Synthesis and stability of arylsulfatase A and B in fibroblasts from multiple sulfatase deficiency

Fibroblasts from patients with multiple sulfatase deficiency were analyzed for activities of arylsulfatase A and B, iduronate 2-sulfatase and sulfamatase. A group of patients (group I) severely deficient in all sulfatases (residual activities less than or equal to 10% of control) were differentiated from patients (group II) with residual sulfatase activities of up to 90% of control. The synthesis and stability of arylsulfatase A and B were determined in pulse-chase labelling experiments. The apparent rate of synthesis of arylsulfatase A and B varied from 30% to normal in both fibroblasts from group I and II multiple sulfatase deficiency. In group I the molecular activity of the arylsulfatase A and B was more than 10-fold lower than in control fibroblasts. In group II the molecular activity of the arylsulfatase A was twofold to threefold lower and that of arylsulfatase B half of normal. In fibroblasts of both groups the stability of arylsulfatase A polypeptides was significantly diminished. For arylsulfatase B the instability was restricted to the mature 47000-Mr polypeptide and was variable within both groups. These results demonstrate that multiple sulfatase deficiency is a heterogeneous disorder, in which the primary defects can impair both the catalytic properties and the stability of sulfatases.     

Rapid degradation of steroid sulfatase in multiple sulfatase deficiency

Pulse labeling followed by SDS-PAGE electrophoresis of immunoprecipitated [35S]methionine-labeled steroid sulfatase (STS) gave a single band of molecular weight 65,000 daltons. After a chase period of 18 hours the material appeared as molecular weight approximately 64,000. No labeled STS could be detected in fibroblasts from individuals with STS deficient X-linked ichthyosis. Pulse-chase labeling of normal and multiple sulfatase deficiency (MSD) fibroblasts showed a normal rate of synthesis of STS in MSD during a 3 hour pulse but during the chase the STS of MSD cells disappeared with a half-life of 4 to 6 hours until approximately 25% of the material remained after 24 hr. STS of normal cells had a half-life of 6 days. The material produced in MSD cells had the same molecular size as normal and had the same amount of endoglycosidase sensitive carbohydrate as normal. The defect in MSD thus seems to result in degradation after the addition of N-linked oligosaccharides.     

Genetic heterogeneity of steroid sulfatase deficiency revealed with cDNA for human steroid sulfatase

Three cDNA clones with inserts of 1.2-1.6 kb that reacted both with antibodies and oligonucleotides specific for steroid sulfatase were isolated from a human placental library in lambda gt11. The 5'-end of one of the inserts, STS-3, was sequenced and colinearity with the amino acid sequence of 3 peptides of steroid sulfatase encompassing 64 amino acids was demonstrated. STS-3 hybridized with 2.5, 4.6 and 6.3 kb species in poly(A)+RNA and with 2.5, 4 and 9 kb fragments of EcoRI digested human DNA. The frequency of the EcoRI fragments in DNA from females was approximately twice that in DNA from males. DNA from two patients with steroid sulfatase deficiency and X-linked ichthyosis did not hybridize with STS-3. DNA from a third patient showed a normal hybridization pattern. It is concluded that steroid sulfatase deficiency is a genetically heterogenous disorder.     

Arysulfatase A modulation with pH in multiple sulfatase deficiency disorder fibroblasts.

It has been observed that multiple sulfatase deficiency disorder (MSDD) fibroblasts contained from profoundly deficient to near normal amounts of arylsulfatase (ARS) A depending on the medium in which they were cultured. Our present findings show that the major factor determining the enzyme level is the pH of the medium during growth. In media which became acidic or was maintained at low pH (less than 7), the cells expressed the enzymopathy, while in high pH media (7.4), the cells produced enzyme. The high and low enzyme states were reversible. The ARS A deficiency in MSDD must, therefore, be a secondary manifestation of a mutation in another system.     

Presence of arylsulfatase A (ARS A) in multiple sulfatase deficiency disorder fibroblasts.

Multiple deficiency disorder fibroblasts cultured in MEM-CO2 showed deficiencies of arylsulfatase A(ARS A) comparable to the deficiency in metachromatic leukodystrophy fibroblasts. However, the MSDD fibroblasts cultured in MEM-HEPES contained near normal levels of ARS A. Moreover, the enzyme from the latter fibroblasts was indistinguishable from ARS A of control fibroblasts on DEAE-cellulose chromatography, ratio of activity with several substrates, thermal inactivation, sensitivity to inhibitors, and precipitation by antiserum to human ARS A. These data support the conclusion that the ARS A genome is intact in MSDD fibroblasts and, by extension, in MSDD patients. Other sulfatases were present at levels ranging from mildly deficient to near normal but never as low as seen in the corresponding specific sulfatase deficient disorders.     

Linkage analysis in X-linked ichthyosis (steroid sulfatase deficiency)

Summary Linkage analysis has been carried out in nine unrelated families segregating for X-linked ichthyosis (steroid sulfatase deficiency) using seven polymorphic DNA markers from the distal Xp. Close linkage was found between the disease locus and the loci DXS16, DXS89, and DXS143. In all families except one, Southern hybridization with the human steroid sulfatase cDNA and GMGX9 probes showed a deletion of corresponding loci in affected males. Three patients belonging to the same family had no evident deletion with either of the two above-mentioned probes. None of the other six DNA loci included in the linkage analysis were found to be deleted.     

Activity of steroid sulfatase in fibroblasts with numerical and structural X chromosome aberrations

Summary In cultured fibroblasts of patients with numerical and structural X chromosome aberrations the activity of steroid sulfatase (STS) is correlated with the number of functional STS gene copies. While normally, this X-linked gene is not inactivated, our data suggest that it may be subject to inactivation when carried on a structurally altered X-chromosome. Similar inactivation patterns have been reported earlier for the Xg locus which, like STS, is located on the distal protion of Xp.     

Serum steroid hormone levels in neonates born from the mother with placental sulfatase deficiency

Placental sulfatase deficiency (PSD) is a rare disorder with low estrogen production due to placental enzymatic deficiency. Although many papers have been published on this enzymatic deficiency, little information is available on steroidal environment in newborn babies from PSD mothers. Seven cases of PSD were confirmed and serum concentrations of nine steroids which included cortisol, free and conjugated pregnenolone, 16 alpha-hydroxypregnenolone, DHA and 16 alpha-hydroxy-DHA in cord blood at delivery and peripheral veins during the neonatal period were measured by radioimmunoassay. In all seven instances, healthy male infants were delivered, but six of the babies developed ichthyosis. Conjugated delta 5-steroid concentrations in cord blood were found to be high, while 16 alpha-hydroxypregnenolone was low when the PSD cases were compared with the controls. In the PSD cases, free 16 alpha-hydroxy-DHA and 16 alpha-hydroxy-pregnenolone were both lower than in controls during the first seven days after birth. These results indicate that the production of delta 5-C21 steroid in PSD infants is limited. In the present study of newborn infants with PSD, the pattern of circulating steroids was first demonstrated and the relationship between the sulfatase activity in the neonates and ichthyosis was discussed.     

Complementation of multiple sulfatase deficiency in somatic cell hybrids

Multiple sulfatase deficiency (MSD) is an inherited disorder characterized by deficient activity of seven different sulfatases. Genetic complementation for steroid sulfatase (STS), arylsulfatase A, and N-acetylgalactosamine 6-SO4 sulfatase was demonstrated in somatic cell hybrids between MSD fibroblasts and mouse cells ( LA9 ) or Chinese hamster cells ( CHW ). In an electrophoretic system that separates human and rodent STS isozymes, enzyme from hybrids migrated as human enzyme. We concluded that the rodent cell complemented the MSD deficiency and allowed normal expression of the STS structural gene. Some MSD- LA9 hybrids showed significant levels of human arylsulfatase A activity, as shown by the immunoprecipitation of active enzyme by human-specific antiserum. Complementation was also suggested for N-acetylgalactosamine 6- sulfatate sulfatase (GalNAc-6S sulfatase) in several MSD- LA9 hybrids by the demonstration of a significant increase in activity (10-fold) over that of the GalNAc-6S sulfatase-deficient parental mouse and MSD cells. Thus, it was possible to demonstrate complementation for more than one sulfatase in a single MSD-rodent hybrid. Normal levels of sulfatase activity in hybrids indicate that the sulfatase structural genes are intact in MSD cells.     

High levels of oxysterol sulfates in serum of patients with steroid sulfatase deficiency

Steroid sulfatase (STS) deficiency is the underlying cause of the skin condition known as recessive X-linked ichthyosis (RXLI). RXLI patients show scales on their skin caused by high concentrations of cholesterol sulfate (CS), as they are not capable of releasing the sulfate group from its structure to obtain free cholesterol. CS has been reported, so far, as the sole sulfated steroid with increased concentrations in the blood of RXLI patients. A non-targeted LC-MS approach in negative mode detection (LC-MS precursor ion scan mode) was applied to serum samples of 12 RXLI patients and 19 healthy males. We found that CS was not the only sulfated compound consistently elevated in RXLI patients, because a group of compounds with a m/z of 481 was found in high concentrations too. Further LC-MS/MS demonstrated that the main contributor to the m/z 481 signal in RXLI serum is 27-hydroxycholesterol-3-sulfate (27OHC3S). Accordingly, a new method for 27OHC3S quantification in the context of RXLI has been developed and validated. Other hydroxycholesterol sulfate compounds were elevated as well in RXLI patients.     

Clinical and biochemical investigations on patients with partial deficiency of placental steroid sulfatase

Summary We report on three independent cases with a partial deficiency of placental steroid sulfatase (E.C.3.1.6.2). Upon routine pregnancy monitoring these patients were detected on the basis of low estriol excretion and failing induction of labor. In all three cases a male was delivered and subsequently the diagnosis of partial deficiency of placental steroid sulfatase was confirmed enzymatically in placenta homogenates. In one case, fibroblast cultures were established from skin explants of mother and son. In fibroblasts of the child, as in placental tissue, the activity of steroid sulfatase was only 34% of normal. Similar values were obtained for arylsulfatase C, though this enzyme is clearly separable from steroid sulfatase by electrophoresis. In cells of the mother, enzyme activities were unremarkable.     

Biochemical evidence for the non-inactivation of the steroid sulfatase locus in human placenta and fibroblasts

Summary Steroid sulfatase activities are significantly higher in placentas obtained after the birth of girls than after the birth of boys, and also in female fibroblasts compared to male strains. This constitutes biochemical evidence for the non-inactivation of the X-linked sulfatase locus. No hydrolytic activity is found in the fibroblasts of ichthyotic boys. Heterozygosity is demonstrated in the fibroblasts of the four mothers studied, as they have steroid sulfatase activity of less or equivalent to the normal male value.     

Association of steroid sulfatase with one of the arylsulfatase C isozymes in human fibroblasts

When arylsulfatase C, a microsomal membrane-bound enzyme, is assayed with its natural substrates, the 3-beta-hydroxysteroid sulfates, it is also known as steroid sulfatase. Whether arylsulfatase C and steroid sulfatase are identical enzymes or not, however, has long been disputed. We now report that two electrophoretic variants of arylsulfatase C occur in normal human fibroblasts: one has a single anodic band of activity, "s," and the other has an additional faster migrating band, "f". The two types, s and "f + s", occur in cells from either sex. When fibroblast strains with the f + s forms of arylsulfatase C were cloned, two types of primary clones were always obtained: s and f + s. A single f band was never seen. When these primary clones were subcloned, however, the arylsulfatase C phenotype remained unchanged: primary s clones gave rise to s subclones and f + s clones to f + s subclones only. Therefore, these forms were clonal in origin and demonstrated a novel inheritance pattern in human cultured cells. The appearance of increasing amounts of the f band was correlated with up to 4-fold increase of arylsulfatase C activity, whereas the steroid sulfatase activity remained constant, thus demonstrating that arylsulfatase C was not identical with steroid sulfatase activity. Polyclonal antibodies raised against the s form immunoprecipitated activities of the s form of arylsulfatase C and steroid sulfatase but not the f form of arylsulfatase C. Therefore, we conclude that only the s form of arylsulfatase C is immunologically related to steroid sulfatase so that arylsulfatase C per se is not necessarily identical with steroid sulfatase. In addition, a novel form of genetic heterogeneity of isozymes in human fibroblasts is demonstrated.     

Multiple sulfatase deficiency: degradation of arylsulfatase A and B after endocytosis in fibroblasts

Multiple sulfatase deficiency can be classified into group I with severe and group II with moderate deficiencies in sulfatases. In fibroblasts in both groups the stability of arylsulfatase A and of the 47000-Mr form of arylsulfatase B is decreased [F. Steckel, A. Hasilik & K. von Figura (1985) Eur. J. Biochem. 151, 141-145]. After endocytosis in control fibroblasts or those from multiple sulfatase deficiency, arylsulfatase A and B derived from the latter were subjected to enhanced degradation in both types of recipient cells. The degradation was closely linked in time to endocytosis. Whereas instability of arylsulfatase A derived from different cell lines from multiple sulfatase deficiency was comparable, a marked heterogeneity was observed for the instability of the 47000-Mr polypeptide of arylsulfatase B. Each of the cell lines from multiple sulfatase deficiency synthesized arylsulfatase A and B polypeptides with normal and with decreased stability. Treatment with benzyloxycarbonyl-Phe-Ala-CHN2, an inhibitor of cysteine proteinases, stabilized arylsulfatase A polypeptides and partially restored arylsulfatase A activity in group II fibroblasts. The inhibitor had no protective effect on the 47000-Mr polypeptide or the activity of arylsulfatase B. The bearing of these findings on the yet unknown primary defect in multiple sulfatase deficiency is discussed.     

Purification and properties of steroid sulfatase from human placenta.

Steroid sulfatase was purified approximately 170-fold from normal human placental microsomes and properties of the enzyme were investigated. The major steps in the purification procedure included solubilization with Triton X-100, column chromatofocusing, and hydrophobic interaction chromatography on phenylsepharose CL-4B. The purified sulfatase showed a molecular weight of 500-600 kDa on HPLC gel filtration, whereas the enzyme migrated as a molecular mass of 73 kDa on sodium dodecyl sulfate polyacrylamide gel electrophoresis. The isoelectric point of steroid sulfatase was estimated to be 6.7 by isoelectric focusing in polyacrylamide gel in the presence of 2% Triton X-100. The addition of phosphatidylcholine did not enhance the enzyme activity in the placental microsomes obtained from two patients with placental sulfatase deficiency (PSD) after solubilization and chromatofocusing. This result indicates that PSD is the result of a defect in the enzyme rather than a defect in the membrane-enzyme structure. Amino acid analysis revealed that the purified human placental sulfatase did not contain cysteine residue. The Km and Vmax values of the steroid sulfatase for dehydroepiandrosterone sulfate (DHA-S) were 7.8 microM and 0.56 nmol/min, while those for estrone sulfate (E1-S) were 50.6 microM and 0.33 nmol/min, respectively. The results of the kinetic study suggest the substrate specificity of the purified enzyme, but further studies should be done with different substrates and inhibitors.     

Solubilization and partial purification of steroid sulfatase from rat liver: characterization of estrone sulfatase.

Steroid sulfatase, a membrane-bound enzyme present in many mammalian tissues, was extracted from rat liver microsomes by treatment with Miranol H2M, a zwitterion detergent, and sonication. It has been purified approximately 33-fold. All steps of the purification, which included salt and solvent fractionation, hydroxylapatite treatment, ion-exchange chromatography, and gel filtration were performed in the presence of Miranol H2M, most of which was removed from the final preparation by gel filtration. The final preparation did not contain any detectable NADPH-cytochrome c reductase or glucose-6-phosphate phophatase activities. According to the elution volume on a Sephadex G-200 column, steroid sulfatase has a molecular weight of approximately 130,000. Polyacrylamide-gel electrophoresis in the presence of Miranol H2M revealed one major protein band which was enzymatically active. Purified steroid sulfatase hydrolyzes all the sulfate esters of estrone, dehydroepiandrosterone, pregnenolone, testosterone, and cholesterol as well as p-nitrophenyl sulfate, the substrate for arylsulfatase C, during the purification. However, estrone sulfatase and arylsulfatase C activities were enriched more than the others. Analysis of kinetic data and the effects of different buffers and of Miranol H2M also suggested that estrone sulfatase and arylsulfatase C are identical but that they are distinct from the other sulfatases. Competitive inhibition studies suggest that estrone sulfatase also catalyzes the hydrolysis of the sulfate esters of other estrogens.     

Synthesis, in vitro and in vivo activity of benzophenone-based inhibitors of steroid sulfatase

Steroid sulfatase (STS) is an important new therapeutic target in oncology. Attempts to design nonsteroidal STS inhibitors, because of the oestrogenicity of the original lead oestrone 3-O-sulfamate in rodents, have led to the discovery of benzophenone-4,4'-O,O-bis-sulfamate (BENZOMATE, 3). The nonfused bicyclic BENZOMATE is a highly potent STS inhibitor in vitro, inhibiting STS activity in intact MCF-7 breast cancer cells by > 70% at 0.1 microM and in placental microsomes by > 98% at 10 microM. When MCF-7 cells were pre-treated with 3 at 1 microM and then washed to remove unbound inhibitor, the initial 94% inhibition was reduced to 89% suggesting that 3, like other sulfamate-based STS inhibitors, inhibits the enzyme irreversibly. This agent also inhibits rat liver STS activity by 84% and 93% respectively 24 h after a single dose of 1 or 10 mg/kg, demonstrating that BENZOMATE possesses similar in vivo potency to the established potent nonsteroidal inhibitor 667COUMATE. Several modifications were made to BENZOMATE structurally and effects on in vitro activity were examined. These structure-activity relationship studies show that its carbonyl and bis-sulfamate groups are pivotal for activity, although conformational flexibility is not required. Two rigid anthraquinone-based sulfamate derivatives however showed inhibitory activity significantly better than BENZOMATE in the MCF-7 cell assay. BENZOMATE and related analogues therefore represent an important class of non-steroidal STS inhibitor and lead compounds for future drug design.     

Genetic complementation in somatic cell hybrids of cerebroside sulfatase activator deficiency and metachromatic leukodystrophy fibroblasts

Summary Several cases of metachromatic leukodystrophy (MLD) have been described with normal or near normal activities of arylsulfatase A (cerebroside sulfatase). However, the ability of intact cultured fibroblasts to hydrolyze cerebroside sulfate was impaired. Since the impairment was corrected by cerebroside sulfatase activator, a deficiency of activator was implied. In the absence of direct demonstration of deficiency, other types of evidence were needed to support the premise that the genetic defect was not associated with the arylsulfatase A locus as in classical MLD. Therefore, somatic cell hybrids of activator deficiency and MLD fibroblasts were analyzed. Complementation was indicated by enhanced hydrolysis of cerebroside sulfate, supporting the view that cerebroside sulfatase activator deficiency and MLD are nonallelic.