Effects of hyaluronate and heparan sulphate on collagen-fibronectin interactions

Interactions of fibronectin and glycosaminoglycans and the involvement of heparan sulphate and hyaluronate in fibronectin-collagen interactions have been studied by affinity chromatography. Partially periodate-oxidized glycosaminoglycans were coupled to adipic acid dihydrazide-substituted agarose. The elution of fibronectin was performed by using increasing concentrations of NaCl. Of the copolymeric glycosaminoglycans, heparin and self-associating heparan sulphates display the highest affinity towards fibronectin while hyaluronic acid and chondroitin 6-sulphate do not bind fibronectin. Competitive release experiments suggest the existence of common binding sites for copolymeric glycosaminoglycans on the fibronectin backbone. Heparan sulphate favours the formation of collagen-fibronectin complexes at low molarity, while hyaluronate is ineffective at low concentrations and prevents the formation of complexes when present at concentrations > 1 mg ml^?1. It is suggested that heparan sulphate promotes the formation of complexes which bind with fibronectin thus producing steric changes that increase the affinity for collagen, while hyaluronate prevents the binding of fibronectin to collagen by a steric exclusion mechanism.     

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.     

Heterogeneity of heparan sulfate chains in a proteoglycan from bovine lung

A heparan sulfate proteoglycan from bovine lung gas-exchange tissue was isolated by extraction of the tissue with 4.0 M guanidine HCl in the presence of multiple protein inhibitors. The proteoglycan was purified by precipitation with cetylpyridinium chloride in 0.5 M KCl followed by CsCl isopycnic centrifugation (po = 1.45) in 4.0 M guanidine/HCl. Further purification was achieved by gel filtration on Sepharose CL-2B and by chromatography in DEAE-Sepharose CL-6B column. The proteoglycan had 14.9% protein and 22.4% uronate. Heparan sulfate chains from the proteoglycan were isolated after beta-elimination. Fractionation of heparan sulfate chains was achieved on Dowex-1 Cl- column, eluting with a stepwise increase in the concentration of NaCl, 1.0 to 2.0 M with 0.2 M increments. Of the total heparan sulfate recovered from the column, about 10% eluted by 1.2 M NaCl, 68% by 1.4 M NaCl, 18% by 1.6 M NaCl and 4% by 1.8 M NaCl. The fractions varied in their total and N-sulfate ester contents and iduronic acid to glucuronic acid ratios. The fraction that eluted from the Dowex-1 Cl- column at 1.6 M NaCl had the highest molecular weight, 37000, and the fraction that eluted at 1.8 M NaCl had the lowest molecular weight, 12000, as determined by gel filtration method, and the greatest sulfate content. The core protein, obtained by digestion of proteoglycan by heparan sulfate lyase, showed mostly a single band in SDS-polyacrylamide gel electrophoresis. The observations indicate a heterogeneity of the composition of heparan sulfate chains in the proteoglycan. This heterogeneity likely contributes to variations in biologic properties of different heparan sulfate proteoglycan preparations.     

Domain structure of proteoheparan sulphate from confluent cultures of human embryonic skin fibroblasts.

Radiolabelled proteoheparan sulphates were isolated from confluent monolayers of fibroblasts and from their spent media. The cell-surface-associated proteoglycan (Mr 350 000) has a core protein of Mr 180 000 that is cleaved by reduction of disulphide bonds into polypeptides of Mr 90 000, both of which can bind transferrin [Fransson, Carlstedt, Cöster & Malmström (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 5657-5661]. Thrombin digestion of the proteoglycan yielded two major fragments. The larger one contained the heparan sulphate chains and glycoprotein-type oligosaccharides, whereas the smaller one contained interchain disulphide bond(s) and had affinity for transferrin as well as for octyl-Sepharose. The larger thrombic fragment was cleaved by trypsin into fragments containing the heparan sulphate chains and the oligosaccharides respectively. The smaller proteoheparan sulphate derived from the culture medium (Mr 150 000) had a core protein of Mr 30 000, which contained heparan sulphate-attachment and oligosaccharide-attachment regions, but no domains for binding of transferrin or for hydrophobic interactions.     

Isolation and partial characterization of heparan sulphate proteoglycan from the human glomerular basement membrane.

Heparan sulphate proteoglycan was solubilized from human glomerular basement membranes by guanidine extraction and purified by ion-exchange chromatography and gel filtration. The yield of proteoglycan was approx. 2 mg/g of basement membrane. The glycoconjugate had an apparent molecular mass of 200-400 kDa and consisted of about 75% protein and 25% heparan sulphate. The amino acid composition was characterized by a high content of glycine, proline, alanine and glutamic acid. Hydrolysis with trifluoromethanesulphonic acid yielded core proteins of 160 and 110 kDa (and minor bands of 90 and 60 kDa). Alkaline NaBH4 treatment of the proteoglycan released heparan sulphate chains with an average molecular mass of 18 kDa. HNO2 oxidation of these chains yielded oligosaccharides of about 5 kDa, whereas heparitinase digestion resulted in a more complete degradation. The data suggest a clustering of N-sulphate groups in the peripheral regions of the glycosaminoglycan chains. A polyclonal antiserum raised against the intact proteoglycan showed reactivity against the core protein. It stained all basement membranes in an intense linear fashion in immunohistochemical studies on frozen kidney sections from man and various mammalian species.     

Initiation of altered heparan sulphate on beta-D-xyloside in rat hepatocytes

Inhibition of protein synthesis by cycloheximide 10(-3)M reduced the incorporation of [35S]sulphate into heparan sulphate to about 5% of untreated hepatocytes. Addition of rho-nitrophenyl beta-D-xyloside could partially revert this inhibitory effect. The sulphated material isolated from the cell layer or secretions of hepatocytes grown in presence of cycloheximide and rho-nitrophenyl beta-D-xyloside were shown to be mostly free heparan sulphate chains not bound to core protein. Covalent association of beta-xylosides to the heparan sulphates was demonstrated for heparan sulphate synthetized in the presence of [35S]sulphate, cycloheximide and the fluorogenic 4-methylumbelliferyl beta-D-xyloside. Beta-Xylosides served as an initiator of heparan sulphate chain synthesis in rat hepatocytes only in the absence of protein synthesis. Heparan sulphates primed on artificial beta-xylosides are slightly smaller in molecular size and are more sulphated than chains linked to core protein.     

Isolation and characterization of dermatan sulphate proteoglycans from bovine sclera.

1. Proteoglycans were extracted from sclera with 4 M-guanidine hydrochloride in the presence of proteinase inhibitors and purified by ion-exchange chromatography and density-gradient centrifugation. 2. The entire proteoglycan pool was characterized by compositional analyses and by specific chemical (periodate oxidation) and enzymic (chondroitinases) degradations. The glycan moieties of the molecules were exclusively galactosaminoglycans (dermatan sulphate-chondroitin sulphate co-polymers). In addition, the preparations contained small amounts of oligosaccharides. 3. The scleral proteodermatan sulphates were fractionated into one larger (I) and one smaller (II) component by gel chromatography. Proteoglycan I was eluted in a more excluded position on gel chromatography in 0.5 M-sodium acetate than in 4.0 M-guanidine hydrochloride. Reduced and alkylated proteoglycan I was eluted in the same position (in 0.5 M-sodium acetate) as was the starting material (in 4.0 M-guanidine hydrochloride). The elution position of proteoglycan II was the same in both solvents. Proteoglycans I and II had s0 20,w values of 2.8 x 10(-13) and 2.2 x 10(-13) s respectively in 6.0 M-guanidine hydrochloride. 4. The two proteoglycans differed with respect to the nature of the protein core and the co-polymeric structure of their side chains. Also proteoglycan I contained more side chains than did proteoglycan II. The dermatan sulphate side chains of proteoglycan I were D-glucuronic acid-rich (80%), whereas those of proteoglycan II contained equal amounts of D-glucuronic acid and L-iduronic acid. Furthermore, the co-polymeric features of the side chains of proteoglycans I and II were different. The protein core of proteoglycan I was of larger size than that of proteoglycan II. The latter had an apparent molecular weight of 46 000 (estimated by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis), whereas the former was greater than 100 000. In addition, the amino-acid composition of the two core preparations was different. 5. As proteoglycan I altered its elution position on gel chromatography in 4 M-guanidine hydrochloride compared with 0.5 M-sodium acetate it is proposed that a change in conformation or a disaggregation took place. If the latter hypothesis is favoured, aggregation may be due to self-association or mediated by an extrinsic molecule, e.g. hyaluronic acid.     

Polyamine requirement for streptomycin action on protein synthesis in bacteria

Self-association between various heparan sulphate species and oligosaccharide fragments thereof have been studied by affinity chromatography. Polysaccharides or oligosaccharides were coupled to agarose and free chains were applied at low concentrations (less than or equal to 2 mg/ml) in 0.15 M NaCl to minimize self-association between free chains. The results show that the interaction may be specific. Heparan sulphate chains chiefly bind to gels substituted with cognate chains, i.e. the same kind or closely similar ones. Oligosaccharides of the general structure glucosamine-(iduronate/glucuronate-glucosamine)n--O--C(=CH2)--CHO were prepared by periodate oxidation/alkaline elimination and also coupled to agarose via the --CHO group. Cognate heparan sulphate chains were bound to this affinity matrix with the same affinity as in the case of heparan-sulphate--agarose. Free oligosaccharides were not bound to oligosaccharide-agarose, nor to the corresponding heparan-sulphate--agarose. Oligosaccharides of the same size and containing only iduronate were ineffective as affinity ligands. It is concluded that the segments comprising both iduronate and glucuronate may serve as contact zones in the heparan sulphate/heparan sulphate self-association and that the strength of binding is dependent on cooperative interactions between a number of such zones. The putative contact zones, as ligands on the matrix, showed an emerging lack of specificity as non-associating or unrelated and associating chains were bound to this gel. This is ascribed to a randomization of the contact zones which, in the polymeric chains, are placed in their proper register by the intervening (glucuronate-N-acetylglucosamine)n segments.     

Structure of heparan sulphate oligosaccharides and their degradation by exo-enzymes.

Oligosaccharides obtained from heparan sulphate by nitrous acid degradation were shown to be degraded sequentially by beta-D-glucuronidase or alpha-L-iduronidase followed by alpha D-N-acetylglucosaminidase. Structural analysis of the tetrasaccharide fraction showed the following. (1) N-Acetylglucosamine is preceded by a non-sulphated uronic acid residue that can be either D-glucuronic of L-iduronic acid, but followed by a glucuronic acid residue. (2) The N-acetylglucosamine in the major fraction is sulphated. (3) Very few if any of the uronic acid residues are sulphated (4). The results indicate that the area of the heparan sulphate chain where disaccharides containing N-acetylglucosamine and N-sulphated glucosamine residues alternate is higher in sulphate content than expected and that the sulphate groups are mainly located on the hexosamine units.     

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.     

Structural Properties of the Heparan Sulfate Proteoglycans of Brain

The heparan sulfate proteoglycans present in a deoxycholate extract of rat brain were purified by ion exchange chromatography, affinity chromatography on lipoprotein lipase agarose, and gel filtration. Heparitinase treatment of the heparan sulfate proteoglycan fraction (containing 86% heparan sulfate and 10% chondroitin sulfate) that was eluted from the lipoprotein lipase affinity column with 1 M NaCl led to the appearance of a major protein core with a molecular size of 55,000 daltons, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Comparison of the effects of heparinase and heparitinase treatment revealed that the heparan sulfate proteoglycans of brain contain a significant proportion of relatively short N-sulfoglucosaminyl 6-O-sulfate [or N-sulfoglucosaminyl](alpha 1-4)iduronosyl 2-O-sulfate(alpha 1-4) repeating units and that the portions of the heparan sulfate chains in the vicinity of the carbohydrate-protein linkage region are characterized by the presence of D-glucuronic acid rather than L-iduronic acid. After chondroitinase treatment of a proteoglycan fraction that contained 62% chondroitin sulfate and 21% heparan sulfate (eluted from lipoprotein lipase with 0.4 M NaCl), the charge and density of a portion of the heparan sulfate-containing proteoglycans decreased significantly. These results indicate that a population of "hybrid" brain proteoglycans exists that contain both chondroitin sulfate and heparan sulfate chains covalently linked to a common protein core.     

Inactivation of unbound rat liver glucocorticoid receptor by N-alkylmaleimides at sub-zero temperatures

Biosynthetically radiolabelled heparan sulphate proteoglycans have been isolated from the growth medium and the cell lysate of a human neuroblastoma cell line (CHP100). Chromatography on Sepharose CL-4B identified two heparan sulphate proteoglycans in the medium (Kav 0.220 and 0.389), whereas in the cell lysate the major proteoglycan species were more heterogenous and of a smaller overall molecular size (Kav 0.407) than the medium-derived counterparts. Chromatography on Sepharose CL-6B of free heparan sulphate glycosaminoglycan chains showed that the majority of cell-layer-derived material heparan sulphate 2, Kav = 0.509) was smaller than medium heparan sulphates (heparan sulphate 1 and heparan sulphate 2, Kav 0.230 and 0.317). Analysis of the patterns of polymer sulphation by nitrous acid treatment, gel chromatography and high-voltage electrophoresis established that in each heparan sulphate fraction there was on average 1.1 sulphate residues per disaccharide with an N:O sulphate ratio of 1.1. Heparan sulphate in the medium had a high proportion of di-O-sulphated disaccharides in regions of the chain with repeat disaccharide sequences of structure GlcA-GlcNSO3, whereas cell-associated material was enriched in di-O-sulphated tetrasaccharides of alternating sequences GlcA-GlcNAc-GlcA-GlcNSO3. The identification of several populations of heparan sulphate proteoglycans differing in molecular size and glycosaminoglycan fine structure may reflect the functional diversity of this family of macromolecules in the nervous system.     

Differences in the distribution of O-sulphate groups of cell-surface and secreted heparan sulphate produced by human neuroblastoma cells in culture

Confluent cultures of a human neuroblastoma cell line (CHP100) were incubated for 48 h with d-[1-³H]glucosamine and sodium [³⁵S]sulphate. Radioactive glycosaminoglycans were analysed in the growth medium, rapid trypsin digest of the cell monolayer and a 1% (w/v) Triton/0.5 M NaOH extract of the final cell pellet. Sulphated glycosaminoglycans co-chromatographed when eluted by NaCL gradient from DEAE-cellulose. The medium contained mainly chondroitin sulphates, whereas the cell surface was enriched in heparan sulphate. Heparan sulphate was isolated as chondroitinase ABC-resistant material and treated with nitrous acid. Analysis of the scission products on Bio-Gel P-10 yielded fragments varying in size from single disaccharides to glycans consisting of nine disaccharide units. Cell-surface and medium heparan sulphate had respectively 52% and 54% N-sulphated glucosamine residues distributed in similar patterns along the polymer chain. The N:O-sulphate ratio of neuroblastoma heparan sulphate was 1.1:1. Analysis by high-voltage electrophoresis of di- and tetrasaccharide products produced by nitrous acid treatment showed that the distribution of $\text{‘O’-}\text{sulphate}$ groups differed strikingly between heparan sulphates from the medium and cell-surface compartments. A di-O-sulphated tetrasaccharide was identified in both heparan sulphate species. The absence of detectable amounts of ³⁵[S]sulphate associated with fragments larger than tetrasaccharide supports the close topographical association of N-sulphate and O-sulphate groups.     

Oligosaccharide mapping of heparan sulphate by polyacrylamide-gradient-gel electrophoresis and electrotransfer to nylon membrane.

A new method that we have called 'oligosaccharide mapping' is described for the analysis of radiolabelled heparan sulphate and other glycosaminoglycans. The method involves specific enzymic or chemical scission of polysaccharide chains followed by high-resolution separation of the degradation products by polyacrylamide-gradient-gel electrophoresis. The separated oligosaccharides are immobilized on charged nylon membranes by electrotransfer and detected by fluorography. A complex pattern of discrete bands is observed covering an oligosaccharide size range from degree of polymerization (d.p.) 2 (disaccharide) to approximately d.p. 40. Separation is due principally to differences in Mr, though the method also seems to detect variations in conformation of oligosaccharide isomers. Resolution of oligosaccharides is superior to that obtained with isocratic polyacrylamide-gel-electrophoresis systems or gel chromatography, and reveals structural details that are not accessible by other methods. For example, in this paper we demonstrate a distinctive repeating doublet pattern of iduronate-rich oligosaccharides in heparitinase digests of mouse fibroblast heparan sulphate. This pattern may be a general feature of mammalian heparan sulphates. Oligosaccharide mapping should be a valuable method for the analysis of fine structure and sequence of heparan sulphate and other complex polysaccharides, and for making rapid assessments of the molecular distinctions between heparan sulphates from different sources.     

Molecular distinctions between heparan sulphate and heparin. Analysis of sulphation patterns indicates that heparan sulphate and heparin are separate families of N-sulphated polysaccharides.

Heparan sulphate and heparin are chemically related alpha beta-linked glycosaminoglycans composed of alternating sequences of glucosamine and uronic acid. The amino sugars may be N-acetylated or N-sulphated, and the latter substituent is unique to these two polysaccharides. Although there is general agreement that heparan sulphate is usually less sulphated than heparin, reproducible differences in their molecular structure have been difficult to identify. We suggest that this is because most of the analytical data have been obtained with degraded materials that are not necessarily representative of complete polysaccharide chains. In the present study intact heparan sulphates, labelled biosynthetically with [3H]glucosamine and Na2(35)SO4, were isolated from the surface membranes of several types of cells in culture. The polysaccharide structure was analysed by complete HNO2 hydrolysis followed by fractionation of the products by gel filtration and high-voltage electrophoresis. Results showed that in all heparan sulphates there were approximately equal numbers of N-sulpho and N-acetyl substituents, arranged in a similar, predominantly segregated, manner along the polysaccharide chain. O-Sulphate groups were in close proximity to the N-sulphate groups but, unlike the latter, the number of O-sulphate groups could vary considerably in heparan sulphates of different cellular origins ranging from 20 to 75 O-sulphate groups per 100 disaccharide units. Inspection of the published data on heparin showed that the N-sulphate frequency was very high (greater than 80% of the glucosamine residues are N-sulphated) and the concentration of O-sulphate groups exceeded that of the N-sulphate groups. We conclude from these and other observations that heparan sulphate and heparin are separate families of N-sulphated glycosaminoglycans.     

A synthetic heparan sulfate pentasaccharide, exclusively containing L-iduronic acid, displays higher affinity for FGF-2 than its D-glucuronic acid-containing isomers.

It has been suggested that the FGF-2 binding site on heparan sulfate chains is a trisulfated pentasaccharide containing three hexuronic acid units. The configuration at C-5 of two of them being undetermined, we have synthesized the four possible pentasaccharides, and have evaluated their FGF-2 binding affinity through in vitro biological assays. The pentasaccharide containing L-iduronic acid as the sole hexuronic acid showed higher affinity for FGF-2 than the other pentasaccharides, where one hexuronic acid unit at least is D-glucuronic acid.     

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.     

Identification of N-sulphated disaccharide units in heparin-like polysaccharides.

1. Preparations of heparin and heparan sulphate were degraded with HNO2. The resulting disaccharides were isolated by gel chromatography, reduced with either NaBH4 or NaB3H4 and were then fractionated into non-sulphated, monosulphated and disulphated species by ion-exchange chromatography or by paper electrophoresis. The non-sulphated disaccharides were separated into two, and the monosulphated disaccharides into three, components by paper chromatography. 2. The uronic acid moieties of the various non- and mono-sulphated disaccharides were identified by means of radioactive labels selectively introduced into uronic acid residues (3H and 14C in D-glucuronic acid, 14C only in L-iduronic acid units) during biosynthesis of the polysaccharide starting material. Labelled uronic acids were also identified by paper chromatography, after liberation from disaccharides by acid hydrolysis or by glucuronidase digestion. Similar procedures, applied to disaccharides treated with NaB3H4, indicated 2,5-anhydro-D-mannitol as reducing terminal unit. On the basis of these results, and the known positions and configurations of the glycosidic linkages in heparin, the two non-sulphated disaccharides were identified as 4-O-(beta-D-glucopyranosyluronic acid)-2,5-anhydro-D-mannitol and 4-O-(alpha-L-idopyranosyluronic acid)-2,5-anhydro-D-mannitol. 3. The three monosulphated [1-3H]anhydromannitol-labelled disaccharides were subjected to Smith degradation or to digestion with homogenates of human skin fibroblasts, and the products were analysed by paper electrophoresis. The results, along with the 1H n.m.r. spectra of the corresponding unlabelled disaccharides, permitted the allocation of O-sulphate groups to various positions in the disaccharides. These were thus identified as 4-O-(beta-D-glucopyranosyl-uronic acid)-2,5-anhydro-D-mannitol 6-sulphate, 4-O-(alpha-L-idopyranosyluronic acid)-2,5-anhydro-D-mannitol 6-sulphate and 4-O-(alpha-L-idopyranosyluronic acid 2-sulphate)-2,5-anhydro-D-mannitol. The last-mentioned disaccharide was found to be a poor substrate for the iduronate sulphatase of human skin fibroblasts, as compared with the disulphated species, 4-O-(alpha-L-idopyranosyluronic acid 2-sulphate)-2,5-anhydro-D-mannitol 6-sulphate. 4. The identified [1-3H]anhydromannitol-labelled disaccharides were used as reference standards in a study of the disaccharide composition of heparins and heparan sulphates. Low N-sulphate contents, most pronounced in the heparin sulphates, were associated with high ratios of mono-O-sulphated/di-O-sulphated (N-sulphated) disaccharide units, and in addition, with relatively large amounts of 2-sulphated L-iduronic acid residues bound to C-4 of N-sulpho-D-glucosamine units lacking O-sulphate substituents.     

Heterogeneity of cell-associated and secretory heparan sulphate proteoglycans produced by cultured human neuroblastoma cells

Biosynthetically radiolabelled heparan sulphate proteoglycans have been isolated from the growth medium and the cell lysate of a human neuroblastoma cell line (CHP100). Chromatography on Sepharose CL-4B identified two heparan sulphate proteoglycans in the medium (K_av 0.220 and 0.3890, whereas in the cell lysate the major proteoglycan species were more heterogenous and of a smaller overall molecular size (K_av 0.407) than the medium-derived counterparts. Chromatography on Sepharose CL-6B of free heparan sulphate glycosaminoglycan chains showed that the majority of cell-layer-derived material heparan sulphate 2, K_av=0.509) was smaller than medium heparan sulphates (heparan sulphate 1 and heparan sulphate 2, K_av 0.230 and 0.317). Analysis of the patterns of polymer sulphation by nitrous acid treatment, gel chromatography and high-voltage electrophoresis established that in each heparan sulphate fraction there was on average 1.1 sulphate residues per disaccharide with an N:O sulphate ratio of 1.1 Heparan sulphate in the medium had a high proportion of di-O-sulphated disaccharides in regions of the chain with repeat disaccharide sequences of structure GlcA-GlcNSO₃, whereas cell-associated material was enriched in di-O-sulphated tetrasaccharides of alternating sequences GlcA-GlcNAc-GlcA-GlcNSO₃. The identification of several populations of heparan sulphate proteoglycans differing in molecular size and glycosaminoglycan fine structure may reflect the functional diversity of this family of macromolecules in the nervous system.