Synthesis of pyrene derivatives of cerebroside sulfate and their use for determining arylsulfatase A activity

Two fluorescent derivatives of cerebroside sulfate ('sulfatide') have been synthesized and used as substrates for determining arylsulfatase A activity. These were 12-(1-pyrene)dodecanoyl cerebroside sulfate (P12-sulfatide) and 12(1-pyrenesulfonylamido)dodecanoyl cerebroside sulfate (PSA12-sulfatide). When incubated at pH 5.0 in the presence of 5 mM MnCl2 and 5.5 mM of taurodeoxycholate, either substrate was hydrolyzed by arylsulfatase A of human leukocytes. The rate of hydrolysis was proportional to the incubation time and concentration of enzyme; Michaelis-Menten type kinetics were observed with increasing concentrations of substrate. For determining the rate of hydrolysis, each of the two products (i.e., P12- and PSA12-cerebrosides) were separated from the bulk of respective unreacted sulfatide on small columns of DEAE-Sephadex A-25 and their fluorescence intensities read at 343-378 and 350-380 nm for the excitation and emission wavelengths for P12- and PSA12-cerebrosides, respectively. When extracts of skin fibroblasts derived from normal individuals and patients with Maroteaux-Lamy (lacking arylsulfatase B) or metachromatic leukodystrophy (lacking arylsulfatase A) were used as source of enzyme, P12-sulfatide was hydrolyzed by the former two but not by the latter cell extract. Several derivatives of cerebroside sulfate were also synthesized and found to inhibit the hydrolysis of pyrenesulfatide by leukocyte arylsulfatase A. The results demonstrate that these two pyrene containing sulfatides can be effectively used as specific substrates for the determination of arylsulfatase A activity in extract of cells and most probably also of tissues.     

Identification of tyrosine O-sulfate in proteins by reverse-phase high-performance liquid chromatography: use of base hydrolysis combined with precolumn derivatization using phenyl isothiocyanate

A procedure has been developed for the analysis of tyrosine O-sulfate in proteins. Samples are subjected to base hydrolysis with Ba(OH)2, neutralized with sulfuric acid, and the majority of other amino acids removed by chromatography on Dowex AG 50 X 8. The average recovery of tyrosine O-sulfate from these procedures was 43%. Tyrosine O-sulfate was identified by reverse-phase HPLC as the phenylthiocarbamyl derivative following precolumn derivatization with phenyl isothiocyanate. The method has been applied to bovine fibrinogen giving a tyrosine O-sulfate content ranging from 0.59 to 1.23 mol/mol. These procedures were also shown to be suitable for the analysis of the incorporation of [35S]sulfate into tyrosine O-sulfate residues in proteins by intact cells.     

Formation of tyrosine O-sulfate by mitochondria and chloroplasts of Euglena

Mitochondria that have been purified from cells of light-grown wild-type Euglena gracilis Klebs var. bacillaris Cori or dark-grown mutant W10BSmL and incubated with 35SO4(2-) and ATP accumulate a labeled compound in the surrounding medium. This compound is also labeled when mitochondria are incubated with [14C]tyrosine and nonradioactive sulfate under the same conditions. This compound shows exact coelectrophoresis with synthetic tyrosine O-sulfate at pH 2.0, 5.8, and 8.0, and yields sulfate and tyrosine on acid hydrolysis. Treatment with aryl sulfatase from Aerobacter aerogenes yields sulfate and tyrosine but no tyrosine methyl ester; no hydrolysis of tyrosine methyl ester to tyrosine is observed under identical conditions, ruling out methyl esterase activity in the aryl sulfatase preparation. Thus the compound is identified as tyrosine O-sulfate. No tyrosine O-sulfate is found outside purified developing chloroplasts of Euglena incubated with 35SO4(2-) and ATP, but both chloroplasts and mitochondria accumulate labeled tyrosine-O-sulfate externally when incubated with adenosine 3'-phosphate 5'-phospho[35S]-sulfate (PAP35S). Since tyrosine does not need to be added, it must be provided from endogenous sources. Labeled tyrosine O-sulfate is found in the free pools of light-grown Euglena cells grown on 35SO4(2-) or in dark-grown cells incubated with 35SO4(2-) in light, but none is found in the medium after cell growth. No labeled tyrosine O-sulfate is found in Euglena proteins (including those in extracellular mucus) after growth or incubation of cells with 35SO4(2-) or after incubation of organelles with 35SO4(2-) and ATP or PAP35S, ruling out sulfation of the tyrosine in protein or incorporation of free-pool tyrosine O-sulfate into protein. The system forming tyrosine O-sulfate is membrane-bound and may be involved in transporting tyrosine out of the organelles.     

Comparative studies of rodent anionic arylsulfatases

Approximately 25 and 40%, respectively, of murine (Mus musculus) and rat (Rattus norvegicus) hepatic arylsulfatase (EC 3.1.6.1) activity eluted from DEAE-ion exchange resins under high salt conditions. This high salt fraction contained arylsulfatase A and an enzyme which was immunologically similar to arylsulfatase B. The latter enzyme was thermostable, resistant to inhibition by silver, completely inhibited by phosphate, displayed linear kinetics, and had a higher pH optimum than arylsulfatase A. Anionic arylsulfatase B also hydrolyzed chondroitin-4-SO4 heptasaccharide. Sephacryl S-300 gel filtration resolved anionic arylsulfatase B into 55 and 115 kd fractions. Rodent arylsulfatase A activity was grossly underestimated when 4-methyl-umbelliferyl sulfate was employed as substrate.     

Kinetic fluorescence measurement of fluorescein di-beta-D-galactoside hydrolysis by beta-galactosidase: intermediate channeling in stepwise catalysis by a free single enzyme

Kinetic fluorescence measurements were employed to quantitative to stepwise hydrolysis of fluorescein di-beta-D-galactoside (FDG) by beta-galactosidase and the intermediate fluorescein mono-beta-D-galactoside (FMG) channeling. The kinetic parameters, Michaelis-Menten constant Km and enzymatic catalysis rate k2, for FDG hydrolysis to FMG by beta-galactosidase were obtained as 18.0 microM and 1.9 mumol.(min-mg)-1, respectively. The FMG intermediate is hydrolyzed via two modes: (1) FMG that is in free solution binding to the enzyme substrate binding site in competition with FDG and then being hydrolyzed (binding mode); (2) FMG being directly hydrolyzed into the final products of fluorescein and galactose before the FMG can diffuse away from the enzyme active site (channeling mode). The extent of the FMG channeling mode was found to depend on the FDG hydrolysis rate but to be independent of the free enzyme concentration. A channeling factor, defined as the ratio of the real FMG hydrolysis rate with both binding and channeling modes over that which would be observed with an exclusive binding mode, was used to quantitate the effect of the intermediate channeling. The FMG channeling factor was determined to be close to 1 at low FDG concentration (about 5.1 microM), where the slow FDG hydrolysis rate gives an ineffective channeling and where the FMG is then hydrolyzed mainly via the binding mode. However, the channeling factor dramatically increases at higher FDG concentrations (greater than Km), strongly indicating that the effective FMG channeling mode, resulting from the considerable FDG hydrolysis rate at high FDG concentrations, becomes a primary pathway to channel a steady system hydrolysis with a high rate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Characterization of arylsulfatase formed by derepressed synthesis in Citrobacter braakii

Arylsulfatase activity was detected in a bacterial strain, Citrobacter braakii 69-b, isolated from soil by enrichment cultivation using porcine gastric mucin. The production of arylsulfatase was derepressed markedly in a synthetic medium by the addition of tyramine. The purified enzyme hydrolyzed 4-nitrophenyl sulfate, 4-nitrocatechol sulfate, and 3-indoxyl sulfate, and was classified as type I arylsulfatase.     

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.     

Enzymatic sulfation of gastrin in rat gastric mucosa

An enzyme which catalyzes the transfer of sulfate from 3'-phosphoadenosine 5'-phosphosulfate (PAPS) to gastrin (G17) was identified in rat gastric mucosal cells. The enzyme activity was detected in the 105,000xg supernatant fraction. Formation of gastrin sulfate was shown by using 125I-gastrin and non-radioactive PAPS. The product was sensitive to acid hydrolysis, arylsulfatase treatment and removed by gastrin antibody, but not changed by treatments with chondro-4-sulfatase and chondro-6-sulfatase. The product had a molecular weight of 2050 daltons, close to the molecular weight of G17 sulfate, and, therefore, indicating the sulfated product is not APS derived from the degradation of PAPS. The enzyme activity showed a Km value of 5 microM for PAPS and a pH optimum of 6.0. The activity was not detected in the liver preparation.     

Pseudo arylsulfatase a deficiency: Evidence for a structurally altered enzyme

Analysis of arylsulfatase A from pseudo arylsulfatase A deficiency fibroblasts by sodium dodecyl sulfate polyacrylamide gel electrophoresis and immunoradiochemical nitrocellulose blot radiography revealed two subunit bands which migrated faster than subunit bands of enzyme from normal fibroblasts. Immunoreactive material was present only at levels comparable to enzyme activity. These findings imply that arylsulfatase A in pseudodeficiency is structurally altered, but it is catalytically equivalent to normal arylsulfatase A. This altered enzyme must be the product of the pseudodeficiency gene since no immunoreactive product of the metachromatic leukodystrophy gene could be detected in metachromatic leukodystrophy cells by the procedure employed. It is not clear from the present data if the attenuated arylsulfatase A activity in pseudodeficiency results from a decreased rate of synthesis or an increased lability of the mutant enzyme.     

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.     

Chemical characterization and substrate specificity of rabbit liver aryl sulfatase A

Rabbit liver aryl sulfatase A (aryl-sulfate sulfohydrolase, EC 3.1.6.1) is a glycoprotein containing 4.6% carbohydrate in the form of 25 residues of mannose, seven residues of N-acetylglucosamine, and three residues of sialic acid per enzyme monomer of molecular weight 140 000. Each monomer consists of two equivalent polypeptide chains. The protein has a relatively high content of proline, glycine and leucine, and the amino acid composition of rabbit liver aryl sulfatase A is similar to that of other known liver sulfatases. Rabbit liver aryl sulfatase A catalyzes the hydrolysis of a wide variety of sulfate esters, although it appears possible that cerebroside sulfate is a physiological substrate for the enzyme because the Km is very low (0.06 mM). The turnover rate for hydrolysis of nitrocatechol sulfate or related synthetic substrates is much higher than the rate with most naturally occurring sulfate esters such as cereroside sulfate, steroid sulfates, L-tyrosine sulfate or glucose 6-sulfate. However, the turnover rate with ascorbate 2-sulfate is comparable to the rates measured using most synthetic substrates. These results are discussed in relationship to several previously described sulfatase enzymes which were claimed to have unique specificities.     

Purification and characterization of an oat fructan exohydrolase that preferentially hydrolyzes beta-2,6-fructans.

Oat (Avena sativa cv Fulghum) fructan hydrolase was purified by ammonium sulfate precipitation and anion-exchange, hydrophobic interaction, and size-exclusion chromatography. The enzyme was purified to homogeneity as determined by the presence of a single band (43 kD) on a silver-stained sodium dodecyl sulfate-polyacrylamide gel. A mixture of beta-2,6-linked fructan (neokestin) isolated from oat was used as the substrate to purify fructan hydrolase. Neokestin and small degree of polymerization fructan isomers were used to characterize the substrate specificity of the purified enzyme. The purified fructan hydrolase catalyzed hydrolysis of the terminal beta-2,6 linkage of 6G,6-kestotetraose 3.5 times more rapidly than it hydrolyzed the terminal beta-2,6 linkage of 6G-kestotriose and approximately 10 times faster than it hydrolyzed the terminal beta-2,1 linkage of chicory inulin. Sucrose and 1-kestose were not substrates. The Km for neokestin (beta-2,6-linked fructans with a degree of polymerization of 7-14) hydrolysis was 2.8% (w/v), and the Vmax was 0.041 mumol min-1 mL-1. The Km for hydrolysis of 6G,6-kestotetraose was 5.6% (w/v), and the Vmax was 0.138 mumol min-1 mL-1. Catalysis was exolytic and by multiple chain attack. Hydrolysis of neokestin was maximal at pH 4.5 to 5.0.     

A thiocyanate hydrolase of Thiobacillus thioparus. A novel enzyme catalyzing the formation of carbonyl sulfide from thiocyanate.

A thiocyanate hydrolase that catalyzes the first step in thiocyanate degradation was purified to homogeneity from Thiobacillus thioparus, an obligate chemolithotrophic eubacterium metabolizing thiocyanate to sulfate as an energy source. The thiocyanate hydrolase was purified 52-fold by steps involving ammonium sulfate precipitation, DEAE-Sephacel column chromatography, and hydroxylapatite column chromatography. The enzyme hydrolyzed 1 mol of thiocyanate to form 1 mol of carbonyl sulfide and 1 mol of ammonia as follows: SCN- + 2H2O----COS + NH3 + OH-. This is the first report describing the hydrolysis of thiocyanate to carbonyl sulfide by an enzyme. The enzyme had a molecular mass of 126 kDa and was composed of three different subunits: alpha (19 kDa), beta (23 kDa), and gamma (32 kDa). The enzyme exhibited optimal activities at pH 7.5-8.0 and at temperatures ranging from 30 to 40 degrees C. The Km value for thiocyanate was approximately 11 mM. Immunoblot analysis with polyclonal antibodies against the purified enzyme suggested that it was induced in T. thioparus cells when the cells were grown with thiocyanate.     

Human placental sterylsulfatase. Interaction of the isolated enzyme with substrates, products, transition-state analogues, amino-acid modifiers and anion transport inhibitors.

The enzymatic properties of a homogeneous sterylsulfatase preparation isolated from human term placenta were studied. The enzyme exhibited both arylsulfatase and sterylsulfatase activity: it catalysed the hydrolysis of sulfuric acid esters of (in the order of decreasing specific activity) non-steroidal phenols, of a phenolic steroid, and of neutral 3 beta-, 21- and (though at a very low rate) 17 beta-hydroxysteroids. However, among all the substrates tested only the 3-sulfates of phenolic and neutral steroids exhibited high affinity towards the sulfatase. Vitamin D3 sulfate was not hydrolysed by the sterylsulfatase but strongly inhibited its activity. The products of the catalytic reaction, free steroids or phenols as well as the sulfate anion or analogues thereof, likewise interfered with the enzyme's activity. Ki values of unconjugated steroids were ten- to hundredfold higher than Km values of the respective sulfoconjugates. Inorganic sulfate only slightly inhibited the sulfatase activity; its inhibitory potency, however, increased in a time-dependent manner when it was preincubated with the enzyme prior to assay. In contrast to sulfate, the hypothetical transition-state analogues sulfite and vanadate acted as strong inhibitors of the sulfatase activity. According to the results of an analysis of the effect of pH on sterylsulfatase kinetics, enzyme constituents with pK values of approximately 5.8 and 8.0 are involved in a general acid-base catalysed reaction. Treatment of the sulfatase with amino-acid side chain modifying reagents directed against arginine, cysteine, cystine, serine or tyrosine residues did not result in significant alteration of its activity. Diethyl-pyrocarbonate known to react primarily with histidyl groups, however, rapidly inactivated the enzyme; this inactivation reaction was markedly retarded in the presence of substrate. Histidine thus appears to be essential for the catalytic activity of the sulfatase. Taken together, the present results reveal a considerable similarity between the catalytic mechanism of human placental sterylsulfatase and the ones already proposed for the lysosomal arylsulfatases A and B. Taurocholate, salicylate, ouabain, and 4,4'-substituted stilbene-2,2'-disulfonates are well known inhibitors of carrier-mediated transport of anions across cellular membranes. With the exception of ouabain, these compounds likewise turned out to inhibit the enzymatic hydrolysis of steryl sulfates; the pattern of dose dependences of their interference with the sulfatase activity resembles the one reported for inhibition of anion transport. Since the sterylsulfatase in vivo strongly is associated with cellular membranes including the plasma membrane of the syncytiotrophoblast, this finding supports the speculation that similar molecular structures may be involved in both placental transport and hydrolysis of anionic steryl sulfates.     

Kinetics of hydrolysis of phenylthiazolones of arginine, homoarginine, norarginine, and canaavanine by trypsin.

Phenylthiazolones (PTAs) of arginine and its homologs and analogs, homoarginine, norarginine (alpha-amino-gamma-guanidinobutyric acid), canavanine, and gamma-hydroxyarginine, were prepared. A steady-state kinetic analysis of the trypsin [EC 3.4.21.4]-catalyzed hydrolysis reactions was carried out and the kinetic parameters for these internal thioesters were compared with those for normal linear ester substrates. PTA-gamma-hydroxyarginine was so labile that hydrolysis by the enzyme could not be followed. PTA-arginine has a specificity constant (Kcat/Km) comparable to that for the Nalpha-unblocked arginine ester substrate, though the value is about 0.1% of that for a specific ester substrate, Nalpha-tosylarginine methyl ester. PTA derivatives of canavanine and homoarginine were hydrolyzed with Kcat/Km walues of the same order of magnitude as that for PTA-arginine. However, PTA-noraginine was much less susceptible to tryptic hydrolysis that PTA-homoarginine, while the linear esters of norarginine are known to be more susceptible than those of homoarginine.     

Purification and characterization of arylsulfatase from<Emphasis Type="Italic"> Sphingomonas</Emphasis> sp. AS6330

Arylsulfatase was purified from Sphingomonas sp. AS6330 through ionic exchange, hydrophobic- and gel-chromatographies. The purity increased 12,800-fold with approximately 19.1% yield against cell homogenate. The enzyme was a monomeric protein with apparent molecular weight of 62 kDa as determined by sodium dodecylsulfate-polyacrylamide gel electrophoresis, and 41 kDa as determined by gel filtration. The enzyme had optimum reaction conditions for hydrolysis of sulfate ester bonds in agar and p-nitrophenyl sulfate (NPS) at pH 7.0 and 45°C, with a specific activity of 3.93 and 97.2 U, respectively. The enzyme showed higher activity towards agar than other sulfated marine polysaccharides such as porphyran, fucoidan and carrageenan. The K _m and V _max of the enzyme for hydrolysis of NPS were 54.9 M and 113 mM/min, respectively. With reaction of 200 g agar with 100 U arylsulfatase for 8 h at 45°C, gel strength increased 2.44-fold, and 97.7% of the sulfate in the agar was hydrolyzed.     

Stimulation of bacterial arylsulfatase activity by arylamines: evidence for substrate activation.

A number of arylamines (including tyramine and tryptamine) increased the in vitro activity of arylsulfatase from Pseudomonas sp. strain C12B. Amino acid analogs of these amines (e.g., tyrosine and tryptophan) failed to exert an effect. Stimulation of activity by tyramine could not be accounted for in terms of sulfotransferase activity for this phenol, and no shift in the pH optimum for the enzyme occurred in the presence of tryptamine. Increased Vmax due to these amines was independent of enzyme concentration but varied significantly with substrate concentration. Evidence is presented which suggests that arylamines enhance arylsulfatase activity by forming a salt linkage with the substrate and rendering it more susceptible to enzymatic and acid-catalyzed hydrolyses. The recrystallized tryptamine salt of the substrate exhibited a reduced affinity for the enzyme but was hydrolyzed more rapidly than the potassium salt, which is normally employed as the assay substrate.     

Molecular cloning and biochemical characterization of L-N-carbamoylase from Sinorhizobium meliloti CECT4114

An N-carbamoyl-L-amino acid amidohydrolase (L-N-carbamoylase) from Sinorhizobium meliloti CECT 4114 was cloned and expressed in Escherichia coli. The recombinant enzyme catalyzed the hydrolysis of N-carbamoyl alpha-amino acid to the corresponding free amino acid, and its purification has shown it to be strictly L-specific. The enzyme showed broad substrate specificity, and it is the first L-N-carbamoylase that hydrolyses N-carbamoyl-L-tryptophan as well as N-carbamoyl L-amino acids with aliphatic substituents. The apparent Km values for N-carbamoyl-L-methionine and tryptophan were very similar (0.65 +/- 0.09 and 0.69 +/- 0.08 mM, respectively), although the rate constant was clearly higher for the L-methionine precursor (14.46 +/- 0.30 s(-1)) than the L-tryptophan one (0.15 +/- 0.01 s(-1)). The enzyme also hydrolyzed N-formyl-L-methionine (kcat/Km = 7.10 +/- 2.52 s(-1) x mM(-1)) and N-acetyl-L-methionine (kcat/Km = 12.16 +/- 1.93 s(-1) x mM(-1)), but the rate of hydrolysis was lower than for N-carbamoyl-L-methionine (kcat/Km = 21.09 +/- 2.85). This is the first L-N-carbamoylase involved in the 'hydantoinase process' that has hydrolyzed N-carbamoyl-L-cysteine, though less efficiently than N-carbamoyl-L-methionine. The enzyme did not hydrolyze ureidosuccinic acid or 3-ureidopropionic acid. The native form of the enzyme was a homodimer with a molecular mass of 90 kDa. The optimum conditions for the enzyme were 60 degrees C and pH 8.0. Enzyme activity required the presence of divalent metal ions such as Ni2+, Mn2+, Co2+ and Fe2+, and five amino acids putatively involved in the metal binding were found in the amino acid sequence.     

beta-lactamase from Streptomyces cacaoi. Purification and properties

A beta-lactamase was purified to an apparently homogeneous state from Streptomyces cacaoi. The molecular weight calculated from the mobility in sodium dodecyl sulfate polyacrylamide gel electrophoresis was 34,000. pI was 4.7 and the optimal pH was 6.5. The optimum temperature was found to be between 40 degrees C and 45 degrees C, but the enzyme lost activity above 50 degrees C. N-Bromosuccinimide was the strongest inhibitor among the reagents tested, followed by iodine. p-Chloromercuribenzoate showed a weak inhibitory effect. Diisopropylfluorophosphate and sodium chloride did not show any inhibitory effect on the enzyme. The beta-lactamase catalyzed the hydrolysis of methicillin and cloxacillin at two-thirds to one-third the rate of benzylpenicillin. On the other hand, the enzyme hydrolyzed cephalosporins and 7-methoxycephalosporin only slowly. With benzylpenicillin as a substrate, the Km increased sharply with decreasing pH and the pK alpha estimated from the Km versus pH curve was 6.5 to 7.0. In contrast, with cloxacillin as a substrate, the Km showed a minimum at pH 7.5. The Vmax changed with pH in a bell-shaped curve in the case of benzylpenicillin, but the Vmax for cloxacillin changed only within a small range. In addition, the ratio of the hydrolysis rate of benzylpenicillin and cloxacillin at 30 degrees C and 20 degrees C (V30 degrees/V20 degrees) was found to be 1.23 and 1.55, respectively. These results indicate that the S. cacaoi beta-lactamase behaves differently toward benzylpenicillin and cloxacillin, although both are penicillins. S. cacaoi seems to release beta-lactamase into the culture medium soon after its biosynthesis without retaining it in the membrane and the soluble fraction. The possible relationships between beta-lactamases from Streptomyces and those from pathogenic bacteria are discussed.     

Ascorbic acid-2-sulfate sulfhohydrolase activity of human arylsulfatase A.

Pure human arylsulfatase A (EC 3.1.6.1) was found to hydrolyze ascorbic acid 2-sulfate to ascorbic acid and inorganic sulfate at rates from 200 to 2000 mumol/mg per h depending on the method of assay. This rate was lower than that observed with the synthetic substrate 4-nitrocatechol sulfate, but higher than that seen with the physiological substrate cerebroside sulfate. Extracts of cultured fibroblasts from normal subjects were also shown to hydrolyze ascorbic acid 2-sulfate; extracts of fibroblasts from patients with metachromatic leukodystrophy, known to be deficient in arylsulfatase A, did not. Similarly, hydrolysis of ascorbic acid 2-sulfate was not observed when a partially purified preparation of human arylsulfatase B was tested under a variety of conditions. Thus, in the human, arylsulfatase A appears to be the major, if not the only, ascorbic acid-2-sulfate sulfohydrolase.