Heparan sulfates from Swiss mouse 3T3 and SV3T3 cells: O-sulfate difference

A difference in the extent of sulfation between the heparan sulfate isolated from Swiss 3T3 mouse cells and that from Swiss 3T3 cells transformed by the DNA virus SV40 has been reported previously. This variance is manifested by different chromatographic and electrophoretic properties. Heparan sulfates from the two cell types were treated with nitrous acid under conditions that gave selective deaminative cleavage of glucosaminyl residues with sulfated amino groups in order to define the nature of the difference in sulfation further. The O-sulfate containing fragments from the heparan sulfates were compared by gel filtration and ion-exchange chromatography. The results showed that the 3T3 heparan sulfate contains 8% more O-sulfate than does the SV3T3 heparan sulfate. Analysis of uronic acids revealed that both types of heparan sulfates contain 45% L-iduronic acid and 55% D-glucuronic acid. These and other observations indicate that the primary difference in sulfation between the 3T3 and SV3T3 heparan sulfates lies in the extent of O-sulfation.     

Biosynthesis of glycosaminoglycans in the human colonic tumor cell line Caco-2: structural changes occurring with the morphological differentiation of the cells

The human colon cancer cell line Caco-2 cultured in vitro displayed morphological differentiation which was shown to be a growth-related event. We have investigated this phenomenon further in relation to the cell surface glycosaminoglycans produced by growing (5-day, i.e., prior to differentiation) and confluent (9-day, i.e., after morphological and functional differentiation) cultures. Neosynthesized [35S]glycosaminoglycans were purified on DEAE-cellulose; at confluency, they were bound more strongly to the column than the corresponding fractions from the growing cells. Analysis of Kav values of heparan sulfate and chondroitin sulfates from growing and confluent cells indicated an increase in chain length of both glycosaminoglycans in morphologically differentiated cells. Heparan sulfate was the main 35S-labeled glycosaminoglycan of the cell surface of both 5-day and 9-day cultures. Paper chromatography of the unsaturated disaccharides obtained by chondroitinase digestion showed that chondroitin sulfate chains were primarily 6-sulfated in the 2 studied extracts. Heparan sulfate chains were isolated as chondroitinase-resistant material and treated with nitrous acid. Analysis of N- and O-sulfate group-related radioactivity showed an increase in the amount of 35S-label in the form of N-sulfate groups and an increase in the O-35S-sulfation pattern in heparan sulfate from morphologically differentiated cells. Thus, the structural features of both chondroitin sulfates and heparan sulfate were significantly different when the growing cells became morphologically differentiated.     

The spacing of S-domains on HS glycosaminoglycans determines whether the chain is a substrate for intracellular heparanases

Heparanases are mammalian endoglucuronidases that degrade heparan sulfate (HS) glycosaminoglycans to short 5-6 kDa pieces. In the Golgi, HS glycosaminoglycans are modified by a series of interdependent reactions which result in chains that have regions rich in N- and O-sulfate groups and iduronate residues (S-domains), separated by regions that are nearly devoid of sulfate. Structural analysis of the short HS chains produced by Chinese hamster ovary (CHO) cell heparanases indicate that the enzymes recognize differences in sulfate content between S-domains and unmodified sequences, and cleave the chain at junctions between these regions. To look more closely at whether the spacing of S-domains on the gly- cosaminoglycan influences its ability to be cleaved by heparanases, we examined the susceptibility of the HS chains synthesized by the proteoglycan synthesis mutant, pgsE-606. PGS:E-606 cells are deficient in the modification enzyme N-deacetylase/N-sulfotransferase I, and synthesize HS chains that have fewer N- and O-sulfate groups and iduronate residues compared to wild-type (Bame et al., (1991), J. Biol. Chem., 266, 10287). HS glycosaminoglycans were isolated from wild-type and pgsE-606 cells and separated into populations based on sulfate content. Compared to wild-type HS, which has 14 S-domains, pgsE-606 cells synthesize three HS species, 606-1, 606-2, and 606-3, with 1, 4, and 8 S-domains, respectively. The spacing of the S-domains on the pgsE-606 HS chains is similar to the spacing the modified sequences on wild-type HS, indicating that each mutant glycosaminoglycan is composed of wild-type-like sequences and sequences devoid of S-domains. When incubated with partially purified CHO heparanases, only the portion of the mutant HS chains that had S-domains were degraded. Structural analysis of the heparanase-products confirmed that both the number and the arrangement of S-domains on the HS glycosaminoglycan are important for heparanase susceptibility. The structure of the different pgsE-606 HS chains also suggests mechanisms for the placement of S-domains when the gly- cosaminoglycan is synthesized.     

Glycosaminoglycan production by bovine aortic endothelial cells cultured in sulfate-depleted medium

Bovine aortic endothelial cells were cultured in medium containing [3H]glucosamine and concentrations of [35S]sulfate ranging from 0.01 to 0.31 mM. While the amount of [3H]hexosamine incorporated into chondroitin sulfate and heparan sulfate was constant, decreasing concentrations of sulfate resulted in lower [35S]sulfate incorporation. Sulfate concentrations greater than 0.11 mM were required for maximal [35S]sulfate incorporation. Chondroitin sulfate was particularly affected so that the sulfate to hexosamine ratio in [3H]chondroitin [35S]sulfate dropped considerably more than the sulfate to hexosamine ratio in [3H] heparan [35S]sulfate. Sulfate concentration had no effect on the ratio of chondroitin 4-sulfate to chondroitin 6-sulfate. The ratios of sulfate to hexosamine in cell-associated glycosaminoglycans were essentially identical with the ratios in media glycosaminoglycans at all sulfate concentrations. DEAE-cellulose chromatography confirmed that sulfation of chondroitin sulfate was particularly sensitive to low sulfate concentrations. While cells incubated in medium containing 0.31 mM sulfate produced chondroitin sulfate which eluted later than heparan sulfate, cells incubated in medium containing less than 0.04 mM sulfate produced chondroitin sulfate which eluted before heparan sulfate and near hyaluronic acid, indicating that many chains were essentially unsulfated. At intermediate concentrations of sulfate, chondroitin sulfate was found in very broad elution patterns suggesting that most did not fit an "all or nothing" mechanism. Heparan sulfate produced at low concentrations of sulfate eluted with narrower elution patterns than chondroitin sulfate, and there was no indication of any "all or nothing" sulfation.     

Glycosaminoglycan production in cultures of early and late passage human endothelial cells: the influence of an anionic endothelial cell growth factor and the extracellular matrix

An endothelial cell (EC) growth factor isolated from bovine brain stimulates in vitro growth of human umbilical vein endothelial cells, and permits long term serial propagation. In the presence of increasing concentrations of EC growth factor, confluent cultures of early (CPDL less than or equal to 20) and late (CPDL greater than 20) passage human endothelial cells exhibit an increased incorporation of 3H-glucosamine and Na235SO4 into the glycosaminoglycans (GAG), hyaluronic acid, chondroitin, chondroitin-4-sulfate, dermatan-4-sulfate, and chondroitin-6-sulfate. An increase in both labelled sulfated and nonsulfated GAG was observed in the cytosol, membrane, secreted and extracellular matrix fractions. In contrast, endothelial cells grown in the presence of EC growth factor contained decreased amounts of labelled heparan sulfate than cells grown without EC growth factor. Confluent cultures of early passage cells had significantly more labelled GAG but significantly less heparan sulfate than cultures of late passage cells on a per cell basis. Extracellular matrix from early passage cells contained about two- to seven-fold more labelled GAG than extracellular matrix from late passage cells, but only about half as much labelled heparan sulfate. Cell adhesion was enhanced when cells were grown in the presence of EC growth factor as compared to adhesion of cells grown without EC growth factor. Conversely, trypsin-mediated detachment of cells grown in the presence of growth factor was inhibited as compared to detachment of cells grown in medium without EC growth factor. The composition of the extracellular matrix influenced incorporation of labelled GAG into extracellular matrix. Early passage cells grown to confluence on a matrix from late passage cells incorporated significantly less labelled GAG into extracellular matrix than when grown to confluence on matrix from early passage cells. Incorporation of labelled GAG into extracellular matrix was significantly higher when late passage cells were grown on a matrix from early passage endothelial cells than when grown on matrix from late passage cells. We conclude that EC growth factor selectively stimulates incorporation of isotopic precursors into GAG in cultures of early and late passage endothelial cells but inhibits incorporation of radiolabel into heparan sulfate; early passage cells contain more GAG but less heparan sulfate than late passage cells, extracellular matrix controls the amount of GAG and heparan sulfate incorporated into matrix.(ABSTRACT TRUNCATED AT 400 WORDS)     

Presence of unsulfated heparan chains on the heparan sulfate proteoglycan of human colon carcinoma cells. Implications for heparan sulfate proteoglycan biosynthesis

We provide direct evidence for the presence of unsulfated, but fully elongated heparan glycosaminoglycans covalently linked to the protein core of a heparan sulfate proteoglycan synthesized by human colon carcinoma cells. Chemical and enzymatic studies revealed that a significant proportion of these chains contained glucuronic acid and N-acetylated glucosamine moieties, consistent with N-acetylheparosan, an established precursor of heparin and heparan sulfate. The presence of unsulfated chains was not dependent upon the exogenous supply of sulfate since their synthesis, structure, or relative amount did not vary with low exogenous sulfate concentrations. Culture in sulfate-free medium also failed to generate undersulfated heparan sulfate-proteoglycan, but revealed an endogenous source of sulfate which was primarily derived from the catabolism of the sulfur-containing amino acids methionine and cysteine. Furthermore, the presence of unsulfated chains was not due to a defect in the sulfation process because pulse-chase experiments showed that they could be converted into the fully sulfated chains. However, their formation was inhibited by limiting the endogenous supply of hexosamine. The results also indicated the coexistence of the unsulfated and sulfated chains on the same protein core and further suggested that the sulfation of heparan sulfate may occur as an all or nothing phenomenon. Taken together, the results support the current biosynthetic model developed for the heparin proteoglycan in which unsulfated glycosaminoglycans are first elongated on the protein core, and subsequently modified and sulfated. These data provide the first evidence for the presence of such an unsulfated precursor in an intact cellular system.     

Altered expression of glycosaminoglycans in metastatic 13762NF rat mamma adenocarcinoma cells

A difference in the expression and metabolism of sulfated glycosaminoglycans between rat mammary tumor cells derived from a primary tumor and those from its metastatic lesions has been observed. Cells from the primary tumor possessed about equal quantities of chondroitin sulfate and heparan sulfate on their cell surfaces but released fourfold more chondroitin sulfate than heparan sulfate into their medium. In contrast, cells from distal metastatic lesions expressed approximately 5 times more heparan sulfate than chondroitin sulfate in both medium and cell surface fractions. This was observed to be the result of differential synthesis of the glycosaminoglycans and not of major structural alterations of the individual glycosaminoglycans. The degree of sulfation and size of heparan sulfate were similar for all cells examined. However, chondroitin sulfate, observed to be only chondroitin 4-sulfate, from the metastases-derived cells had a smaller average molecular weight on gel filtration chromatography and showed a decreased quantity of sulfated disaccharides upon degradation with chondroitin ABC lyase compared to the primary tumor derived cells. Major qualitative or quantitative alterations were not observed for hyaluronic acid among the various 13762NF cells. The metabolism of newly synthesized sulfated glycosaminoglycans was also different between cells from primary tumor and metastases. Cells from the primary tumor continued to accumulate glycosaminoglycans in their medium over a 72-h period, while the accumulation of sulfated glycosaminoglycans in the medium of metastases-derived cells showed a plateau after 18-24 h. A pulse-chase kinetics study demonstrated that both heparan sulfate and chondroitin sulfate were degraded by the metastases-derived cells, whereas the primary tumor derived cells degraded only heparan sulfate and degraded it at a slower rate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Tyrosine O-sulfation of the fibrinogen gamma B chain in primary cultures of rat hepatocytes

Sulfation of fibrinogen was studied in a primary culture of rat hepatocytes. After cells were incubated with [35S]sulfate, 35S-labeled fibrinogen was obtained from the medium by immunoprecipitation and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis/fluorography. It was demonstrated that [35S]sulfate is exclusively incorporated into the gamma B chain, which is a minor variant form found in rat fibrinogen, in addition to a major gamma A chain. When the purified 35S-gamma B chain was digested with carboxypeptidase Y, the radioactivity was almost completely released from the protein, and the labeled product released was identified as tyrosine O-sulfate. Based on the available primary structure of the gamma B chain, the results suggest that sulfation occurs on the tyrosine residue at the second position from its COOH terminus. Pulse-chase experiments using both [3H]leucine and [35S]sulfate showed that 35S-labeled fibrinogen is secreted into the medium much faster than the 3H-labeled molecule. Incubation of cells with monensin, an inhibitor of Golgi function, strongly inhibited the sulfation of fibrinogen. In addition, in vitro sulfation experiments demonstrated that sulfotransferase activity is localized in the Golgi fraction. These results indicate that the sulfation of fibrinogen takes place in the Golgi complex, especially in the trans Golgi region, just before its secretion.     

Undersulfated heparan sulfate in a Chinese hamster ovary cell mutant defective in heparan sulfate N-sulfotransferase

Heparan sulfate N-sulfotransferase catalyzes the transfer of sulfate groups from adenosine 3'-phosphate, 5'-phosphosulfate to the free amino groups of glucosamine residues in heparan sulfate. We have identified a Chinese hamster ovary cell mutant, designated pgsE-606, which is 3-5-fold defective in N-sulfotransferase activity. The residual enzyme activity is indistinguishable from the wild-type enzyme with respect to Km values for adenosine 3'-phosphate,5'-phosphosulfate and N-desulfoheparin, pH dependence, Arrhenius activation energy, and thermal lability. The mutation is recessive, and mixing experiments indicate that the mutant does not produce soluble antagonists of N-sulfotransferase. Inspection of the heparan sulfate chains from the mutant showed that the extent of N-sulfation is reduced about 2-3-fold. The addition of sulfate to hydroxyl groups on the chain is reduced to a similar extent, suggesting that N-sulfation and O-sulfation are normally coupled. Nitrous acid fragmentation of the chains showed that N-sulfated glucosamine residues are spaced much less frequently than in heparan sulfate from wild-type cells. The close correlation of enzyme activity to the number and position of N-sulfate groups indicates that N-sulfotransferase plays a pivotal role in determining the extent of sulfation of heparan sulfate.     

Effect of chlorate on the sulfation of lipoprotein lipase and heparan sulfate proteoglycans. Sulfation of heparan sulfate proteoglycans affects lipoprotein lipase degradation

In avian-cultured adipocytes 76% of the newly synthesized lipoprotein lipase is degraded before release into the medium (Cupp, M., Bensadoun, A., and Melford, K. (1987) J. Biol. Chem. 262, 6383-6388). The same group (Cisar, L. A., Hoogewerf, A. J., Cupp, M., Rapport, C. A., and Bensadoun, A. (1989) J. Biol. Chem. 264, 1767-1774) has proposed that the interaction of lipoprotein lipase with a class of cell surface heparan sulfate proteoglycans is necessary for degradation to occur. To test further this hypothesis, the binding capacity of the plasma membrane for the lipase was decreased by inhibiting the sulfation of glycosaminoglycans with sodium chlorate, an inhibitor of sulfate adenyltransferase. Chlorate decreased sulfate incorporation into trypsin-releasable heparan sulfate proteoglycans to 20% of control levels. The amount of uronic acid in the trypsin-releasable heparan sulfate proteoglycans remained constant. Therefore, chlorate decreased sulfation density on heparan sulfate chains by approximately 5-fold. In the same fractions, chlorate increased the median heparan sulfate Mr measured on Sephacryl S-300. Chlorate decreased the maximum binding of 125I-lipoprotein lipase to adipocytes by 4-fold, but no significant effects on the affinity constants were observed. Chlorate increased lipoprotein lipase secretion in a dose-dependent relationship up to 30 mM. Utilizing a pulse-chase protocol, it was shown that lipase synthesis in control and chlorate-treated cells was not significantly different and that the increased secretion could be accounted for by a decreased lipoprotein lipase degradation rate. In control cells 77 +/- 11% of the synthesized enzyme was degraded whereas in chlorate-treated cells degradation was reduced to 42 +/- 9% of the synthesized amount. The present study shows that decreased sulfation of heparan sulfate proteoglycans decreases the maximum binding of the lipase for the adipocyte cell surface. Consistent with the model that binding of lipoprotein lipase to cell surface heparan sulfate is required for lipase degradation, degradation is reduced in chlorate-treated cultures. In this report it is also shown that chlorate inhibits lipoprotein lipase sulfation and that desulfation of the enzyme has no effect on its catalytic efficiency or on its binding to cultured adipocytes.     

Transformed mouse mammary epithelial cells synthesize undersulfated basement membrane proteoglycan

Proteoglycans deposited in the basal lamina of [14C] glucosamine-labeled normal and [3H]glucosamine-labeled transformed mouse mammary epithelial cells grown on type I-collagen gels, were extracted in 4 M guanidinium chloride and cofractionated over Sepharose CL 4B. The heparan sulfate chains carried by these proteoglycans were isolated by treatment with alkaline borohydride, protease K, chondroitinase ABC, and cetylpyridinium chloride precipitation. Heparan sulfate isolated from transformed cell cultures consistently eluted from DEAE-cellulose at lower salt concentrations and was of smaller apparent Mr when chromatographed over Sepharose CL 6B, than heparan sulfate of normal cell cultures. Experiments using doubly labeled cultures ([3H]glucosamine and [35S]sulfate) demonstrated an approximately 30% reduction in the sulfate/hexosamine ratio in heparan sulfate derived from transformed cultures. Both N- and O-sulfate were decreased. The decreased Mr and decreased sulfation of heparan sulfate upon transformation appear sufficient to explain the altered heparan sulfate/chondroitin sulfate ratios previously observed in these cells. These changes may have implications for the molecular interactions in which these proteoglycans are normally engaged during basal lamina assembly, and cause the poor basal lamina formation displayed by these transformed cells.     

Heparan sulfate fine structure and specificity of proteoglycan functions

Heparan sulfate chains have markedly heterogeneous structures in which distinct patterns of sulfation determine the binding specificity for ligand proteins. These "fine structures" of heparan sulfate are mainly produced by the regulated introduction of sulfate groups at the N-, 2-O-, 6-O-, and 3-O-positions of the sugar chain. Recent biochemical, histochemical, and genetic studies have demonstrated that different fine structures mediate distinct molecular recognition events to regulate a variety of cellular functions. In this review, we focus on the molecular basis of growth factor control by the sulfation status of heparan sulfate.     

A peptide found by phage display discriminates a specific structure of a trisaccharide in heparin

A number of recent studies have shown that heparan sulfate can control several important biological events on the cell surface through changes in sulfation pattern. The in vivo modification of sugar chains with sulfates, however, is complicated, and the discrimination of different sulfation patterns is difficult. Heparin, which is primarily produced by mast cells, is closely approximated by the structural analog heparan sulfate. Screening of heparin-associating peptides using phage display and antithrombin-bound affinity chromatography identified a peptide, heparin-associating peptide Y (HappY), that acts as a target of immobilized heparin. The peptide consists of 12 amino acid residues with characteristic three arginines and exclusively binds to heparin and heparan sulfate but does not associate with other glycosaminoglycans. HappY recognizes three consecutive monosaccharide residues in heparin through its three arginine residues. HappY should be a useful probe to detect heparin and heparan sulfate in studies of glycobiology.     

Structural diversity of N-sulfated heparan sulfate domains: distinct modes of glucuronyl C5 epimerization, iduronic acid 2-O-sulfation, and glucosamine 6-O-sulfation

The N-sulfated regions (NS domains) represent the modified sequences of heparan sulfate chains and mediate interactions of the polysaccharide with proteins. We have investigated the relationship between the type/extent of polymer modification and the length of NS domains in heparan sulfate species from human aorta, bovine kidney, and cultured NMuMG and MDCK cells. C5 epimerization of D-glucuronic acid to L-iduronic acid was found to be extensive and essentially similar in all heparan sulfate species studied, regardless of domain size, whereas the subsequent 2-O-sulfation of the formed iduronic acid residues varies appreciably. In aorta heparan sulfate, up to 90% of the formed iduronate residues were 2-O-sulfated, whereas in kidney heparan sulfate 2-O-sulfation occurred only in 相似文献   

Is there a glycosaminoglycan-related heterogeneity of the thymic epithelium?

We determined the synthesis and secretion of glycosaminoglycans by three distinct preparations of mouse cultured thymic epithelial cells. These comprised primary cultures of thymic nurse cells (TNCs), which are normally located within the cortex of the thymic lobules, as well as two murine thymic epithelial cells, bearing a mixed, yet distinct, cortico-medullary phenotype. We first identified and measured the relative proportions of the various glycosaminoglycans in the three epithelial cells. Non-sulfated glycosaminoglycans are preponderantly secreted by the TNCs, while the sulfated glycans (particularly heparan sulfate) are relatively more abundant on the cell surface. The three types of epithelial cells differ markedly in their heparan sulfate composition, mainly due to different patterns of N- and O-sulfation. In addition, the cells differ in the synthesis and secretion of other glycosaminoglycans. Thus, TNCs secrete high amounts of dermatan sulfate + chondroitin sulfate to the culture medium. IT-76M1 cells secrete high proportions of heparan sulfate while 2BH4 cells show a more equilibrated proportion of dermatan sulfate/chondroitin sulfate and heparan sulfate. The three epithelial cells also differ in their capacity to produce hyaluronic acid and 2BH4 cells are distinguished by their high rate of synthesis of this glycosaminoglycan. In conclusion, our results show that distinct thymic epithelial cells can synthesize different types of glycosaminoglycans. Although it remains to be definitely determined whether these differences reflect the in vivo situation, our data provide new clues for further understanding of how glycosaminoglycan-mediated interactions behave in the thymus.     

Inhibition by 5-bromo-2'-deoxyuridine of differentiation-dependent changes in glycosaminoglycans of the retina.

Embryonic chick neural retinas incorporated radio-labeled precursors into glycosaminoglycans in the same relative amounts whether cultured as intact tissues, cell aggregates, or monolayers. Incubation with 5-bromo-2′-deoxyuridine inhibited histogenesis and caused the pattern of synthesis to remain more like that in undifferentiated tissue, when compared with controls without this nucleoside analog. This was determined by the level of incorporation and the ratios of chondroitin sulfate to heparan sulfate and chondroitin-4-sulfate to chondroitin-6-sulfate incorporation. Incubation with 4-methylumbelliferyl-β-D-xylopyranoside stimulated synthesis and release of chondroitin sulfate and heparan sulfate into the medium. The results taken together imply that the production of specific glycosaminoglycans during the course of differentiation in the retina is regulated at the gene level in parallel with histogenesis in this tissue.     

Characterization of Slit protein interactions with glypican-1

We have demonstrated previously that the Slit proteins, which are involved in axonal guidance and related developmental processes in nervous tissue, are ligands of the glycosylphosphatidylinositol-anchored heparan sulfate proteoglycan glypican-1 in brain (Liang, Y., Annan, R. S., Carr, S. A., Popp, S., Mevissen, M., Margolis, R. K., and Margolis, R. U. (1999) J. Biol. Chem. 274, 17885--17892). To characterize these interactions in more detail, recombinant human Slit-2 protein and the N- and C-terminal portions generated by in vivo proteolytic processing were used in an enzyme-linked immunosorbent assay to measure the binding of a glypican-Fc fusion protein. Saturable and reversible high affinity binding to the full-length protein and to the C-terminal portion that is released from the cell membrane was seen, with dissociation constants in the 80-110 nm range, whereas only a relatively low level of binding to the larger N-terminal segment was detected. Co-transfection of 293 cells with Slit and glypican-1 cDNAs followed by immunoprecipitation demonstrated that these interactions also occur in vivo, and immunocytochemical studies showed colocalization in the embryonic and adult central nervous system. The binding affinity of the glypican core protein to Slit is an order of magnitude lower than that of the glycanated proteoglycan. Glypican binding to Slit was also decreased 80--90% by heparin (2 microg/ml), enzymatic removal of the heparan sulfate chains, and by chlorate inhibition of glypican sulfation. The differential effects of N- or O-desulfated heparin on glypican binding also indicate that O-sulfate groups on the heparan sulfate chains play a critical role in heparin interactions with Slit. Our data suggest that glypican binding to the releasable C-terminal portion of Slit may serve as a mechanism for regulating the biological activity of Slit and/or the proteoglycan.     

Sulfate transport-deficient mutants of Chinese hamster ovary cells. Sulfation of glycosaminoglycans dependent on cysteine

We isolated 59 Chinese hamster ovary cell mutants defective in 35SO4 incorporation into glycosaminoglycans. Thirty-five mutants incorporated [6-3H]glucosamine into glycosaminoglycans normally, suggesting that they were specifically impaired in sulfate incorporation. Cell hybridization studies revealed that the 35 mutants defined a unique complementation group. Pulse-labeling one of the mutants with 35SO4 showed that it possessed a defect in a saturable, 4-acetamido-4-isothiocyanostilbene-2,2'-disulfonic acid-sensitive transport system required for sulfate uptake. Despite the dramatic reduction in 35SO4 incorporation, the mutant synthesized sulfated heparan and chondroitin chains. Incubation of the mutant with [35S]cysteine resulted in the formation of 35SO4, which was subsequently incorporated into the glycosaminoglycans. Similar results were obtained when wild-type cells were incubated in sulfate-free growth medium containing [35S]cysteine, and isotope dilution analysis indicated that about 15 microM of sulfate was derived from cysteine catabolism. We also found that the sulfate transport deficiency rendered the mutant resistant to 5 microM sodium chromate, whereas wild-type cells did not divide under these conditions. However, the mutant also did not proliferate in medium containing 5 microM chromate when grown in the presence of wild-type cells, suggesting that chromate was transported through cell-cell contacts. Since co-cultivating sulfate transport-deficient mutants with mutants defective in xylosyltransferase or galactosyltransferase I partially restored 35SO4 incorporation into glycosaminoglycans, intercellular sulfate transport occurred as well. Therefore, the availability of sulfate for glycosaminoglycan synthesis depends on sulfate uptake, turnover of sulfur-containing amino acids, and sulfate transport between cells.     

Highly sulfated glycosaminoglycans inhibit aggrecanase degradation of aggrecan by bovine articular cartilage explant cultures.

The catabolism of 35S-labeled aggrecan and loss of tissue glycosaminoglycans was investigated using bovine articular cartilage explant cultures maintained in medium containing 10(-6) M retinoic acid or 40 ng/ml recombinant human interleukin-1alpha (rHuIL-1alpha) and varying concentrations (1-1000 microg/ml) of sulfated glycosaminoglycans (heparin, heparan sulfate, chondroitin 4-sulfate, chondroitin 6-sulfate, dermatan sulfate and keratan sulfate) and calcium pentosan polysulfate (10 microg/ml). In addition, the effect of the sulfated glycosaminoglycans and calcium pentosan polysulfate on the degradation of aggrecan by soluble aggrecanase activity present in conditioned medium was investigated. The degradation of 35S-labeled aggrecan and reduction in tissue levels of aggrecan by articular cartilage explant cultures stimulated with retinoic acid or rHuIL-1alpha was inhibited by heparin and heparan sulfate in a dose-dependent manner and by calcium pentosan polysulfate. In contrast, chondroitin 4-sulfate, chondroitin 6-sulfate, dermatan sulfate and keratan sulfate did not inhibit the degradation of 35S-labeled aggrecan nor suppress the reduction in tissue levels of aggrecan by explant cultures of articular cartilage. Heparin, heparan sulfate and calcium pentosan polysulfate did not adversely affect chondrocyte metabolism as measured by lactate production, incorporation of [35S]-sulfate or [3H]-serine into macromolecules by articular cartilage explant cultures. Furthermore, heparin, heparan sulfate and calcium pentosan polysulfate inhibited the proteolytic degradation of aggrecan by soluble aggrecanase activity. These results suggest that highly sulfated glycosaminoglycans have the potential to influence aggrecan catabolism in articular cartilage and this effect occurs in part through direct inhibition of aggrecanase activity.     

Heparan sulfate chains from glypican and syndecans bind the Hep II domain of fibronectin similarly despite minor structural differences

Numerous functions of heparan sulfate proteoglycans are mediated through interactions between their heparan sulfate glycosaminoglycan chains and extracellular ligands. Ligand binding specificity for some molecules, including many growth factors, is determined by complex heparan sulfate fine structure, where highly sulfated, iduronate-rich domains alternate with N-acetylated domains. Syndecan-4, a cell surface heparan sulfate proteoglycan, has a distinct role in cell adhesion, suggesting its chains may differ from those of other cell surface proteoglycans. To determine whether the specific role of syndecan-4 correlates with a distinct heparan sulfate structure, we have analyzed heparan sulfate chains from the different surface proteoglycans of a single fibroblast strain and compared their ability to bind the Hep II domain of fibronectin, a ligand known to promote focal adhesion formation through syndecan-4. Despite distinct molecular masses of glypican and syndecan glycosaminoglycans and minor differences in disaccharide composition and sulfation pattern, the overall proportion and distribution of sulfated regions and the affinity for the Hep II domain were similar. Therefore, adhesion regulation requires core protein determinants of syndecan-4.