Endogenous hyaluronate-cell surface interactions in 3T3 and simian virus-transformed 3T3 cells

3T3 cells have a large, pericellular coat which contains 30 times more hyaluronate than the amount of cell surface hyaluronate associated with simian virus 40-transformed 3T3 (SV-3T3) cells. On the other hand, SV-3T3 cells have high affinity binding sites for exogenously added hyaluronate, whereas 3T3 cells have much lower affinity sites. Removal of cell surface hyaluronate from SV-3T3 cells by treatment with hyaluronidase caused a reproducible increase in their maximum binding capacity for exogenous hyaluronate but no significant change in binding affinity or specificity. For 3T3 cells, however, the maximum amount of binding decreased and the affinity of binding increased after hyaluronidase treatment. When endogenous cell surface hyaluronate was labeled metabolically and then the cells incubated in the presence of exogenous unlabeled hyaluronate, the labeled cell surface hyaluronate was quantitatively displaced from the SV-3T3 cells but was not displaced from the 3T3 cells. Chondroitin sulfate and heparin did not displace cell surface hyaluronate from either cell type. Membranes isolated from SV-3T3 cells bound hyaluronate specifically and with high affinity, whereas membranes from 3T3 cells did not consistently bind a significant amount of hyaluronate. We conclude from these studies that the retention of endogenous hyaluronate on the surface of SV-3T3 cells is mediated by binding sites similar to those detected by the addition of exogenous hyaluronate, and the mechanism of retention of endogenous hyaluronate on the surface of 3T3 cells differs from SV-3T3 cells.     

Aggregation of macrophages and fibroblasts is inhibited by a monoclonal antibody to the hyaluronate receptor

To examine the role of the hyaluronate receptor in cell to cell adhesion, we have employed the K-3 monoclonal antibody (MAb) which specifically binds to the hyaluronate receptor and blocks its ability to interact with hyaluronate. In the first set of experiments, we investigated the spontaneous aggregation of SV-3T3 cells, which involves two distinct mechanisms, one of which is dependent upon the presence of divalent cation and the other is independent. The divalent cation-independent aggregation was found to be completely inhibited by both intact and Fab fragments of the K-3 MAb. In contrast, the K-3 MAb had no effect on the divalent cation-dependent aggregation of cells. In a second set of experiments, we examined alveolar macrophages. The presence of hyaluronate receptors on alveolar macrophages was demonstrated by the fact that detergent extracts of these cells could bind [3H]hyaluronate, and this binding was blocked by the K-3 MAb. Immunoblot analysis of alveolar macrophages showed that the hyaluronate receptor had a Mr of 99,500, which is considerably larger than the 85,000 Mr for that on BHK cells. When hyaluronate was added to suspensions of alveolar macrophages, the cells were induced to aggregate. This effect was inhibited by the K-3 MAb, suggesting that the hyaluronate-induced aggregation was mediated by the receptor.     

Cartilage proteoglycans. Structure and heterogeneity of the protein core and the effects of specific protein modifications on the binding to hyaluronate.

Purified proteoglycans extracted from pig laryngeal cartilage in 0.15 M-NaCl and 4 M-guanidinium chloride were analysed and their amino acid compositions determined. Selective modification of amino acid residues on the protein core confirmed that binding to hyaluronate was a function of the protein core, and was dependent on disulphide bridges, intact arginine and tryptophan residues, and epsilon-amino groups of lysine. Fluorescence measurement suggested that tryptophan was not involved in direct subsite interactions with the hyaluronate. The polydispersity in size and heterogeneity in composition of the aggregating proteoglycan was compatible with a structure based on a protein core containing a globular hyaluronate-binding region and an extended region of variable length also containing a variable degree of substitution with chondroitin sulphate chains. The non-aggregated proteoglycan extracted preferentially in 0.15 M-NaCl, which was unable to bind to hyaluronate, contained less cysteine and tryptophan than did other aggregating proteoglycans and may be deficient in the hyaluronate-binding region. Its small average size and low protein and keratan sulphate contents suggest that it may be a fragment of the chondroitin sulphate-bearing region of aggregating proteoglycan produced by proteolytic cleavage of newly synthesized molecules before their secretion from the cell.     

Hyaluronate binding properties of versican.

We have previously cloned a large chondroitin sulfate proteoglycan (versican) from human fibroblasts. The primary sequence shows that the N terminus contains sequence homology with known hyaluronate-binding molecule, suggesting that versican can bind hyaluronate. To test this hypothesis we have reconstructed a full-length versican cDNA and a versican cDNA fragment encoding the N terminus and have transfected Chinese hamster ovary cells and mouse 3T3 fibroblasts, respectively, with these constructs. The transfected Chinese hamster ovary cells make a proteoglycan shown to be versican by enzymatic and immunologic analysis. No corresponding proteoglycan was seen in the control cells. Using hyaluronate affinity chromatography, we show that recombinant versican specifically binds hyaluronate and does not bind to heparin or chondroitin sulfate. The transfected fibroblasts make a 78-kDa truncated form of versican that also binds hyaluronate and does not bind the related polysaccharides, showing that the hyaluronate binding activity resides at the N terminus of versican. The binding of versican to hyaluronate is substrate-concentration dependent and time dependent and can be competed with unlabeled versican. The dissociation constant for versican binding to hyaluronate was determined to be 4 x 10(-9) M.     

Reduced allorecognition of adenovirus-2 infected cells

The early region 3 of adenovirus 2 encodes the membrane glycoprotein E19. This protein specifically binds class I transplantation antigens of a variety of species. Concomitant with this interaction the intracellular transport of newly synthesized class I heavy chains is abrogated. At late stages of the virus infection this leads to a notable decrease in the cell surface expression of class I antigens. We have studied how infection with adenovirus 2 influences target cell recognition by alloreactive cytolytic T lymphocytes. We found that the E19 protein-induced reduction of the HLA-B7 cell surface expression led to a greatly reduced lysis of the infected cells. These findings support our hypothesis that the E19 protein has evolved to facilitate the in vivo replication of the virus by reducing the expression of HLA class I antigens.     

Release of hyaluronate from eukaryotic cells.

The mechanism of hyaluronate shedding from eukaryotic cell lines was analysed. All cell lines shed identical sizes of hyaluronate as were retained on the surface. They differed in the amount of hyaluronate synthesized and in the proportions of hyaluronate which were released and retained. A method was developed which could discriminate between shedding due to intramolecular degradation and that due to dissociation as intact macromolecules. This method was applied to B6 and SV3T3 cells in order to study the mechanism of hyaluronate release in more detail. The cells were pulse-labelled to form hyaluronate chains with labelled and unlabelled segments, and the sizes of labelled hyaluronate released into the medium during the pulse extension period were determined by gel filtration. B6 cells released identical sizes of hyaluronate at all labelled segment lengths, indicating that no intramolecular degradation occurred. When chain elongation was blocked by periodate-oxidized UDP-glucuronic acid, hyaluronate release was simultaneously inhibited. These results indicated that B6 cells dissociated hyaluronate as an intact macromolecule. In contrast, SV3T3 cells released hyaluronate of varying molecular mass distributions during extension of the labelled segment, suggesting partial degradation. Exogenous hyaluronate added to SV3T3 cultures was also degraded. This degradation could be prevented by the presence of radical scavengers such as superoxide dismutase and tocopherol. Degradation of endogenous hyaluronate could be inhibited by salicylate. These results led to the conclusion that SV3T3 cells released hyaluronate not only by dissociation, but also by radical-induced degradation.     

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.     

Hyaluronate degradation in 3T3 and simian virus-transformed 3T3 cells

The cellular control of hyaluronate levels was examined in cultures of simian virus 40-transformed 3T3 (SV3T3) and 3T3 cells which are known to differ in their metabolism of hyaluronate. When [3H]hyaluronate was added to cultures of the two cell lines, four times more ligand was bound per mg of protein by the SV3T3 cells than by the 3T3 cells. Of the bound [3H] hyaluronate, 40% was degraded by the SV3T3 cells to oligosaccharides characteristic of the breakdown of hyaluronate, but only 2% was degraded by 3T3 cells. Hyaluronidase activity was found in the cell layer and medium of the SV3T3 cultures, but was not detectable in 3T3 cells. The SV3T3 enzyme was active only at acidic pH, but at neutral pH the secreted SV3T3 hyaluronidase was thermally more stable then the cell-associated enzyme. In contrast, both cell lines were found to contain similar amounts of beta-glucuronidase and beta-N-acetylglucosaminidase activity. We conclude that the elevated capacity of SV3T3 cells to degrade hyaluronate may be partially responsible for their lack of the hyaluronate-containing pericellular coat which is prominent around 3T3 cells.     

Hyaluronate is synthesized at plasma membranes

The hybrid cell B6 line, which synthesizes large amounts of hyaluronate as the predominant glycosaminoglycan, was grown in the presence of [3H]glucosamine. The [3H]hyaluronate has a high molecular weight and was excluded by Sephacryl S-1000. After disruption of the cells the [3H]hyaluronate could further be elongated by incubation with UDP-GlcNAc and UDP-[14C]GlcA, yielding a hybrid molecule of hyaluronate labelled with [3H]GlcNAc and [14C]GlcA. Treatment of the cells with hyaluronidase before disruption eliminated the large [3H]hyaluronate and elongation of nascent chains in vitro commenced from low-molecular-weight chains. Thus nascent hyaluronate chains were degraded extracellularly by hyaluronidase and were therefore synthesized at the inner side of plasma membranes and extruded to the cell surface.     

Interaction between hyaluronate and the cell surface of Pseudomonas aeruginosa

Abstract Treatment of Pseudomonas aeruginosa cells with the non-metabolizable polysaccharide hyaluronate led to a strong increase in extracellular lipase activity. Alteration of the cell surface either by treatment with the chelator EDTA or by selecting for phage-resistant mutants significantly altered the bacterial response to hyaluronate. Binding of ¹⁴C-labeled hyaluronate to the bacteria was shown to depend on polysaccharide concentration and on cell number. Cell-free exolipase interacted with chemically cross-linked hyaluronate. The results suggested an interaction between hyaluronate and the cell surface of P. aeruginosa as a prerequisite for the polysaccharide to be effective.     

Immunochemical characterization and ultrastructural localization of chondroitin sulfates and keratan sulfate in embryonic chick bone marrow

Summary Monoclonal antibodies directed against specific carbohydrate epitopes on chondroitin 4-/dermatan sulfate, chondroitin 6-sulfate, keratan sulfate, and a monoclonal antibody directed against the hyaluronate binding region were used to characterize proteoglycans extracted from embryonic chick bone marrow. About half of the proteoglycans separate into the high density fraction on a CsCl gradient. Glycosaminoglycan-specific antibodies recognize proteoglycans from all fractions; this includes an antibody directed against keratan sulfate. Some proteoglycans, principally in the high buoyant density fraction, contain sites recognized by the antibody specific for the hyaluronate binding region. Within limits of detection, all core proteins belong to the high-molecular-weight category, with weights in excess of 212 kD. Antibodies directed against chondroitin 4-/dermatan sulfate and against keratan sulfate primarily bind to extracellular matrix material located in the extracellular spaces and to matrix elements in the pericellular regions of fibroblastic stromal cells. The antibody that recognizes chondroitin 6-sulfate binds to sites on surfaces of fibroblastic stromal cells and also to extracellular matrix material. Little or no antibody binding is detected on surfaces of granulocytic cells. These studies indicate that chondroitin sulfate and keratan sulfate chains are both present in the proteoglycan extract.     

Identification of distinct T cell receptor (TCR)-gamma delta heterodimers using an anti-TCR-gamma variable region serum

T cell hybridomas were generated from CD3+, CD4-, CD8- splenocytes and fetal thymocytes. V gamma 1-expressing proteins present on these murine TCR-gamma delta hybridomas were identified by using an anti-TCR V gamma 1 peptide serum. This antiserum specifically immunoprecipitated 41-kDa TCR V gamma-C gamma 4 chains and 31-kDa TCR V gamma-C gamma 1/2 chains from distinct heterodimers expressed on the TCR-gamma delta T cell hybridomas. The RNA from a hybridoma with a 31-kDa TCR-gamma chain hybridized with a V gamma 1 probe but failed to hybridize with a V gamma 2 probe. In contrast, the RNA from a hybridoma with a 32-kDa TCR-gamma chain hybridized with a V gamma 2 probe. This 32-kDa TCR-gamma chain was not immunoprecipitated by the anti-V gamma 1 serum. These data were consistent with the conclusion that the 31-kDa protein was the product of a V gamma 1 to C gamma 2 rearrangement, whereas the 32-kDa protein was the product of a V gamma 2 to C gamma 1 rearrangement. Furthermore, Southern analyses confirmed that the 32-kDa protein was the product of a V gamma 1.2-J gamma 2 rearrangement, and all three of the 41-kDa TCR-gamma chains were the results of V gamma 1.1-J gamma 4 rearrangements. This was the first demonstration at the clonal level of TCR-gamma proteins which use members of the V gamma 1 gene family, as well as the C gamma 2 constant region. Additional biochemical analyses of the TCR-gamma and -delta proteins from three independently derived C gamma 4-bearing T cell hybridomas suggested that most of the molecular mass diversity observed in the bulk subpopulation of peripheral C gamma 4-containing heterodimers may be contributed by the TCR-delta chains.     

Purification of a hyaluronate-binding protein fraction that modifies cell social behavior

A hyaluronate-binding protein fraction (HABP) has been purified from the supernatant media of chick fibroblas cultures by ultrafiltration and Dowex-hyaluronate affinity chromatography. This protein fraction binds more avidly to Dowex-hyaluronate than to other Dowex-glycosaminoglycans. It can be inserted into the cell layer of urea-pretreated fibroblast monolayers where it specifically increases the amount of exogenous hyaluronate, but not sulfated glycosaminoglycans, attached to the cell glycocalyx. This interaction promotes a culture morphology and nuclear overlap ratio similar to virally-transformed cells. The principal hyaluronate-binding protein in the affinity purified fraction has a m.w. app. of 60,000–63,000 daltons.     

Formation of proteoglycan aggregates in rat chondrosarcoma chondrocyte cultures treated with tunicamycin

Proteoglycan monomer and link protein isolated from the Swarm rat chondrosarcoma both contain glycosylamine-linked oligosaccharides. In monomer, these N-linked oligosaccharides are concentrated in a region of the protein core which interacts specifically with both hyaluronate and link protein to form proteoglycan aggregates present in cartilage matrix. Chondrocyte cultures were treated with tunicamycin to inhibit synthesis of the N-linked oligosaccharides, and the ability of the deficient proteoglycan and link protein to form aggregates was studied. Cultures were pretreated with tunicamycin for 3 h and then labeled with either [3H]mannose, [3H]glucosamine, [3H]serine, or with [35S]sulfate for 6 h in the presence of tunicamycin. Formation of link protein-stabilized proteoglycan aggregates in the culture medium was inhibited by up to 40% when the cells were treated with 3 micrograms of tunicamycin/ml, a concentration which inhibited 3H incorporation with mannose as a precursor by about 90%, but by only 15% with glucosamine as a precursor. When exogenous proteoglycan aggregate was added to the culture medium, however, it was found that both endogenous monomer and link protein synthesized in the presence of tunicamycin were fully able to form link-stabilized aggregates. This suggests that glycosylamine-linked oligosaccharides on monomer and on link protein are not necessary for their specific interactions with hyaluronate and with each other. Further, although tunicamycin did not inhibit net synthesis of hyaluronate, transfer of hyaluronate from the cell layer to the culture medium was retarded. This phenomenon accounted for most if not all of the decrease in the amount of proteoglycan which formed aggregates in the medium of cultures treated with tunicamycin.     

Hyaluronate accumulation and nerve-dependent growth during regeneration of larval Ambystoma limbs

Hyaluronate-mediated expansion of the extracellular matrix has been suggested as an important element of growth and morphogenesis in several developing systems. In vitro, various growth factors have been shown to stimulate hyaluronate synthesis as well as cell proliferation. A similar link between proliferation and hyaluronate production during in vivo growth is difficult to demonstrate, because in most systems the source of growth-promoting factors is either not known or not amenable to experimental manipulation. During amphibian limb regeneration, cell proliferation depends upon paracrine release of factors from axons in the limb stump, and the nerve supply can be eliminated or augmented experimentally for study of growth in this system. Denervated and amputated limbs of larval salamanders do not begin to regenerate until distal areas of the limb stumps are reinnervated. We have used such limbs to examine the effect exerted by the reappearance of nerves on the amount of hyaluronate in the tissue undergoing the growth response. Hyaluronate was demonstrated by the metachromatic dye Ethyl Stains-all, which stains hyaluronate blue while sulfated glycosaminoglycans (GAGs) and proteins in the extracellular matrix stain various shades of violet, and by microspectrophotometry of alcian-blue-stained GAGs in serial sections pretreated with buffer or with Streptomyces hyaluronidase (SH) to remove hyaluronate specifically. Both methods showed little hyaluronate in the distal region of limb stumps prior to reinnervation, while reinnervated stumps had amounts of hyaluronate similar to those of control blastemas. Autoradiography of ³H-glucosamine-labeled limbs indicated that hyaluronate in the blastemas of reinnervated limb stumps included material newly synthesized by cells throughout the growing tissue. The microspectrophotometric study revealed that the relative concentration of hyaluronate increased during the time distal limb areas were undergoing reinnervation, which was monitored by staining of nerve fibers. The increase in hyaluronate concentration was followed immediately by an increase in mitotic activity and a decrease in mesenchymal cell density, two changes leading to blastema formation that others have shown to be associated with reinnervation in this system. These observations indicate that the growth-promoting influence of nerves includes stimulation of hyaluronate production, an effect similar to that of serum or purified mitogens on many cultured cells. Hyaluronate synthesis appears to promote expansion of the limb stump, which occurs when denervated-amputated larval limbs are reinnervated.     

Two immunologically and developmentally distinct chondroitin sulfate proteolglycans in embryonic chick brain.

Two different chondroitin sulfate proteoglycans (CSPG) in embryonic chick brain were distinguished by immunoreactivity either with S103L, a rat monoclonal antibody which reacts specifically with an 11-amino-acid region in the chondroitin sulfate domain of the core protein of chick cartilage CSPG (Krueger, R. C., Jr., Fields, T. A., Mensch, J. R., and Schwartz, N. B. (1990) J. Biol. Chem. 265, 12088-12097), or with HNK-1, a mouse monoclonal antibody which reacts with a 3-sulfoglucuronic acid residue on neural glycolipids and glycoproteins (Chou, D. K. H., Ilyas, A., Evans, J. E. Costello, C., Quarles, R. H., and Jungawala, F. B. (1986) J. Biol. Chem. 261, 11717-11725) but not with both antibodies. This specific immunoreactivity was used to separate the two CSPGs for further characterization. The S103L reactive brain proteoglycan had a core protein of similar size to cartilage CSPG (370 kDa) but exhibited a smaller hydrodynamic size (K(av) of 0.308). It was substituted predominantly with chondroitin sulfate chains and virtually no keratan sulfate chains. The HNK-1 reactive CSPG had a smaller core protein (340 kDa), an even smaller hydrodynamic size (K(av) of 0.564), and was substituted with both chondroitin sulfate and keratan sulfate chains. Glycosidase digestion patterns with endo-beta-galactosidase, N-glycosidase F, neuraminidase, and O-glycosidase, and reactivity with an antibody to the hyaluronate binding region also showed significant differences between the two brain CSPGs. Expression of the S103L reactive brain CSPG was developmentally regulated from embryonic day 7 through 19 with a peak in core protein on day 13, and in mRNA expression at day 10. In contrast the HNK-1 reactive brain CSPG was constitutively present from day 7 through hatching. These data suggest that these two distinct core proteins are immunologically and biochemically unique translation products of two different CSPG genes.     

Processing by Convertases Is Required for Glypican-3-induced Inhibition of Hedgehog Signaling

Glypican-3 (GPC3) is one of the six members of the mammalian glypican family. We have previously reported that GPC3 inhibits Hedgehog (Hh) signaling by competing with Patched (Ptc) for Hh binding. We also showed that GPC3 binds with high affinity to Hh through its core protein, but that it does not interact with Ptc. Several members of the glypican family, including GPC3, are subjected to an endoproteolytic cleavage by the furin-like convertase family of endoproteases. Surprisingly, however, we have found that a mutant GPC3 that cannot be processed by convertases is as potent as wild-type GPC3 in stimulating Wnt activity in hepatocellular carcinoma cell lines and 293T cells and in promoting hepatocellular carcinoma growth. In this study, we show that processing by convertases is essential for GPC3-induced inhibition of Hh signaling. Moreover, we show that a convertase-resistant GPC3 stimulates Hh signaling by increasing the binding of this growth factor to Ptc. Consistent with this, we show that the convertase-resistant mutant binds to both Hh and Ptc through its heparan sulfate (HS) chains. Unexpectedly, we found that the mutant core protein does not bind to Hh. We also report that the convertase-resistant mutant GPC3 carries HS chains with a significantly higher degree of sulfation than those of wild-type GPC3. We propose that the structural changes generated by the lack of cleavage determine a change in the sulfation of the HS chains and that these hypersulfated chains mediate the interaction of the mutant GPC3 with Ptc.     

Absence of covalently linked core protein from newly synthesized hyaluronate.

1. Primary cultures of chondrocytes from the Swarm rat chondrosarcoma were labelled with either [3H]glucosamine or [14C]glucosamine, and hyaluronate synthesized by the cells was isolated from the cell layer. Parallel cultures were labelled with either [3H]serine or [3H]lysine, and identical fractions were isolated from the cell layer. Some cultures were dual-labelled. 2. In cultures labelled with [3H]serine for between 30 min and 24 h and extracted with 4.0 M-guanidine, a procedure that solubilizes predominantly extracellular macromolecules, small amounts of [3H]serine-labelled molecules were found associated with the hyaluronate fraction purified from the extract by dissociative CsCl-density-gradient centrifugation and dissociative Sepharose CL-2B chromatography. About 75% of the [3H]serine-labelled molecules in the fraction were specifically associated with hyaluronate, since they could be removed by prior treatment with proteinase-free Streptomyces hyaluronidase. The association of the [3H]serine-labelled molecules with hyaluronate was non-covalent, since they could be separated from it by further centrifugation in CsCl density gradients containing 4 M-guanidinium chloride and a zwitterionic detergent. 3. In other experiments the cultures were extracted with a sequential zwitterionic-detergent/guanidinium chloride procedure that completely solubilized the cell layer and enabled fractions containing newly synthesized cell-associated hyaluronate to be isolated. Zwitterionic detergent was present throughout. No [3H]lysine was incorporated into these fractions, irrespective of whether the cultures were pulsed concurrently with [3H]lysine and [14C]glucosamine or sequentially with [3H]lysine to prelabel the protein pool (24 h) followed by [14C]-glucosamine to label hyaluronate (1 h). 4. The results show that newly synthesized hyaluronate is not associated with covalently bound protein, and suggest that chain synthesis is initiated by a mechanism other than on to a core protein. Small amounts of [3H]serine-labelled molecules are, however, non-covalently associated with extracellular hyaluronate. Their identity is at present unknown, but they are probably of low molecular weight.