A comparative study of glycosaminoglycans in cultures of human, normal and malignant glial cells.

The glycosaminoglycans (GAG) of human cultured normal glial and malignant glioma cell lines were studied using 35S-sulphate or 3H-glucosamine as markers. 35S-labelled GAG were assayed by precipitation with cetylpyridinium chloride; 3H-labelled sulphated GAG and 3H-labelled hyaluronic acid were quantitated after separation on a DEAE-cellulos column. The net production of GAG and the distribution, composition and turnover of GAG were similar in all of the normal cell lines tested, but showed a great variability in the malignant cell lines. Most of the glioma cell lines produced more hyaluronic acid and less sulphated GAG than the normal cell lines, but exceptions were noted. The GAG of the trypsin susceptible (pericellular pool of normal glial cells consisted mainly of heparan sulphate with only minor amounts of other GAG. The analogous material of most glioma cells showed hyaluronic acid as the major GAG. Material liberated by trypsin from EDTA-detached cells (membrane fraction) was enriched in heparan sulphate as compared to the entire pericellular pool. Substrate attached material (SAM) left with the plastic dish after EDTA treatment of normal cultures was rich in heparan sulphate, whereas SAM of glioma cells lacked heparan sulphate or showed greatly reduced amounts of this component. Release of newly synthesized GAG to the extracellular medium was a rapid process in the normal cells but was more or less delayed in the glioma cells. The extracellular medium of the malignant glioma cultures was consistently poor in dermatan sulphate, as compared to that of normal cultures.     

Synthesis of glycosaminoglycans by human skin fibroblasts cultured on collagen gels.

A comparison has been made of the synthesis of glycosaminoglycans by human skin fibroblasts cultured on plastic or collagen gel substrata. Confluent cultures were incubated with [3H]glucosamine and Na235SO4 for 48h. Radiolabelled glycosaminoglycans were then analysed in the spent media and trypsin extracts from cells on plastic and in the medium, trypsin and collagenase extracts from cells on collagen gels. All enzyme extracts and spent media contained hyaluronic acid, heparan sulphate and dermatan sulphate. Hyaluronic acid was the main 3H-labelled component in media and enzyme extracts from cells on both substrata, although it was distributed mainly to the media fractions. Heparan sulphate was the major [35S]sulphated glycosaminoglycan in trypsin extracts of cells on plastic, and dermatan sulphate was the minor component. In contrast, dermatan sulphate was the principal [35S]sulphated glycosaminoglycan in trypsin and collagenase extracts of cells on collagen gels. The culture substratum also influenced the amounts of [35S]sulphated glycosaminoglycans in media and enzyme extracts. With cells on plastic, the medium contained most of the heparan sulphate (75%) and dermatan sulphate (> 90%), whereas the collagenase extract was the main source of heparan sulphate (60%) and dermatan sulphate (80%) from cells on collagen gels; when cells were grown on collagen, the medium contained only 5-20% of the total [35S]sulphated glycosaminoglycans. Depletion of the medium pool was probably caused by binding of [35S]sulphated glycosaminoglycans to the network of native collagen fibres that formed the insoluble fraction of the collagen gel. Furthermore, cells on collagen showed a 3-fold increase in dermatan sulphate synthesis, which could be due to a positive-feedback mechanism activated by the accumulation of dermatan sulphate in the microenvironment of the cultured cells. For comparative structural analyses of glycosaminoglycans synthesized on different substrata labelling experiments were carried out by incubating cells on plastic with [3H]glucosamine, and cells on collagen gels with [14C]glucosamine. Co-chromatography on DEAE-cellulose of mixed media and enzyme extracts showed that heparan sulphate from cells on collagen gels eluted at a lower salt concentration than did heparan sulphate from cells on plastic, whereas with dermatan sulphate the opposite result was obtained, with dermatan sulphate from cells on collagen eluting at a higher salt concentration than dermatan sulphate from cells on plastic. These differences did not correspond to changes in the molecular size of the glycosaminoglycan chains, but they may be caused by alterations in polymer sulphation.     

D(+)catechin enhances heparan sulphate content in rat liver

Administration of (D+) catechin (100 mg/kg body wt) to rats resulted in an increase in the amount of total sulphated glycosaminoglycans (GAG) in liver. The increase was more pronounced in the case of heparan sulphate than chondroitin sulphate and dermatan sulphate. The liver slices prepared from catechin-treated rats showed a significant increase in the rate of incorporation of 35S-sulphate into GAG. Similarly there was a concentration-dependent increase in the rate of 35S-sulphate incorporation into GAG by normal liver slices in presence of catechin in vitro. Susceptibility to nitrous acid degradation and chondroitinase ABC digestion showed that more than 80% of the GAG labelled in vivo with 35S-sulphate, was heparan sulphate and about 10% chondroitin sulphate and dermatan sulphate. Gel filtration of the 35S-labelled material isolated from livers of normal and catechin-treated animals over sephacryl S-300 did not show any difference probably excluding the possibility of free GAG chains initiated on catechin or any of its metabolites in vivo. These results indicate that catechin stimulates the synthesis of sulphated GAG, particularly heparan sulphate in liver.     

The synthesis of glycosaminoglycans by cultures of rabbit corneal endothelial and stromal cells.

Confluent monolayer cultures of rabbit corneal endothelial and stromal cells were incubated independently with [35S]sulphate and [3H]glucosamine for 3 days. AFter incubation, labelled glycosaminoglycans were isolated from the growth medium and from a cellular fraction. These glycosaminoglycans were further characterized by DEAE-cellulose column chromatography and by sequential treatment with various glycosamino-glycan-degrading enzymes. Both endothelial and stromal cultures synthesized hyaluronic acid as the principal product. The cell fraction from the stromal cultures, however, had significantly less hyaluronic acid than that from the endothelial cultures. In addition, both types of cells synthesized a variety of sulphated glycosaminoglycans. The relative amounts of each sulphated glycosaminoglycan in the two cell lines were similar, with chondroitin 4-sulphate, chondroitin 6-sulphate and dermatan sulphate as the major components. Heparan sulphate was present in smaller amounts. Keratan sulphate was also identified, but only in very small amounts (1-3%). The presence of dermatan sulphate and the high content of hyaluronic acid are similar to the pattern of glycosaminoglycans seen in regenerating or developing tissues, including cornea.     

The effect of charged synthetic polymers on proteoglycan synthesis and sequestration in chick embryo fibroblast cultures

The polycation, poly(l-lysine), repressed the synthesis of glycosaminoglycans in secondary cultures of chick embryo skin fibroblasts and caused sequestration of glycosaminoglycans around the cells. The synthesis of chondroitin sulphate, dermatan sulphate, hyaluronic acid and a fourth component, thought to be heparan sulphate, were all inhibited to the same extent but the sequestration of the sulphated polymers was greater than that of the unsulphated. The sequestered material was retained around and not within the cells. Incubations with the polyanion, poly(l-glutamate), showed a slight stimulation of glycosaminoglycan synthesis and in these and control incubations (no additions to medium), most of the glycosaminoglycan synthesised appeared in the culture medium. The subsequent addition of poly(l-glutamate) to incubations containing poly(l-lysine) reversed the inhibitory and sequestering effect of the polycation. It was concluded that the inhibition of synthesis by poly(l-lysine) was either a direct effect of poly(l-lysine) on the cell membrane or a result of the high local pericellular concentration of sequestered proteoglycan.     

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.     

Glycosaminoglycan synthesis in skin fibroblasts from patients with osteogenesis imperfecta

Glycosaminoglycans were analysed from skin fibroblasts with osteogenesis imperfecta (OI) IIA and IIB. The content of sulphated glycosaminoglycans was greatly increased over age-matched controls and to a lesser extent with respect to older age control. Dermatan sulphate in comparison with older control was unaltered in the cells of OI IIA and IIB. The concentration of heparan sulphate was higher in the cells than in the medium, whereas hyaluronic acid, chondroitin sulphate and dermatan sulphate content was higher in the medium. The level of hyaluronic acid was greatly elevated in the medium of OI IIB with respect to both controls.     

The influence of high ambient glucose level on the production of pericellular glycosaminoglycans by cultured endothelial cells

The 14C-acetate metabolic labeling of glycosaminoglycans (GAGs) was used to investigate the effect of high glucose level on the production of hyaluronic acid (HA), heparan sulphate (HS), chondroitin sulphate (CS) and dermatan sulphate (DS) by human immortalized umbilical vein endothelial cells. It is demonstrated that 30 mM glucose decreased the accumulation of HS and increased the accumulation of CS and DS in the cell layer, pericellular matrix and conditioned medium in 48 h of incubation. The modulation of the overall metabolism of sulphated GAGs by high glucose is in contrast to the observed redistribution of HA from the conditioned medium to the pericellular matrix of endothelial cells. The preincubation at 30 mM glucose increased also the attachment of hyaluronidase-treated endothelial cells to HA-coated surface and had no effect on the cell attachment to poly-D-lysine, indicating the alterations of CD44 binding to immobilized HA. The treatment of endothelial cells with p-nitrophenyl-beta-D-xylopyranoside, which inhibits the coupling of CS to the core protein, attenuated high glucose-induced pericellular HA accumulation and decreased cell attachment to HA-coated surface. It is supposed the implication of CD44-related CS in the accumulation of pericellular HA by endothelial cells exposed to high glucose level.     

Synthesis of glycosaminoglycans by human embryonic lung fibroblasts. Different distribution of heparan sulphate, chondroitin sulphate and dermatan sulphate in various fractions of the cell culture

Foetal human lung fibroblasts, grown in monolayer, were allowed to incorporate ³⁵SO₄²⁻ for various periods of time. ³⁵S-labelled macromolecular anionic products were isolated from the medium, a trypsin digest of the cells in monolayer and the cell residue. The various radioactive polysaccharides were identified as heparan sulphate and a galactosaminoglycan population (chondroitin sulphate and dermatan sulphate) by ion-exchange chromatography and by differential degradations with HNO₂ and chondroitinase ABC. Most of the heparan sulphate was found in the trypsin digest, whereas the galactosaminoglycan components were largely confined to the medium. Electrophoretic studies on the various ³⁵S-labelled galactosaminoglycans suggested the presence of a separate chondroitin sulphate component (i.e. a glucuronic acid-rich galactosaminoglycan). The ³⁵S-labelled galactosaminoglycans were subjected to periodate oxidation of l-iduronic acid residues followed by scission in alkali. A periodate-resistant polymer fraction was obtained, which could be degraded to disaccharides by chondroitinase AC. However, most of the ³⁵S-labelled galactosaminoglycans were extensively degraded by periodate oxidation–alkaline elimination. The oligosaccharides obtained were essentially resistant to chondroitinase AC, indicating that the iduronic acid-rich galactosaminoglycans (i.e. dermatan sulphate) were composed largely of repeating units containing sulphated or non-sulphated l-iduronic acid residues. The l-iduronic acid residues present in dermatan sulphate derived from the medium and the trypsin digest contained twice as much ester sulphate as did material associated with the cells. The content of d-glucuronic acid was low and similar in all three fractions. The relative distribution of glycosaminoglycans among the various fractions obtained from cultured lung fibroblasts was distinctly different from that of skin fibroblasts [Malmström, Carlstedt, Åberg & Fransson (1975) Biochem. J. 151, 477–489]. Moreover, subtle differences in co-polymeric structure of dermatan sulphate isolated from the two cell types could be detected.     

Studies on the incorporation of [U-14C]glucose and [35S]sulphate into the acid glycosaminoglycans of neonatal rat skin

1. The incorporation of [(35)S]sulphate in vivo into the acid-soluble intermediates extracted from young rat skin showed three sulphated hexosamine-containing components. 2. The rates of synthesis of these components were determined in vivo by measuring the incorporation of radioactivity from [U-(14)C]glucose into their isolated hexosamine moieties. 3. The incorporation of radioactivity from [U-(14)C]glucose into the isolated hexosamine and uronic acid moieties of the acid glycosaminoglycans was also measured. These results, combined with those obtained on the intermediary pathways of hexosamine and uronic acid biosynthesis previously determined in this tissue, indicated that the acid-soluble sulphated hexosamine-containing components were not precursors of the sulphated hexosamine found in the acid glycosaminoglycans. 4. The rates of synthesis of the acid glycosaminoglycan fractions were calculated from the incorporation of radioactivity from [U-(14)C]glucose into the hexosamine moiety. The sulphated components containing principally dermatan sulphate, chondroitin 6-sulphate and in smaller amounts, chondroitin 4-sulphate, heparan sulphate and heparin appeared to be turning over about twice as rapidly as hyaluronic acid and about four times as rapidly as the small keratan sulphate fraction. The relative rates of synthesis of the sulphated glycosaminoglycans were calculated from the incorporation of [(35)S]sulphate and were in agreement with those from (14)C-labelling studies.     

Production of proteoglycans by human lung fibroblasts (IMR-90) maintained in a low concentration of serum.

Maintenance of fibroblasts in 0.5% serum results in viable but non-proliferative cells that may be analogous to fibroblasts in vivo. The synthesis of proteoglycans by human embryo lung fibroblasts in Eagle's minimal essential medium with 0.5% newborn-bovine serum or with 10% serum has been compared. A similar amount of [35S]sulphate-labelled glycosaminoglycan per cell was secreted by fibroblasts in 10% or 0.5% serum. 35SO42-incorporation into sulphated glycosaminoglycans was enhanced in 0.5% serum when expressed per mg of cell protein, but [3H]glucosamine incorporation was decreased. The charge density of these glycosaminoglycans was not changed as determined by ion-exchange chromatography. It was concluded that decreased protein/ cell resulted in an apparent increase in 35S-labelled glycosaminoglycan synthesis/mg of cell protein, whereas decreased uptake of [3H]glucosamine resulted in a decrease in their glucosamine labelling. The proteoglycans secreted by fibroblasts in 0.5% serum were similar in glycosaminoglycan composition, chain length and buoyant density to the dermatan sulphate proteoglycan, which is the major secreted component of cells in 10% serum. Larger heparan sulphate and chondroitin sulphate proteoglycans, which comprise about 40% of the total secreted proteoglycans of cultures in 10% serum, were greatly diminished in the medium of cultures in 0.5% serum. The proteoglycan profile of medium from density-inhibited cultures in 10% serum resembles that of proliferating cultures, indicating that lack of proliferation was not responsible for the alteration. The dermatan sulphate proteoglycan, participating in extracellular matrix structure, may be the primary tissue product of lung fibroblasts in vivo.     

Specific association of iduronic acid-rich dermatan sulphate with the extracellular matrix of human skin fibroblasts cultured on collagen gels.

Human skin fibroblasts cultured on collagen gels produced two dermatan sulphate species, one, enriched in iduronic acid residues, that bound specifically to the collagenous fibres of the gel, the other, enriched in glucuronic acid, that accumulated in the culture medium. Collagen-binding and collagen-non-binding dermatan sulphates were also produced by cells grown on plastic surfaces, but in these cultures each constituent was released into the growth medium. Net synthesis of dermatan sulphate was 3-fold higher in cells maintained on collagen gels. In contrast, heparan sulphate synthesis was not influenced by the nature of the culture surface. The concentration of heparan sulphate in surface-membrane extracts was similar for cells grown on plastic and on collagen gels, but cells cultured on collagen showed a notable increase in the content of surface-membrane dermatan sulphate. The patterns of synthesis and distribution of sulphated glycosaminoglycans observed in skin fibroblasts maintained on collagen gels may reflect differentiated cellular functions.     

Extracellular matrix components in uterine leiomyoma and their alteration during the tumour growth

It was found that both normal human myometrium and uterine leiomyoma contain several glycosaminoglycans. In contrast to many normal and tumour tissues the amount of hyaluronic acid is very low and the proportional amount of sulphated glycosaminoglycans is distinctly higher. It is of interest that heparan sulphate is the major glycosaminoglycan component both in normal myometrium, and in leiomyoma. The amount of hyaluronic acid in myometrium and in the leiomyoma is very low. No significant change in hyaluronate content was observed during the tumour growth. In contrast to that the amount of some sulphated glycosaminoglycans (heparan sulphate, keratan sulphate, chondroitin sulphates and heparin) distinctly increased. It is suggested that some of the GAGs participate in the creation of a storage depot for biologically active molecules (growth factors, enzymes) which are thereby stabilized and protected. Hydrolytic degradation of some GAGs may result in the release of some cytokines which may promote the tumour growth and stimulate collagen biosynthesis by tumour cells.     

MDA-MB-231 breast cancer cell viability,motility and matrix adhesion are regulated by a complex interplay of heparan sulfate,chondroitin−/dermatan sulfate and hyaluronan biosynthesis

Proteoglycans and glycosaminoglycans modulate numerous cellular processes relevant to tumour progression, including cell proliferation, cell-matrix interactions, cell motility and invasive growth. Among the glycosaminoglycans with a well-documented role in tumour progression are heparan sulphate, chondroitin/dermatan sulphate and hyaluronic acid/hyaluronan. While the mode of biosynthesis differs for sulphated glycosaminoglycans, which are synthesised in the ER and Golgi compartments, and hyaluronan, which is synthesized at the plasma membrane, these polysaccharides partially compete for common substrates. In this study, we employed a siRNA knockdown approach for heparan sulphate (EXT1) and heparan/chondroitin/dermatan sulphate-biosynthetic enzymes (β4GalT7) in the aggressive human breast cancer cell line MDA-MB-231 to study the impact on cell behaviour and hyaluronan biosynthesis. Knockdown of β4GalT7 expression resulted in a decrease in cell viability, motility and adhesion to fibronectin, while these parameters were unchanged in EXT1-silenced cells. Importantly, these changes were associated with a decreased expression of syndecan-1, decreased signalling response to HGF and an increase in the synthesis of hyaluronan, due to an upregulation of the hyaluronan synthases HAS2 and HAS3. Interestingly, EXT1-depleted cells showed a downregulation of the UDP-sugar transporter SLC35D1, whereas SLC35D2 was downregulated in β4GalT7-depleted cells, indicating an intricate regulatory network that connects all glycosaminoglycans synthesis. The results of our in vitro study suggest that a modulation of breast cancer cell behaviour via interference with heparan sulphate biosynthesis may result in a compensatory upregulation of hyaluronan biosynthesis. These findings have important implications for the development of glycosaminoglycan-targeted therapeutic approaches for malignant diseases.     

Metabolism of sulfated glycosaminoglycans in cultivated bovine arterial cells. I. Characterization of different pools of sulfated glycosaminoglycans.

"Fibroblast-like" cells from the intimal layer of bovine aorta were grown in culture. The formation, composition, molecular weight and turnover rate of different pools of glycosaminoglycans were investigated in cultures incubated in the presence [35S]sulfate or [14C]glucosamine. The newly synthesized glycosaminoglycans are distributed into an extracellular pool (37 - 58%), a cell-membrane associated or pericellular pool (23 - 33%), and an intracellular pool (19 - 30%), each pool exhibiting a characteristic distribution pattern of chondroitin sulfate, dermatan sulfate, heparan sulfate and hyaluronate. The distribution pattern of the extracellular glycosaminoglycans resembles closely that found in bovine aorta. A small subfraction of the pericellular pool - tentatively named "undercellular" pool--has been characterized by its high heparan sulfate content. The intracellular and pericellular [35S]glycosaminoglycan pools reach a constant radioactivity after 8-12 h and 24 h, respectively, whereas the extracellular [35S]glycosaminoglycans are secreted into the medium at a linear rate over a period of at least 6 days. The intracellular glycosaminoglycans are mainly in the process of degradation, as indicated by their low molecular weight and by their half-life of 7 h, but intracellular dermatan sulfate is degraded more rapidly (half-life 4-5 h) than intracellular chondroitin sulfate and heparan sulfate (half-life 7-8 h). Glycosaminoglycans leave the pericellular pool with a half-life of 12-14 h by 2 different routes: about 60% disappear as macromolecules into the culture medium, and the remainder is pinocytosed and degraded to a large extent. Extracellular and at least a part of the pericellular glycosaminoglycans are proteoglycans. Even under dissociative conditions (4M guanidinium chloride) their hydrodynamic volume is sufficient for partial exclusion from Sepharose 4B gel. The existence of topographically distinct glycosaminoglycan pools with varying metabolic characteristics and differing accessibility for degradation requiresa reconsideration and a more reserved interpretation of results concerning the turnover rates of glycosaminoglycans as determined in arterial tissue.     

Proteoglycans synthesized in vitro by nude and normal mouse peritoneal macrophages

Peritoneal macrophages from nude mice were found to be functionally similar to 'activated' macrophages from normal mice. The objective of the present study was to characterize the proteoglycans synthesized and secreted in vitro by peritoneal macrophages isolated from nude and normal Balb/c mice and to investigate the relationship between macrophage 'activation' and changes in the proteoglycan patterns. Macrophages obtained by peritoneal lavage were seeded in Petri dishes. After 2 h incubation at 37 degrees C, the adherent cells (macrophages) were exposed to [35S]sulphate for the biosynthetic labelling of proteoglycans. After incubation, the cell and medium fractions were collected and analysed for proteoglycans and glycosaminoglycans. The glycosaminoglycans were identified and characterized by a combination of agarose gel electrophoresis and enzymatic degradation with specific mucopolysaccharidases. It was shown that 3/4 of the total 35S-labelled glycosaminoglycans were in the extracellular compartment after 24-48 h. The macrophages synthesized dermatan sulphate (68%), chondroitin sulphate (7%) and heparan sulphate (25%). Both cell and medium fractions of normal and nude mouse macrophages contained glycosaminoglycans with the same ratios, although the nude mouse macrophages synthesized 2-fold less glycosaminoglycans than the normal mouse macrophages. Lower levels of 35S-proteoglycans were also obtained from in vitro 'activated' macrophages, but the ratios of dermatan sulphate:chondroitin sulphate: heparan sulphate were altered in these cells as compared to the control. Furthermore, all the 35S-macromolecules found in the extracellular compartment of nude and normal control cells were of proteoglycan nature, in contrast to the medium fractions of 'activated' macrophages, which contain both intact proteoglycans and 'free' glycosaminoglycan chains. These results indicate that, at least as regards the proteoglycans and glycosaminoglycans, the nude mouse macrophages are not identical to the 'activated' macrophages from normal mice.     

Distribution of proteoglycans and hyaluronic acid in transverse sections of bovine thoracic aorta

Summary The distribution of hyaluronic acid and proteoglycans in bovine thoracic aorta was studied by Alcian Blue staining of frozen tissue sections under controlled electrolyte conditions with and without prior enzymic digestion. Some sections were digested with chondroitinase ABC, testicular hyaluronidase or bacterial collagenase and subsequent staining permitted conclusions to be drawn about the distribution of specific glycosaminoglycans within the tissue. The total glycosaminoglycan content was maximal in the intima and decreased across the arterial wall to the outermost adventitial layer. The content of proteoglycan containing chondroitin sulphate and/or dermatan sulphate chains paralleled this distribution. However, other glycosaminoglycans also contributed significantly to staining, although there was no evidence for any appreciable concentration of heparin or highly sulphated heparan sulphate.Several experiments indicated that proteoglycan containing chondroitin sulphate and/or dermatan sulphate was associated with elastic laminae which were often seen stained along their periphery. Hyaluronic acid was present at significant concentrations in all locations of the aorta and there was evidence for a similar distribution of heparan sulphate which was possibly also present at a high concentration in the endothelium. Staining of sections after treatment with 4m guanidinium chloride confirmed that this extractant removed most of the proteoglycan from the tissue section.     

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.     

A chondroitin sulphate proteoglycan from human cultured glial cells aggregates with hyaluronic acid

Media harvested from cultures of glial cells grown in the presence of ³⁵S-sulphate were shown to contain ³⁵S-labelled proteoglycans. One of the components was a chondroitin sulphate proteoglycan that had an apparent monomer size similar to that of cartilage-derived chondroitin sulphate proteoglycan. The glial proteoglycan formed aggregates in the presence of hyaluronic acid; aggregation was abolished in the presence of deca- to tetradecasaccharides derived from hyaluronic acid or by previous reduction and alkylation of the proteoglycan. It is concluded that the ability to produce large chondroitin sulphate proteoglycan molecules capable of binding to hyaluronic acid is not confined to cartilage cells.     

Antiangiogenic effect of sulphated and nonsulphated glycosaminoglycans and polysaccharides in the chick embryo chorioallantoic membrane

The inhibiting effect of sulphated and nonsulphated glycosaminoglycans and polysaccharides on the normal outgrowth of capillaries was tested in the chick embryo chorioallantoic membrane (CAM) with and without the presence of hydrocortisone. An antiangiogenic response to 50 µg of heparin and heparan sulphate (without hydrocortisone present) was observed in 38.8% and 23.1% of the CAMS, respectively, while the antiangiogenic response rate for dermatan sulphate, chondroitin sulphate A or C, hyaluronic acid and keratan sulphate was 15.9–0%. All sulphated homopolysaccharides tested were more effective than the naturally occurring glycosaminoglycans. Nonsulphated dextran and (methyl) cellulose had no antiangiogenic effect, while largely desulphated heparin retained such an effect. Hydrocortisone generally improved the antiangiogenic effect, a 100% response was obtained when it was combined with cellulose sulphate or fucoidan (polyfucose sulphate derived from marine algae), but the antiangiogenic effect of the largely desulphated heparin was unaffected by the presence of hydrocortisone. The results show that different polysulphated polysaccharides also have an antiangiogenic effect, without the addition of corticosteroids. The effect was apparently independent of their degree of sulphation, but the glycosidic structure may be of critical importance.