Heparan/chondroitin/dermatan sulfate primer 2-(6-hydroxynaphthyl)-O-beta-D-xylopyranoside preferentially inhibits growth of transformed cells.

Xylose forms the direct carbohydrate-protein link in extra- or pericellular proteoglycans (PGs) that are substituted with either chondroitin sulfate (CS)/dermatan sulfate (DS) and/or heparan sulfate (HS). Cell surface PGs carrying HS are important regulators of cell growth. Xylose coupled to an aromatic compound can enter cells and initiate either CS/DS synthesis or both HS and CS/DS synthesis, depending on the nature of the aromatic adduct. Here, we show that 2-(6-hydroxynaphthyl)-O-beta-D-xylopyranoside, which can prime both types of glycan chains, inhibits growth of a set of normal and transformed cells. Transformed cells are preferentially inhibited, and at a concentration of 0.15-0.20 mM xyloside, transformed cells are totally growth arrested, whereas normal cells are only < or = 50% inhibited. No inhibition of growth is observed with the stereoisomeric 2-(6-hydroxynaphthyl)-O-beta-L-xylopyranoside, which does not prime glycosaminoglycan synthesis at all; with the nonhydroxylated 2-naphthyl-O-beta-D-xylopyranoside, which only primes CS/DS synthesis under these conditions; or with p-nitrophenyl-O-beta-D-xylopyranoside, which is known to prime only CS/DS synthesis. We conclude that growth inhibition is due to priming of HS and/or CS/DS synthesis, which may either lead to the formation of specific antiproliferative glycans or glycan fragments or to interference with endogenous PG synthesis and turnover.

Effects of primer-concentration on uronosyl-epimerization and sulfation patterns in p-hydroxyphenyl-O-beta-D-xylopyranoside-primed galactosaminoglycans produced by skin fibroblasts.

By supplying skin fibroblasts with different concentrations of the galactosaminoglycan chain-primer p-hydroxyphenyl-O-beta-D-xylopyranoside we have produced and recovered glycan-chains that were subsequently radio-iodinated in the hydroxyphenyl group and subjected to sequence analysis by using graded enzymic treatment followed by a combination of gel chromatography and electrophoresis. Fragments extending from the tagged reducing end to the cleavage-point were identified and quantified. Degradation by chondroitin B lyase of chains primed at 0.1 or 0.5 mM xyloside gave profiles indicating a periodic and wave-like distribution of iduronate-containing repeats, with high incidence around positions 2, 5 and onwards, whereas in chains produced at 1.0 mM xyloside the incidence of iduronate was similar in positions 1-4 and then declined. Degradation by chondroitin AC lyase indicated a high incidence of glucuronate in or near the linkage-region. There was a relatively uniform degree of sulfation in chains primed at low xyloside concentration, whereas chains primed at 1.0 mM xyloside gave very heterogeneous charge-patterns in all segments of the chain, including the linkage-region, giving the impression that adequate sulfation, probably at C-4 and at the first opportunity, is necessary to obtain an ordered and periodic epimerization pattern.

Glypican (heparan sulfate proteoglycan) is palmitoylated, deglycanated and reglycanated during recycling in skin fibroblasts.

Skin fibroblasts treated with brefeldin A produce a recycling variant of glypican (a glycosylphosphatidylinositolanchored heparan-sulfate proteoglycan) that is resistant to inositol-specific phospholipase C and incorporates sulfate and glucosamine into heparan sulfate chains (Fransson, L.-A. et al., Glycobiology, 5, 407-415, 1995). We have now investigated structural modifications of recycling glypican, such as fatty acylation from [3H]palmitate, and degradation and assembly of heparan sulfate side chains. Most of the 3H-radioactivity was recovered as lipid-like material after de-esterification. To distinguish between formation of heparan sulfate at vacant sites, elongation of existing chains or degradation followed by re-elongation of chain remnants, cells were pulse-labeled with [3H]glucosamine and then chase-labeled with [14C]glucosamine. Material isolated from the cells during the chase consisted of proteoglycan and mostly [3H]-labeled heparan-sulfate degradation products (molecular mass, 20-80 kDa) showing that the side chains were degraded during recycling. The degradation products were initially glucuronate-rich, but became more iduronate-rich with time. The glypican proteoglycan formed during the chase was degraded either with alkali to release intact side chains or with heparinase to generate distally located chain fragments that were separated from the core protein, containing the proximally located, covalently attached chain remnants. All of the [14C]-radioactivity incorporated during the pulse was found in peripheral chain fragments, and the chains formed were not significantly longer than the original ones. We therefore conclude that newly made heparan-sulfate chains were neither made on vacant sites, nor by extension of existing chains but rather by re-elongation of degraded chain remnants. The remodeled chains made during recycling appeared to be more extensively modified than the original ones.

Heparan sulphate/heparin glycosaminoglycans with strong affinity for the growth-promoter spermine have high antiproliferative activity.

Depletion of intracellular polyamine pools inhibits cell proliferation. Polyamine pools are maintained by intracellular synthesis and by uptake from the extracellular environment. It may be expected that cationic polyamines are sequestered by the polyanionic glycosaminoglycan substituents of extracellular proteoglycans. Moreover, highly sulphated heparin-related glycans inhibit growth of human embryonic lung fibroblasts. We have therefore investigated interactions between polyamines and heparin-related glycosaminoglycans. Affinity chromatography of various polyamines on heparin-agarose indicated that spermine was the only polyamine that bound efficiently to this type of glycan. By using equilibrium dialysis we found that spermine binds to a highly sulphated heparan sulphate/heparin preparation with a dissociation constant of 3.7 x 10(-5)M. Enzymatic degradation of heparan sulphate using three different heparan sulphate/heparin lyases, separately or in combination and in the absence or presence of spermine, was used to generate spermine-binding and degradation-protected oligosaccharides. As indicated by chromatographic and electrophoretic analysis a size- and chargeheterogeneous collection was obtained. However, protected oligosaccharides derived from antiproliferative heparan sulphates were inactive. Highly sulphated, antiproliferative heparan sulphates were subfractionated on spermine-agarose yielding high-affinity material with increased antiproliferative activity. A very potent material was obtained from pig skin. Although there was generally a clear correlation between high spermine-affinity and strong growth-inhibition, no correlation with sulphate content or oligosaccharide mapping patterns could be detected. Beef lung heparan sulphate comprised naturally occurring fragments of eicosasaccharide size with substantially increased specific activity. As these fragments were longer than oligosaccharides generated by enzymatic degradation in the presence of spermine (hexa- to tetradecasaccharide), multiple spermine-binding sites in tandem may be necessary to induce antiproliferative activity.

Recycling of a glycosylphosphatidylinositol-anchored heparan sulphate proteoglycan (glypican) in skin fibroblasts.

We have used suramin and brefeldin A to investigate the nature of a heparan sulphate proteoglycan that appears to recycle from the cell surface to intracellular compartments which synthesize new heparan sulphate chains. Suramin, which would block internalization and deglycanation of a putative recycling cell surface proteoglycan, markedly increases the yield of a membrane-bound proteoglycan with a core protein of 60-70 kDa and unusually long heparan sulphate side chains. When transport of newly made core proteins to their Golgi sites for glycosaminoglycan assembly is blocked, by using brefeldin A, [3H]glucosamine and [35S]sulphate incorporation into cell surface-bound heparan sulphate proteoglycan can still take place. After chemical biotinylation of cell surface proteins in brefeldin A-treated cells, followed by metabolic [35S]sulphation in the presence of the same drug, biotin-tagged [35S]proteoglycan can be demonstrated, indicating the presence of recycling proteoglycan species. By pre-labelling cells with [3H]leucine or [3H]inositol in the presence of suramin, followed by chase labelling with [35S]sulphate in the presence of brefeldin A, a 3H- and 35S-labelled, hydrophobic heparan sulphate proteoglycan with a core protein of 60-65 kDa is obtained. The proteoglycan loses its hydrophobicity when glucosamine-inositol bonds are cleaved, indicating that it is membrane bound via a glycosylphosphatidylinositol anchor. However, treatment with phosphatidylinositol-specific phospholipase C has no effect, suggesting that the inositol moiety may be acylated. We propose that a portion of the lipid-anchored proteoglycan glypican is internalized, recycled via the Golgi, where heparan sulphate chains are added, and finally re-deposited at the cell surface.

Sequence analysis of p-hydroxyphenyl-O-beta-D-xyloside initiated and radio-iodinated dermatan sulfate from skin fibroblasts.

To generate xyloside-primed dermatan sulfate suitable for sequence analysis, skin fibroblasts were incubated with p-hydroxyphenyl-beta-D-xylopyranoside and [3H]galactose, and free [3H]glycosaminoglycan chains were isolated from the culture medium by ion exchange and gel chromatography. After 125I labelling of their reducing-terminal hydroxyphenyl groups, chains were subjected to various chemical and enzymatic degradations, both partial and complete, followed by gradient polyacrylamide gel electrophoresis and autoradiographic identification of fragments extending from the labelled reducing-end to the point of cleavage. Results of periodate oxidation-alkaline scission indicated that the xylose moiety remained unsubstituted at C-2/C-3; exhaustive treatment with chondroitin AC-I lyase afforded the fragment delta HexA-Gal-Gal-Xyl-R (R = radio-iodinated hydroxyphenyl group), and complete degradations with chondroitin ABC lyase as well as testicular hyaluronidase yielded the fragments delta HexA/HexA-GalNAc-GlcA-Gal-Gal-Xyl-R with or without sulfate on the N-acetylgalactosamine. Partial digestions with testicular hyaluronidase or chondroitin B lyase indicated that glucuronic acid was common in the first three repeats after the linkage region and that iduronic acid could occupy any position thereafter. Hence, there were no indications of a repeated, periodic appearance of the clustered GlcA-GalNAc repeats which was previously observed in proteoglycan derived dermatan sulfate [Fransson L-A, Havsmark B, Silverberg I (1990) Biochem J 269:381-8], suggesting a role for the protein part in controlling the formation of particular copolymeric features during glycosaminoglycan assembly.

A method for the sequence analysis of dermatan sulphate.

We are attempting to develop methods for the sequencing of glycosaminoglycans from their reducing end. Here we describe a procedure for the analysis of dermatan sulphate from pig skin. The glycosaminoglycan is released from its parent proteoglycan by exhaustive proteolysis by using both endo- and exo-peptidases. The amino group of the residual serine residue is conjugated with a p-hydroxyphenyl group, which in turn is iodinated with 125I (the Bolton-Hunter reagent, BHR). The ion-exchange-purified end-labelled dermatan sulphate is then degraded partially or completely by various enzymic or chemical means to yield fragments extending from the labelled serine residue to the point of cleavage. The various products are separated by gradient PAGE, detected by autoradiography and quantified by videodensitometry. Complete digestion with chondroitin ABC lyase affords the labelled fragment delta HexA-GalNAc(-SO4)-GlcA-Gal-Gal-Xyl-Ser(-BHR). The structure was confirmed by sequential degradation from the non-reducing end by chondroitin AC lyase, HgCl2, and beta-galactosidase. Periodate oxidation cleaves most of the Xyl even without treatment with alkaline phosphatase, showing that Xyl is not substituted with phosphate. Results from partial and selective periodate oxidation indicate that most of the non-sulphated IdoA residues are located towards the non-reducing end. Partial or complete digestions with testicular hyaluronidase (in the presence of an excess of beta-glucuronidase) or chondroitin AC lyase identify the positions of GlcA residues. The results confirm that HexA next to Gal is always GlcA. Moreover, GlcA is common in the first three disaccharide repeats. Results with testicular hyaluronidase indicate that the distribution of clustered GlcA-GalNAc repeats is periodic and peaks at positions 1-3, 8-9 and around 25. Although there must be chains that contain IdoA in nearly all of the available positions, regions that have not been fully processed during biosynthesis are markedly non-random.

Structural requirements for heparan sulphate self-association.

To investigate heparan sulphate self-association, various sub-fractions of beef-lung heparan sulphate have been subjected to affinity chromatography on heparan sulphate-agarose. A particular variant of heparan sulphate was chiefly bound to matrices substituted with the same or cognate heparan sulphates. N-desulphation and N-acetylation abolished the chain-chain interaction. Also, dermatan sulphates and chondroitin sulphates showed affinity for heparan sulphate-agarose. [3H]Heparan sulphates that were bound to a heparan sulphate-agarose were desorbed by elution with the corresponding heparan sulphate chains and also with unrelated heparan sulphates, heparin, and the galactosaminoglycans to various degrees. However, the corresponding heparan sulphate species was the most efficient at low concentrations. Dextran sulphate was unable to desorb bound heparan sulphate. When the corresponding heparan sulphate was N-desulphated/N-acetylated, carboxyl-reduced, or periodate-oxidised (D-glucuronate), the modified polymer was unable to displace [3H]heparan sulphate from heparan sulphate-agarose. The displacing ability of heparin was also destroyed by periodate oxidation. It is concluded that self-interaction between heparan sulphate chains is strongly dependent on the overall molecular conformation. The N-sulphate and carboxylate groups as well as the integrity of the D-glucuronate residue are all essential for maintaining the proper secondary structure.

Structural differences between beef-lung heparan sulphates with specific self-associations.

Three, specifically self-associating variants of heparan sulphate (HS2-A, HS3-A, and HS4-A) from beef lung were subjected to (a) deaminative cleavage of bonds between 2-deoxy-2-sulphoaminoglucose and uronic acid and (b) periodate oxidation of glucuronic acid residues in fully N-acetylated block-regions. In addition, the periodate-oxidised and alkali-cleaved chains were re-oxidised with periodate to identify the glucuronic acid residues in the N-sulphate-containing regions. The results showed that HS2-A was distinguished by much longer (GlcA-GlcNAc)n-segments than HS3-A and HS4-A. The latter two species were characterised by the structure of the variously N-acetyl- and N-sulphate-containing regions. In HS3-A, there was a significant contribution from segments composed of both N-acetylated and N-sulphated 2-amino-2-deoxyglucose residues. The N-sulphate-rich regions contained chiefly iduronic acid. In contrast, HS4-A had mixed or alternating arrangements of the two epimeric uronic acids in the N-sulphate-rich regions. These differences may be the basis for specific self-associations between heparan sulphate chains.

Co-polymeric glycosaminoglycans in transformed cells. Transformation-dependent changes in the co-polymeric structure of heparan sulphate.

1. Heparan sulphates from normal 3T3 fibroblasts are association-prone as indicated by their affinity for agarose gels substituted with cognate heparan sulphate species. Heparan sulphates from SV40-transformed or polyoma-virus-transformed cells have no affinity for the same gels. 2. Heparan sulphates from the medium, the pericellular and intracellular pools of normal, SV40-transformed and polyoma-transformed 3T3 cells were separated into four subfractions (HS1-HS4) by ion-exchange chromatography. In general, HS1-HS3 were found in cell-derived heparan sulphates, whereas HS3-HS4 were present in the medium. The heparan sulphates from transformed cells were more heterogeneous and of lower charge density than those from the normal counterpart. 3. Degradations via periodate oxidation/alkaline elimination yielded the oligomers glucosamine-(hexuronate-glucosamine)(n)-R with n=1-5 and a large proportion of N-sulphate groups. There was a large contribution of fragments n=4-5 from heparan sulphates of normal cells. These fragments were less common in low-sulphated heparan sulphates of transformed cells. In the case of medium-drived heparan sulphates all species had a low content of fragments n=4-5. 4. The size distribution of (glucuronate-N-acetylglucosamine)(n) regions was assessed after deaminative cleavage. It was broad and ranged from n=1-10 for all heparan sulphate species. In the case of medium-derived heparan sulphates there were distinct differences between normal and transformed cells. In the latter chains the N-acetyl-rich segments were both shorter and longer than in the normal case. The shape of the disaccharide peak was consistent with a lower content of O-sulphate in the heparan sulphates from transformed cells. 5. It was concluded that heparan sulphates from medium or transformed cells exhibit the greatest structural deviation from the normal case. The finding of lower proportions of extended, iduronate/glucuronate-bearing, N-sulphate-rich segments in heparan sulphates of transformed cells was particularly interesting in view of the fact that these elements have been associated with ability to self-interact.

Self-association of heparan sulfate. Demonstration of binding by affinity chromatography of free chains on heparan sulfate-substituted agarose gels.

We have developed an affinity chromatography procedure which measures binding of heparan sulfate species to agarose gels substituted with different heparan sulfates. Three major subfractions of bovine lung heparan sulfate (HS2, HS3, and HS4) which differ in sulfate content and hexuronate composition have been used. Association-prone variants of these species (HS2-A, HS3-A, and HS4-A) were prepared by gel chromatography. Free heparan sulfate chains were applied to columns of various heparan sulfate-agaroses which were eluted with a linear guanidine gradient and binding was assessed by measuring the hexuronate content of the effluent. Associating heparan sulfate of a particular subfraction was chiefly bound to gels that were substituted with chains of the same kind, i.e. HS2-A to HS2-A-agarose, HS3-A and HS4-A to HS3-A-agarose, and HS4-A to HS4-A-agarose. N-Desulfation and N-acetylation of HS2-A markedly reduced binding to HS2-A-agarose and periodate oxidation of glucuronate in HS3-A completely abolished binding to HS3-A-agarose. Partially oxidized HS2-A was separated into bound and unbound material by affinity chromatography on HS2-A-agarose. Gel chromatography of these fractions indicated that unbound chains were significantly smaller than bound ones. It is concluded that association between heparan sulfate chains may be quite specific and that the strength of binding is dependent on co-operative interactions between a number of contact zones. The latter may correspond to the N-sulfated and iduronate- and glucuronate-containing segments.

Structural studies on heparan sulphates. Characterization of oligosaccharides; obtained by periodate oxidation and alkaline elimination.

Three heparan sulphate fractions were subjected to degradation by periodate oxidation and alkaline elimination. The starting materials were one low-sulphated fraction rich in glucuronic acid and N-acetylglucosamine (I), one fraction (IV) that was medium-sulphated, contained similar proportions of N-acetyl and N-sulphate as well as of glucuronic and iduronic acid and one fraction (V) that was oversulphated, contained an excess of N-sulphate and was rich in iduronic acid. Selective periodate oxidation of glucuronic acid residues within N-acetylated regions followed by scission in alkali yielded three categories of fragments that were isolated by gel and ion-exchange chromatography. (a) N-Acetylglucosamine-R compounds where R is the remnant of an oxidised and degraded glucuronic acid residue. (b) Medium-sized oligosaccharides, of the general structure glucosamine-(glycuronic acid-glucosamine)n-R where n = 1--4, contained largely glucuronic acid associated with glucosamines that were N-sulphated, N-acetylated or unsubstituted. In saccharides where n = 4 indications of an alternating arrangement of N-sulphate and N-acetyl groups as well as of iduronic and glucuronic acid residues were obtained. The glucuronic acid residues of the oligosaccharide fragments were susceptible to reoxidation with periodate. The smaller saccharides were not depolymerised by HNO2 despite the presence of N-sulphate groups. (c) Longer oligosaccharide fragments (n greater than or equal to 5) that were highly sulphated and contained heparin-like repeating units, i.e. iduronic acid--glucosamine-N-sulphate with ester-sulphate on both sugars. These oligosaccharides were susceptible to deaminative cleavage.