrolysate of the included materials in the Bio-Gel column demonstrated mannose 6-phosphate and an unknown phosphorylated compound which migrates more than Man-6-P on electrophoresis and chromatography.     

Purification of a derepressible arylsulfatase from Chlamydomonas reinhardti. Properties of the enzyme in intact cells and in purified state.

Arylsulfatase (aryl-sulfate sulfohdydrolase, EC 3.1.6.1) has been purified from SO4-2-minus-starved cells of Chlamydomonas reinhardti. The enzyme was isolated from acetone-powder extract by (NH4)2SO4 precipitation, Sephadex G-200 filtration and ion-exchange chromatography. Only one fraction of aryl-sulfatase was found. The final preparation was homogenous by the criteria of sedimentation, diffusion and polyacrylamide gel electrophoresis. The purified enzyme had a molecular weight of about 150 000, estimated by ultracentrifugation and gel filtration, and an isoelectric point of 9.0. The properties of the enzyme as investigated in intact cells and in the purified state were found to be very similar except for the temperature optimum. Imidazole strongly increased the enzyme by increasing the V, but reduced the affinity for the substrate. The enzyme activity was competitively inhibited by borate with a greater affinity for borate than for the substrate. The Chlamydomonas enzyme is a Type I arylsulfatase since it was inhibited by CN-minus, but not SO4-2-minus and phosphate.     

Isolation and comparison of arylsulfatase A from rat liver and Morris hepatoma 7777

Rat liver and Morris hepatoma 7777 arylsulfatase A were isolated from the soluble lysosomal extract by a procedure involving blue-Sepharose affinity chromatography, DEAE-cellulose chromatography, hydrophobic chromatography on phenyl-Sepharose and preparative polyacrylamide gel electrophoresis. The preparation obtained by this method was apparently homogenous in disc electrophoresis and in immunoelectrophoresis. The comparative studies revealed that the properties of arylsulfatase A from rat liver and Morris hepatoma 7777 are very similar, considering molecular weight of the native monomer and its subunits, the ability to form tetramers, isoelectric point, Michaelis constant and the anomalous kinetics of the reaction. The twofold elevation of arylsulfatase B activity found in Morris hepatoma 7777 suggests that the enzyme may have certain functions in tumor growth.     

The activity of arylsulfatase A and B on tyrosine O-sulfates.

L-Tyrosine O-sulfate was hydrolyzed by pure human arylsulfatase A (arylsufate sulfohydrolase, EC 3.1.6.1). The rate of hydrolysis was 1/20 of the rate with nitrocatechol sulfate, but was comparable to the rate with cerebroside sulfate. The reaction was optimal at pH 5.3--5.5 and displayed zero order kinetics with time and enzyme concentration. The Km was about 35 mM. The enzyme showed no stereospecificity and hydrolyzed D-tyrosine O-sulfate with Km and V similar to those for the L-isomer. Arylsulfatase B was less than 5% as effective as arylsulfatase A in catalyzing the hydrolysis of the tyrosine sulfates. The daily urinary excretion of tyrosine sulfate by a patient with metachromatic leukodystrophy (arylsulfatase A deficiency) was comparable to the excretion by control subjects. The biological relevance of the tyrosine sulfatase activity of arylsulfatase A remains uncertain.     

Purification and some properties of a novel ethylene-forming enzyme produced by Penicillium digitatum

We purified heat-labile enterotoxins (LThs) from YT3, H-10407 and YT240 strains isolated from human diarrheal patients. These LThs were immunologically identical to each other. The molecular weights of their A and B subunits were also the same by means of SDS-polyacrylamide gel electrophoresis. However, the ionic charges of the molecular surfaces of these LThs were different as shown by polyacrylamide gel isoelectric focusing. Though the pI points of B subunits of the LThs were identical to each other, the pI points of A subunits were found to be different. These data suggest that the ionic charge differences among A subunits cause differences in holo LThs in their charge, and that there is heterogeneity among A subunits produced by strains of human enterotoxigenic Escherichia coli.     

A two-component affinity chromatography purification of Helix pomatia arylsulfatase by tyrosine vanadate

The inhibition of Helix pomatia arylsulfatase by the synergistic combination of N-acetyl-l-tyrosine ethyl ester and vanadate has been extended to affinity chromatography for purification. In the presence of vanadate, l-tyrosine ethyl ester (TEE), immobilized on CH-Sepharose 4B retained arylsulfatase from the digestive juice or lyophilized powder of H. pomatia. No enzyme was retained without vanadate or with arsenate or phosphate. Arylsulfatase was eluted from the column matrix by removing the vanadate to less than 50 microM with buffer containing EDTA to chelate the vanadate. Escherichia coli alkaline phosphatase and potato acid phosphatase, two enzymes which are inhibited by vanadate but not by the vanadate-TEE complex, were not retained by the immobilized TEE under any conditions used. The sulfatase activity was completely separated from contaminating glucuronidase activity present in the crude enzyme extracts. The Ki for the immobilized vanadate-TEE system was found to be 5.0 x 10(-7) M with a capacity of 25 mg/ml swollen gel. A purification of greater than 40-fold from the lyophilized powder of H. pomatia (Sigma Type H-5) was achieved using this technique. The Ki/Keq of other phenols with vanadate were determined in a 96-well plate format as an example of a rapid screening technique that could be extended to other phosphoryl and sulfuryl-transfer enzyme classes.     

A variant form of arylsulfatase A in human urine derived directly from the renal pelvis: kinetic and immunological characterization

Arylsulfatase A (aryl-sulfate sulfohydrolase, EC 3.1.6.1) was examined in voided and in nephrostomic urine. A variant form of the enzyme was found in nephrostomic urine, in addition to the minor form, which is the sole component of arylsulfatase A in voided urine. The nephrostomic enzyme differed from the voided urine enzyme with respect to the kinetic parameters, the isoelectric point, heat stability and immunological reactivity. The isoelectric points of the voided urine and nephrostomic enzymes were 4.7 and 5.3, respectively. The nephrostomic enzyme was more heat-labile at 62.5 degrees C than the voided urine enzyme. Although the Km values of the two enzymes with nitrocatechol sulfate as substrate were almost the same, the V value of the nephrostomic enzyme was approx. one-hundredth that of the voided urine enzyme. The molecular weight (almost 130 000) did not differ between the voided urine and nephrostomic enzymes. It was demonstrated by various methods, using IgG antibody against the purified voided urine enzyme, that the nephrostomic enzyme was antigenically distinct from the voided urine enzyme.     

Isoproteins of human apolipoprotein A-II: isolation and characterization

In human serum, polymorphism of apoA-II predominantly in HDL3 could be demonstrated. HDL3-apoA-II was composed of four isoproteins, each with a molecular weight of 8600 (reduced form) and identical immunological properties. The isoproteins are designated apoA-II-1 (pI 5.16), apoA-II-2 (pI 4.89) corresponding to the already known apoA-II monomer band, apoA-II-3 (pI 4.58), and apoA-II-4 (pI 4.31). The amino acid compositions of the A-II isoproteins were virtually identical with the published data for apoA-II. Treatment with acid phosphatase, alkaline phosphatase, or neuraminidase before electrophoresis did not alter the apoA-II pattern. The apoA-II isoprotein pattern was studied in ten male and ten female normolipidemic volunteers, in two patients with Tangier disease, and in three patients with abetalipoproteinemia. The isoelectric focusing patterns of apoA-II appeared virtually identical in all subjects. However, in Tangier disease, due to the low apo-A-II concentration, only apoA-II-1 and apoA-II-2 were detectable, and in abetalipoproteinemia a different relative distribution pattern of the individual isoforms was found as compared to normal HDL3. Our studies indicate that apoA-II, similar to apoA-I, exists in several isoforms. The relationship of these isoforms to each other is at present unclear. They may originate from relatively basic isoproteins that are modified in charge by post-translational processes such as proteolytic cleavage, sequential deamidation, or other mechanisms.     

Comparative biochemistry of murine arylsulfatase B

Arylsulfatase B was purified 4500-fold from liver and kidney of C57BL/6J mice. Hepatic and renal arysulfatase B are apparently determined by a single structural locus; however, posttranslational modification introduces inter- and intratissue microheterogeneity. Partially purified enzyme from C57BL/6J, A/J, C3H/HeJ, and SWR/J mice has similar catalytic properties. The 4500-fold-purified arylsulfatase B from SWR/J and C3H/HeJ mice was more thermostable than that from C57BL/6J and A/J mice, strongly suggesting that the thermostability difference reflects an alteration of the primary structure of the enzyme. Thermal stability of arylsulfatase B was pH dependent and markedly influenced by buffer anion. Variation of thermostability did not appear accountable for the observed activity variation among these strains; however, this possibility cannot be rigorously excluded by presently available data. Thirty-five murine strains were found to possess the As-1 ^a allele (thermostable enzyme), while As-1 ^b was largely restricted to A and C57 strains.This research was supported by PHS Biomedical Sciences Research Support Grant RR-07030.     

Studies on the charge isomers of arylsulfatase A

Human liver arylsulfatase A was resolved into six fractions by narrow pH range preparative isoelectric focusing. Analytical isoelectric focusing revealed that most enzyme fractions were composed of two adjacent charge isomers. Nevertheless, there was considerable enrichment of charge species which allowed a comparative study of selected properties. Except for the most cationic fraction, neuraminidase treatment converted enzyme in all fractions to the three most cationic species. The most electronegative enzyme species had the highest molecular mass being made up of 64-kDa subunits. As electronegativity decreased, there was concomitant decrease in molecular mass and increase in complexity of subunit composition. Two subunits--61 and 55 kDa--prevailed with increasing proportions of the smaller unit with loss of electronegativity. There was also an increasing amount of a 26-kDa fraction which became a substantial component of the most cationic subfraction. Only enzyme in the two fractions containing the largest and most anionic species were taken up by cultured fibroblasts at higher efficiency than unfractionated enzyme. It is suggested that processing or maturation of arylsulfatase A incurs stepwise removal of charge groups and/or peptide segments leading to smaller, less-charged enzyme species.     

Purification of rat liver arylsulfatase A and its microheterogeneity assayed by crossed affinity-immunoelectrophoresis.

Arylsulfatase A (arylsulfatase sulfohydrolase) EC 3.1.6.1 was purified from rat liver by a procedure consisting of differential centrifugation, Con A-Sepharose and Blue Sepharose chromatography, PBE 94 chromatofocusing, DEAE-cellulose and gel filtration chromatography followed by preparative electrophoresis. A molecular mass of 132,000 was estimated by gradient PAGE. Particular proteins were detected by immunoelectrophoresis. Isoelectric focusing combined with immunoelectrophoresis gave two peaks of arylsulfatase A, with isoelectric points of pH 3.9 and 4.5. Microheterogeneity of rat liver arylsulfatase A was studied by affinity immunoelectrophoresis with 9 different lectins. The presence of concanavalin A-, Lens culinaris agglutinin-, Lotus tetragonolobus agglutinin- and wheat germ agglutinin-reactive forms permitted assessment of the types of carbohydrate moieties in arylsulfatase A.