Arylsulfatase B-deficient mucopolysaccharidosis in rats.

A rat colony with mucopolysaccharidosis VI was established and the clinical, pathological, and biochemical features were characterized. Affected rats had facial dysmorphia, dysostosis multiplex, and increased urinary excretion of glucosaminoglycans (GAGs). Ultrastructural studies revealed storage of GAGs throughout the reticuloendothelial cells, cartilage, and other connective tissues, but no deposition was observed in the nervous system. Biochemical analyses demonstrated that the excreted GAG was dermatan sulfate and the activity of hepatic arylsulfatase B was < 5% of the normal mean value. Pedigree analysis showed that the phenotype was inherited as an autosomal recessive single trait. The availability of a rat model of human mucopolysaccharidosis VI should permit the development and evaluation of various strategies to treat the human disease.

Structure of a human lysosomal sulfatase.

BACKGROUND: . Sulfatases catalyze the hydrolysis of sulfuric acid esters from a wide variety of substrates including glycosaminoglycans, glycolipids and steroids. There is sufficient common sequence similarity within the class of sulfatase enzymes to indicate that they have a common structure. Deficiencies of specific lysosomal sulfatases that are involved in the degradation of glycosamino-glycans lead to rare inherited clinical disorders termed mucopolysaccharidoses. In sufferers of multiple sulfatase deficiency, all sulfatases are inactive because an essential post-translational modification of a specific active-site cysteine residue to oxo-alanine does not occur. Studies of this disorder have contributed to location and characterization of the sulfatase active site. To understand the catalytic mechanism of sulfatases, and ultimately the determinants of their substrate specificities, we have determined the structure of N-acetylgalactosamine-4-sulfatase. RESULTS: . The crystal structure of the enzyme has been solved and refined at 2.5 resolution using data recorded at both 123K and 273K. The structure has two domains, the larger of which belongs to the alpha/beta class of proteins and contains the active site. The enzyme active site in the crystals contains several hitherto undescribed features. The active-site cysteine residue, Cys91, is found as the sulfate derivative of the aldehyde species, oxo-alanine. The sulfate is bound to a previously undetected metal ion, which we have identified as calcium. The structure of a vanadate-inhibited form of the enzyme has also been solved, and this structure shows that vanadate has replaced sulfate in the active site and that the vanadate is covalently linked to the protein. Preliminary data is presented for crystals soaked in the monosaccharide N-acetylgalactosamine, the structure of which forms a product complex of the enzyme. CONCLUSIONS: . The structure of N-acetylgalactosamine-4-sulfatase reveals that residues conserved amongst the sulfatase family are involved in stabilizing the calcium ion and the sulfate ester in the active site. This suggests an archetypal fold for the family of sulfatases. A catalytic role is proposed for the post-translationally modified highly conserved cysteine residue. Despite a lack of any previously detectable sequence similarity to any protein of known structure, the large sulfatase domain that contains the active site closely resembles that of alkaline phosphatase: the calcium ion in sulfatase superposes on one of the zinc ions in alkaline phosphatase and the sulfate ester of Cys91 superposes on the phosphate ion found in the active site of alkaline phosphatase.

Lysosomal arylsulfatases of human leukocytes: increment of phosphorylated B variants in chronic myelogenous leukemia.

Lysosomal arylsulfatases A and B of peripheral leukocytes from patients with chronic myelogenous leukemia and from healthy subjects were studied. Two enzyme activities of leukemia cells were significantly higher than those of cells from healthy subjects, irrespective of total and differential counts of leukemic cells. Upon anion-exchange chromatography, the arylsulfatases of chronic myelogenous leukemia cells and normal leukocytes were separated into the basic B enzyme and its anionic variant (B1) and A enzyme. However, the amount of B1 enzyme relative to B enzyme or the activity ratio of B1 enzyme to total arylsulfatase B (B + B1) was higher in chronic myelogenous leukemia cells than in normal cells. The anionic property of the enzyme was found to be due to phosphate groups bound to the carbohydrate moiety of the arylsulfatase, based on the following results. When B1 enzyme was treated with alkaline phosphatase followed by isoelectric focusing, it was changed to a less anionic enzyme with heterogeneous components which are ascribed to phosphodiester groups linked to the heterogeneous carbohydrate moiety of the enzyme; no effect was observed by sialidase treatment. Upon treatment of B1 enzyme with endo-beta-N-acetylglucosaminidase H, which cleaves sugar chains of a high mannose type in glycoproteins, the anionic heterogeneous components were converted to the basic component similar to B enzyme. From our present and previous observations, it can be concluded that the increase of phosphorylated forms of the lysosomal hydrolase represents one characteristic of rapidly proliferating neoplastic cells.

Animal model studies of allelism: characterization of arylsulfatase B mutations in homoallelic and heteroallelic (genetic compound) homozygotes with feline mucopolysaccharidosis VI.

The identification of a second structural gene mutation at the feline arylsulfatase B locus (MPS VIb) provided the opportunity to investigate the expression of allelism by characterization of the residual enzymatic activity in feline mucopolysaccharidosis VI, an animal analogue of human Maroteaux-Lamy syndrome. Matings were designed to produce affected homozygotes who were homoallelic for the MPS VIa and MPS VIb mutations or heteroallelic genetic compounds (MPS VIa/VIb). The physicokinetic and immunological properties of the partially purified residual hepatic arylsulfatase B isozymes from the affected homoallelic and heteroallelic cats were compared to those of the normal feline enzyme. The residual hepatic arylsulfatase B activities from the inbred MPS VIa and MPS VIb homozygotes were distinguished by differences in physicokinetic and immunological properties. The newly identified mutant isozyme b had abnormal kinetic properties toward artificial and natural substrates, normal cryo- and thermostabilities, a normal molecular weight and an altered electrophoretic mobility. Polyacrylamide gel electrophoresis demonstrated that the mutant b subunits formed dimers with normal subunits in obligate heterozygotes (MPS VI+/b). In contrast, mutant isozyme a subunits from obligate MPS VIa/+ heterozygotes did not dimerize with the normal subunit, and the mutant and normal isozymes could be separated by anion exchange chromatography and polyacrylamide gel electrophoresis. Characterization of the partially purified residual hepatic arylsulfatase B activity from the heteroallelic homozygotes revealed the presence of both mutant isozymes a and b. The demonstration of two allelic mutations in the feline arylsulfatase B gene documented the occurrence of genetic heterogeneity in feline mucopolysaccharidosis VI and permitted characterization of the enzymatic defect in homoallelic and heteroallelic (genetic compound) homozygotes, providing a model for the study of allelism in human genetic disorders.

Conversion of cysteine to formylglycine in eukaryotic sulfatases occurs by a common mechanism in the endoplasmic reticulum.

Sulfatases undergo an unusual protein modification leading to conversion of a specific cysteine residue into alpha-formylglycine. This conversion is essential for catalytic activity. In arylsulfatase A the alpha-formylglycine is generated inside the endoplasmic reticulum at a late stage of protein translocation. Using in vitro translation in the presence of transport-competent microsomes we found that arylsulfatase B is also modified in a similar way by the formylglycine-generating machinery. Modification depended on protein transport and on the correct position of the relevant cysteine. Arylsulfatase A and B did not compete for modification, as became apparent in co-expression experiments. This could argue for an association of the modification machinery with the protein translocation apparatus.

Automated DNA purification and amplification from blood-stained cards using a robotic workstation.

A new method for the purification of DNA on blood-stained cards was developed. This method was implemented into a high-throughput automated system using a Biomek 1000 robotic workstation. In addition, the processes of DNA purification and amplification were coupled into a completely automated and uninterrupted prototype system, and the resultant PCR products generated by this system were subjected to automated desalting for capillary electrophoresis analysis.

Maroteaux-Lamy syndrome in a large consanguineous kindred: biochemical and immunological studies.

We describe a large consanguineous German-Acadian ("Cajun") family from a rural area in Louisiana in which 11 persons in two generations had the Maroteaux-Lamy syndrome. The mutant arylsulfatase B enzyme in this family was similar to the mutant enzyme in previously studied families in its cross-reactivity with specific antibodies to the enzyme, but it differed in both its electrophoretic mobility and its residual enzymatic activity. These findings indicate that a different mutational event leading to Maroteaux-Lamy syndrome occurred in this family.

[A novel nonsense point mutation in the arylsulfatase B gene with a severe type Maroteaux-Lamy syndrome].

Maroteaux-Lamy syndrome (MLS, also known as Mucopolysaccharidosis VI) is an inherited lysosomal disease due to a deficiency of the enzyme arylsulfatase B (ASB). Clinically, severe, intermediate and mild types are classified according to the symptoms and the age of onset. In recent years, several cases have been reported in which various mutations have been found by sequence analysis of ASB cDNA or genomic DNA. All of these mutations were reported occurred in single patients. Here I report a severe type MLS patient. A new point mutation was found on ASB gene which resulted in a stop codon at ASB peptide 421 (Glu). Due to this point mutation, a peptide fragment composed of 112 amino acids should have been deleted out. This point mutation was confirmed as a homoallele by direct sequence analysis of genomic DNA. Expression experiment on this point mutation revealed that the mutant produced neither mature ASB protein nor enzyme activity.

[Further steps in regional localization of the gene coding for human arylsulfatase B (ARSB): gene assignment to the section q11-qter of chromosome 5]. / Dalsze badania nad lokalizacja genu strukturalnego arylosulfatazy B (ARSB) czlowieka: przypisanie genu do odcinka q11-qter chromosomu 5.

The structural gene coding for human arylsulfatase B (ARSB) has been assigned to chromosome 5 and then to 5p11-5qter by means of somatic cell hybridization. The somatic cell hybrids used in the present studies were derived from fusion experiments between Chinese hamster, a3 line (TK-) and human leukocytes from a patient carrying the reciprocal balanced translocation t (5;21) (q11;q22) according to the method described previously. About 90 independent hybrid clones were selected for further analysis. They were tested for the presence of human markers employing the methods routinely used. ARSB activity was checked upon as previously. Giemsa banding technique was used to identify human and hamster chromosomes in the hybrid cells. Human ARSB activity was detected in 12 hybrid clones; 6 of them appeared to be informative. Out of 78 clones negative for human ARSB, 3 containing the product of translocation, 5pter-5q11: 21q22-21qter were found. Human superoxide dismutase-1 (SOD1) activity, a marker for chromosome 21, was found in 27 clones. The informative hybrid clones both positive and negative for ARSB are presented in table I. Six informative clones retained the region 5q11-5qter as the only portion of chromosome 5 and they expressed the activity of human ARSB and hexosaminidase B (HEXB), a marker for 15q13. It seems worth-while to point out that human ARSB activity was found only in the hybrids which retained the product of the translocation carrying 5q11-5qter in high percentage of the cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Chromosomal localization of ARSB, the gene for human N-acetylgalactosamine-4-sulphatase.

A deficiency of N-acetylgalactosamine-4-sulphatase (G4S, gene symbol ARSB), results in the accumulation of undegraded substrate and the lysosomal storage disorder, Maroteaux-Lamy syndrome (mucopolysaccharidosis type VI). In situ hybridization using an 3H-labelled human G4S genomic DNA fragment to human metaphase chromosomes localized ARSB to chromosome 5q13-5q14. This location is consistent with, an refines, previous chromosomal assignments based on the expression of human G4S in somatic cell hybrids.

Biosynthesis and maturation of arylsulfatase B in normal and mutant cultured human fibroblasts.

The biosynthesis of arylsulfatase B in normal and mutant human skin fibroblasts was studied by metabolic labeling with radioactive amino acids, monosaccharides, or 32Pi and by specific immunoprecipitation followed by polyacrylamide gel electrophoresis and fluorography. Three major polypeptides with apparent molecular weights of 47,000, 40,000, and 31,000 were found intracellularly and one of 64,000 in the medium. Pulse-chase labeling and uptake experiments showed that arylsulfatase B synthesized and secreted as a 64,000 precursor was intracellularly processed within less than 24 h via short lived intermediates to two different forms. Form I (chains of 47,000 and 11,500) was labeled earlier and was about twice as stable as form II (chains of 40,000 and 31,000). The secreted 64,000 precursor and the 40,000 chain of form II contained oligosaccharides resistant to endo-beta-N-acetylglucosaminidase H. In the other chains mainly cleavable and phosphorylated oligosaccharides were found. Arylsulfatase B activity was associated with the 64,000 precursor and with form I, but not with form II. Fibroblasts of four patients with the severe form of mucopolysaccharidosis type VI, which were deficient in arylsulfatase B activity, synthesized and secreted the 64,000 precursor at a normal rate. This precursor, however, had little if any catalytic activity and one of its mature forms (I) was rapidly degraded.

Linkage of loci affecting a murine liver protein and arylsulfatase B to chromosome 13.

As-1 is the putative structural locus for murine arylsulfatase B, and Lth-1 determines the presence or absence of a 35 000 dalton acidic liver protein. As-1 and Lth-1 were found to be closely linked using recombinant inbred (RI) strains. Both loci were found to have been cotransferred with the pearl (pe) coat color mutation (chromosome 13) in the B6.C3H pe/pe congenic strain. The linkage relationships between pe, Lth-1, and As-1 were further defined in a backcross. On the basis of the RI data, the congenic strain result, and the backcross data, the following genetic distances were estimated: pe--As-1, 7.1 +/- 4.0 cM; As-1--Lth-1, 2.5 +/- 1.0 cM; and pe--Lth-1, less than 6.9 cM. As-1 and Lth-1 are the first biochemically defined loci to be added to the chromosome 13 linkage map.

Confirmation of the assignment of the gene for arylsulfatase A to chromosome 22 using somatic cell hybrids.

Human/hamster hybrid cell cultures were examined for the presence of ARSA and other marker enzymes. Many of these hybrids were also analyzed for human chromosomes. Our results confirm the assignment of ARSA to chromosome 22.

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 x 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 of identical to Apl. Kidney, brain, and spleen arylsulfatase B electrofocusing patterns did not appear to differ between SM/J and C57BL/6J mice.

Overexpression of N-acetylgalactosamine-4-sulphatase induces a multiple sulphatase deficiency in mucopolysaccharidosis-type-VI fibroblasts.

High-titre stocks of an amphotropic retrovirus, constructed so as to express a full-length cDNA encoding the human lysosomal enzyme N-acetylgalactosamine-4-sulphatase (4-sulphatase) from the cytomegalovirus immediate early promoter, were used to infect skin fibroblasts from a clinically severe mucopolysaccharidosis type VI (MPS VI) patient. The infected MPS VI cells showed correction of the enzymic defect with the enzyme being expressed at high levels and in the correct subcellular compartment. Surprisingly this did not result in correction of glycosaminoglycan turnover as measured by accumulation of 35S in metabolically labelled cells. We demonstrate that this is apparently caused by an induced reduction of the activities of other lysosomal sulphatases, presumably due to competition for a sulphatase-specific processing mechanism by the over-expressed 4-sulphatase. The level of steroid sulphatase, which is a microsomal sulphatase, was also reduced. Infection of skin fibroblasts from a second, clinically mildly affected, MPS VI patient with the same virus also resulted in no significant change in the level of glycosaminoglycan storage. However, in this case the cause of the observed phenomenon was less clear. These results are of obvious practical importance when considering gene therapy for a sulphatase deficiency such as MPS VI and also provide possible new avenues for exploration of the processes involved in sulphatase synthesis and genetically determined multiple sulphatase deficiency.

Analysis of N-acetylgalactosamine-4-sulfatase protein and kinetics in mucopolysaccharidosis type VI patients.

A sensitive and specific, monoclonal antibody-based immunoquantification assay has facilitated determination of the N-acetylgalactosamine-4-sulfatase (4-sulfatase) protein content in cultured fibroblasts from normal controls and mucopolysaccharidosis type VI (MPS VI) patients. The assay enabled the quantification of 4-sulfatase protein by using a panel of seven monoclonal antibodies and has shown that fibroblasts from 16 MPS VI patients contained less than or equal to 5% of the level determined for normal controls. Fibroblasts from the most severely affected patients contained the lowest levels of 4-sulfatase protein, usually with few epitopes detected, while fibroblasts from mildly affected patients had higher levels of 4-sulfatase protein, with all seven epitopes detected. The pattern of epitope expression is proposed to reflect the conformational changes in the 4-sulfatase protein that arise from different mutations in the 4-sulfatase gene. Immunoquantification in combination with a specific and highly sensitive 4-sulfated trisaccharide-based assay of enzyme activity in these MPS VI patient fibroblasts enabled the determination of residual 4-sulfatase catalytic efficiency (kcat/Km). The capacity of fibroblasts to degrade substrate (catalytic capacity) was calculated as the product of 4-sulfatase catalytic efficiency and the content of 4-sulfatase in fibroblasts. One patient, 2357, with no clinical signs of MPS VI but with reduced 4-sulfatase activity and protein (both 5% of normal) and dermatansulfaturia, had 5% of normal catalytic capacity. The other 15 MPS VI patient fibroblasts had 0%-1.4% of the catalytic capacity of fibroblasts from normal controls and were representative of the spectrum of MPS VI clinical phenotypes, from severe to mild.(ABSTRACT TRUNCATED AT 250 WORDS)

An N-acetylgalactosamine-4-sulfatase mutation (delta G238) results in a severe Maroteaux-Lamy phenotype.

Maroteaux-Lamy syndrome (mucopolysaccharidosis type VI, MPS VI) is an autosomally inherited lysosomal storage disorder caused by a deficiency of N-acetylgalactosamine-4-sulfatase (EC 3.1.6.1; 4-sulfatase). In order to determine the gene defect in a clinically severe MPS VI patient, polymerase chain reaction (PCR) products were generated from the patient's fibroblast mRNA and also from a 4-sulfatase cDNA clone and subjected to the chemical cleavage technique to detect mismatched bases, which were then identified by direct DNA sequencing of the PCR products. The patient was homozygous for an early frameshift mutation caused by the deletion of a G at position 238 (delta G238), which produces a truncated 4-sulfatase with an altered amino acid sequence from amino acid 80 to a premature stop codon at codon 113 relative to the normal 4-sulfatase reading frame of 533 amino acids. Since the mutation occurs only 40 amino acids past the signal peptidase cleavage site, it is most likely that this will result in a protein with no 4-sulfatase activity. This is consistent with the severe clinical presentation and the absence of 4-sulfatase enzyme activity or mutant 4-sulfatase protein in the patient. The patient was also found to be homozygous for two polymorphisms, i.e., a G to A transition at nucleotide 1072 resulting in a valine358 to methionine substitution (V358M) and a salient A to G transition in the third base of the proline397 codon at nucleotide 1191.

Feline arylsulfatase B (ARSB): isolation and expression of the cDNA, comparison with human ARSB, and gene localization to feline chromosome A1.

Arylsulfatase B (ARSB) is the lysosomal enzyme that catalyzes the hydrolysis of 4-sulfate groups from N-acetylgalactosamine 4-sulfate moieties on the glycosaminoglycans, dermatan sulfate and chondroitin sulfate A. In man, a deficiency of this enzymatic activity causes the lysosomal storage disorder, Maroteaux-Lamy disease (mucopolysaccharidosis Type VI; MPS VI). MPS VI in Siamese cats also has been described, and the comparative pathologic and biochemical abnormalities of the human and feline disorders have been well characterized. The present study describes the isolation and expression of cDNAs encoding feline ARSB and the assignment of the feline ARSB gene to feline chromosome A1. The full-length feline ARSB cDNA sequence is 1939 bp, including 3 and 328 bp of 5' and 3' untranslated sequences, respectively, and a 1608-bp open reading frame encoding 535 amino acids. The predicted human and feline ARSB proteins are 91% identical and 94% similar. However, despite this high homology, the predicted feline ARSB polypeptide has nine cysteine residues, while the human enzyme has eight. The presence of the extra cysteine residue at position 451 in the feline enzyme may explain why feline ARSB is a homodimer and the human enzyme is a monomer. To facilitate comparative structure/function studies of the human and feline enzymes and to initiate somatic gene therapy trials in the MPS VI cats, a full-length feline ARSB cDNA was reconstructed from a 1440-bp partial cDNA and an ARSB fragment amplified from feline first-strand cDNA by the polymerase chain reaction. The functional integrity of this cDNA was demonstrated by transient expression in human embryonic kidney cells.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

Lysosomal arylsulfatase deficiencies in humans: chromosome assignments for arylsulfatase A and B.

Genetics of human lysosomal arylsulfatases A and B (aryl-sulfate sulfohydrolase, EC 3.1.6.1), associated with childhood disease, has been studied with human-rodent somatic cell hybrids. Deficiency of arylsulfatase A (ARS(A)) in humans results in a progressive neurodegenerative disease, metachromatic leukodystrophy. Deficiency of arylsulfatase B (ARS(B)) is associated with skeletal and growth malformations, termed the Maroteaux-Lamy syndrome. Simultaneous deficiency of both enzymes is associated with the multiple sulfatase deficiency disease, suggesting a common relationship for ARS(A) and ARS(B). The genetic and structural relationships of human ARS(A) and ARS(B) have been determined by the use of human-Chinese hamster somatic cell hybrids. Independent enzyme segregation in cell hybrids demonstrated different chromosome assignments for the structural genes, ARS(A) and ARS(B), coding for the two lysosomal enzymes. ARS(A) activity showed concordant segregation with mitochondrial aconitase encoded by a gene assigned to chromosome 22. ARS(B) segregated with beta-hexosaminidase B encoded by a gene assigned to chromosome 5. These assignments were confirmed by chromosome analyses. The subunit structures of ARS(A) and ARS(B) were determined by their electrophoretic patterns in cell hybrids; a dimeric structure was demonstrated for ARS(A) and a monomeric structure for ARS(B). Although the multiple sulfatase deficiency disorder suggests a shared relationship between ARS(A) and ARS(B), independent segregation of these enzymes in cell hybrids did not support a common polypeptide subunit or structural gene assignment. The evidence demonstrates the assignment of ARS(A) to chromosome 22 and ARS(B) to chromosome 5. A third gene that affects ARS(A) and ARS(B) activity is suggested by the multiple sulfatase deficiency disorder.