Hydrocortisone regulates arylsulfatase A (cerebroside-3-sulfate-3-sulfohydrolase) by decreasing the quantity of the enzyme in cultures of cells dissociated from embryonic mouse cerebra

Previous work from our laboratory (Biochem. J. 219:689–697 (1984) had shown that hydrocortisone stimulated the net accumulation of the myelin-specific sulfolipid in cultures of cells dissociated from embryonic mouse cerebra. This accumulation caused by hydrocortisone was shown to be due to a decrease of sulfolipid degradation by arylsulfatase A (ASA) and not due to a stimulation of its synthesis by a sulfotransferase. Both ASA activity and the turnover of sulfolipid were decreased by hydrocortisone to 60–62% of untreated cells. In current work the same decrease in enzyme activity was obtained and enzyme linked immunosorbent assays demonstrate that hydrocortisone decreased the number of ASA protein molecules to 61% of untreated cells [(-)hydrocorcortisone 0.31±0.06 ng ASA/g protein; (+)hydrocortisone: 0.18±0.04 ng ASA/g protein]. This decrease in the number of ASA molecules correlates well with the decrease in both the enzyme activity and the sulfolipid turnover, which suggests that the major mode of inhibition of ASA activity by hydrocortisone involves a decrease in the concentration of ASA in the cells rather than some other mechanism of inhibition.The material in this paper has been included in a dissertation submitted by A.J.M. in partial fulfillment of the requirements for the degree of Doctor of Philosophy. Temple University.     

Purification and characterization of sulfatases from Haliotis rufescens: evidence for changes in synthesis and heterogeneity during development

Summary The digestive glands of many marine molluscs are rich sources of arylsufatase enzymes which may function in the catabolism of sulfated polysaccharides in the diets of herbivorous species. Arylsulfatases, partially purified from the hepatopancreas of the red abalone, Haliotis rufescens, were investigated with respect to heterogeneity, catalytic requirements, and timing of induction during development. Four hepatopancreatic enzymes were purified from adult animals using a combination of hydrophobic interaction and anion-exchange chromatography. Zymograms of the four partially-purified enzymes produced by electrophoresis under nondenaturing conditions revealed a fifth, relatively more basic isozyme. All four partially-purified enzymes appear to be monomeric, with molecular weights of approximately 43 000 Da each, as measured by gel filtration. The affinities for p-nitrocatechol sulfate, pH optima, and strengths of inhibition by anions displayed by these enzymes are similar to the values reported for other molluscan arylsulfatases. Three of the four enzymes have K _m values between 0.8 and 2.0 mM for p-nitrocatechol sulfate; the remaining enzyme (A₂) has a K _m of 6.7 mM. All four enzymes have pH and temperature optima of 5.5 and 45°C, respectively. Three of the four enzymes have-t_1/2(50°C) values of 3.5 min; the enzyme A₄ has a t_1/2 has a t_1/2(50°C) of 8.5 min. A monoclonal antibody directed against form A_1b does not cross react with any of the other hepatopancreatic arylsulfatases when assayed by Western blot, confirming the structural heterogeneity of the adult enzymes.Total arylsulfatase activity increases in a biphasic manner during early abalone development, with the first increase occurring early in larval maturation. The secoad phase of enzyme expression is dependent upon the induction of settlement and metamorphosis of the competent veliger larvae, strongly suggesting that the expression of arylsulfatase synthesis (and the maturation of the digestive gland, the hepatopancreas) is controlled by genetic events which occur as a result of metamorphosis. Competent veliger larvae express only two arylsulfatase forms, which share many physicochemical and kinetic characteristics with the adult hepatopancreatic enzymes. However, neither of the larval arylsulfatases is recognized by the monoclonal antibody to form A_1b from adult hepatopancreas. Endogenous enzyme inhibitor levels in larvae remain constant throughout the period of arylsulfatase induction, and therefore do not contribute to the control of arylsulfatase activity levels during development.These results are the first documentation of the developmental induction of a specific protein(s) in abalone as a result of metamorphosis. The significance of the timing of arylsulfatase expression is discussed in relation to potential physiological substrates and the dietary switching which occurs at metamorphosis. Possible genetic events which are consistent with the observed patterns of expression of these enzymes also are considered.Abbreviations BSA bovine serum albumin - C centigrade - Da daltons - DEAE diethylaminoethyl - ELISA enzyme-linked immunosorbent assay - FPLC fast protein and polynucleotide liquid chromatography - GABA -aminobutyric acid - HAT hypoxanthine, aminopterin, thymidine - Hepes N-(2-Hydroxythyl)piperazine-N'-(2-ethanesulfonic acid) - HPLC high pressure liquid chromatography - KBS Kantor's balanced salt solution - K _m Michaelis constant - PBS phosphate buffered saline - R _m relative mobility - RPMI Roswell Park Memorial Institute - SDS sodium dodecyl sulfate - T time - TBS TRIS buffered saline - V _max maximal velocity     

Three Novel Mutant Arylsulfatase A Alleles Causing Metachromatic Leukodystrophy

Metachromatic leukodystrophy is a lysosomal storage disorder caused by the deficiency of arylsulfatase A. This leads to the accumulation of 3-O-sulfogalactosylceramide, which results in severe demyelination. Here we describe a novel non-sense mutation W124ter and two disease-causing missense mutations E382Q and C500F in arylsulfatase A gene. Another so far unknown allele harbors three sequence alterations: two polymorphisms (N350S, R496H) and a missense mutation (R288H). The R288H substitution and the N350S polymorphism have previously been found on one allele together with a polymorphism in a polyadenylation signal characteristic for the arylsulfatase A pseudodeficiency allele. The R496H has been shown to occur on another allele. The presence of the R288H, N350S, and R496H substitution on one allele in the absence of the polyadenylation site polymorphism shows that this allele has probably arisen by recombination between the nucleotides of codon 350 and 496.     

Characteristics of arylsulfatase in Russian sturgeon (Acipenser gueldenstaedti) semen

Spermatozoa of sturgeons (Acipenseriformes), unlike teleosts, possess an acrosome. This paper provides data concerning biochemical characteristics of arylsulfatase (AS), an acrosomal enzyme, found in Russian sturgeon spermatozoa and seminal plasma. The enzymes were purified by a four-step procedure, using n-butanol extraction, ion-exchange chromatography repeated twice and gel filtration. High purity of our enzymes was confirmed by silver staining electrophoresis and an immunological experiment. Kinetic parameters indicated that the purified enzymes belong to arylsulfatase type A. Similarity of the seminal plasma arylsulfatase to the spermatozoan enzyme showed us that arylsulfatase from seminal plasma might originate from damaged spermatozoa. The possible physiological consequences of the presence of arylsulfatase in Russian sturgeon semen are discussed.     

Exocytosis of storage material in a lysosomal disorder

Lysosomal exocytosis is a ubiquitously occurring process, which has a physiological role in repair of wounds of the plasma membrane. Lysosomal storage disorders are a group of more than 40 different diseases, which are characterized by intralysosomal storage of various substances. Metachromatic leukodystrophy is a lysosomal disease caused by the deficiency of arylsulfatase A, which results in the storage of the sphingolipid 3-O-sulfogalactosylceramide (sulfatide) in, e.g., oligodendrocytes and distal tubule kidney cells. Here we show that sulfatide storing cultured primary kidney cells of arylsulfatase A deficient mice can undergo calcium induced lysosomal exocytosis and that this results in the delivery of storage material to the culture medium. In metachromatic leukodystrophy extracellular sulfatide has been found in urine and cerebrospinal fluid. Lysosomal exocytosis may explain the presence of sulfatide in these body fluids.     

Arylsulfatase K,a Novel Lysosomal Sulfatase

The human sulfatase family has 17 members, 13 of which have been characterized biochemically. These enzymes specifically hydrolyze sulfate esters in glycosaminoglycans, sulfolipids, or steroid sulfates, thereby playing key roles in cellular degradation, cell signaling, and hormone regulation. The loss of sulfatase activity has been linked to severe pathophysiological conditions such as lysosomal storage disorders, developmental abnormalities, or cancer. A novel member of this family, arylsulfatase K (ARSK), was identified bioinformatically through its conserved sulfatase signature sequence directing posttranslational generation of the catalytic formylglycine residue in sulfatases. However, overall sequence identity of ARSK with other human sulfatases is low (18–22%). Here we demonstrate that ARSK indeed shows desulfation activity toward arylsulfate pseudosubstrates. When expressed in human cells, ARSK was detected as a 68-kDa glycoprotein carrying at least four N-glycans of both the complex and high-mannose type. Purified ARSK turned over p-nitrocatechol and p-nitrophenyl sulfate. This activity was dependent on cysteine 80, which was verified to undergo conversion to formylglycine. Kinetic parameters were similar to those of several lysosomal sulfatases involved in degradation of sulfated glycosaminoglycans. An acidic pH optimum (∼4.6) and colocalization with LAMP1 verified lysosomal functioning of ARSK. Further, it carries mannose 6-phosphate, indicating lysosomal sorting via mannose 6-phosphate receptors. ARSK mRNA expression was found in all tissues tested, suggesting a ubiquitous physiological substrate and a so far non-classified lysosomal storage disorder in the case of ARSK deficiency, as shown before for all other lysosomal sulfatases.     

Improved high-performance liquid chromatographic method for N-acetylgalactosamine-4-sulfate sulfatase (arylsulfatase B) activity determination using uridine diphosho-N-acetylgalactosamine-4-sulfate

UDP-N-acetylgalactosamine-4-sulfate (UDP-GalNAc-4-S) was isolated from hen oviduct (isthmus) with a yield of 31 μmol per 100 g of wet tissue and used for arylsulfatase B (ASB) activity determination. Two HPLC methods of separation and quantitation of the reaction product were described: (1) an original gradient elution method which makes it possible to determine the reaction product when only partially purified ASB was used and additional uridine derivatives were formed during incubation: (2) an improved, fast isocratic elution method which may be used in the case of purified ASB preparations, devoid of other nucleotide hydrolysing enzymes. For both methods the detection limit was 0.1 nmol of product with standard error of determination ?3%. Using the gradient elution method we have found that UDP-GalNAc-4-S was hydrolysed by bovine arylsulfatase B1 most efficiently at pH 5.0 and concentration 0.5 mM with K_m=85 μM.     

Structure of slow-reacting substance of anaphylaxis (SRS-A)

To elucidate the chemical structure of slow-reacting substance of anaphylaxis from rat (SRS-A^rat), SRS-A^rat were purified by the method of Orange with modification using DEAE-Sephadex A-25 chromatography. Ultraviolet absorption spectrum of purified SRS-A^rat indicated the presence of conjugated triene. Arylsulfatase B degradation products and HCl degradation products were subjected to analysis by a gas chromatography and mass spectrometry and a thin layer chromatography. Products obtained by arylsulfatase B catalysis contained 5,6-dihydroxy-7,9,11,14-eicosatetraenoic acid. HCl degradation products showed the presence of glycine, glutamic acid and cysteic acid. Furthermore, the analysis of anhydrous hydrazine degradation products of SRS-A^rat and of HCl hydrolyzed products of dinitrophenylated SRS-A^rat revealed the presence of glycine at C-terminal and glutamic acid at N-terminal. The study of the substrate specificity of arylsulfatase B against various materials including SRS-A^rat suggested the presence of sulfone in SRS-A^rat. The molecular ion peak of SRS-A^rat sodium salt was observed at m/e 680 in field desorption mass spectrum of SRS-A^rat.On the basis of these data, we identified the structure of SRS-A^rat as [γ-glutamyl-4(5-hydroxy-7,9,11,14-eicosatetraenoic acid-6-yl)-4,4-dioxocysteinyl] glycine.     

Generation of a novel disease model mouse for mucopolysaccharidosis type VI via c. 252T>C human ARSB mutation knock-in

Mucopolysaccharidosis type VI (MPS VI) is an autosomal recessive lysosomal disorder caused by a mutation in the ARSB gene, which encodes arylsulfatase B (ARSB), and is characterized by glycosaminoglycan accumulation. Some pathogenic mutations have been identified in or near the substrate-binding pocket of ARSB, whereas many missense mutations present far from the substrate-binding pocket. Each MPS VI patient shows different severity of clinical symptoms. To understand the relationship between mutation patterns and the severity of MPS VI clinical symptoms, mutations located far from the substrate-binding pocket must be investigated using mutation knock-in mice. Here, I generated a knock-in mouse model of human ARSB Y85H mutation identified in Japanese MPS VI patients using a CRISPR-Cas9-mediated approach. The generated mouse model exhibited phenotypes similar to those of MPS VI patients, including facial features, mucopolysaccharide accumulation, and smaller body size, suggesting that this mouse will be a valuable model for understanding MPS VI pathology.