A new biochemical subtype of the Sanfilippo syndrome: characterization of the storage material in cultured fibroblasts of Sanfilippo C patients.

Fibroblasts cultured from the skin of three unrelated patients with the clinical symptoms of the Sanfilippo syndrome (mucopolysaccharidosis III) accumulated intracellularly excessive amounts of heparan sulfate and showed a lengthened turnover time for this mucopolysaccharide. They exhibited, however, neither a deficiency of heparan sulfate sulfamidase or alpha-N-acetylglucosaminidase nor of any other known glycosaminoglycan-degrading hydrolase. This new mucopolysaccharidosis was therefore designated as type C of the Sanfilippo syndrome. The abnormal heparan sulfate metabolism of Sanfilippo C fibroblasts could not be normalized by addition of crude urinary proteins or concentrated secretions from normal fibroblasts to the culture medium or by cocultivation with normal fibroblasts. The accumulated heparan sulfate was characterized by a reduced negative net charge. A small proportion of it could be adsorbed onto a cation exchange resin. It was sensitive to nitrous acid degradation under conditions where glucosamine residues with free amino groups are attacked. It is therefore suggested that the primary defect in this new mucopolysaccharidosis concerns the step which follows the hydrolysis of N-sulfonate groups in heparan sulfate degradation.     

Mucopolysaccharidosis 3 A (Sanfilippo A disease): deficiency of a heparin sulfamidase in skin fibroblasts and leucocytes

Cultured skin fibroblasts and peripheral leucocytes from patients with Sanfilippo A disease are strikingly deficient in sulfamidase activity (sulfamatase, EC 3.1.6.?), as measured with heparin - N³⁵SO₄. A partial sulfamidase deficiency was found in the cells of the heterozygote carriers. Since Sanfilippo A fibroblasts have normal sulfate ester hydrolase activities towards oligosaccharides prepared from ³⁵SO₄-labelled heparan sulfate by nitrous acid treatment, the basic defect in Sanfilippo A disease is considered to be the inactivity of a heparin (heparan sulfate) sulfamidase.     

Characterization of extracellular matrix-associated glycosaminoglycans produced by untransformed and transformed bovine corneal endothelial cells in culture

A cloned bovine corneal endothelial cell line was transformed in vitro by simian virus 40, and the subendothelial extracellular matrix-associated sulfated glycosaminoglycans synthesized by the cells were isolated and compared with their untransformed counterpart. The transformed endothelial cells grew at faster rates to higher stationary cell densities in the absence of fibroblast growth factor than did the untransformed cells. On a per-cell basis, the transformed cells produced slightly lower amounts of sulfated glycosaminoglycans. The rate of production of sulfated glycosaminoglycans in extracellular matrix increased during seven days of culture. At confluency the extracellular matrix-associated sulfated glycosaminoglycans synthesized by the untransformed endothelial cells consisted of about 80% heparan sulfate and about 20% chondroitin sulfate. Extracellular matrix-associated sulfated glycosaminoglycans of transformed endothelial cells were composed of about 70% heparan sulfate and about 30% chondroitin sulfate plus dermatan sulfate. High-speed gel permeation chromatography profiles on Fractogel TSK HW-55(S) of matrix-associated heparan sulfate from untransformed and transformed endothelial cells were very similar, and gave single peaks (Kav = 0.19). Apparent Mr estimated from the eluting position of the peaks were approximately 47000. Heparan sulfate from both untransformed and transformed endothelial cells was degraded by incubation with a metastatic B16 melanoma cell lysate containing heparanase (heparan-sulfate-specific endo-beta-glucuronidase). The eluting position of the heparan sulfate degradation products on gel permeation column were similar (Kav = 0.43). Size analysis and anion-exchange chromatography of the degradation products after nitrous acid deamination at low pH indicated that the degree of N-sulfation of heparan sulfate was similar in untransformed and transformed endothelial cells. The results indicated that transformation of endothelial cells only slightly changes the molecular nature of subendothelial matrix-associated sulfated glycosaminoglycans.     

Differentiation-associated modulation of heparan sulfate structure and function in CaCo-2 colon carcinoma cells

Heparan sulfate species expressed by different cell and tissue types differ in their structural and functional properties. Limited information is available on differences in regulation of heparan sulfate biosynthesis within a single tissue or cell population under different conditions. We have approached this question by studying the effect of cell differentiation on the biosynthesis and function of heparan sulfate in human colon carcinoma cells (CaCo-2). These cells undergo spontaneous differentiation in culture when grown on semipermeable supports; the differentiated cells show phenotypic similarity to small intestine enterocytes. Metabolically labeled heparan sulfate was isolated from the apical and basolateral media from cultures of differentiated and undifferentiated cells. Compositional analysis of disaccharides, derived from the contiguous N-sulfated regions of heparan sulfate, indicated a greater proportion of 2-O- sulfated iduronic acid units and a smaller amount of 6-O-sulfated glucosamine units in differentiated than in undifferentiated cells. By contrast, the overall degree of sulfation, the chain length and the size distribution of the N-acetylated regions were similar regardless the differentiation status of the cells. The structural changes were found to affect the binding of heparan sulfate to the long isoform of platelet-derived growth factor A chain but not to fibroblast growth factor 2. These findings show that heparan sulfate structures change during cell differentiation and that heparan sulfate-growth factor interactions may be affected by such changes.      

Regulation of urokinase/urokinase receptor interaction by heparin-like glycosaminoglycans

We show here that the interaction between the urokinase-type plasminogen activator and its receptor, which plays a critical role in cell invasion, is regulated by heparan sulfate present on the cell surface and in the extracellular matrix. Heparan sulfate oligomers showing a composition close to the dimeric repeats of heparin (glucosamine-NSO(3)(6-OSO(3))-iduronic acid(2-OSO(3))) n = 5 and n > 5, where iduronic acid may alternate with glucuronic acid, exhibit affinity for urokinase plasminogen activator and confer specificity on urokinase/urokinase receptor interaction. Cell surface clearance of heparan sulfate reduces the affinity of such interaction with a parallel decrease of specific urokinase binding in the presence of an unaltered expression of receptor. Transfection of human urokinase plasminogen activator receptor in normal Chinese hamster ovary fibroblasts and in Chinese hamster ovary cells defective for the synthesis of sulfated glycosaminoglycans results in specific urokinase/receptor interaction only in nondefective cells. Heparan sulfate/urokinase and receptor/urokinase interactions exhibit similar K(d) values. We concluded that heparan sulfate functions as an adaptor molecule that confers specificity on urokinase/receptor binding.     

Secondary storage of dermatan sulfate in Sanfilippo disease

Mucopolysaccharidoses are a group of genetically inherited disorders that result from the defective activity of lysosomal enzymes involved in glycosaminoglycan catabolism, causing their intralysosomal accumulation. Sanfilippo disease describes a subset of mucopolysaccharidoses resulting from defects in heparan sulfate catabolism. Sanfilippo disorders cause severe neuropathology in affected children. The reason for such extensive central nervous system dysfunction is unresolved, but it may be associated with the secondary accumulation of metabolites such as gangliosides. In this article, we describe the accumulation of dermatan sulfate as a novel secondary metabolite in Sanfilippo. Based on chondroitinase ABC digestion, chondroitin/dermatan sulfate levels in fibroblasts from Sanfilippo patients were elevated 2-5-fold above wild-type dermal fibroblasts. Lysosomal turnover of chondroitin/dermatan sulfate in these cell lines was significantly impaired but could be normalized by reducing heparan sulfate storage using enzyme replacement therapy. Examination of chondroitin/dermatan sulfate catabolic enzymes showed that heparan sulfate and heparin can inhibit iduronate 2-sulfatase. Analysis of the chondroitin/dermatan sulfate fraction by chondroitinase ACII digestion showed dermatan sulfate storage, consistent with inhibition of iduronate 2-sulfatase. The discovery of a novel storage metabolite in Sanfilippo patients may have important implications for diagnosis and understanding disease pathology.     

Sulfated mucopolysaccharides from normal and virus transformed rodent fibroblasts.

The sulfated mucopolysaccharide composition of normal and virus transformed Balb 3T3 and BHK21 cell lines is reported. It is shown that normal 3T3 cells contain mainly chondroitin sulfate B and heparitin sulfate. Relatively higher amounts of chondroitin sulface AC were observed in polyoma virus transformed 3T3 cells, besides an absolute increase of all the three sulfated mucopolysaccharides in the polyoma and SV 40 transformed cells. It is shown also that the three sulfated mucopolysaccharides are at least in part at the cell surface. Similar differences in sulfated mucopolysaccharide composition of normal and virus transformed BHK cell lines were also observed.     

Transport of heparan sulfate into the nuclei of hepatocytes

Monolayer cultures of a rat hepatocyte cell line shown previously to accumulate a nuclear pool of free heparan sulfate chains that are enriched in sulfated glucuronic acid (GlcA) residues (Fedarko, N.S., and Conrad, H.E., (1986) J. Cell Biol. 587-599) were incubated with 35SO4(2-), and the rate of appearance of heparan [35S]sulfate in the nuclei was measured. Heparan [35S]sulfate began to accumulate in the nuclei 2 h after the administration of 35SO4(2-) to the cells and reached a steady state level after 20 h. Heparan [35S]sulfate was lost from the nuclei of prelabeled cells with a t1/2 of 8 h. Chloroquine did not inhibit the transport of heparan sulfate into the nucleus, but increased the t1/2 for the exit of heparan sulfate from the nucleus to 20 h and led to a doubling of the steady state level of nuclear heparan sulfate. Heparan [35S]sulfate which was obtained from the medium or from the cell matrix of a labeled culture and which contained only low levels of GlcA-2-SO4 residues was incubated with cultures of unlabeled cells, and the uptake of the exogenous heparan [35S]sulfate was studied. At 37 degrees C the cells took up proteoheparan [35S]sulfate and transported about 10% of the internalized heparan [35S]sulfate into the nucleus, where it appeared as free chains. The heparan [35S]sulfate isolated from the nucleus was enriched in GlcA-2-SO4 residues, whereas the heparan [35S]sulfate remaining in the rest of the intracellular pool showed a corresponding depletion in GlcA-2-SO4 residues. At 16 degrees C, where endocytosed materials do not enter the lysosomes, the cells also transported exogenous proteoheparan [35S]sulfate to the nucleus with similar processing. Thus, the metabolism of exogenous heparan sulfate by hepatocytes follows the same pathway observed in continuously labeled cells and does not involve lysosomal processing of the internalized heparan sulfate.     

Production of sulfated proteoglycans by human breast cancer cell lines: Binding to fibroblast growth factor-2

The cellular distribution and nature of proteoglycans synthesised by human breast cancer cells in culture were studied. Proteoglycans were labelled with [³⁵S] sulfate, purified, and characterised after ion-exchange chromatography followed by gel-filtration chromatography and treatment with glycosaminoglycan degrading enzymes. Proteoglycans were isolated from the culture medium and from cell layers of the hormono-dependent well-differentiated MCF-7 cell line, the hormono-independent poorly-differentiated MDA-MB-231 and the HBL-100 cell line which is derived from non malignant breast epithelium. HBL-100 and MDA-MB-231 cells produced larger amounts of proteoglycans which had a lower degree of sulfation than MCF-7 cells. Gel-filtration chromatography on Sepharose CL-6B indicated that HBL-100 and MDA-MB-231 cells accumulated cell surface heparan sulfate proteoglycans (HSPG), with a high apparent molecular weight (K_av 0.1). In contrast, the MCF-7 cell monolayers synthesised small sulfated macromolecules (K_av 0.4) which possessed mostly chondroitin sulfate chains. Moreover, considerable differences in the nature of the sulfated proteoglycans released into the culture medium of these breast epithelial cell lines were observed. MCF-7 cells released into the culture medium HSPG as the main proteoglycan component while MDA-MB-231 and HBL-100 cells released mainly chondroitin sulfate proteoglycans. In these three cell lines, medium-released sulfated macromolecules have a higher hydrodynamic size than cell-associated ones. Proteoglycans purified by ion-exchange chromatography were tested for their ability to bind ¹²⁵I FGF-2. We demonstrated that HBL-100 and MDA-MB-231 cells bind more FGF-2 to their heparan sulfate proteoglycans than MCF-7 cells. Taken together, these results suggest that differences in proteoglycan synthesis of human breast epithelial cells could be responsible for differences in their proliferative and/or invasive properties. J. Cell. Biochem. 64:605–617. © 1997 Wiley-Liss, Inc.     

Heparin releases heparan sulfate from the cell surface.

Heparan sulfate of the cell surface of cultured Chinese hamster cells (line CHO) was promptly released when the cells were incubated with balanced salt solutions containing heparin. The released heparan sulfate included multichain proteoglycan of high molecular weight. The data suggest that the cell-surface localization of heparan sulfate is dependent, at least in part, upon cell-surface receptors with binding sites for the sugar chain moieties of sulfated glycosaminoglycans.     

Proteoglycan and glycosaminoglycan synthesis by cultured rat mesangial cells

The synthesis of metabolically labeled proteoglycans and glycosaminoglycans from medium, cell layer and substrate attached material by rat glomerular mesangial cells in culture was characterized. The cellular localization of the labeled proteoglycans and glycosaminoglycans was determined by treating the cells with Flavobacterial heparinase. Of the total sulfated glycosaminoglycans, 33% were heparan sulfate; 55% of the cell layer material was heparan sulfate; 80% of sulfated proteins in the medium were chondroitin sulfate/dermatan sulfate. Putative glycosaminoglycan free chains of heparan sulfate and chondroitin sulfate were found in both the medium and cell layer; 95% of total proteoglycans and most (90%) of the putative heparan sulfate free chains were removed from the cell layer by the heparinase, whereas only 50% of the chondroitin sulfate and 25% of dermatan sulfate were removed. Large amounts of hyaluronic acid labeled with 3H glucosamine were found in the cell layer. In summary, approximately 60% of total sulfated glycoproteins was in the form of putative glycosaminoglycan free chains. Thus rat mesangial cells may synthesize large amounts of putative glycosaminoglycan free chains, which may have biological functions in the glomerulus independent of proteoglycans.     

A mouse model for mucopolysaccharidosis type III A (Sanfilippo syndrome)

Mucopolysaccharidosis type III A (MPS III A, Sanfilippo syndrome) is a rare, autosomal recessive, lysosomal storage disease characterized by accumulation of heparan sulfate secondary to defective function of the lysosomal enzyme heparan N- sulfatase (sulfamidase). Here we describe a spontaneous mouse mutant that replicates many of the features found in MPS III A in children. Brain sections revealed neurons with distended lysosomes filled with membranous and floccular materials with some having a classical zebra body morphology. Storage materials were also present in lysosomes of cells of many other tissues, and these often stained positively with periodic-acid Schiff reagent. Affected mice usually died at 7-10 months of age exhibiting a distended bladder and hepatosplenomegaly. Heparan sulfate isolated from urine and brain had nonreducing end glucosamine- N -sulfate residues that were digested with recombinant human sulfamidase. Enzyme assays of liver and brain extracts revealed a dramatic reduction in sulfamidase activity. Other lysosomal hydrolases that degrade heparan sulfate or other glycans and glycosaminoglycans were either normal, or were somewhat increased in specific activity. The MPS III A mouse provides an excellent model for evaluating pathogenic mechanisms of disease and for testing treatment strategies, including enzyme or cell replacement and gene therapy.     

AXONAL TRANSPORT OF SULFATED GLYCOPROTEINS AND MUCOPOLYSACCHARIDES IN THE GARFISH OLFACTORY NERVE

—Application of ³⁵SO₄ to the olfactory mucosa of the long-nosed garfish is found to label sulfated macromolecules which are transported down the olfactory nerve. The transported molecules pass along the nerve as a discrete peak whose leading edge has a transport velocity of 206 ± 6 mm/day. A large portion of the radioactivity from the peak is deposited along the axon. At 2 days after isotope application 83% of the total nerve radioactivity is in the axons and the remaining 17% has accumulated at the terminals in the olfactory bulb. Characterization of sulfated material in the migrating peak indicates that both sulfated glycoproteins (isolated as glycopeptides) and mucopolysaccharides, including chondroitin sulfate and heparan sulfate, are undergoing transport.     

An antiproliferative heparan sulfate species produced by postconfluent smooth muscle cells

Heparan sulfate was isolated form the cell surface, cell pellet, and culture medium of exponentially growing as well as postconfluent bovine aortic smooth muscle cells (SMCs). After chromatography on DEAE-Sephadex and Sepharose 4B, the various mucopolysaccharides were examined for their ability to cause growth inhibition in a SMC bioassay. The heparan sulfate isolated from the surface of postconfluent SMCs possessed approximately eight times the antiproliferative potency per cell of the heparan sulfate obtained from the surface of exponentially growing SMCs. Heparan sulfate isolated from other fractions of exponentially growing or postconfluent SMCs possesses little growth inhibitory activity. The difference in the antiproliferative activities of heparan sulfate obtained from the surface of SMCs in the two growth states could not be attributed to the synthesis of a greater mass of mucopolysaccharide by postconfluent SMCs. Indeed, heparan sulfate isolated from the surface of the postconfluent SMCs exhibits a specific antiproliferative activity which is 13-fold greater than mucopolysaccharide obtained from the surface of exponentially growing SMCs and more than 40-fold greater than commercially available heparin. In addition, exponentially growing SMCs did not exhibit an enhanced ability to degrade the complex carbohydrate. Furthermore, other investigations indicate that the small amount of growth inhibitory activity intrinsic to heparan sulfate isolated from the surface of exponentially growing SMCs is due to residual, biologically active, mucopolysaccharide produced by the primary postconfluent SMCs from which the exponentially growing SMCs were derived. These studies suggest that bovine aortic SMCs are capable of controlling their own growth by the synthesis of a specific form of heparan sulfate with antiproliferative potency.     

Structure of the pericellular matrix: Association of heparan and chondroitin sulfates with fibronectin-procollagen fibers

Immunofluorescent staining of a pericellular matrix produced by cultured human embryonic skin fibroblasts showed a codistribution among fibronectin, heparan sulfate proteoglycans and part of the chondroitin sulfate in a fibrillar network. Isolated matrix in an “intact” form could be scraped off the dish after detergent solubilization of the cells. On centrifugation In cesium chloride density gradients, most sulfated glycosaminoglycans and matrix proteins remained associated and were recovered at a density of 1.34 g/cm³ (≥2 M CsCI). However, when 4 M guanidine hydrochloride was included in the gradient medium, the components dissociated, suggesting that the sulfated glycosaminoglycans are bound to matrix proteins by strong noncovalent linkages. Interactions between sulfated glycosaminoglycans produced by the fibroblasts and fibronectin could also be demonstrated by affinity chromatography on immobilized plasma fibronectin and by immunoprecipitation of fibronectin in conditioned culture medium, which resulted in a coprecipitation of the sulfated glycosaminoglycans. In these two systems, the fibronectin glycosaminoglycan bonds were broken at 0.2 M salt and were apparently weaker than the bonds responsible for the structural integrity of the matrix. These findings Implicate heparan and chondroitin sulfate proteoglycans as Integral components of the pericellular matrix fibers and suggest that the association of the proteoglycans with the fibronectin-procollagen matrix is stabilized by multiple molecular Interactions.     

Thymic epithelial cells synthesize a heparan sulfate with a highly sulfated region

Epithelial cells are important components of the thymus microenvironment and are involved in thymocyte differentiation. The production and secretion of sulfated glycosaminoglycans by these cells grown in culture were investigated using labeling with radioactive ³⁵S-Na₂SO₄ and ³H-glucosamine. The major glycosaminoglycans synthesized by these cells are heparan sulfate and hyaluronic acid. The structure of the heparan sulfate was investigated by the pattern of degradation products formed by deaminative cleavage with nitrous acid. The ratio ³⁵S-sulfate/³H-glucosamine is high in the segments of the heparan sulfate released during the deaminative cleavage with nitrous acid but low in the resistant portion of the molecule. Thus, the heparan sulfate synthesized by the thymic epithelial cells contains a highly sulfated region. Digestion with heparitinase reveals that this highly sulfated region is a heparin-like segment of the molecule. The heparan sulfate is rapidly incorporated into the cell surface but its secretion to the extracellular medium requires a longer incubation period. Finally, heparin was used to mimic the possible effect of this heparan sulfate with a highly sulfated region, as ascertained by its ability to modulate thymocyte adhesion to thymic epithelial cells. Since heparin actually enhanced thymocyte adhesion, it is suggested that the heparan sulfate described herein, secreted by the thymic epithelium, may play a role upon intrathymic heterotypic cellular interactions. J Cell Physiol 178:51–62, 1999. © 1999 Wiley-Liss, Inc.     

Kinetics of proteoheparan sulfate synthesis, secretion, endocytosis, and catabolism by a hepatocyte cell line

The metabolism of heparan sulfate proteoglycan was studied in monolayer cultures of a rat hepatocyte cell line. Late log cells were labeled with 35SO4(2-) or [3H] glucosamine, and labeled heparan sulfate, measured as nitrous acid-susceptible product, was assayed in the culture medium, the pericellular matrix, and the intracellular pools. Heparan sulfate in the culture medium and the intracellular pools increased linearly with time, while that in the matrix reached a steady-state level after a 10-h labeling period. When pulse-labeled cells were incubated in unlabeled medium, a small fraction of the intracellular pool was released rapidly into the culture medium while the matrix heparan sulfate was taken up by the cells, and the resulting intracellular pool was rapidly catabolized. The structures of the heparan sulfate chains in the three pools were very similar. Both the culture medium pool and the cell-associated fraction of heparan sulfate contained proteoheparan sulfate plus a polydisperse mixture of heparan chains which were attached to little, if any, protein. Pulse-chase data suggested that the free heparan sulfate chains were formed as a result of catabolism of the proteoglycan. When NH4Cl, added to inhibit lysosomal function, was present during either a labeling period or a chase period, the total catabolism of the heparan sulfate chains to monosaccharides plus free SO2-4 was blocked, but the conversion of the proteoglycan to free heparan sulfate chains continued at a reduced rate.     

Multi-faceted substrate specificity of heparanase

Heparan sulfate is a highly sulfated polysaccharide abundantly present in the extracellular matrix. Heparan sulfate consists of a disaccharide repeating unit of glucosamine and glucuronic and iduronic acid residues. The functions of heparan sulfate are largely dictated by its size as well as the sulfation patterns. Heparanase is an enzyme that cleaves heparan sulfate polysaccharide into smaller fragments, regulating the functions of heparan sulfate. Understanding the substrate specificity plays a critical role in dissecting the biological functions of heparanase and heparan sulfate. The prevailing view is that heparanase recognizes specific sulfation patterns in heparan sulfate. However, emerging evidence suggests that heparanase is capable of varying its substrate specificities depending on the saccharide structures around the cleavage site. The plastic substrate specificity suggests a complex role of heparanase in regulating the structures of heparan sulfate in matrix biology.