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.     

Heparan sulphate with no affinity for antithrombin III and the control of haemostasis

Heparan sulphate with no affinity for antithrombin III (ATIII) was observed to cause acceleration of the factor Xa:ATIII interaction by 1100-fold (k2, 7 X 10(7) M-1.min-1) and the prothrombinase:ATIII interaction by 2900-fold (k2, 2.5 X 10(7) M-1.min-1). Although high-affinity heparan sulphate catalyzed higher acceleration and at lower concentration, in natural mixtures of the two forms the activity of the no affinity form predominated. Heparan sulphate had no significant effect on the thrombin:ATIII interaction but inhibited its potentiation by heparin (Kd 0.3 microM). From the estimated concentration of heparan sulphate on the endothelial cell surface it is proposed that the non-thrombogenic property of blood vessels is due to the acceleration of the factor Xa or prothrombinase:ATIII interaction by the greater mass of surface-bound heparan sulphate rather than by the much smaller proportion of heparin-like molecules (with high affinity for antithrombin III) which may be present.     

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.     

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.     

Hepatic heparan sulphate proteoglycan and the recycling of transferrin.

Heparan sulphate proteoglycan, labelled with [35S]sulphate, was prepared from rat livers for studies of its interaction with purified rat transferrin. Affinity chromatography of the preparation on columns of immobilized differic transferrin and apotransferrin showed that the proteoglycan possessed affinity for both types of matrices at pH 7.3 and that this affinity significantly increased at pH 5.6. The glycosaminoglycan chains liberated from the proteoglycan by heparan sulphate lyase also bound to apotransferrin, albeit less strongly, whereas the deglycosylated core protein exhibited virtually no interaction with this matrix. In the presence of the proteoglycan at pH 5.6, the release of iron from the N-lobe of transferrin was accelerated. These observations suggest that heparan sulphate proteoglycan from the liver can mimick some of the known functions of bona fide transferrin receptors and, hence, interaction with the proteoglycan may provide an alternative nondegradative pathway for transferrin through hepatic cells.     

The catabolism of intravenously injected heparan N-[35S]sulphate in the rat

The metabolic fate of heparan N-[(35)S]sulphate was studied in rats. Heparan sulphate was obtained from either bovine aorta or lung and labelled with (35)S by desulphation and subsequent resulphation in vitro. Experiments in which heparan N-[(35)S]sulphate was administered intravenously to either free-range or wholly anaesthetized rats with ureter cannulae established that substantial desulphation occurs in vivo, with elimination of inorganic [(35)S]sulphate in urine. Oligosaccharides labelled with (35)S, possible intermediates in heparan sulphate degradation, could not be detected in urine or blood. The general distribution of radioactivity after administration of heparan N-[(35)S]sulphate, as demonstrated by whole-body radioautography, suggested that desulphation was not restricted to one organ in particular. Support for this view was obtained in experiments in which heparan N-[(35)S]sulphate was administered to animals after the removal of kidneys, liver, spleen, pancreas or gastrointestinal tract. In all cases inorganic [(35)S]sulphate was still produced. The ability of rats of desulphate heparan N-[(35)S]sulphate was progressively impaired by increasing concentrations of heparin administered simultaneously. It was concluded that heparan sulphate is metabolized at a number of sites in the body by a sequence of degradative events leading to the formation of inorganic sulphate. It is also concluded that at least some of these events are common to heparan sulphate and heparin.     

Immunocytochemical localization of heparan sulphate proteoglycan in the rat submandibular gland

Summary Heparan sulphate proteoglycan is the predominant proteoglycan synthesized by the parenchymal cells of the rat submandibular gland. A polyclonal antibody was used to localize this proteoglycan in the adult rat submandibular gland. Localization was accomplished by indirect immunoperoxidase cytochemistry at the light and electron microscopic levels. Heparan sulphate proteoglycan was localized in a continuous, linear pattern in the lamina densa of the basement membrane surrounding all of the epithelial components of the gland as well as the basement membrane of the capillaries and small arterioles in the glandular stroma. In addition, heparan sulphate proteoglycan was seen in vesicles and pits along the acinar cell basal plasmalemma adjacent to the basement membrane and in the endoplasmic reticulum and Golgi apparatus of the acinar cells.     

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.     

Specific modification of heparan sulphate is required for normal cerebral cortical development

Proteoglycans are cell surface and extracellular matrix molecules to which long, unbranched glycosaminoglycan side chains are attached. Heparan sulphate, a type of glycosaminoglycan chain, has been proposed as a co-factor necessary for signalling by a range of growth factors. Here we provide evidence that loss of 2-O-sulphation in heparan sulphate leads to a significant reduction in cell proliferation in the developing cerebral cortex. The gene encoding heparan sulphate 2-sulphotransferase (Hs2st) is expressed in embryonic cortex and histological analysis of mice homozygous for a null mutation in Hs2st indicated a reduction in the thickness of the embryonic cerebral cortex. Using 5′-bromodeoxyuridine (BrdU) incorporation assays we found a reduction of approximately 40% in labelling indices of cortical precursor cells at E12. Comparison of the fates of cortical cells born on E13 and E15 in Hs2st^−/− mutant and wildtype littermate embryos revealed no differences in the pattern of cell migration. Our findings suggest a critical role for 2-O-sulphation of heparan sulphate proteoglycan (HSPG) in regulating cell proliferation during development of the cerebral cortex, perhaps through the modulation of cellular responses to growth factor signalling.     

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.     

Synthesis of glycosaminoglycans by cloned bovine endothelial cells cultured on collagen gels

Sulphated glycosaminoglycans have been analysed in cloned bovine aortic endothelial cells cultured on collagen gels after incubation with [3H]glucosamine and Na2(35)SO4. Radioactive products were analysed in the culture medium, in sequential collagenase and trypsin extracts of the cell monolayer and the associated extracellular matrix, and in the remaining viable cells. Heparan sulphate and chondroitin sulphate were found in each compartment: the heparan sulphate had a low degree of sulphation (approximately 0.4 N-sulphate and 0.2 O-sulphate groups per disaccharide unit on average). In the nitrous acid scission products of heparan sulphate, O-sulphated substituents were confined to disaccharide and tetrasaccharide fragments, indicating that local regions of the chain (which might be susceptible to excission by the platelet endoglycosidase) are highly sulphated. Only minor structural differences in heparan sulphate were observed between the various compartments. In contrast the chondroitin sulphate found in the collagenase extract had a higher iduronic acid content than corresponding material in the trypsin extract and the culture medium, indicating that collagenase and trypsin may extract glycosaminoglycans from different regions of the extracellular and pericellular matrix.     

Glycosaminoglycans of arterial basement membrane-like material from cultured rabbit aortic myomedial cells

Arterial basement membrane-like material was prepared by a sonication-differential centrifugation technique from cultures of rabbit aortic myomedial cells after metabolic labelling with [35S]sulphate and [3H]glucosamine. Labelled glycosaminoglycans were obtained from isolated basement membrane-like material by proteinase digestion and gel filtration. Glycosaminoglycans were identified by a combination of Sephadex G-50 chromatography and sequential degradation with nitrous acid, Streptomyces hyaluronidase, testicular hyaluronidase and chondroitinase ABC. The data showed that heparan sulphate and chondroitin sulphate were the predominant glycosaminoglycans of myomedial basement membrane-like material. Heparan sulphate accounted for about 55% of [3H]glucosamine-labelled glycosaminoglycans. In addition small amounts of hyaluronic acid was present. Only trace amounts of dermatan sulphate was found. The glycosaminoglycans were analysed by DEAE-cellulose chromatography. Two major peaks were found in the chromatogram consistent with the predominance of heparan sulphate and chondroitin sulphate.     

Syndecans in wound healing, inflammation and vascular biology

Syndecans are heparan sulphate proteoglycans consisting of a type I transmembrane core protein modified by heparan sulphate and sometimes chondroitin sulphate chains. They are major proteoglycans of many organs including the vasculature, along with glypicans and matrix proteoglycans. Heparan sulphate chains have potential to interact with a wide array of ligands, including many growth factors, cytokines, chemokines and extracellular matrix molecules relevant to growth regulation in vascular repair, hypoxia, angiogenesis and immune cell function. This is consistent with the phenotypes of syndecan knock-out mice, which while viable and fertile, show deficits in tissue repair. Furthermore, there are potentially important changes in syndecan distribution and function described in a variety of human vascular diseases. The purpose of this review is to describe syndecan structure and function, consider the role of syndecan core proteins in transmembrane signalling and also their roles as co-receptors with other major classes of cell surface molecules. Current debates include potential redundancy between syndecan family members, the significance of multiple heparan sulphate interactions, regulation of the cytoskeleton and cell behaviour and the switch between promoter and inhibitor of important cell functions, resulting from protease-mediated shedding of syndecan ectodomains.     

Release of diamine oxidase into plasma by glycosaminoglycans in rats

Plasma diamine oxidase (DAO) values are enhanced by intravenous injection of heparin which releases the enzyme, synthesized in small bowel enterocytes, from binding sites located on endothelial cells of the intestinal microvasculature. Intestinal DAO, in analogy with lipoprotein lipase (another heparin-released enzyme), is believed to be electrostatically linked to endothelial binding sites composed of a glycosaminoglycan (GAG) which is presumably heparan sulphate, but the complete mechanism of enzyme release is not known. In this study we assayed in rats the DAO-releasing capability of heparan sulphate, dermatan sulphate, chondroitin sulphate A and hyaluronic acid, all heparin related compounds. Heparan sulphate, a compound with the same hexosamine as heparin but with a lower concentration of sulphated iduronic acid, induced a very high release of DAO (3-fold less than heparin), while the other tested GAGs, composed of higher proportions of non sulphated uronic acid and with galactosamine instead of glucosamine, induced a significantly lower release. In rats treated with 60 mg heparan sulphate the significant decrease in ileal mucosal DAO activity indicates that, in analogy with heparin, the high plasma enzymatic activity induced is of enterocytic origin. It is suggested that the high charge density of the compounds tested, due to the degree of sulphatation, is the decisive factor in promoting the release of intestinal DAO.     

Increased sulphation improves the anticoagulant activities of heparan sulphate and dermatan sulphate.

Heparan sulphate and dermatan sulphate have both antithrombotic and anticoagulant properties. These are, however, significantly weaker than those of a comparable amount of standard pig mucosal heparin. Antithrombotic and anticoagulant effects of glycosaminoglycans depend on their ability to catalyse the inhibition of thrombin and/or to inhibit the activation of prothrombin. Since heparan sulphate and dermatan sulphate are less sulphated than unfractionated heparin, we investigated whether the decreased sulphation contributes to the lower antithrombotic and anticoagulant activities compared with standard heparin. To do this, we compared the anticoagulant activities of heparan sulphate and dermatan sulphate with those of their derivatives resulphated in vitro. The ratio of sulphate to carboxylate in these resulphated heparan sulphate and dermatan sulphate derivatives was approximately twice that of the parent compounds and similar to that of standard heparin. Anticoagulant effects were assessed by determining (a) the catalytic effects of each glycosaminoglycan on the inhibition of thrombin added to plasma, and (b) the ability of each glycosaminoglycan to inhibit the activation of 125I-prothrombin in plasma. The least sulphated glycosaminoglycans were least able to catalyse the inhibition of thrombin added to plasma and to inhibit the activation of prothrombin. Furthermore, increasing the degree of sulphation improved the catalytic effects of glycosaminoglycans on the inhibition of thrombin by heparin cofactor II in plasma. The degree of sulphation therefore appears to be an important functional property that contributes significantly to the anticoagulant effects of the two glycosaminoglycans.     

Expression of heparan sulphate N-deacetylase/N-sulphotransferase by vascular smooth muscle cells

Heparan sulphate is an important mediator in determining vascular smooth muscle cell (SMC) phenotype. The sulphation pattern of the heparan sulphate chains is critical to their function. We have examined the initial step in the biosynthesis of the sulphated domains mediated by the enzyme heparan sulphate N-deacetylase/N-sulphotransferase (NDST). Rabbit aortic SMC in primary culture exhibited NDST enzyme activity and expressed NDST-1 in their Golgi apparatus, with maximal expression in SMC 2 days after dispersal in primary culture confirmed by Western blot analysis. Endothelial cells, macrophages and fibroblasts expressed NDST-1 but had generally less intense staining than SMC, although SMC expression decreased with culture. The uninjured rat aorta also showed widespread expression of NDST-1. After balloon de-endothelialisation, NDST-1 could not be detected in SMC of the neointima in the early stages of neointimal formation, but was re-expressed at later time points (after 12 weeks). In human coronary arteries, SMC of the media and the diffuse intimal thickening expressed NDST-1, while SMC in the atherosclerotic plaque were negative for NDST-1. We conclude that SMC may regulate their heparan sulphate sulphation at the level of expression of the enzyme heparan sulphate NDST in a manner related to their phenotypic state.     

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.     

Interactions between glycosaminoglycans and blood coagulation factors: 1. Affinity chromatography of glycosaminoglycans on thrombin-substituted agarose

Various glycosaminoglycans have been subjected to affinity chromatography on immobilized bovine thrombin. Chondroitin sulphate, dermatan sulphate and heparan sulphate variants with a sulphate-to-hexosamine molar ratio of ～ 1 exhibited weak affinities. Heparan sulphate/heparin fractions of higher sulphate content could be separated into material with high and low affinity for thrombin. Removal of N-sulphate followed by N-acetylation did not affect binding, whereas oxidation and cleavage of non-sulphated hexuronate abolished the interaction. Heparan-related molecules of high thrombin-affinity comprised sequences where large blocks of sulphated iduronate-containing repeats were joined via a few repeats carrying non-sulphated iduronate or glucuronate to form continuous segments that were larger than decasaccharide.