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.     

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.     

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).     

beta-D-xyloside-mediated alteration in the synthesis of basement membrane proteoglycan

The effect of nitrophenyl-beta-D-xyloside (xyloside), a synthetic initiator of glycosaminoglycan synthesis, on proteoglycan and glycosaminoglycan synthesis by a basement membrane producing tumor was studied. While xyloside markedly stimulated the formation of chondroitin sulfate chains, it depressed the formation of a basement membrane heparan sulfate proteoglycan and caused only little formation of free heparan sulfate chains. However, when the synthesis of the core protein of the proteoglycan was inhibited by cycloheximide, heparan sulfate chains were produced by xyloside treatment. These heparan sulfate chains had a sulfate content higher than that of heparan sulfate found on the proteoglycan. The data indicate that xyloside can substitute for the heparan sulfate initiation site on the core protein of the proteoglycan and that this initiation is enhanced in the absence of core protein. This suggests that under normal conditions the formation of heparan sulfate chains may be tightly linked to the production of the core protein.     

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.     

A fibroblast heparan sulphate proteoglycan with a 70 kDa core protein is linked to membrane phosphatidylinositol

Here we present evidence that a fibroblast heparan sulphate proteoglycan of approx. 300 kDa and with a core protein of apparent molecular mass 70 kDa is covalently linked to the plasma membranevia a linkage structure involving phosphatidylinositol. Phosphatidylinositol-specific phospholipase C releases such a heparan sulphate proteoglycan only from cells labelled with [³⁵S]sulphate in the absence of serum. Cell cultures labelled with [³H]myo-inositol in the absence or presence of serum produce a radiolabelled heparan sulphate proteoglycan which was purified by gel-permeation chromatography and ion-exchange chromatography on MonoQ. Digestion with heparan sulphate lyase and analysis by gel-permeation chromatography and sodium dodecylsulphate-polyacrylamide gel-electrophoresis revealed that the³H-label is associated with a core protein of apparent mass 70 kDa.     

Four classes of cell-associated proteoglycans in suspension cultures of articular-cartilage chondrocytes.

The characteristics of cell-associated proteoglycans were studied and compared with those from the medium in suspension cultures of calf articular-cartilage chondrocytes. By including hyaluronic acid or proteoglycan in the medium during [35S]sulphate labelling the proportion of cell-surface-associated proteoglycans could be decreased from 34% to about 15% of all incorporated label. A pulse-chase experiment indicated that this decrease was probably due to blocking of the reassociation with the cells of proteoglycans exported to the medium. Three peaks of [35S]sulphate-labelled proteoglycans from cell extracts and two from the medium were isolated by gel chromatography on Sephacryl S-500. These were characterized by agarose/polyacrylamide-gel electrophoresis, by SDS/polyacrylamide-gel electrophoresis of core proteins, by glycosaminoglycan composition and chain size as well as by distribution of glycosaminoglycans in proteolytic fragments. The results showed that associated with the cells were (a) large proteoglycans, typical for cartilage, apparently bound to hyaluronic acid at the cell surface, (b) an intermediate-size proteoglycan with chondroitin sulphate side chains (this proteoglycan, which had a large core protein, was only found associated with the cells and is apparently not related to the large proteoglycans), (c) a small proteoglycan with dermatan sulphate side chains with a low degree of epimerization, and (d) a somewhat smaller proteoglycan containing heparan sulphate side chains. The medium contained a large aggregating proteoglycan of similar nature to the large cell-associated proteoglycan and small proteoglycans with dermatan sulphate side chains with a higher degree of epimerization than those of the cells, i.e. containing some 20% iduronic acid.     

The cell surface proteoglycan from mouse mammary epithelial cells bears chondroitin sulfate and heparan sulfate glycosaminoglycans

The cell surface proteoglycan fraction isolated by mild trypsin treatment of NMuMG mouse mammary epithelial cells contains largely heparan sulfate, but also 15-24% chondroitin sulfate glycosaminoglycans. We conclude that this fraction contains a unique hybrid proteoglycan bearing both heparan sulfate and chondroitin sulfate glycosaminoglycans because (i) the proteoglycan behaves as a single species by sizing, ion exchange and collagen affinity chromatography, and by isopycnic centrifugation, even in the presence of 8 M urea or 4 M guanidine hydrochloride, (ii) the behavior of the chondroitin sulfate in these separation techniques is affected by heparan sulfate-specific probes and vice versa, and (iii) proteoglycan core protein bearing both heparan sulfate and chondroitin sulfate is recognized by a single monoclonal antibody. Removal of both types of glycosaminoglycan reduces the proteoglycan to a core protein of approximately 53 kDa. The proteoglycan fraction is heterogeneous in size, largely due to a variable number and/or length of the glycosaminoglycan chains. We estimate that one or two chondroitin sulfate chains (modal Mr of 17,000) exist on the proteoglycan for every four heparan sulfate chains (modal Mr of 36,000). Synthesis of these chains is reportedly initiated on an identical trisaccharide that links the chains to the same amino acid residues on the core protein. Therefore, some regulatory information, perhaps residing in the amino acid sequence of the core protein, must determine the type of chain synthesized at any given linkage site. Post-translational addition of these glycosaminoglycans to the protein may provide information affecting its ultimate localization. It is likely that the protein is directed to specific sites on the cell surface because of the ability of the glycosaminoglycans to recognize and bind extracellular components.     

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.     

Purification of the transforming growth factor-beta (TGF-beta) binding proteoglycan betaglycan.

We report the purification of betaglycan, a low-abundance membrane proteoglycan with high affinity for transforming growth factor-beta (TGF-beta). Betaglycan solubilized from rat embryo membrane preparations was purified to near-homogeneity by sequential chromatography through DEAE-Trisacryl, wheat germ lectin-Sepharose, and TGF-beta 1-agarose. Purified betaglycan has properties similar to betaglycan affinity-labeled in intact cells: it binds TGF-beta 1 and TGF-beta 2 with KD approximately 0.2 nM, contains heparan sulfate and chondroitin sulfate glycosaminoglycan (GAG) chains and N-linked glycans attached to a 110-kDa core protein, and can spontaneously associate with phosphatidylcholine liposomes. The betaglycan core obtained by enzymatic removal of the GAG chains has high affinity for TGF-beta and associates with artificial liposomes, indicating that the core protein binds TGF-beta and anchors to membranes independently of the GAG chains present on the native protein or of any ancillary protein.     

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

We have used suramin and brefeldin A to investigate the natureof a heparan sulphate proteoglycan that appears to recycle fromthe cell surface to intracellular compartments which synthesizenew heparan sulphate chains. Suramin, which would block internalizationand deglycanation of a putative recycling cell surface proteoglycan,markedly increases the yield of a membrane-bound proteoglycanwith a core protein of 60–70 kDa and unusually long heparansulphate side chains. When transport of newly made core proteinsto their Golgi sites for glycosaminoglycan assembly is blocked,by using brefeldin A, [³H]glucosamine and [³⁵S]sulphate incorporationinto cell surface-bound heparan sulphate proteoglycan can stilltake place. After chemical biotinylation of cell surface proteinsin brefeldin A-treated cells, followed by metabolic [³⁵S]sulphationin the presence of the same drug, biotin-tagged [³⁵S]proteoglycancan be demonstrated, indicating the presence of recycling proteoglycanspecies. By prelabelling cells with [³H]leucine or [³H]inositolin the presence of suramin, followed by chase labelling with[³⁵S]sulphate in the presence of brefeldin A, a ³H- and ³⁵S-labelled,hydrophobic heparan sulphate proteoglycan with a core proteinof 60–65 kDa is obtained. The proteoglycan loses its hydrophobicitywhen glucosamineinositol bonds are cleaved, indicating thatit is membrane bound via a glycosylphosphatidylinositol anchor.However, treatment with phosphatidylinositol-specific phospholipaseC has no effect, suggesting that the inositol moiety may beacylated. We propose that a portion of the lipid-anchored proteoglycanglypican is internalized, recycled via the Golgi, where heparansulphate chains are added, and finally re-deposited at the cellsurface. glycosylphosphatidylinositol-anchored glypican heparan sulphate proteoglycan recycling     

Fractionation of proteoglycans from bovine corneal stroma.

Proteoglycans were extracted from bovine corneal stroma with 4M-guanidinum chloride, purified by DEAE-dellulose chromatography (Antonopoulos et al., 1974) and fractionated by precipitation with ethanol into three fractions of approximately equal weight. One of these fractions consisted of a proteoglycan that contained keratan sulphate as the only glycosaminoglycan. In the othertwo fractions proteoglycans that contained chondroitin sulphate, dermatan sulphate and keratan sulphate were present. Proteoglycans which had a more than tenfold excess of galactosaminoglycans over keratan sulphate could be obtianed by further subfractionation. The gel-chromatographic patterns of the glucosaminoglycans before and after digestion with chondroitinase AC differed for the fractions. The individual chondroitin sulphate chains seemed to be larger in cornea than in cartilage. Oligosaccharides, possibly covalently linked to the protein core of the proteoglycans, could be isolated from all fractions. The corneal proteoglycans were shown to have higher protein contents and to be of smaller molecular size than cartilage proteoglycans.     

Expression of collagen XVIII and localization of its glycosaminoglycan attachment sites

Collagen XVIII is the only currently known collagen that carries heparan sulfate glycosaminoglycan side chains. The number and location of the glycosaminoglycan attachment sites in the core protein were determined by eukaryotic expression of full-length chick collagen XVIII and site-directed mutagenesis. Three Ser-Gly consensus sequences carrying glycosaminoglycan side chains were detected in the middle and N-terminal part of the core protein. One of the Ser-Gly consensus sequences carried a heparan sulfate side chain, and the remaining two had mixed chondroitin and heparan sulfate side chains; thus, recombinant collagen XVIII was a hybrid of heparan sulfate and chondroitin proteoglycan. In contrast, collagen XVIII from all chick tissues so far assayed have exclusively heparan sulfate side chains, indicating that the posttranslational modification of proteins expressed in vitro is not entirely identical to the processing that occurs in a living embryo. Incubating the various mutated collagen XVIIIs with retinal basement membranes showed that the heparan sulfate glycosaminoglycan side chains mediate the binding of collagen XVIII to basement membranes.     

Structure and metabolism of rat liver heparan sulphate

Rat liver cells grown in primary cultures in the presence of [³⁵S]sulphate synthesize a labelled heparan sulphate-like glycosaminoglycan. The characterization of the polysaccharide as heparan sulphate is based on its resistance to digestion with chondroitinase ABC or hyaluronidase and its susceptibility to HNO₂ treatment. The sulphate groups (including sulphamino and ester sulphate groups) are distributed along the polymer in the characteristic block fashion. In ³H-labelled heparan sulphate, isolated after incubation of the cells with [³H]galactose, 40% of the radioactive uronic acid units are l-iduronic acid, the remainder being d-glucuronic acid. The location of heparan sulphate at the rat liver cell surface is demonstrated; part of the labelled polysaccharide can be removed from the cells by mild treatment with trypsin or heparitinase. Further, a purified plasma-membrane fraction isolated from rats previously injected with [³⁵S]sulphate contains radioactively labelled heparan sulphate. A proteoglycan macromolecule composed of heparan sulphate chains attached to a protein core can be solubilized from the membrane fraction by extraction with 6m-guanidinium chloride. The proteoglycan structure is degraded by treatment with papain, Pronase or alkali. The production of heparan [³⁵S]sulphate by rat liver cells incubated in the presence of [³⁵S]sulphate was followed. Initially the amount of labelled polysaccharide increased with increasing incubation time. However, after 10h of incubation a steady state was reached where biosynthetic and degradative processes were in balance.     

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.     

Stimulation of heparan sulphate synthesis in cultured rat hepatocytes by (+)-catechin.

The secretion of heparan sulphate by cultured rat hepatocytes was increased in the presence of (+)-catechin. The increase was due to a new species of heparan sulphate that lacked the carbohydrate-protein linkage between xylose and serine in normal heparan sulphate proteoglycan. The mean molecular weight of this heparan sulphate varied between 6300 and 9500, was not affected by treatment with alkali or Pronase and was 2-3-fold lower than that of chains released from heparan sulphate proteoglycan. After digestion with Pronase, only a minor fraction of chains contained serine, and after treatment with alkali and NaB3H4 reduction less than 5% of the chains exposed [3H]xylitol at the reducing terminals. These results suggested that (+)-catechin or metabolites of it acted as acceptors of heparan sulphate synthesis. In cultures treated wih cycloheximide, synthesis of heparan sulphate decreased to less than 5%. (+)-Catechin could restore the heparan sulphate synthesis to almost normal values. The (+)-catechin-induced heparan sulphate was secreted. Only a small fraction was incorporated into the plasma membrane or other cellular compartments. This may indicate that the protein core is essential for association of heparan sulphate with cellular compartments.     

Biosynthesis of proteoglycans by isolated rabbit glomeruli

Isolated rabbit glomeruli were incubated in vitro with 35SO4 in order to analyze the proteoglycans synthesized. Proteoglycans extracted with 4 M guanidine HCl from whole isolated glomeruli and from purified glomerular basement membrane (GBM) were analyzed by gel filtration chromatography. Two types of sulfated proteoglycans were found to be synthesized by rabbit glomeruli and these contained either heparan sulfate or chondroitin/dermatan sulfate glycosaminoglycan chains. These glycosaminoglycans were characterized by their sensitivity to selective degradation by nitrous acid or chondroitinase ABC, respectively. The major proteoglycan extracted from the whole glomeruli was a chondroitin/dermatan sulfate species (75%), while purified GBM contained mostly heparan sulfate (70%). The glycosaminoglycan chains were estimated to be about 12,000 molecular weight which is consistent with previous estimates for similar molecules extracted from the rat GBM.     

Visualization of the large heparan sulfate proteoglycan from basement membrane

Kleinschmidt spreading, negative staining, and rotary shadowing were used to examine the large form of (basement membrane) heparan sulfate proteoglycan in the electron microscope. Heparan sulfate proteoglycan was visualized as consisting of two parts: the core protein and, emerging from one end of the core protein, the glycosaminoglycan side chains. The core protein usually appeared as an S-shaped rod with about six globules along its length. Similar characteristics were observed in preparations of core protein in which the side chains had been removed by heparitinase treatment ("400-kDa core") as well as in a 200-kDa trypsin fragment ("P200") derived from one end of the core protein. The core protein was sensitive to lyophilization and apparently also to the method of examination, being condensed following Kleinschmidt spreading (length means = 52 nm) and extended following negative staining (length means = 83 nm) or rotary shadowing (length means = 87 nm; 400-kDa core length means = 80 nm; P200 length means = 44 nm). Two or three glycosaminoglycan side chains (length means = 146 +/- 53 nm) were attached to one end of the core protein. The side chains often appeared tangled or to merge together as one. Thus, the large heparan sulfate proteoglycan from basement membrane is an asymmetrical molecule with a core protein containing globular domains and terminally attached side chains. This structure is in keeping with that previously predicted by enzymatic digestions and with the proposed orientation in basement membranes, i.e., the core protein bound in the lamina densa and the heparan sulfate side chains in the lamina lucida arranged along the surface of the basement membranes.     

Structural characterization of proteoheparan sulfate isolated from plasma membranes of an ascites hepatoma,AH 66

A proteoglycan isolated from plasma membranes of an ascites hepatoma, AH 66, was characterized structurally. The glycosaminoglycan was obtained by alkali treatment and was identified as heparan sulfate. It was essentially the only type of carbohydrate chain attached to the core protein. The identification was based on chemical analysis, electrophoresis, and digestibility with heparitinase from Flavobacterium heparinum. Analysis of neutral sugars of the proteoglycan by mass fragmentography indicated the presence of xylose and galactose which should be involved in the linkage region between a heparan sulfate chain and the core protein. The weight-average molecular weights of the proteoglycan and its heparan sulfate chain were determined to be 71,000 and 21,000, respectively, by meniscus depletion equilibrium centrifugation. The latter value was in good agreement with those obtained by chemical analysis and by gel filtration. From these values for molecular weight and the protein content of the proteoglycan (10.6%), the molecular weight of the core protein was estimated to be 7500. On the basis of these molecular parameters, it was proposed that three heparan sulfate chains on average are linked to the core protein.