Isolation and characterization of dermatan sulphate and heparan sulphate proteoglycans from fibroblast culture.

35SO42(-)- and [3H]leucine-labelled proteoglycans were isolated from the medium and cell layer of human skin fibroblast cultures. Measures were taken to avoid proteolytic modifications during isolation by adding guanidinium chloride and proteolysis inhibitors immediately after harvest. The proteoglycans were purified and fractionated by density-gradient centrifugation, followed by gel and ion-exchange chromatography. Our procedure permitted the isolation of two major proteoglycan fractions from the medium, one large, containing glucuronic acid-rich dermatan sulphate chains, and one small, containing iduronic acid-rich ones. The protein core of the latter proteoglycan had an apparent molecular weight of 47000 as determined by polyacrylamide-gel electrophoresis, whereas the protein core of the former was considerably larger. The major dermatan sulphate proteoglycan of the cell layer was similar to the large proteoglycan of the medium. Only small amounts of the iduronic acid-rich dermatan sulphate proteoglycan could be isolated from the cell layer. Instead most of the iduronic acid-rich glycans appeared as free chains. The heparan sulphate proteoglycans found in the cell culture were largely confined to the cell layer. This proteoglycan was of rather low buoyant density and seemed to contain a high proportion of protein. The major part of the heparan sulphate proteoglycan from the medium had a higher buoyant density and contained a smaller amount of protein.     

Inventory of human skin fibroblast proteoglycans. Identification of multiple heparan and chondroitin/dermatan sulphate proteoglycans.

Heparan sulphate and chondroitin/dermatan sulphate proteoglycans of human skin fibroblasts were isolated and separated after metabolic labelling for 48 h with 35SO4(2-) and/or [3H]leucine. The proteoglycans were obtained from the culture medium, from a detergent extract of the cells and from the remaining ''matrix'', and purified by using density-gradient centrifugation, gel and ion-exchange chromatography. The core proteins of the various proteoglycans were identified by electrophoresis in SDS after enzymic removal of the glycosaminoglycan side chains. Skin fibroblasts produce a number of heparan sulphate proteoglycans, with core proteins of apparent molecular masses 350, 250, 130, 90, 70, 45 and possibly 35 kDa. The major proteoglycan is that with the largest core, and it is principally located in the matrix. A novel proteoglycan with a 250 kDa core is almost entirely secreted or shed into the culture medium. Two exclusively cell-associated proteoglycans with 90 kDa core proteins, one with heparan sulphate and another novel one with chondroitin/dermatan sulphate, were also identified. The heparan sulphate proteoglycan with the 70 kDa core was found both in the cell layer and in the medium. In a previous study [Fransson, Carlstedt, Cöster & Malmström (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 5657-5661] it was suggested that skin fibroblasts produce a proteoglycan form of the transferrin receptor. However, the core protein of the major heparan sulphate proteoglycan now purified does not resemble this receptor, nor does it bind transferrin. The principal secreted proteoglycans are the previously described large chondroitin sulphate proteoglycan (PG-L) and the small dermatan sulphate proteoglycans (PG-S1 and PG-S2).     

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.     

Dermatan sulphate proteoglycans of human articular cartilage. The properties of dermatan sulphate proteoglycans I and II.

Dermatan sulphate proteoglycans were purified from juvenile human articular cartilage, with a yield of about 2 mg/g wet wt. of cartilage. Both dermatan sulphate proteoglycan I (DS-PGI) and dermatan sulphate proteoglycan II (DS-PGII) were identified and the former was present in greater abundance. The two proteoglycans could not be resolved by agarose/polyacrylamide-gel electrophoresis, but could be resolved by SDS/polyacrylamide-gel electrophoresis, which indicated average Mr values of 200,000 and 98,000 for DS-PGI and DS-PGII respectively. After digestion with chondroitin ABC lyase the Mr values of the core proteins were 44,000 for DS-PGI and 43,000 and 47,000 for DS-PGII, with the smaller core protein being predominant in DS-PGII. Sequence analysis of the N-terminal 20 amino acid residues reveals the presence of a single site for the potential substitution of dermatan sulphate at residue 4 of DS-PGII and two such sites at residues 5 and 10 for DS-PGI.     

The synthesis of dermatan sulphate proteoglycans by fetal and adult human articular cartilage.

Non-aggregating dermatan sulphate proteoglycans can be extracted from both fetal and adult human articular cartilage. The dermatan sulphate proteoglycans appear to be smaller in the adult, this presumably being due to shorter glycosaminoglycan chains, and these chains contain a greater proportion of their uronic acid residues as iduronate. Both the adult and fetal dermatan sulphate proteoglycans contain a greater amount of 4-sulphation than 6-sulphation of the N-acetylgalactosamine residues, in contrast with the aggregating proteoglycans, which always show more 6-sulphation on their chondroitin sulphate chains. In the fetus the major dermatan sulphate proteoglycan to be synthesized is DS-PGI, though DS-PGII is synthesized in reasonable amounts. In the adult, however, DS-PGI synthesis is barely detectable relative to DS-PGII, which is still synthesized in substantial amounts. Purification of the dermatan sulphate proteoglycans from adult cartilage is hampered by the presence of degradation products derived from the large aggregating proteoglycans, which possess similar charge, size and density properties, but which can be distinguished by their ability to interact with hyaluronic acid.     

The presence of a cartilage-like proteoglycan in the adult human meniscus.

Proteoglycans were extracted from the adult human meniscus under dissociative conditions and purified by CsCl-density-gradient centrifugation. The preparations of highest density contained proteoglycan that possessed the ability to interact with hyaluronic acid, was of large subunit size and was composed of chondroitin sulphate, keratan sulphate and sialic acid-containing oligosaccharides. This 'cartilage-like' proteoglycan also exhibited subunit and aggregate structures analogous to those of hyaline-cartilage proteoglycans when examined by electron microscopy. However, the composition of this proteoglycan was more comparable with proteoglycans from immature cartilage than from age-matched cartilage. The preparations from lower density, which were enriched in dermatan sulphate, contained smaller proteoglycan that was not able to interact with hyaluronic acid. This non-aggregating proteoglycan may be structurally distinct from the 'cartilage-like' proteoglycan, which does not contain dermatan sulphate.     

Biosynthesis and secretion of dermatan sulphate proteoglycans in cultures of human skin fibroblasts.

Fibroblasts in culture were incubated with [3H]leucine and [35S]sulphate for 1-24 h. A large glucuronic acid-rich and a small iduronic acid-rich dermatan sulphate proteoglycan were isolated with the use of isopycnic density-gradient centrifugation, ion-exchange and gel chromatography. After 3 h the accumulation in the cell layer of the small proteoglycan reached a steady state, whereas the large one continued to increase, albeit more slowly. In the medium both proteoglycans accumulated 'linearly', although the large one appeared somewhat later than the small one. The composition of the polysaccharide chains and the size of the protein cores did not vary during the experiment. The two proteoglycans were synthesized at approximately similar rates, but were distributed differently in the culture. The small proteoglycan was mainly confined to the medium, whereas the large one was found in the medium as well as in a cell-associated pool. There was an intracellular accumulation of iduronic acid-rich dermatan sulphate as free polysaccharides.     

Proteoglycans of bovine periodontal ligament and skin. Occurrence of different hybrid-sulphated galactosaminoglycans in distinct proteoglycans.

A proteoglycan purified from 4 M-guanidinium chloride extracts of bovine periodontal ligament closely resembled that of bovine skin, except for a rather lower protein content and a higher molecular weight (120 000 compared with about 90 000) by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. The latter difference was explained by the molecular weights (29 000 and 16 000) of the respective dermatan sulphate components, each of which was rich in L-iduronate (about 75% of the total hexuronate). Significant amounts of other glycosaminoglycans did not occur in these proteoglycans, which were homogenous on gel chromatography and agarose/polyacrylamide-gel electrophoresis. Polydispersity was observed in sedimentation equilibrium experiments, but proteolysis or self-association of the proteodermatan sulphates may have affected these results. Ligament proteoglycans that were almost completely extracted with 0.1 M-NaCl contained less protein of a completely different amino acid composition than the proteodermatan sulphates. They were heterogeneous in size but generally smaller than cartilage proteoglycans and L-iduronate was a component, comprising about 7% of the total hexuronate of the sulphated galactosaminoglycan chains. The latter consisted of two fractions differing in molecular weight, but a dermatan sulphate with a high L-iduronate content was not present. These proteoglycans had some resemblance to D-glucuronate-rich proteoglycans of other non-cartilaginous tissues. Such compounds, however, are difficult to categorize at present.     

Transforming growth factor-beta induces selective increase of proteoglycan production and changes in the copolymeric structure of dermatan sulphate in human skin fibroblasts.

Human embryonic skin fibroblasts were pretreated with transforming growth factor-beta (TGF-beta) for 6 h and then labeled with [35S]sulphate and [3H]leucine for 24 h. Radiolabeled proteoglycans from the culture medium and the cell layer were isolated and separated by isopycnic density-gradient centrifugation, followed by gel, ion-exchange and hydrophobic-interaction chromatography. The major proteoglycan species were examined by polyacrylamide gel electrophoresis in sodium dodecyl sulphate before and after enzymatic degradation of the polysaccharide chains. The results showed that TGF-beta increased the production of several different 35S-labelled proteoglycans. A large chondroitin/dermatan sulphate proteoglycan (with core proteins of approximately 400-500 kDa) increased 5-7-fold and a small dermatan sulphate proteoglycan (PG-S1, also termed biglycan, with a core protein of 43 kDa) increased 3-4-fold both in the medium and in the cell layer. Only a small effect was observed on another dermatan sulphate proteoglycan, PG-S2 (also named decorin). These observations are generally in agreement with results of other studies using similar cell types. In addition, we have found that the major heparan sulphate proteoglycan of the cell layer (protein core approximately 350 kDa) was increased by TGF-beta treatment, whereas all the other smaller heparan sulphate proteoglycans with protein cores from 250 kDa to 30 kDa appeared unaffected. To investigate whether TGF-beta also influences the glycosaminoglycan (GAG) chain-synthesizing machinery, we also characterized GAGs derived from proteoglycans synthesized by TGF-beta-treated cells. There was generally no increase in the size of the GAG chains. However, the dermatan sulphate chains on biglycan and decorin from TGF-beta treated cultures contained a larger proportion of D-glucuronosyl residues than those derived from untreated cultures. No effect was noted on the 4- and 6-sulphation of the GAG chains. By the use of p-nitrophenyl beta-D-xyloside (an initiator of GAG synthesis) it could be demonstrated that chain synthesis was also enhanced in TGF-beta-treated cells (approximately twofold). Furthermore, the dermatan sulphate chains synthesized on the xyloside in TGF-beta-treated fibroblasts contained a larger proportion of D-glucuronosyl residues than those of the control. These novel findings indicate that TGF-beta affects proteoglycan synthesis both quantitatively and qualitatively and that it can also change the copolymeric structure of the GAG by affecting the GAG-synthesizing machinery. Altered proteoglycan structure and production may have profound effects on the properties of extracellular matrices, which can affect cell growth and migration as well as organisation of matrix fibres.     

Aortic endothelial cells synthesize a large chondroitin sulphate proteoglycan capable of binding to hyaluronate.

Confluent cultures of mouse aortic endothelial (END-D) were incubated with either [35S]methionine or 35SO4 2-, and the radiolabelled proteoglycans in media and cell layers were analysed for their hyaluronate-binding activity. The proteoglycan subfraction which bound to hyaluronate accounted for about 18% (media) and 10% (cell layers) of the total 35S radioactivity of each proteoglycan fraction. The bound proteoglycan molecules could be dissociated from the aggregates either by digestion with hyaluronate lyase or by treatment with hyaluronate decasaccharides. Digestion of [methionine-35S]proteoglycans with chondroitinase and/or heparitinase, followed by SDS/polyacrylamide-gel electrophoresis, indicated that the medium and cell layer contain at least three chondroitin sulphate proteoglycans, one dermatan sulphate proteoglycan, and two heparan sulphate proteoglycans which differ from one another in the size of core molecules. Among these, only the hydrodynamically large chondroitin sulphate species with an Mr 550,000 core molecule was shown to bind to hyaluronate. A very similar chondroitin sulphate proteoglycan capable of binding to hyaluronate was also found in cultures of calf pulmonary arterial endothelial cells (A.T.C.C. CCL 209). These observations, together with the known effects of hyaluronate on various cellular activities, suggest the existence of possible specialized functions of this proteoglycan subspecies in cellular processes characteristic of vascular development and diseases.     

Isolation of 35S- and 3H-labelled proteoglycans from cultures of human embryonic skin fibroblasts.

35SO42- - and [3H]-leucine-labelled proteoglycans were isolated from the medium of a fibroblast culture, from an EDTA extract of the monolayer, and from consecutive dithiothreitol and guanidine hydrochloride extracts of the cells. Proteoglycans of different sizes were isolated from the extracts by gel chromatography on Sepharose 4B. In the medium and the EDTA extract the largest proteoglycans contained only 35S-labelled galactosaminoglycan, whereas all other fractions contained in addition heparan [35S-labelled galactosaminoglycan, whereas all other fractions contained in addition heparin [35S]sulphate. The galactosaminoglycan-containing proteoglycans of the various extracts were separated into a larger component, containing chondroitin sulphate-like side chains, and a smaller component, containing dermatan sulphate. The larger proteoglycan of the medium showed reversible association-dissociation behaviour when chromatographed on Sepharose CL2B in phosphate-buffered saline and 4M-guanidine hydrochloride respectively. This property remained after removal of extraneous proteins by CsCl-density-gradient centrifugation in guanidine hydrochloride. The association was markedly increased by the addition of high-molecular-weight hyaluronic acid.     

The dermatan sulfate proteoglycans of bovine sclera and their relationship to those of articular cartilage. An immunological and biochemical study

Dermatan sulfate proteoglycans were isolated from adult bovine sclera and adult bovine articular cartilage. Their immunological relationships were studied by enzyme-linked immunosorbent assays using polyclonal antibodies raised against the large and small dermatan sulfate proteoglycans from sclera and a polyclonal and monoclonal antibody directed against the small dermatan sulfate proteoglycans from cartilage. The small dermatan sulfate proteoglycans from sclera and cartilage displayed immunological cross-reactivity while there was no convincing evidence of shared epitope(s) with the larger dermatan sulfate proteoglycans, nor did these larger proteoglycans share any common epitopes with each other. A hyaluronic acid binding region was detected immunologically on the larger scleral dermatan sulfate proteoglycan but was absent from the larger dermatan sulfate proteoglycan of cartilage and both the small dermatan sulfate proteoglycans. These antibodies were used in immunofluorescence microscopy to localize the scleral proteoglycans and molecules containing these epitopes in the eye. The large scleral dermatan sulfate proteoglycan was restricted to sclera while molecules related to the small scleral and cartilage proteoglycans were found in the sclera, anterior uveal tract, iris, and cornea. Amino acid sequencing of the amino-terminal regions of the core proteins of the small dermatan sulfate proteoglycans from sclera and articular cartilage showed that all the first 14 amino acids analyzed were identical and the same as reported earlier for the small bovine skin and tendon dermatan sulfate proteoglycans. These studies demonstrate that the larger dermatan sulfate proteoglycans of sclera and cartilage are chemically unrelated to each other and to the smaller dermatan sulfate proteoglycans isolated from these tissues. The latter have closely related core proteins and probably represent a molecule with a widespread distribution in which the degree of epimerization of glucuronic acid and iduronic acid varies between tissues.     

A chondroitin sulphate proteoglycan from human cultured glial and glioma cells. Structural and functional properties.

A chondroitin sulphate proteoglycan capable of forming large aggregates with hyaluronic acid was identified in cultures of human glial and glioma cells. The glial- cell- and glioma-cell-derived products were mutually indistinguishable and had some basic properties in common with the analogous chondroitin sulphate proteoglycan of cartilage: hydrodynamic size, dependence on a minimal size of hyaluronic acid for recognition, stabilization of aggregates by link protein, and precipitability with antibodies raised against bovine cartilage chondroitin sulphate proteoglycan. However, they differed in some aspects: lower buoyant density, larger, but fewer, chondroitin sulphate side chains, presence of iduronic acid-containing repeating units, and absence (less than 1%) of keratan sulphate. Apparently the major difference between glial/glioma and cartilage chondroitin sulphate proteoglycans relates to the glycan rather than to the protein moiety of the molecule.     

Analysis of glycosaminoglycan chains from different proteoglycan populations in human embryonic skin fibroblasts.

1. The structure of chondroitin/dermatan and heparan-sulphate chains from various proteoglycan populations derived from cultured human skin fibroblasts have been examined. Confluent cell cultures were biosynthetically labelled with [3H]-glucosamine and 35SO4(2-), and proteoglycans were purified according to buoyant density, size and charge density [Schmidtchen, A., Carlstedt, I., Malmstr?m, A. & Fransson, L.-A. (1990) Biochem. J. 265, 289-300]. Some proteoglycan fractions were further fractionated according to hydrophobicity on octyl-Sepharose in Triton X-100 gradients. The glycosaminoglycan chains, intact or degraded by chemical or enzymic methods were then analysed by gel chromatography on Sepharose CL-6B, Bio-Gel P-6, ion exchange HPLC and gel electrophoresis. 2. Three types of dermatan-sulphate chains were identified on the basis of disaccharide composition and chain length. They were derived from the large proteoglycan, two small proteoglycans and a cell-associated proteoglycan with core proteins of 90 kDa and 45 kDa. Intracellular, free dermatan-sulphate chains were very similar to those of the small proteoglycans. 3. Heparan-sulphate chains from different proteoglycans had, in spite of small but distinct differences in size, strikingly similar compositional features. They contained similar amounts of D-glucuronate, L-iduronate (with or without sulphate) and N-sulphate groups. They all displayed heparin-lyase-resistant domains with average molecular mass of 10-15 kDa. The heparan-sulphate chains from proteoglycans with 250-kDa and 350-kDa cores were the largest greater than 50 kDa), containing an average of four or five domains, in contrast to heparan-sulphate chains from the small heparan-sulphate proteoglycans which had average molecular mass of 45 kDa and consisted of three or four such domains. Free, cell-associated heparan-sulphate chains were heterogeneous in size (5-45 kDa). 4. These results suggest that the core protein may have important regulatory functions with regard to dermatan-sulphate synthesis. On the other hand, synthesis of heparan sulphate may be largely controlled by the cell that expresses a particular proteoglycan core protein.     

Effect of trimethylcolchicinic acid on the synthesis and excretion of proteoglycans in tissue culture.

The action of trimethylcolchicinic acid on the synthesis and excretion of proteoglycans has been studied on the L cell strain. The incorporation of precursors has been measured, and proteoglycans produced in the culture medium have been extracted and their concentration determined. The mucopolysaccharide components have been studied by electrophoresis. Control cultures produce hyaluronic acid, dermatan sulfate and very low concentrations of chondroitin 4-sulphate or 6-sulphate. Cultures treated with trimethycolchicinic acid (4 mu g/ml) produce hyaluronic acid, very high concentrations of chondroitin 4-sulphate or 6-sulphate and only traces of dermatan sulphate. So, trimethylcolchicinic acid does not modify the synthesis of hyaluronic acid: it considerably increases the production of chondroitin 4-sulphate or 6-sulphate and inhibits the production of dermatan sulphate. Protein fraction of the proteoglycans is proportionally increased in treated cultures, but there is no marked difference between amino acid concentrations of proteoglycans extracted from control and treated cultures. A slight fall in the cystine concentrations was the only change in the amino acid content of proteoglycans extracted from treated cultures. A hypothesis to explain these results is discussed.     

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.     

Identification of the core proteins in proteoglycans synthesized by vascular endothelial cells.

Proteoglycans, metabolically labelled with [3H]leucine and 35SO4(2-), were isolated from the spent media and from guanidinium chloride extracts of cultured human umbilical-vein endothelial cells by using isopycnic density-gradient centrifugation, gel filtration and ion-exchange h.p.l.c. The major proteoglycan species were subjected to SDS/polyacrylamide-gel electrophoresis before and after enzymic degradation of the polysaccharide chains. The cell extract contained mainly a heparan sulphate proteoglycan that has a buoyant density of 1.31 g/ml and a protein core with apparent molecular mass 300 kDa. The latter was heterogeneous and migrated as one major and one minor band. After reduction, the apparent molecular mass of the major band increased to approx. 350 kDa, indicating the presence of intrachain disulphide bonds. The proteoglycan binds to octyl-Sepharose and its polysaccharide chains are extensively degraded by heparan sulphate lyase. The proteoglycans of the medium contained 90% of all the incorporated 35SO4(2-). Here the predominant heparan sulphate proteoglycan was similar to that of the cell extract, but was more heterogeneous and contained an additional core protein with apparent molecular mass 210 kDa. Furthermore, two different chondroitin sulphate proteoglycans were found: one 200 kDa species with a high buoyant density (approx. 1.45 g/ml) and one 100 kDa species with low buoyant density (approx. 1.3 g/ml). Both these proteoglycans have a core protein of molecular mass approx. 47 kDa.     

Endothelial heparan sulphate: Compositional analysis and comparison of chains from different proteoglycan populations

From cultures of human umbilical vein endothelial cells incubated with³H-glucosamine or³⁵S-sulphate, we have purified three heparan sulphate proteoglycans: 1) a low density (1.31 g/ml) proteoglycan from the cell extract, 2) a low density proteoglycan from the medium, and 3) a high density (>1.4 g/ml) proteoglycan from the medium. The disaccharide composition of heparan sulphate chains from the low density proteoglycan of the medium was examined, using specific chemical and enzymic degradations followed by gel chromatography and strong anion exchange HPLC. Chains released from each of the different proteoglycan populations were then compared by gel chromatography and gradient polyacrylamide gel electrophoresis before and after various specific degradations. The results indicate that heparan sulphate from human endothelial cells are large polymers (MW>50,000) of low overall sulphation (32–35%N-sulphated glucosamine and an N/O-linked sulphate ratio of 2.0) with rare and solitary heparin-like disaccharides. Heparan sulphate from the different proteoglycan populations appeared to have similar structure except that chains from the high density fraction were larger polymers.Abbreviations HSPG heparan sulphate proteoglycan - DSPG dermatan sulphate proteoglycan - GlcNAc(6S) N-acetylglucosamine 6-sulphate - GlcNAc6R glucosamine with either-OH or-OSO₃ at C-6 - GlcNR glucosamine with either-SO₃ or-COCH₃ as N-substituent - GlcNSO₃ N-sulphated glucosamine - GlcNSO₃(3S) N-sulphated glucosamine 3-sulphate - GlcA d-glucuronic acid - IdoA l-iduronic acid - IdoA(2S) iduronic acid 2-sulphate - HexA hexuronic acid - DHexA hexuronic acid with a 4,5-double bond - Xyl xylose - SAX strong anion exchange - d.p. degree of polymerization (a disaccharide has d.p.=1 etc) - AUFS absorbance units full scale The codes used for proteoglycans denote in turn: C 2, low-density (1.35–1.28 g/ml) HSPG from the cell extract; M 1a, high density (>1.4 g/ml) HSPG fraction from the spent medium; M 2a, low-density (1.31 g/ml) HSPG from the spent medium [6].     

Synthesis and release of chondroitin sulphate and heparan sulphate proteoglycans from mouse macrophagesin vitro

Macrophages were obtained from the mouse peritoneal cavity and culturedin vitro. The cells were exposed to³⁵S-sulphate for 20 h, and labelled proteoglycans were recovered from both medium and cell fractions by sodium dodecylsulphate solubilization. The cell fraction contained both proteoglycans and glycosaminoglycans, whereas only intact proteoglycans could be recovered from the medium fraction. ³⁵S-Glycosaminoglycans isolated from cell and medium fractions by papain digestion were shown to contain approximately 25% heparan sulphate and 75% galactosaminoglycans comprising 55% chondroitin sulphate and 20% dermatan sulphate. The galactosaminoglycans were shown by paper chromatography to contain more than 95% 4-sulphated units. Pulse-chase experiments showed that approximately 80% of the cell-associated material was released within 6 h of incubation.³⁵S-Proteoglycans released did not bind to the macrophages, but were recovered in a soluble form from the culture medium.Abbreviations CSPG chondroitin sulphate proteoglycan - HSPG heparan sulphate proteoglycan - SDS sodium dodecylsulphate - DME Dulbecco's Minimum Essential Medium - GAG glycosaminoglycan     

Influence of the cells on the pericellular environment. The effect of hyaluronic acid on proteoglycan synthesis and secretion by chondrocytes of adult cartilage.

The chondrocyte is a specialized cell that synthesizes proteoglycans of a type found only in cartilage and nucleus pulposus. These proteoglycans are distinct in forming multiple aggregates of unique structure in which hyaluronic acid provides a central chain to which many proteoglycan molecules are bound at one end only. Chondrocytes were isolated from adult cartilage and used in suspension culture to test the effect of compounds in the medium on the synthesis of proteoglycans. Hyaluronic acid alone, among a number of compounds extracted from or analogous to those in cartilage, reduced the incorporation of [35S] sulphate into macromolecular material.Oligosaccharides of hyaluronic acid of the size of decasaccharides and above also had this effect but hyaluronic acid already bound to proteoglycan did not. The proportion of total labelled material associated with the cells increased at the expense of that in the medium. Treatment of the cells with trypsin abolished the effect of hyaluronic acid but treatment with chondroitinase did not. It is suggested that hyaluronic acid interacts with proteoglycans at the cell surface by a specific mechanism similar to that involved in proteoglycan aggregation, as a result of which the secretion and synthesis of proteoglycans is reduced.