Differential repression of arylsulphatase synthesis in Aspergillus oryzae.

1. The activities of the three arylsulphatases (arylsulphate sulphohydrolase, EC 3.1.6.1) of Aspergillus oryzae produced under a variety of repressing and non-repressing conditions were determined. 2. These enzymes exhibit different sensitivities to repression by inorganic sulphate. 3. Arylsulphatase I, but not arylsulphatases II and III, exhibits a transient de-repression in the early growth phase in sulphate media. 4. When the fungus is cultured in repressing media and subsequently transferred to non-repressing media, the synthesis of the three enzymes is non-co-ordinate. 5. Growth of the fungus in media containing choline O-sulphate or tyrosine O-sulphate as the sole source of sulphur results in complete de-repression of arylsulphatase I, But the synthesis of arylsulphatases II and III is essentially fully repressed. 6. The marked similarities between the repression characteristics of arylsulphatases II and III, contrasted with those of arylsulphatase I, indicate that the genetic locus of arylsulphatase I is distinct from that of arylsulphatases II and III, suggesting that there are distinct physiological roles for the enzyme.     

Purification and properties of arylsulphatase A from rabbit testis.

Rabbit testis arylsulphatase A was purified 140-fold with a recovery of 20% from detergent extracts of an acetone-dried powder by using DE-52 cellulose column chromatography, gel filtration on Sephadex G-200 and preparative isoelectric focusing. The purified enzyme showed one major band with one minor contaminant on electrophoresis in a 7.5% (w/v) polyacrylamide gel at pH8.3. On sodiumdodecyl sulphate/polyacrylamidegel electrophoresis, a single major band was observed with minor contaminants. The final preparation of enzyme was free from general proteolytic, esterase, hyaluronidase, beta-glucuronidase and beta-galactosidase activities. Rabbit testicular arylsulphatase A exists as a dimer of mol.wt. 110000 at pH7.1. At pH5.0 the enzyme is a tetramer of mol.wt. 220000. Arylsulphatase A appears to consist of two identical subunits of mol.wt. 55000 each. The highly purified enzyme has pI4.6. The enzyme hydrolyses p-nitrocatechol sulphate with Km and Vmax, of 4.1 mM and 80nmol/min respectively, but has no activity toward p-nitrophenyl sulphate. The pH optimum of the enzyme varies with the incubation time. By applying Sephacex G-200 chromatography and preparative isoelectric focusing, one form of enzyme was obtained. The enzyme has properites common to arylsulphatase A of other sources with respect to the anomalous time-activity relationship, pI, inhibition by PO42-, SO32- and Ag+ ions and substrate affinity to p-nitrocatechol sulphate. However, the enzyme shows the temperature optimum of arylsulphatase B of other species.     

Enzymic studies of sulphatases in tissues of the normal human and in metachromatic leukodystrophy with multiple sulphatase deficiencies: arylsulphatases A, B and C, cerebroside sulphatase, psychosine sulphatase and steroid sulphatases

Abstract— Several sulphatases (arylsulphatases A, B and C, cholesterol sulphatase, dehydroepiandroster-one sulphatase, cerebroside sulphatase and psychosine sulphatase) were deficient in various tissues from two patients with a variant form of metachromatic leukodystrophy. Deficient activities of cerebroside sulphatase and psychosine sulphatase, using physiological substrates, in tissues from metachromatic leukodystrophy with multiple sulphatase deficiencies provided another example that these enzymes may be identical to arylsulphatase A. β-Galactosidase activity was reduced to about 30-50 per cent of normal in brain and liver. Other lysosomal enzyme activities were found to be normal or elevated five to eight times. Arylsulphatase B isolated from the liver of one patient was abnormal, with respect to pi (70) and enzyme kinetics. In mixing experiments with normal enzymes the reduced activities of arylsulphatases A. B and C, cerebroside sulphatase and steroid sulphatases were shown not to be due to the presence of endogenous inhibitors. No arylsulphatase A or B activity in the brain specimen from the patient with multiple sulphatase deficiencies could be detected on isoelectric focussing. In normal brain tissue arylsulphatase A had a pi of 4-6-4-8 while arylsulphatase B had a pi of 7-8 and 8-1. When 4-methylumbelliferyl sulphate was used as a substrate the elution patterns of normal brain and liver arylsulphatase B were more heterogeneous and showed more variation than that when p-nitrocatechol sulphate was used. Arylsulphatase C and steroid sulphatases (cholesterol sulphatase, dehydroepiandrosterone sulphatase and oes-trone sulphatase I were solubilized by the addition of lysolecithin and Triton X-100 and subjected to isoelectric focussing. The pi of cholesterol sulphatase, oestrone sulphatase and arylsulphatase C was 6-8, and the elution patterns of the activities of these enzymes were similar. The pattern of dehydroepiandrosterone sulphatase was more heterogeneous and two major peaks were observed at pi 6 5 and 70. Residual enzyme activities of arylsulphatase C and steroid sulphatases from the brain of the patient with multiple sulphatase activities were not detectable by isoelectric focussing. Simultaneous deficiencies of arylsulphatase C and steroid sulphatases plus isoelectric focussing findings in tissues suggest that these enzymes are closely related in regard to their function. The nature of the genetic defect in metachromatic leukodystrophy with multiple sulphatase deficiencies is discussed.     

Primary alkylsulphatase activities of the detergent-degrading bacterium Pseudomonas C12B. Purification and properties of the P1 enzyme.

The P1 primary alkylsulphatase of Pseudomonas C12B was purified 1500-fold to homogeneity by a combination of streptomycin sulphate precipitation of nucleic acids, (NH4)2SO4 fractionation and chromatography on columns of DEAE-cellulose, Sephacryl S-300 and butyl-agarose. The protein was tetrameric with an Mr of 181000-193000, and exhibited maximum activity at pH 6.1. Primary alkyl sulphates of carbon-chain length C1-C5 or above C14 were not substrates, but the intermediate homologues were shown to be substrates, either by direct assay (C6-C9 and C12) or by gel zymography (C10, C11, C13 and C14). Increasing the chain length from C6 to C12 led to diminishing Km. Values of delta G0' for binding substrates to enzyme were dependent linearly on chain length, indicating high dependence on hydrophobic interactions. Vmax./Km values increased with increasing chain length. Inhibition by alk-2-yl sulphates and alkane-sulphonates was competitive and showed a similar dependence on hydrophobic binding. The P1 enzyme was active towards several aryl sulphates, including o-, m- and p-chlorophenyl sulphates, 2,4-dichlorophenyl sulphate, o-, m- and p-methoxyphenyl sulphates, m- and p-hydroxyphenyl sulphates and p-nitrophenyl sulphate, but excluding bis-(p-nitrophenyl) sulphate and the O-sulphate esters of tyrosine, nitrocatechol and phenol. The arylsulphatase activity was weak compared with alkylsulphatase activity, and it was distinguishable from the de-repressible arylsulphatase activity of Pseudomonas C12B reported previously. Comparison of the P1 enzyme with the inducible P2 alkylsulphatase of this organism, and with the Crag herbicide sulphatase of Pseudomonas putida, showed that, although there are certain similarities between any two of the three enzymes, very few properties are common to all three.     

Characterization of multiple forms of phosphoinositide-specific phospholipase C from bovine aorta.

Three forms (I, II and III) of phospholipase C were separated from the cytosol of bovine aorta by chromatography on Blue Sepharose. All three forms showed an increase of enzyme activity when free Ca2+ in the assay was raised between 40 microM and 9 mM. The pH optimum was in the range of 6.0 to 6.5 for each subtype. Marked differences in thermostability were found when the three enzyme forms were pre-incubated at 50 degrees C prior to the assay. All three forms were able to hydrolyse phosphatidylinositol as well as phosphatidylinositol 4-phosphate and phosphatidylinositol 4,5-bisphosphate. In contrast, when phosphatidylcholine was used as substrate, no enzyme activity was observed. Spermine and spermidine, but not putrescine, were able to stimulate form I and III; neomycin sulphate inhibited all three subtypes.     

Comparison of the cerebroside sulphatase and the arylsulphatase activity of human sulphatase A in the absence of activators.

A cerebroside sulphatase (cerebroside-3-sulphate 3 sulphohydrolase, EC 3.1.6.8) assay based on radio thin-layer chromatography is described. The substrate was labelled by the catalytic addition of tritium to cerebroside sulphate. Using this assay the cerebroside sulphatase activity of sulphatase A (Aryl-sulphate sulphohydrolase, EC 3.1.6.1) from human liver and kidney in the absence of activators was investigated. The pH optimum of this reaction depends on the buffer concentration, being pH 4.5 at 50 mM and 5.3 at 10 mM sodium formate. With the latter concentration the apparent Km for cerebroside sulphate is 0.06 mM; SO2-4 and nitrocatechol sulphate inhibit noncompetitively with a Ki of 4.51 mM for Na2SO4 and 0.43 mM for nitrocatechol sulphate. The cerebroside sulphatase activity of sulphatase A is highly dependent on the ionic strength. The optimum sodium formate concentration is 10 mM, and the cerebroside suophatase activity decreases rapidly with increasing buffer concentration. The same concentration dependence is observed in the inhibitory effect of cerebroside sulphate on the arylsulphatase reaction. The inhibition decreases at increasing buffer concentrations, becoming an activation at 70 mM sodium formate. The progress curve of the cerebroside sulphatase reaction shows a deviation from linearity similar to that of the arylsulphatase reaction. Investigation of the effect of preincubation with cerebroside sulphate on the arylsulphatase activity of the enzyme shows that cerebroside sluphatase activity and inactivation of the enzyme by cerebroside sulphate occur simultaneously. These observations are interpreted as supporting the assumption that cerebroside suophate and arylsulphates are degraded at an identical active site on the same enzyme. Differences in the properties of the cerebroside sulphatase and the arylsulphatase reaction of the enzyme may be attributed to the differences in the physiocochemical state of the two substrates.     

Catalytic and immunochemical properties of arylsulphatase A from urine, modified by potassium ferrate

Arylsulphatase A (EC 3.1.6.1.) from urine was inactivated with potassium ferrate, a strong oxidizing agent. The inhibition could be prevented by competitive inhibitors, tetraborate and orthophosphate. Tetraborate which was shown to be a powerful competitive inhibitor (determined Ki = 4 X 10(-5) M) gave more efficient protection. The partially inactivated enzyme exhibited a Km value similar to that of the unmodified arylsulphatase A, and its Vmax decreased in proportion to the loss of enzymatic activity. The partially modified enzyme did not lose its ability to catalyse hydrolysis of p-nitrocatechol sulphate according to the "anomalous kinetics" exhibited towards this substrate and characteristic for arylsulphatase A. The immunochemical properties of arylsulphatase A either fully or partially inactivated were similar to those of the native enzyme. The results allow to conclude that ferrate reacts with arylsulphatase A in its active site. Thus ferrate seems to be a very sensitive probe for amino acid residues essential for catalytic activity of arylsulphatase A.     

Differential stabilities of soil enzymes. Assay and properties of phosphatase and arylsulphatase.

Methods have been refined for the assay of phosphatase and arylsulphatase activities in soil, based on the chromogenic p-nitrophenyl ester substrates. Basic assay conditions have been defined, and pH optima and kinetic parameters have been determined. The enzymes follow Michaelis-Menten kinetics; this conclusion is based on three methods of analysis of data determined over a wide range of substrate concentrations. The enzyme activities are very stable to storage of wet soil for up to 4 weeks at soil temperatures and above. For example, phosphatase had a half-life of approximately 2 weeks at 50 degrees C; arylsulphatase was rather less stable. Both enzymes retained 80% of activity after incubation with pronase for 1 week at 25 degrees C. On the basis of this work and studies on other soil enzymes, it is concluded that remarkable stability is a general feature of soil enzymes.     

The development of arylsulphatase in the small intestine of the rat

1. Arylsulphatase activity was measured in stomach, proximal and distal third of small intestine, colon, liver and kidney of foetal and neonatal Sprague-Dawley rats and Swiss mice, with nitrocatechol sulphate as substrate. 2. The specific activity in the distal small intestine, but not in the stomach, proximal small intestine or colon, increased about fourfold between 5 and 16 days after birth in both conventional and germ-free rats. 3. No comparable increase occurred in the distal small intestine of the mouse. 4. The specific activity of acid phosphatase in the distal small intestine of the rat rose only slightly when the arylsulphatase activity increased. 5. The pH optimum and Michaelis constant of arylsulphatase activity of the distal small intestine were similar for 1-day-old, 9-day-old and adult rats. 6. When extracts of distal small intestine of 1-day-old and 9-day-old rats were incubated together, the arylsulphatase activities were additive.     

Purification of soluble arylsulphatases from ox brain

1. Two soluble arylsulphatases (A and B) have been extracted from ox brain by a modified Albers autolysis method and purified by acetone and ammonium sulphate precipitation and dialysis. 2. A 1600-fold purification was achieved with arylsulphatase A and 320-fold purification with arylsulphatase B. 3. The specific activity of arylsulphatase A was 266000 4-nitrocatechol units/mg. of protein N, and that of arylsulphatase B was 64600units/mg. of protein N. 4. Arylsulphatase A seems to be electrophoretically homogeneous. 5. With 3mm-dipotassium 2-hydroxy-5-nitrophenyl sulphate as substrate the optimum pH for the activity of arylsulphatase A was 4.7, and for arylsulphatase B it was 6.1 with a 60mm solution of the same substrate.     

Diagnosis of Maroteaux-Lamy syndrome by the use of radiolabelled oligosaccharides as substrates for the determination of arylsulphatase B activity.

The kinetic parameters (Km and V) of human arylsulphatase B (4-sulpho-N-acetylgalactosamine sulphatase) activity in cultured skin fibroblasts were determined with a variety of substrates matching structural aspects of the physiological substrates in vivo chondroitin 4-sulphate and dermatan sulphate. More structurally complex substrates, in which several aspects of the aglycone structure of the natural substrate were maintained, were desulphated up to 4400 times faster than the minimum arylsulphatase-B-specific substrate, namely the monosaccharide N-acetylgalactosamine 4-sulphate. Aglycone structures that influence substrate binding and/or enzyme activity were an adjacent-residue C-6 carboxy group and a second but internal N-acetylgalactosamine 4-sulphate residue. Arylsulphatase B activity in fibroblast homogenates assayed with O-(beta-N-acetylgalactosamine 4-sulphate)-(1----4)-O-D-(beta-glucuronic acid)-(1----3)-O-D-N-acetyl[1-3H] galactosaminitol 4-sulphate derived from chondroitin 4-sulphate as substrate clearly distinguished Maroteaux-Lamy-syndrome patients from normal controls and other mucopolysaccharidosis patients. We recommend the use of the above trisaccharide substrate for both postnatal and prenatal diagnosis of Maroteaux-Lamy syndrome.     

3',5'-Cyclic nucleotide phosphodiesterase activity of the sulphatase A of ox liver

The sulphatase A (aryl-sulphate sulphohydrolase, EC 3.1.6.1) of ox liver hydrolyses adenosine 3',5'-monophosphate (cyclic AMP) to adenosine 5'-phosphate at an optimum pH of approx. 4.3, close that for the hydrolysis of cerebroside sulphate, a physiological substrate for sulphatase A. The Km is 11.6 mM for cyclic AMP. On polyacrylamide gel electrophoresis sulphatase A migrates as a single protein band which coincides with both the arylsulphatase and phosphodiesterase activities, suggesting that these are due to a single protein. Cyclic AMP competitively inhibits the arylsulphatase activity of sulphatase A, showing that both activities are associated with a single active site on the enzyme. sulphatase A also hydrolyses guanosine 3',5'-monophosphate, but not uridine 3',5'-monophosphate nor adenosine 2',3'-monophosphate.     

Arylsulphatase activity of corn (Zea mays L.) seedling roots

The crude lysosomal fraction of corn seedling root tips contains an arylsulphatase (E.C. 3.1.6.1) which hydrolysed p-nitrophenyl sulphate at pH 8.0 but had no activity towards p-nitrocatechol sulphate. The Km value for p-nitrophenyl sulphate was 1.24 mM. The hydrolysis of p-nitrophenyl sulphate was linear up to 2 h and the rate was proportional to the amount of enzyme added. The enzyme was strongly inhibited by cyanide, fluoride and phosphate ions and did not resemble the arylsulphatases of bacterial and animal origin.     

Biliary excretion of some anionic derivatives of diethylstilboestrol and phenolphthalein in the guinea pig.

The metabolic fates and modes of excretion of diethylstilboestrol mono[35S]sulphate and diethylstilboestrol di[35S]sulphate were studied in the guinea pig. Comparative studies were also made with [G-3H]diethylstilboestrol and phenolphthalein di[35S]sulphate. Diethylstiboesterol di[35S]sulphate was extensively eliminated in the bile unchanged. After administration of diethylstilboestrol mono[35S]sulphate, extensive biliary elimination of radioactivity was also recorded. Radioactive components were identified as diethylstilboestrol disulphate, diethylstilboestrol monosulphate monoglucuronide and unchanged diethylstilboestrol monosulphate. When [G-3H]diethylstilboestrol was administered, 3H-labelled diethylstilboestrol monoglucuronide, diethylstilboestrol monosulphate monoglucuronide and diethylstilboestrol disulphate appeared in the bile. Phenolphthalein di[35S]sulphate was excreted unchanged in bile. These findings are discussed in relation to studies carried out in the rat [Barford, Olavesen, Curtis & Powell (1977) Biochem. J. 164, 423--430] and species differences are related to differences in enzyme activities in rat and guinea-pig liver.     

Histochemical localization of the soluble arylsulphatase activities in rat brain

Summary The modified method of Goldfischer has been used for the localization of soluble arylsulphatase activities in the rat brain. The highest activity of these enzymes was found in some parts of the drive system and in nervous tracts. The bulk of activity in neurons and glial cells is localized in the lysosomes. Some arylsulphatase activity has been found to be bound to myelin sheaths. We have not been able to ascribe this activity to any defined subcellular structures, by light microscopy.The method of Goldfischer does not permit differentiation of the two soluble arylsulphatases (enzymes: A and B). We suggest however, that these enzymes may have different functions in the brain. Arylsulphatase A (cerebrosidesulphatase) may be primarily connected with the nervous tracts, a hypothesis supported by the character of disorders caused by lack of this enzyme in metachromatic leucodystrophy. Arylsulphatase B, hydrolysing sulphuric esters of catecholamines, may be involved in the function of the drive system.Arylsulphate sulphohydrolase, EC 3. 1.6. 1.     

Higher-plant cyclic nucleotide phosphodiesterases. Resolution, partial purification and properties of three phosphodiesterases from potato tuber.

1. Three phosphodiesterases that are capable of hydrolysing 3':5'-cyclic nucleotides were purified from potato tubers. 2. The phosphodiesterases were fractionated by (NH4)2SO4 precipitation and CM-cellulose chromatography. The phosphodiesterases were resolved from each other and further purified by gel filtration in high- and low-ionic-strength conditions. 3. All three enzymes lacked significant nucleotidase activity. 4. Enzymes I and II had mol. wts. 240,000 and 80,000 respectively, determined by gel filtration, whereas enzyme III showed anomalous behaviour on gel filtration, behaving as a high- or low-molecular-weight protein in high- or low-ionic-strength buffers respectively. 5. All enzymes hydrolysed 2':3'-cyclic nucleotides as well as 3':5'-cyclic nucleotides. The enzymes also had nucleotide pyrophosphatase activity, hydrolysing NAD+ and UDP-glucose to various extents. Enzymes I and II hydrolyse cyclic nucleotides at a greater rate than NAD+, whereas enzyme III hydrolyses NAD+ at a much greater rate than cyclic nucleotides. All three enzymes hydrolysed the artificial substrate bis-(p-nitro-phenyl) phosphate. 6. The enzymes do not require the addition of bivalent cations for activity. 7. Both enzymes I and II have optimum activity at pH6 with 3':5'-cyclic AMP and bis-(p-nitrophenyl) phosphate as substrates. The products of 3':5'-cyclic AMP hydrolysis were 3'-AMP and 5'-AMP, the ratio of the two products being different for each enzyme and varying with pH. 8. Theophylline inhibits enzymes I and II slightly, but other methyl xanthines have little effect. Enzymes I and II were competitively inhibited by many nucleotides containing phosphomonoester and phosphodiester bonds, as well as by Pi. 9. The possible significance of these phosphodiesterases in cyclic nucleotide metabolism in higher plants is discussed.     

Properties of two molecular forms of beta-glucuronidase from the mollusc Littorina littorea L.

The occurrence of the two molecular forms, I and II, in the beta-glucuronidase of the liver (hepatopancreas) from the marine mollusc Littorina littorea L. has been demonstrated for the first time. The two forms have been purified 355-fold and 1262-fold, respectively. Form I and II of beta-glucuronidase behave differently on DEAE-cellulose chromatography, polyacrylamide gel disc electrophoresis, isoelectric focusing (pH 5.5 and 4.2, respectively), optimum pH (4.4 and 3.4--4.1, respectively), thermal stability, Km (1.2 mM and 0.5 mM with p-nitrophenyl beta-D-glucuronide, 0.3 mM and 0.15 mM with phenolphthalein beta-D-glucuronide as substrates for form I and II, respectively) and V. Their molecular weight, estimated by gel filtration through Sephadex G-200, was about 250000 for both forms. Several subunits were separated by polyacrylamide gel electrophoresis in presence of sodium dodecyl sulphate. This beta-glucuronidase is a glycoprotein, but sialic acid(s) were not detected. The enzyme was very active on synthetic substrates and also on hexasaccharides and tetrasaccharides containing glucuronic acid residues with beta 1 leads to 3 linkages; it had practially no activity on certain glycosaminoglycans. Hg2+ and glucaro-1,4-lactone were very effective inhibitors of this enzyme; the latter by a competitive mechanism.     

Studies on the Arylsulphatase and phenol sulphotransferase activities of Aspergillus oryzae.

1. Crude extracts of Aspergillus oryzae grown under conditions of sulphur limitation possess high arylsulphatase activity. 2. This activity can be greatly enhanced by the inclusion of tyramine or a number of other phenols in the assay medium. 3. The arylsulphatase activity of these extracts can be resolved into three distinct fractions by chromatography on DEAE-cellulose. 4. The effect of tyramine is restricted to one of these fractions only. 5. Evidence is presented which indicates that this effect is the consequence of a phenol sulphotransferase activity, which shows no requirement for 3'-phosphoadenosine 5'-phosphate as a cofactor, and which will not transfer sulphate from 3'-phosphoadenosine 5'-sulphatophosphate to potential phenolic acceptors. 6. The three enzymes differ also in their molecular weights and substrate specificities.     

Biochemical investigation to the reliability of the histochemical demonstration of microsomal arylsulphatase activity in cryostat sections

Summary Polyacrylamide gel-electrophoresis was performed with an extract from cultivated skin fibroblasts. Arylsulphatase activity is measured and visualised using the biochemical substrate dehydroepiandrosterone sulphate and the histochemical substrate 6-bromo-2-naphthyl sulphate respectively. The histochemical substrate was hydrolysed at Rf=0.49 and 0.58 while the biochemical substrate was hydrolysed only at 0.49. We conclude that two different microsomal arylsulphatases exist: a sulphatase able to hydrolyse steroid sulphatases (Rf=0.49) and one unable to hydrolyse steroid sulphatases (Rf=0.58). In consequence it is recommended to carry out an electrophoresis experiment after the histochemical investigation, in order to discriminate between these two types of sulphatase.     

Purification and properties of the cellulases from the thermophilic fungus Thermoascus aurantiacus.

Three cellulases and a beta-glucosidase were purified from the culture filtrate of the thermophilic fungus Thermoascus aurantiacus. The isolated enzymes were all homogeneous on polyacrylamide-disc-gel electrophoresis. Data from chromatography on Bio-Gel P-60 and sodium dodecyl sulphate/polyacrylamide-gel electrophoresis indicated mol.wts. of 87000 (beta-glucosidase), 78000 (cellulase I), 49000 (cellulase II) and 34000 (cellulase III); the carbohydrate contents of the enzymes were 33.0, 5.5, 2.6 and 1.8% (w/w) respectively. Although the three purified cellulases were active towards filter paper, only cellulases I and III were active towards CM(carboxymethyl)-cellulose. Cellulase I was also active towards yeast glucan. The Km and catalytic-centre-activity values for the enzymes were as follows; 0.52 mumol/ml and 6.5 X 10(4) for beta-glucosidase on p-nitrophenyl beta-D-glucoside, 3.9 mg/ml and 6.3 for cellulase I on CM-cellulose, 1.2 mg/ml and 1.1 for cellulase I on yeast glucan, 35.5 mg/ml and 0.34 for cellulase II on filter paper, and 1.9 mg/ml and 33 for cellulase III on CM-cellulose.