Structural analysis of chick-embryo cartilage proteoglycan by selective degradation with chondroitin lyases (chondroitinases) and endo-beta-D-galactosidase (keratanase)

Polydispersity in sulfation profile of oligosaccharide alditols isolated from the protein-linkage region and the repeating disaccharide region of chondroitin 4-sulfate of bovine nasal septal cartilage

Proteoglycans of bovine nasal septal cartilage bear predominantly chondroitin 4-sulfate. After exhaustive chondroitinase ABC digestion of a chondromucoprotein preparation rich in proteoglycans and subsequent reductive beta-elimination, five hexasaccharide alditols were isolated from the glycosaminoglycan-protein linkage region. They were analyzed by enzymatic digestion in conjunction with HPLC and by one-dimensional and two-dimensional 1H-NMR spectroscopy. They share the conventional core saccharide structure delta 4.5HexA alpha 1-3GalNAc beta 1-4GlcA beta 1-3Gal beta 1-3Gal beta 1-4Xyl-ol (where delta 4.5HexA is 4,5-unsaturated hexuronic acid), but have different sulfation profiles. One compound (I) does not contain sulfate. Two of the three monosulfated compounds (II and III) have an O-sulfate group at either C6 or at C4 of the GalNAc residue. The other monosulfated compound (IV) is hitherto unreported and has a O-sulfate at C4 of the Gal residue preceding the GlcA residue, whereas the GalNAc is not sulfated. The disulfated compound (V) has sulfate groups at C4 of both the Gal residue preceding GlcA and the GalNAc residue. The molar ratio of compounds I-V is 38.3:5.9:43.0:1.6:11.2. The structural heterogeneity of these hexasaccharide alditols reflects the polydispersity in the linkage region of the chondroitin sulfate chains. In addition, two trisaccharide and two tetrasaccharide alditols derived from the repeating disaccharide region of the chondroitin sulfate chains were also isolated. Their structures were unambiguously determined by enzymatic analysis and by 1H-NMR spectroscopy as delta 4.5HexA alpha 1-3GalNAc(4-O- or 6-O-sulfate)beta 1-4GlcA-ol and delta 4.5HexA alpha 1-3GalNAc(4-O- or 6-O-sulfate) beta 1-4GlcA beta 1-3GalNAc(4-O-sulfate)-ol, respectively.

Structural analysis of unsaturated hexasaccharides isolated from shark cartilage chondroitin sulfate D that are substrates for the exolytic action of chondroitin ABC lyase

The enzymatic action of highly purified chondroitin ABC lyase from Proteus vulgaris is dependent on the size of the substrate, and the enzyme does not cleave tetrasaccharides, irrespective of their sulfation profiles [Sugahara, K., Shigeno, K., Masuda, M., Fujii, N., Kurosaka, A. & Takeda, K. (1994) Carbohydr. Res. 255, 145-163]. To characterize the enzyme action in more detail, we isolated nine sulfated hexasaccharides from commercial shark cartilage chondroitin sulfate D, after partial digestion with highly purified chondroitin ABC lyase, by means of gel chromatography and HPLC on an amine-bound silica column. Structural analysis by 500-MHz H-NMR spectroscopy, and enzymatic digestion in conjunction with HPLC, demonstrated that these hexasaccharides, with the common core saccharide structure delta 4 HexA (alpha 1-3)GalNAc(beta 1-4)GlcA(beta 1-3)GalNAc(beta 1-4) GlcA(beta 1-3)GalNAc(where delta 4 HexA and GlcA represent 4-deoxy-alpha-L-threo-hex-4-enepyranosyluronic acid and glucuronic acid, respectively) bear three or four sulfate groups in different combinations. In the hexasaccharides, the D, disaccharide unit GlcA2-SO3 (beta 1-3) GalNAc4SO(3-) which is characteristic of chondroitin sulfate D, was arranged on the reducing side of the A disaccharide unit GlcA(beta 1-3)GalNAc4SO(3)-, and thus formed an A-D tetrasaccharide sequence GlcA(beta 1-3)GalNAc4SO(3)-(beta 1-4)GlcA2SO(3)-(beta 1-3) GalNAc6SO(3)-. Analysis of the degradation products of these hexasaccharides with highly purified chondroitin ABC lyase indicated that the enzyme preferentially acted on the unsaturated hexasaccharides in an exolytic fashion and removed an unsaturated disaccharide unit from the non-reducing termini, irrespective of the sulfation profiles of the hexasaccharides.

Proteoglycan synthesis in human and murine haematopoietic progenitor cell lines: isolation and characterization of a heparan sulphate proteoglycan as a major proteoglycan from the human haematopoietic cell line TF-1

Proteoglycans of bone-marrow stromal cells and their extracellular matrix are important components of the microenvironment of haematopoietic tissues. Proteoglycans might also be involved in the interaction of haematopoietic stem and stromal cells. Recently, several studies have been reported on the proteoglycan synthesis of stromal cells, but little is known about the proteoglycan synthesis of haematopoietic stem or progenitor cells. Here we report on the isolation and characterization of proteoglycans from two haematopoietic progenitor cell lines, the murine FDCP-Mix A4 and the human TF-1 cell line. Proteoglycans were isolated from metabolically labelled cells and purified by several chromatographic steps, including anion-exchange and size-exclusion chromatography. Biochemical characterization was performed by electrophoresis or gel-filtration chromatography before and after digestion with glycosaminoglycan-specific enzymes or HNO2 treatment. Whereas FDCP-Mix A4 cells synthesize a homogeneous chondroitin 4-sulphate proteoglycan, isolation and characterization of proteoglycans from the human cell line TF-1 revealed, that TF-1 cells synthesize, in addition to a chondroitin sulphate proteoglycan, a heparan sulphate proteoglycan as major proteoglycan. For this heparan sulphate proteoglycan a core protein size of approx. 59 kDa was determined. Immunochemical analysis of this heparan sulphate proteoglycan revealed that it is not related to the syndecan family nor to glypican.

Degradation of aggrecan precursors within a specialized subcompartment of the chicken chondrocyte endoplasmic reticulum

Chicken chondrocytes in culture synthesize aggrecan proteoglycan as a 370 kDa precursor that is glycosylated and secreted into the medium with a half-life of 30 min. In metabolic studies the 370 kDa precursor was shown to render a degradation intermediate of 190 kDa, which appeared with no measurable lag phase; it was dependent on temperature ( > 20 degrees C) and inhibited by certain serine and serine/cysteine protease inhibitors such as leupeptin and PMSF. By contrast, degradation was unaffected by treatment of the cells with brefeldin A or with lysosomotropic agents. Aggrecan precursors were detected by immunofluorescence analysis within a subcompartment of the endoplasmic reticulum (ER), previously characterized as a smooth-membrane-bound subregion [Vertel, Velasco, LaFrance, Walters and Kaczman-Daniel (1989) J. Cell Biol. 109, 1827-1836]. Analysis of the subcellular fractions derived from chondrocytes indicated that the degradation intermediate was concentrated in the ER subcompartment. Degradation was dependent on the Ca2+ concentration and the redox state in the ER. Treatment of the cells with agents or conditions that alter the degradation rate of aggrecan precursors, such as protease inhibitors, decreased temperature or dithiothreitol, also modified the retention of these molecules in the ER subcompartment, as seen by immunofluorescence. These results indicate that a fraction of the 370 kDa aggrecan precursor is targeted to a smooth ER subcompartment where it undergoes degradation.

CD44 expression on epidermal melanocytes

We examined CD44 expression on melanocytes to begin to understand what role CD44 might have in the normal behavior of melanocytes and to provide a basis for comparing CD44 expression in melanoma cells. CD44 was expressed on the entire surface of melanocytes and accentuated at the tips of dendritic processes. Two predominant forms of CD44 are expressed on cultured human foreskin melanocytes. One form has the covalent addition of chondroitin sulfate, whereas the other form has no chondroitin sulfate. Both use the hematopoietic, or CD44H, core protein. Using polymerase chain reaction primers that span the site where alternative splicing of CD44 occurs, we found only the cDNA coding CD44H. 12-O-Tetradecanoylphorbol 13-acetate increases the size of the chondroitin sulfate chain(s) attached to CD44 but not the proportion of CD44 molecules that carry chondroitin sulfate. Ninety percent of proteoglycans on melanocytes are chondroitin sulfate proteoglycans, and the CD44 chondroitin sulfate proteoglycan represented 10% of that total. These data show that CD44H is expressed as a "part-time" chondroitin sulfate proteoglycan on normal cultured melanocytes.

Nature and distribution of chondroitin sulphate and dermatan sulphate proteoglycans in rabbit alveolar bone

The type and distribution of mineral binding and collagenous matrix-associated chondroitin sulphate and dermatan sulphate proteoglycans in rabbit alveolar bone were studied biochemically and immunocytochemically, using three monoclonal antibodies (mAb 2B6, 3B3, and 1B5). The antibodies specifically recognize oligosaccharide stubs that remain attached to the core protein after enzymatic digestion of proteoglycans and identify epitopes in chondroitin 4-sulphate and dermatan sulphate; chondroitin 6-sulphate and unsulphated chondroitin; and unsulphated chondroitin, respectively. In addition, mAb 2B6 detects chondroitin 4-sulphate with chondroitinase ACII pre-treatment, and dermatan sulphate with chondroitinase B pre-treatment. Bone proteins were extracted from fresh specimens with a three-step extraction procedure: 4 M guanidine HCl (G-1 extract), 0.4 M EDTA (E-extract), followed by guanidine HCl (G-2 extract), to characterize mineral binding and collagenous matrix associated proteoglycans in E- and G2-extracts, respectively. Biochemical results using Western blot analysis of SDS-polyacrylamide gel electrophoresis of E- and G2-extracts demonstrated that mineral binding proteoglycans contain chondroitin 4-sulphate, chondroitin 6-sulphate, and dermatan sulphate, whereas collagenous matrix associated proteoglycans showed a predominance of dermatan sulphate with a trace of chondroitin 4-sulphate and no detectable chondroitin 6-sulphate or unsulphated chondroitin. Immunocytochemistry showed that staining associated with the mineral phase was limited to the walls of osteocytic lacunae and bone canaliculi, whereas staining associated with the matrix phase was seen on and between collagen fibrils in the remainder of the bone matrix. These results indicate that mineral binding proteoglycans having chondroitin 4-sulphate, dermatan sulphate, and chondroitin 6-sulphate were localized preferentially in the walls of the lacunocanalicular system, whereas collagenous associated dermatan sulphate proteoglycans were distributed over the remainder of the bone matrix.

Immunity to the G1 globular domain of the cartilage proteoglycan aggrecan can induce inflammatory erosive polyarthritis and spondylitis in BALB/c mice but immunity to G1 is inhibited by covalently bound keratan sulfate in vitro and in vivo

Earlier work from this laboratory showed that the human proteoglycan aggrecan from fetal cartilages can induce a CD4+ T cell-dependent inflammatory polyarthritis in BALB/c mice when injected after removal of chondroitin sulfate chains. Adult keratan sulfate (KS)-rich aggrecan does not possess this property. We found that two CD4+ T cell hybridomas (TH5 and TH14) isolated from arthritic mice recognize bovine calf aggrecan and the purified G1 domain of this molecule, which also contains a portion of the interglobular domain to which KS is bound. These hybridoma responses to G1 are enhanced by partial removal of KS by the endoglycosidase keratanase or by cyanogen bromide cleavage of core protein. KS removal results in increased cellular uptake by antigen-present cells in vitro. After removal of KS by keratanase, G1 alone can induce a severe erosive polyarthritis and spondylitis in BALB/c mice identifying it as an arthritogenic domain of aggrecan. The presence of KS prevents induction of arthritis presumably as a result of an impaired immune response as observed in vitro. These observations not only identify the arthritogenic properties of G1 but they also point to the importance of glycosylation and proteolysis in determining the arthritogenicity of aggrecan and fragments thereof.

The investigation of glycosaminoglycan mimotope structure using capillary electrophoresis and other complementary electrophoretic techniques

We have used various electrophoretic techniques to analyse glycosaminoglycan structure. Capillary electrophoresis has been particularly useful in the determination of the sulphation of glycosaminoglycans (GAG) and the sulphation of partly desulphated glycosaminoglycans produced by methanolysis. This, in conjunction with preparative electrophoresis and enzyme linked immunosorbent assay (ELISA) has permitted us to ascertain the length of the oligosaccharide required for binding and sulphate ester groups required for optimal binding and those essential for antibody binding. From these preliminary studies, we have demonstrated that the minimum length of oligosaccharide required for binding was about 12-14 monosaccharides in length. It appears likely that 6 sulphation is required for strong binding but 4 sulphation is not involved in mimotope binding. We propose on the basis of this evidence that the mimotope does not contain 4-sulphate residues but 3-4 6-sulphate ester groups are essential for binding.

Quantitative and qualitative analyses of proteoglycans in cartilage extracts by precipitation with 1,9-dimethylmethylene blue

The dye 1,9-dimethylmethylene blue may be used for the specific and quantitative precipitation of sulphated glycosaminoglycans as well as proteoglycans from the extracts of articular cartilage. The consumption of the dye DMMB enables to determine the amount of the proteoglycans present in the extract, by measuring the decrease of the absorption at 595 nm. The precipitated complex of DMMB and proteoglycans is used for qualitative investigations into the electrophoretic mobility of the different proteoglycans in agarose slab gel and their immunological characterization after blotting. Because of its higher sensitivity and greater simplicity the method described in this report is a promising alternative to the procedure based on alcian blue.

The uniform galactose 4-sulfate structure in the carbohydrate-protein linkage region of human urinary trypsin inhibitor

The carbohydrate-protein linkage region of a chondroitin 4-sulfate chain attached to urinary trypsin inhibitor (UTI) was isolated from human urine and characterized structurally. The chondroitin 4-sulfate chain was released from UTI by beta-elimination using alkaline NaBH4 then digested with chondroitinase ABC. These treatments resulted in only a single hexasaccharide alditol derived from the carbohydrate-protein linkage region. Chemical and enzymic analyses and 600-MHz 1H-NMR spectroscopy revealed that the hexasaccharide alditol had the following structure: delta HexA alpha 1-3GalNAc(4-sulfate) beta 1-4GlcA beta 1- 3Gal(4-sulfate) beta 1-3Gal beta 1-4Xyl-ol, where delta HexA, GlcA and Xyl-ol represent 4-deoxy-alpha-L-threo-hex-4-enepyranosyluronic acid, D-glucuronic acid and D-xylitol, respectively. This structure contained the novel 4-sulfated Gal residue, which was first demonstrated in one of the three linkage hexasaccharide-serines isolated from chondroitin 4-sulfate of rat chondrosarcoma [Sugahara, K., Yamashina, I., de Waard, P., Van Halbeek, H. & Vliegenhart, J. F. G. (1988) J. Biol. Chem. 263, 10168-10174]. This disulfated structure was recently identified as the sole structural component in the linkage hexasaccharide alditol fraction isolated from inter-alpha-trypsin inhibitor (ITI) in human plasma [Yamada, S., Oyama, M., Kinugasa, H., Nakagawa, T., Kawasaki, T., Nagasawa, S., Khoo, K.-H., Morris, H.R., Dell, A. & Sugahara, K. (1995) Glycobiology 5, 335-341]. The structural uniformity in the linkage hexasaccharide structure of ITI and UTI is in marked contrast to the heterogeneity demonstrated in the linkage hexasaccharides isolated from cartilaginous chondroitin sulfate whose linkage regions are sometimes but not always phosphorylated on the Xyl residue or sulfated on the Gal residue(s). The uniform structure containing the novel 4-sulfated Gal residue in the linkage region of UTI and ITI may imply its significance in the biosynthetic mechanism of chondroitin sulfate.

Rat mesangial cells in vitro synthesize a spectrum of proteoglycan species including those of the basement membrane and interstitium

Accumulation of extracellular matrix within the mesangium is an important event in the development of glomerular disease. In this report we have used indirect immunofluorescence to positively identify a number of constituents of the mesangial matrix synthesized by rat mesangial cells (RMC) in vitro including laminin, fibronectin, type IV collagen and the basement membrane heparan sulphate proteoglycan (BM-HSPG) known as perlecan. In addition, using Mab 2B5 we demonstrate that RMC synthesize a specific basement membrane chondroitin sulfate (BM-CSPG), a matrix component that in normal animals is localized in the mesangium but is not found in the pericapillary glomerular basement membrane (GBM). Further characterization of the proteoglycans synthesized by RMC in vitro revealed: (i) a second large CSPG, identified as versican; (ii) two small dermatan sulphate proteoglycans identified as biglycan and decorin, which together account for the majority of the proteoglycans; (iii) a large HSPG-I, probably related to perlecan; and (iv) a small HSPG-II. The cell layer proteoglycans can be sub-divided into a class that are probably free in the membrane, and a class of anchored molecules of the extracellular matrix or stabilized by cytoskeletal elements.

Serglycin and betaglycan proteoglycans are expressed in the megakaryocytic cell line CHRF 288-11 and normal human megakaryocytes

This study has characterized the proteoglycans from the megakaryocytic tumor cell line CHRF 288-11 and the effect of the differentiation-inducing agents phorbol-12-myristate-13-acetate (PMA) and dimethylsulfoxide (DMSO) on proteoglycan synthesis in these cells. There appeared to be two classes of proteoglycans. One, serglycin, was recognized to have a core protein of 31 kDa, an overall molecular mass of 200-300 kDa, and glycosaminoglycan chains of mean size < 25 kDa. The size of this proteoglycan was increased by both PMA and DMSO. Synthesis was increased by PMA and reduced by DMSO. mRNA for serglycin was increased at 24 to 72 hr following PMA treatment. In addition, the cells contained a core protein triplet at 96, 110, and 120 kDa, and the medium only the bands at 96 and 110 kDa, suggesting the presence of betaglycan. Synthesis of this proteoglycan was enhanced by PMA. This proteoglycan had an overall size of 130-150 kDa on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) in control cells, but in the presence of PMA, a component > 250 kDa was present. Probes for Northern blot analysis were prepared by polymerase chain reaction (PCR) based on the sequences of human serglycin and betaglycan. The serglycin probe recognized a 1.4 kb band, and the betaglycan probe recognized a 4.1 kb band, on blots prepared from RNA from CHRF cells and cultured normal human megakaryocytes. Both proteoglycans in their intact form adhered to peptides derived from fibronectin and collagen, but the free GAGs released by alkaline borohydride digestion did not adhere. Synthesis of two proteoglycans appears to be a part of the differentiation process of megakaryocytic tumor cells and normal megakaryocytes.

Accumulation of a pentasaccharide terminating in alpha-N-acetylglucosamine in an animal cell mutant defective in heparan sulfate biosynthesis

Heparan sulfate biosynthesis initiates by the transfer of alpha-D-GlcNAc from UDP-GlcNAc to the D-GlcA moiety of the linkage tetrasaccharide, GlcA beta 1-3Gal beta 1-3Gal beta 1-4Xyl beta 1-core protein. The enzyme catalyzing this reaction differs from the alpha-GlcNAc transferase involved in chain polymerization based on genetic and enzymatic studies of an animal cell mutant defective in chain polymerization (Fritz, T. A., Gabb, M. M., Wei, G., and Esko, J. D. (1994) J. Biol. Chem. 269, 28809-28814). In this report we show that this mutant also accumulates a pentasaccharide intermediate containing alpha-GlcNAc. A fusion protein was made from the IgG-binding domain of protein A and a segment of the proteoglycan, betaglycan. This segment contained one glycosaminoglycan attachment site that primes only chondroitin sulfate and another that primes both heparan sulfate and chondroitin sulfate (Zhang, L., and Esko, J. D. (1994) J. Biol. Chem. 264, 19295-19299). Expression of the chimera in the mutant resulted in the accumulation of an oligosaccharide that labeled with [6-3H]GlcN. The oligosaccharide comigrated with a pentasaccharide standard derived from chondroitin sulfate, but acid hydrolysis gave 98% [3H]GlcN. Heparin lyase III digestion yielded [3H]GlcNAc, suggesting that the GlcNAc residue was alpha-linked to the nonreducing terminus. Enzymatic treatment of [6-3H]Gal-labeled material yielded the tetrasaccharide, delta GlcA-[3H]Gal-[3H]Gal-xylitol. These findings suggest that pentasaccharide had the structure, GlcNAc alpha 1-4GlcA beta 1-3Gal beta 1-3Gal beta 1-4Xyl. Its accumulation in a Chinese hamster ovary cell mutant defective in the polymerizing alpha-GlcNAc transferase provides in vivo evidence that two alpha-GlcNAc transferases catalyze the formation of heparan sulfate.

Nonreducing end structures of chondroitin sulfate chains on aggrecan isolated from Swarm rat chondrosarcoma cultures

Chondrocyte cultures derived from the Swarm rat chondrosarcoma were metabolically labeled with [35S]sulfate or [6-3H]GlcN. Radiolabeled aggrecan was purified from the cell layer and exhaustively digested with chondroitin ABC lyase. Digestion products were resolved into disaccharide and monosaccharide residues using Toyopearl HW40S chromatography. The separated saccharide pools were reduced with NaBH4 and applied onto a CarboPac PA1 column to resolve all of the internal disaccharide alditols (unsaturated) from the nonreducing end disaccharide (saturated) and monosaccharide alditols. Mercuric acetate treatment was used prior to carbohydrate analysis to identify unambiguously the saturated from the unsaturated disaccharides. The chondroitin sulfate (CS) chains from these aggrecan preparations contained: (a) an internal disaccharide composition of unsulfated (3-4 per chain), 4-sulfated (approximately 32 per chain), 6-sulfated (approximately 1 per 14 chains), and 4,6-sulfated disaccharides (approximately 1 per 6 chains) and (b) a nonreducing terminal composition of 4-sulfated GalNAc (approximately 4 out of every 7 chains), 4,6-disulfated GalNAc (approximately 2 out of every 7 chains), and GlcUA adjacent to a 4-sulfated GalNAc residue (approximately 1 out of every 7 chains). Thus, the vast majority of these CS chains terminated with a sulfated GalNAc residue. The presence of 4,6-disulfated GalNAc at nonreducing termini is 60-fold more abundant than 4,6-disulfated GalNAc in interior disaccharides. This observation is consistent with the suggestion that disulfation of terminal GalNAc residues is involved in chain termination.

Structure of chondroitin sulfate on aggrecan isolated from bovine tibial and costochondral growth plates

The structure of chondroitin sulfate on aggrecan isolated from the rib and proximal tibial growth plates of bovine fetuses was investigated, and the previously reported increase in the hydrodynamic size of chondroitin sulfate chains between the reserve and hypertrophic zones of the rib was confirmed in the tibial growth plate. Superose 6 gel chromatography, calibrated for chondroitin sulfate chain length by monosaccharide analysis, showed that the average molecular mass of chondroitin sulfate in the reserve and maturing zones of both growth plates was 21,600 and 30,400, respectively. Determination by capillary zone electrophoresis of the disaccharide composition of chains following chondroitinase digestion showed that delta Di-0S, delta Di-4S, and delta Di-6S together accounted for more than 98% of the disaccharides in the digests from all zones of both growth plates; delta disulfated and delta trisulfated disaccharides were not detected. Furthermore, this analysis revealed a gradient in chondroitin sulfate composition from the reserve to the hypertrophic zone, characterized by a marked increase in the content of delta Di-6S (from about 32% to about 52%) and a marked decrease in the content of delta Di-4S (from about 53% to about 35%). Moreover, this altered pattern of sulfation was detected on chains of all sizes in the hypertrophic zone, suggesting that a proportion of the reserve zone aggrecan might be removed and replaced with aggrecan rich in chondroitin-6-sulfate synthesized during the proliferative and maturation stages of the resident chondrocytes. These data are discussed in relation to the biosynthetic mechanisms that control chondroitin sulfate chain length and sulfation on aggrecan and their modification during chondrocyte proliferation, maturation, and hypertrophy in the growth plate.

Differentiated macrophages synthesize a heparan sulfate proteoglycan and an oversulfated chondroitin sulfate proteoglycan that bind lipoprotein lipase

Lipoprotein lipase (LpL), which facilitates lipoprotein uptake by macrophages, associates with the cell surface by binding to proteoglycans (PGs). Studies were designed to identify and characterize specific PGs that serve as receptors for LpL and to examine effects of cell differentiation on LpL binding. PG synthesis was examined by radiolabeling THP-1 monocytes and macrophages (a cell line originally derived from a patient with acute monocytic leukemia) with [35S]sodium sulfate and [3H]serine or [3H]glucosamine. Radiolabeled PGs isolated from the cell surface were purified by chromatography and identified as chondroitin-4-sulfate (CS) PG and heparan sulfate (HS) PG. A sixfold increase in CSPG and an 11-fold increase in HSPG accompanied cell differentiation. Whereas HS glycosaminoglycan chains from both monocytes and macrophages were 7.5 kD in size, CS chains increased in size from 17 kD to 36 kD with cell differentiation, and contained hexuronyl N-acetylgalactosamine-4,6-di-O sulfate disaccharides. LpL binding was sevenfold higher to differentiated cells, and affinity chromatography demonstrated that two cell surface PGs bound to LpL: HSPG and the oversulfated CSPG produced only by differentiated cells. We conclude that differentiation-associated changes in cell surface PG of human macrophages have functional consequences that could increase the atherogenic potential of the cells.

Phosphorothioate oligonucleotides cause degradation of secretory but not intracellular serglycin proteoglycan core protein in a sequence-independent manner in human megakaryocytic tumor cells

Human megakaryocytic tumor cell lines CHRF-288-11 and HEL (human erythroleukemia) were incubated with antisense phosphodiester (PDE) and phosphorothioate (PS) oligodeoxynucleotides directed against the first six codons of the human serglycin proteoglycan gene. As controls, PDE scrambled and PS sense and scrambled sequences and a probe antisense to a 3' portion of the coding sequence were used. Treatment with PDE-ODNs did not alter the core protein content of cell or culture medium proteoglycans. Treatment with all the PS-ODNs resulted in loss of the 31 kD serglycin core protein in the medium, but not the cell-associated proteoglycans, and concomitant appearance of a heavily labeled core protein band at the dye front. This band appears to arise from truncation of the core protein, which leaves the glycosaminoglycan attachment region intact. The higher molecular weight core proteins, which appear to be derived from a betaglycan-like proteoglycan, were not affected by the PDE or PS-ODN treatment. The same effect was seen with or without electroporation, which was used to enhance uptake of the ODNs. Thus treatment of megakaryocytic tumor cells with PS-ODNs appeared to cause a selective degradation of the serglycin core protein in a sequence-independent manner. Degradation most likely occurred intracellularly, because culture supernatants did not degrade exogenously added serglycin proteoglycan, and the presence of superoxide dismutase and catalase in the culture medium during exposure of the cells to the PS-ODNs did not prevent the degradation.

Action of metalloproteinases on porcine dentin mineralization

Samples containing predentin and mineralized dentin involving the mineralized front (newly formed dentin) were prepared by scraping developing porcine teeth after odontoblastic cell debris had been removed from the predentin surfaces. An extract was obtained separately from the matrices of predentin and of the newly formed dentin with a 4 M guanidine solution before and after demineralization with acetic acid solution. Enzymography detected 56 and 61 kDa gelatinases and 25 kDa proteoglycanase as neutral metalloproteinases in both extracts and proved them to be in an active form. Approximately half of the 56 and 61 kDa gelatinases binds to collagen fibers in predentin matrix. Three high molecular weight proteoglycans (70-85 kDa, 130-180 kDa, and 290 kDa) were found in the predentin matrix, but not in the newly formed dentin. The proteoglycanases in predentin degraded 290 kDa proteoglycan, if incubated together with calcium (Ca) ions. The results of this investigation indicate that active proteoglycanases which existed in the predentin perform no substantial work in proteoglycan degradation because the Ca ions are masked in the predentin matrix by coexisting proteoglycans. When mineralization occurs, however, they can degrade the proteoglycan at the mineralization front because excess Ca ions may be supplied via odontoblastic processes.

Epican, a heparan/chondroitin sulfate proteoglycan form of CD44, mediates cell-cell adhesion

Epican is a heparan/chondroitin sulfate proteoglycan form of CD44 and is expressed on the surface of keratinocytes from the basal layer to the granular layer of the epidermis. To analyze the adhesive properties of epican apart from the influence of other adhesive molecules found on keratinocytes, mouse L cell fibroblasts were transfected with CD44Epican cDNA. The epican expressed on the surface of transfected L cells was predominantly a heparan or chondroitin sulfate proteoglycan. The CD44Epican-transfected L cells acquired: (a) a self-aggregating phenotype that required hyaluronan but was calcium-independent; and (b) a new capacity to adhere to keratinocytes, a property that was blocked by an anti-epican antibody. Both aggregation and adhesion of CD44Epican-transfected cells were completely prevented by pretreatment with hyaluronidase, but were totally restored by the addition of exogenous hyaluronan. Aggregation of transfected L cells was minimally influenced by other glycosaminoglycans, but adhesion of transfected L cells to keratinocytes was substantially inhibited by heparin.

Distribution of heparan sulfate proteoglycans in embryonic chicken neural retina and isolated inner limiting membrane

Quantitative distribution of proteoglycans was studied in retinal neural epithelium and its basement membrane (inner limiting membrane). Heparan sulfate proteoglycans (HSPGs) were primarily associated with both inner and outer plexiform (synaptic) layers, and inner limiting membrane (ILM), as determined by autoradiographs of lyase-digested cryosections. Based on distribution of 35S-sulfate-labeled proteoglycans, the isolated ILM contained on average approximately three fourths of its proteoglycans as HSPGs and one fourth as chondroitin sulfate/dermatan sulfate proteoglycans (CS/DSPGs), whereas the remaining retina contained approximately equal amounts of the two proteoglycans (PGs). Immunohistochemical staining indicates that the core proteins of the HSPGs in the ILM are distinct from those of the plexiform layers. The photoreceptor layer, which other studies have shown to contain much of the extracellular CS/DSPGs, was not examined. Enrichment of distinct HSPGs in the ILM and plexiform layers support the conclusion that the HSPGs may be intimately involved in the different developmental events characterizing the two regions: development and extension of ganglion cell axons in the former, synaptogenesis and neuronal function in the latter.

Glomerular mesangial cells in vitro synthesize an aggregating proteoglycan immunologically related to versican

Recent studies have shown that mesangial cells derived from human adult glomeruli synthesize a number of 35S-labelled proteoglycans including a large chondroitin sulphate proteoglycan (CSPG), two dermatan sulphate proteoglycans (biglycan and decorin) and two heparan sulphate proteoglycans [Thomas, Mason and Davies (1991) Biochem. J. 277, 81-88]. In the present study we have examined the interaction of these proteoglycans with hyaluronan (HA) using associative gel chromatography. Only the large CSPG bound to HA, with 60% of those molecules in the medium and 80% of those in the cell layer being able to interact. Reduction and alkylation, or treatment of the monomer CSPG with proteinases, prevented the formation of aggregates, suggesting that the core protein was involved. The aggregates formed between purified CSPG and HA could be dissociated in the presence of HA-oligosaccharides of at least 10 monosaccharides in length. The inclusion of link protein with CSPG and HA promoted the formation of aggregates. Experiments with 3H-labelled mesangial-cell proteoglycans confirmed that only the large CSPG, with core protein molecular masses of 400 kDa and 500 kDa, interacted with HA. After chondroitin ABC lyase treatment of CSPG isolated from conditioned culture medium, several bands similar to those observed with 3H-labelled core proteins were identified using a polyclonal antiserum that recognizes versican. A monoclonal antibody recognizing the 1-C-6 epitope in the G1 and G2 globular regions of aggrecan did not recognize either mesangial-cell CSPG or bovine aortic versican. Northern-blot analysis confirmed that human mesangial cells express versican. Thus human mesangial large CSPG is a member of the versican family of proteoglycans. The interaction of CSPG and HA within the glomerulus may be important in glomerular cell migration and proliferation.

Development of enzyme immunoassays specific for keratan sulphate- and core-protein-epitopes of the large aggregating proteoglycan from human articular cartilage

In the course of chronic inflammatory and degenerative joint diseases proteoglycans are degraded by the action of proteases and oxygen radicals. Therefore, proteoglycan fragments, released from cartilage into the peripheral blood, might be useful markers of cartilage degradation. Sensitive enzyme immunoassays are useful for the detection of these proteoglycan fragments in serum. We therefore developed specific monoclonal antibodies against the large aggregating proteoglycan (aggrecan), which has been isolated and purified from human articular cartilage. Two monoclonal antibodies which recognize a novel cartilage-specific epitope on the keratan sulphate chain of aggrecan (mAb 4B3/D10) and an epitope of the core-protein of aggrecan (4G4/A10) were selected for the development of competitive enzyme-immunoassays. These assays allow the sensitive and specific detection of cartilage-derived proteoglycan fragments, not only in synovial fluid but also in serum. They can now be used for the study of inflammatory and degenerative joint diseases.

Structural studies on the chondroitinase ABC-resistant sulfated tetrasaccharides isolated from various chondroitin sulfate isomers

Various commercially available chondroitin sulfates, including an A isomer from whale cartilage, C and D isomers from shark cartilage, and an E isomer from squid cartilage, were exhaustively digested with a commercial highly purified Proteus vulgaris chondroitinase ABC. Gel chromatography of all digests yielded a disaccharide and an oligosaccharide fraction which was resistant to the enzyme digestion and which accounts for 20-31 mol% of the produced total oligosaccharides. Variably sulfated tetrasaccharides were isolated from the oligosaccharide fraction of each chondroitin sulfate isomer by HPLC, then characterized chemically and enzymatically. One disulfated and three trisulfated components were also characterized by 500-MHz one- and two-dimensional 1H NMR spectroscopy. The structures of one tetrasulfated, four trisulfated, and five disulfated tetrasaccharides with the common core structure, alpha-L-delta 4,5HexpA-(1-->3)-beta-D-GalpNAc-(1-->4)-beta-D-GlcpA-(1-->3) -D-GalpNAc, were determined. All isolated tetrasaccharides were resistant to the highly purified enzyme, but susceptible to the conventional, commercial chondroitinase ABC. The former was also inactive towards alpha-L-delta 4,5HexpA-(1-->3)-beta-D-GalpNAc-(1-->4)-beta-D-GlcpA-(1-->3) -D-GalpNAc isolated from chondroitin, beta-D-GlcpA-(1-->3)-beta-D-GlcpNAc-(1-->4)-beta-D-GlcpA-(1- ->3)-D-GlcpNAc from hyaluronan, and alpha-L-delta 4,5HexpA-(1-->3)-beta-D-GalpNAc4SO3(-)-(1-->4)-alpha-L-Id opA-(1-->3)-D- GalpNAc4SO3- from dermatan sulfate. These results indicate that, unlike the conventional enzyme, highly purified chondroitinase ABC cannot degrade tetrasaccharides irrespective of their sulfation profiles. The enzymatic action is size-dependent.

Chondroitinase ABC-resistant sulfated trisaccharides isolated from digests of chondroitin/dermatan sulfate chains

Four kinds of sulfated trisaccharides resistant to chondroitinase ABC were isolated after chondroitinase B or ABC treatment of dermatan sulfate or various chondroitin sulfate isomers, respectively. Their composition was determined by chemical analysis and fast atom bombardment-mass spectrometry. Their structures were characterized by chondroitinase ACII digestion in conjunction with HPLC, and 500-MHz one- and two-dimensional 1H NMR spectroscopy. All the four trisaccharides have in common the core saccharide sequence, alpha-L-delta 4,5HexpA-(1-->3)-beta-D-GalpNAc-(1-->4)-D-GlcpA. A monosulfated component isolated from shark scapular cartilage chondroitin sulfate C or bovine aorta dermatan sulfate was elucidated as alpha-L-delta 4,5HexpA-(1-->3)-beta-D-GalpNAc6SO3(-)-(1-->4)-D-GlcpA or alpha-L-delta 4,5HexpA-(1-->3)-beta-D-GalpNAc4SO3(-)-(1-->4)-D-GlcpA , respectively. A disulfated component obtained from shark scapular cartilage chondroitin sulfate C or squid cartilage chondroitin sulfate E was identified as alpha-L-delta 4,5HexpA2SO3(-)-(1-->3)-beta-D-GalpNAc6SO3(-)-(1-->4)-D-G lcpA or alpha-L-delta 4,5HexpA-(1-->3)-beta-D-GalpNAc4SO3(-)6SO3(-)-(1-->4)- D-GlcpA, respectively. These trisaccharides are derived from the reducing termini of the parent polysaccharides. Some of the trisaccharides could be derived from the reducing termini exposed by the peeling reaction during the alkaline treatment while some others may represent the cleavage sites exposed by tissue endo-beta-D-glucuronidase(s), indicating the presence of such enzyme(s) which may release chondroitin/dermatan sulfate fragments from proteoglycans.

The sulphation pattern in chondroitin sulphate chains investigated by chondroitinase ABC and ACII digestion and reactivity with monoclonal antibodies

We have used progressive chondroitinase digestion of pig aggrecan in conjunction with ELISA assays and disaccharide analysis to derive information about the pattern of 4- and 6-sulphation in chondroitin sulphate chains. Digestion with chondroitinase ABC resulted in the release of mainly disaccharides from the nonreducing terminal of chondroitin sulphate chains but there was also the release of some tetra- and hexa-saccharides which were degraded to disaccharides with more extensive digestion. Chondroitinase ACII, in contrast, released only disaccharides. Analysis of the disaccharide composition of the intact and digested products at different stages of digestion showed that there was a slight increase in 6-sulphate content of the chains as they were shortened. Reaction of the partially digested proteoglycans with monoclonal antibodies 3-B-3 and 3-D-5 which recognise chains terminating in 6- or 4-sulphated disaccharides, respectively, showed major differences between chondroitinase ABC and ACII products. The results suggested that chondroitinase ABC preferentially cleaved next to 4-sulphated, rather than 6-sulphated disaccharides and this resulted in some oligosaccharides as well as disaccharide being released. Chondroitinase ACII also cleaved an additional disaccharide next to the linkage to protein of chondroitin sulphate, which was not removed by chondroitinase ABC and this disaccharide was mainly nonsulphated.

Identity of the core proteins of the large chondroitin sulphate proteoglycans synthesized by skeletal muscle and prechondrogenic mesenchyme

Large, chondroitin sulphate-containing proteoglycans are synthesized by three prominent tissue in the embryonic chick limb. One of these proteoglycans is aggrecan, the phenotype-specific proteoglycan of cartilage. Another, PG-M, is produced by prechondrogenic mesenchymal cells. The third, M-CSPG, is made by developing skeletal muscle cells. While the carbohydrate components of PG-M and M-CSPG share some similarities, both of these proteoglycans clearly have different carbohydrate moieties from those of aggrecan. To compare these three proteoglycans at another level, their core protein structures were analysed in three ways: by the presence or absence of monoclonal antibody epitopes, by one-dimensional peptide display of the cyanogen bromide-cleaved core proteins and by electron microscopic imaging of the molecules. Monoclonal antibodies whose epitopes are present in aggrecan core protein were tested with core protein preparations from M-CSPG and PG-M. One of these, 7D1, recognizes both PG-M and M-CSPG, while another, 1C6, shows no reactivity for the non-cartilage proteoglycans. The absence of 1C6 reactivity is of interest, as its epitope is in a region of the aggrecan core protein known to have a functional homologue in the core proteins of PG-M and M-CSPG. The cyanogen bromide-fragmented peptide pattern of M-CSPG is the same as that of PG-M, and both are different from that of aggrecan. The aggrecan pattern has one prominent large band (molecular mass 130 kDa), some less prominent large bands (molecular mass 70-100 kDa) and several smaller bands. In contrast, the PG-M and M-CSPG patterns show no bands with molecular masses > 73 kDa, and the smaller bands (molecular mass < 40 kDa) have a different pattern to that of the smaller bands from aggrecan. The electron microscopic images of aggrecan show a core protein with one end having two globular regions separated by a short linear segment; adjacent to this is a long linear segment, which sometimes contains a third globular region at the end of the core protein opposite the end with the double-globe structure. M-CSPG and PG-M core proteins never show images with the double-globe structure. Instead, one end of the molecule has a single globular domain, and a second globular region is variably present at the opposite end of the core protein. Thus, by all three methods, the core proteins of PG-M and M-CSPG appear to be the same and both differ from the core protein of aggrecan.

Response of stratified cultures of human keratinocytes to disruption of proteoglycan synthesis by p-nitrophenyl-beta-D-xylopyranoside

Proteoglycans play a role in regulating proliferation and adhesion of cells to each other and to the basal lamina. Synthesis of proteoglycans is disrupted by beta-xylosides, which serve as alternate substrate sites for glycosaminoglycan chain attachment and therefore prevent glycosylation of the core protein. We have investigated the effects of p-nitrophenyl-beta-D-xylopyranoside (PNP-xyloside) on cultured human keratinocytes. Stratified cultures were incubated for 7 days with PNP-xyloside (0.05-2.0 mM). Concentrations as low as 0.05 mM increased the secretion of free chondroitin sulfate by 10-15-fold over untreated cultures. Cell-associated proteoglycan decreased as PNP-xyloside concentration increased. At 2 mM PNP-xyloside, heparan sulfate as well as chondroitin sulfate addition to core proteins was disrupted: the core protein of epican, a heparan sulfate form of CD44 found on keratinocytes, was detected immunologically but lacked heparan sulfate. 2.0 mM PNP-xyloside reduced the number of attached cells by 20-25% after 7 days, but had little effect on morphology or protein synthesis. These results indicate that intact proteoglycans are not critical for maintaining epidermal keratinocyte stratification, cell-cell adhesion, or growth.

Core proteins of soluble chondroitin sulfate proteoglycans purified from the rat brain block the cell cycle of PC12D cells

The effects of soluble chondroitin sulfate proteoglycans (CSPGs) purified from the rat brain on proliferation of and neurite outgrowth from PC12D cells (Katoh-Semba et al., J Neurosci Res 17:36, 1987) were investigated. When PC12D cells are cultured under standard conditions, they proliferate with a doubling time of about 2 days, irrespective of the presence or absence of NGF. However, the addition of a mixture of several types of purified soluble brain CSPG (50 nmol uronic acid/ml) to the culture medium prevented the increase in the number of PC12D cells as well as the nerve growth factor (NGF)-induced neurite extension. The dose for 50% inhibition (ID50) was 1.6 nmol/ml for cell proliferation and 2.7 nmol/ml for neurite elongation. The increase in cell number seemed to stop around 6 h after exposure to culture medium supplemented with brain-derived CSPGs, and even substratum-attached CSPGs were able to exert such inhibitory effects. Only brain-type CSPGs, not a cartilage-derived CSPG (PGH) or a hyaluronate-binding PGH, had such inhibitory effects. Furthermore, these inhibitory activities were associated only with the core proteins of brain-derived CSPGs, and not with polysaccharide chains from brain-derived CSPGs. Incorporation of [3H]thymidine into DNA did not decrease for at least the first 12 h. Consequently, the amount of DNA per cell after 48 h of culture was about twofold higher in cells treated with brain CSPGs than in nontreated cells after exposure to the medium with CSPGs. Microspectrophotometry revealed that the population of cells with a high DNA content was greater in the culture treated with brain-derived CSPGs than in the control culture. These findings indicate that purified soluble brain CSPGs block the cell cycle of PC12D cells at the G2 phase with resultant cessation of cell proliferation and the inhibition of neurite outgrowth.

Large chondroitin sulfate proteoglycans of developing chick CNS are expressed in cerebral hemisphere neuronal cultures

Chondroitin sulfate proteoglycans (CSPG) of the extracellular matrix may play regulatory roles in central nervous system (CNS) development. We have examined the expression of two large CSPGs of the embryonic chick brain, which can be differentiated using the monoclonal antibodies HNK-1 and S103L, in cultures of embryonic day 6 chick cerebral hemisphere neurons. Western blot analysis following immunoprecipitation and endoglycosidase treatment revealed that these cultures produce S103L- and HNK-1-reactive proteoglycans which are biochemically indistinguishable from the CSPGs (previously) identified in homogenized chick embryo brain extracts. The HNK-1-reactive CSPG accumulated in the medium throughout the course of cultures. In contrast, the S103L-reactive CSPG was found in a neuron-associated form during the period of aggregate establishment in culture, as well as in a soluble form secreted into the medium. Immunocytochemical staining of cultures with the S103L antibody localized reactivity to most neurons during the period of aggregate formation, while neuronal processes and the few flat cells present (presumably neuroblasts and early glia) were negative. Cell selection experiments confirmed that neurofilament-positive cells were the source of the S103L-reactive CSPG. The use of differential fixation techniques suggested that the cell-associated S103L reactivity may be intracellular. Because of this pattern of expression and localization, we propose that the developmentally regulated S103L-reactive CSPG may play a role in neuronal migration arrest and organization of neurons into functional aggregates.

Immunohistochemical localization of articular cartilage proteoglycan and link protein in situ using monoclonal antibodies and lectin-binding methods

Lectins have specificity for certain carbohydrate structures in macromolecules. Lectins are, therefore, useful histochemical tools for demonstrating the composition and localization of components of connective tissue matrices, such as articular cartilage. In order to assess the significance of observed lectin-binding patterns, experiments were performed in which monoclonal antibodies against chondroitin sulphate- and keratan sulphate-containing proteoglycans and link proteins were applied to sections of bovine articular cartilage after enzymatic digestion with chondroitinase ABC and keratanase. The following conclusions were made: (1) Binding of peanut agglutinin (PNA) in the interterritorial matrix predominantly indicates the presence of keratan sulphate, but may also detect O-linked oligosaccharides of proteoglycans. (2) In normal cartilage wheat germ agglutinin (WGA) binds nearly exclusively to keratan sulphate. In cartilage degraded with chondroitinase ABC and keratanase this lectin may also detect carbohydrates in link protein due to enhanced accessibility. Binding of WGA to O-linked oligosaccharides may eventually occur. (3) In enzymatically digested cartilage matrix, staining with soybean agglutinin (SBA) may be due to link protein, but not to chondroitin sulphate, because specific breakdown of the glycosaminoglycan chain is required for binding of SBA. (4) Ulex europaeus agglutinin I (UEA I) binding sites are only detectable in digested cartilage matrix.

Tissue variation of two large chondroitin sulfate proteoglycans (PG-M/versican and PG-H/aggrecan) in chick embryos

PG-M and PG-H, chick large chondroitin sulfate proteoglycans corresponding to versican (fibroblast-type proteoglycan) and aggrecan (cartilage-characteristic proteoglycan), respectively, which are found in mammals, have been characterized in various tissues of chick embryos. Their distribution and the compositions of the core molecules were analyzed by immunofluorescence staining and immunoblotting, respectively, using various monospecific antibodies. Molecules reactive to a monoclonal antibody to the PG-M core protein (designated MY-174) were distributed in various tissues, including aorta, lung, cornea, brain, skeletal muscle and dermis. Immunoblotting with MY-174 of the chondroitinase ABC-digested tissue extracts showed a tissue variation of MY-174-reactive core molecules (550-kD, 500-kD, 450-kD, and 350-300-kD). In contrast, PG-H, besides massive occurrence in cartilage, was only found in a few tissues such as aorta and brain. In addition, PG-H in aorta, cornea, and skin was atypical in structure, because it lacked keratan sulfate. The expression of PG-M in developing chick embryos was then examined. PG-M was found in some developmentally active areas, such as the perinotochordal mesenchyme between notochord and neural tube, the basement membranes facing neuroepithelial cells, and condensing mesenchymal cells in limb buds, suggesting some functions distinctive of the developing tissues.

Analysis of water-macromolecule proton magnetization transfer in articular cartilage

These studies were designed to establish which structural elements of cartilage are responsible for proton magnetization transfer between water (Hf) and macromolecules (Hr) observed in MRI studies on articular cartilage. Saturation transfer techniques were used to monitor magnetization transfer in vitro on samples of the two major constituents of cartilage: collagen and proteoglycan. Articular cartilage samples were also evaluated in vitro before and after the removal of the proteoglycan fraction. Isolated hydrated collagen exhibited a significant proton magnetization transfer rate with water. In contrast, proteoglycans exhibited no proton magnetization transfer. Articular cartilage, in vitro, exhibited a high degree of magnetization transfer with water protons consistent with previous MRI studies in vivo. Enzymatic removal of proteoglycan from the cartilage did not alter the magnetization transfer rate between Hr and Hf. These data demonstrate that the structure and concentration of the collagen matrix are the predominant determinants of the magnetization transfer process in articular cartilage with little or no contribution from proteoglycans. This specificity of the magnetization transfer effect may prove useful in the noninvasive evaluation of cartilage composition and structure in vivo.

Regenerative neurite growth modulation associated with astrocyte proteoglycans

Adherent GFAP-positive cells of neocortical origin in vitro produce and release members of three families of sulphated proteoglycans and a sulphated protein that copurifies with heparan sulphate proteoglycan (HSPG). Conditioned medium (CM) and the proteoglycans contained in the CM have neurite growth-promoting activity when immobilized on defined substrates of growth but not when in the nonimmobilized compartment. On a poly-D-lysine substrate, the rank ordering of specific neurite growth activity based on protein concentration was 330 kDa HSPG >> 100 kDa HSPG/chondroitin sulphate (CS) PG mixture or hybrid > 330 kDa CSPG > 50 kDa CSPG/dermatan sulphate (DS) PG mixture or hybrid and the 31 kDa sulphoprotein. Astrocyte CM lost its growth facilitatory activity when prepared and released by astrocytes in the presence of soluble mediators of inflammation. Loss of activity could not be explained by qualitative or quantitative alterations of released proteoglycans but appeared to be associated with the presence of an inhibitor. The sulphoprotein that copurified with HSPG was a potent inhibitor of HSPG-mediated neurite growth.

Monoclonal antibodies directed against epitopes within the core protein structure of the large aggregating proteoglycan (aggrecan) from the swarm rat chondrosarcoma

The core protein of the large hyaline cartilage proteoglycan, aggrecan, is composed of six distinct domains: globular 1 (G1), interglobular, globular 2 (G2), keratan sulfate attachment, chondroitin sulfate (CS) attachment, and globular 3 (G3). Monoclonal antibodies that recognize epitopes in these domains were raised against Swarm rat chondrosarcoma aggrecan that was either denatured through reduction and alkylation or partially deglycosylated through chondroitinase ABC digestion or alkali elimination, the latter with or without sulfite addition. Monoclonal antibodies were further characterized for reactivity to purified aggrecan substructures including rat chondrosarcoma G1 and CS attachment domains, a recombinant rat chondrosarcoma G3 domain fusion protein, bovine articular cartilage G2 domain, and rat chondrosarcoma link protein (LP). Biochemical characterization of the specificities of these monoclonal antibodies indicated that one (1C6) recognized an epitope shared by both the G1 and the G2 domains; one (5C4) recognized an epitope shared by both LP and the G1 domain; one (7D1) recognized an epitope shared by both the G1 and the CS attachment domains; two (14A1 and 15B2) recognized epitopes in the CS attachment domain; one (14B4) recognized an epitope in the G3 domain; and one (13D1) recognized a ubiquitous epitope shared by the G1, G2, G3, and CS attachment domains of aggrecan and also LP. Collectively the specificities of these antibodies confirm the occurrence of multiple repeated epitopes (both carbohydrate and protein in nature) throughout the different domain structures of aggrecan. These antibodies have been proven to be useful for identifying aggrecan-like molecules in several connective tissues other than cartilage.

Identification and characterization of a cell surface proteoglycan on keratinocytes

Proteoglycans fill the intercellular space between keratinocytes but their structure and function are not well understood. We have identified and partially characterized one intercellular proteoglycan on human keratinocytes, for which we propose the name epican (epidermal intercellular proteoglycan). Monoclonal antibodies (MoAb) were generated from a mixture of keratinocyte proteoglycans. One, designated MoAb17, identified the core protein of an intercellular proteoglycan that had an apparent mobility of greater than 250 kDa on Western blots. The core protein itself had an apparent mobility of 180 kDa following deglycosylation with trifluoromethanesulfonic acid. Enzymatic deglycosylation revealed that most core protein molecules were substituted with heparan sulfate but that some carried chondroitin sulfate instead. Smaller forms of the core protein were more abundant in tissue-culture medium than in cell extracts. This proteoglycan was localized by immunofluorescence to the intercellular space of the epidermis and the surface of keratinocytes in vitro, particularly at cell-cell contacts. MoAb17 did not react with protoglycans extracted from other skin cells, nor did it bind to basement membranes or connective tissue. Comparison of Western immunoblots using MoAb17 and antibodies to core proteins of other proteoglycans suggested that epican is not related to syndecan but is a member of the CD44 family.

A human osteoblastic cell line, MG-63, produces two molecular types of macrophage-colony-stimulating factor

A human osteoblastic cell line, MG-63, mouse primary osteoblasts, and a mouse osteoblastic cell line, MC3T3-E1, were shown to produce macrophage-colony-stimulating factor (M-CSF) by bone-marrow-cell colony assay, using a specific neutralizing antibody for M-CSF. Immunoblot analysis of M-CSF, produced by MG-63 cells, revealed the presence of a higher-molecular-weight species of M-CSF, in addition to the 85-kDa M-CSF. The higher-molecular-weight species had a high affinity to the DEAE-Sephacel column and was sensitive to chondroitinase ABC and AC. These physico-chemical profiles were wholly compatible with those of the proteoglycan form of M-CSF (PG-M-CSF), which was recently identified by our group in the conditioned medium of Chinese hamster ovary cells transfected with the 4.0-kb cDNA of the M-CSF gene. Conditioned medium of MG-63 cells was fractionated by DEAE-Sephacel column chromatography, and the M-CSF of each fraction was measured by both enzyme-linked immunosorbent assay and bone-marrow-cell colony assay. The fractions eluted by 0.3-0.6 M NaCl, which were shown to contain only PG-M-CSF on immunoblot analysis, also have macrophage-colony-stimulating activity.

Proteoglycan synthesis by scleral chondrocytes is modulated by a vision dependent mechanism

Proteoglycan synthesis was measured in chick sclera at the onset of form-deprivation myopia, as well as in the period immediately following removal of the occluder. Two day-old chicks were monocularly form vision deprived for periods from one to ten days and proteoglycan synthesis was determined after placing posterior scleral buttons in organ culture and measuring 35SO4 incorporation into glycosaminoglycans. Following 24 hrs of form-deprivation, proteoglycan synthesis was 33% higher in myopic eyes as compared with paired control eyes. The rate of proteoglycan synthesis further increased to levels 83% higher than controls after four days of form-deprivation and remained elevated throughout the ten day period of deprivation. Removal of the occluder after 10 days of form-deprivation resulted in a rapid drop in the rate of proteoglycan synthesis to control levels within 24 hrs. Proteoglycan synthesis was also measured in scleral chondrocytes isolated from control and myopic eyes after 10 days of form-deprivation. Proteoglycan synthesis by chondrocytes from myopic eyes did not return to control levels until 48 hrs after plating. Since the rate of proteoglycan synthesis returns to control levels more quickly during the recovery period ex vivo than when scleral chondrocytes from myopic eyes are placed in cell culture, we suggest that a mechanism is present within the eye which rapidly lowers the rate of proteoglycan synthesis in response to form vision.

Characterization of proteoglycan degradation by calpain

Degradation of cartilage proteoglycans was investigated under neutral conditions (pH 7.5) by using pig kidney calpain II (EC 3.4.22.17; Ca(2+)-dependent cysteine proteinase). Aggregate and monomer degradation reached a maximum in 5 min at 30 degrees C when the substrate/enzyme ratio was less than 1000:1. The mode of degradation was limited proteolysis of the core protein; the size of the products was larger than that of papain-digested products and comparable with that of trypsin-digested products. The hyaluronic acid-binding region was lost from the major glycosaminoglycan-bearing region after incubation with calpain II. Calpains thus may affect the form of proteoglycans in connective tissue. Ca(2+)-dependent proteoglycan degradation was unique in that proteoglycans adsorb large amounts of Ca2+ ions rapidly before activation of calpain II: 1 mg of pig cartilage proteoglycan monomer adsorbed 1.3-1.6 mu equiv. of Ca2+ ions before activation of calpain II, which corresponds to half the sum of anion groups in glycosaminoglycan side chains. This adsorption of Ca2+ was lost after solvolysis of proteoglycan monomer with methanol/50 mM-HCl, which was used to desulphate glycosaminoglycans. Therefore cartilage proteoglycans are not merely the substrates of proteolysis, but they may regulate the activation of Ca(2+)-dependent enzymes including calpains through tight chelation of Ca2+ ions between glycosaminoglycan side chains.

Nerve growth factor-induced changes in the structure of sulfated proteoglycans in PC12 pheochromocytoma cells

Structural changes in proteoglycans (PGs) were examined during the neuritogenesis of PC12 cells induced by nerve growth factor (NGF). (1) A heparan sulfate (HS) PG and a chondroitin sulfate (CS) PG were synthesized by PC12 cells, irrespective of the presence of NGF or the duration of culture. PGs released from PC12 cells into the culture medium were mostly CSPGs. (2) In the absence of NGF, the apparent molecular mass of HSPG prepared from PC12 cells after 3 days of culture was in the range of 90-190 kDa for the intact form (Kav = 0.38 on Sepharose CL-6B), 12 kDa for HS, and 61 kDa for the core protein. In the presence of NGF, these values were 90-190 kDa, 10 kDa, and 51 kDa and 61 kDa, respectively. The intact forms of cell-associated CSPG had apparent molecular mass ranges of 120-150 kDa and 120-190 kDa (Kav = 0.38 and 0.34), with CSs of 15 kDa and 20 kDa in the presence and absence of NGF, respectively. The apparent molecular mass of the core protein of cell-associated CSPG was 92 kDa, irrespective of the presence of NGF. The molecular sizes of cell-associated PGs and their glycosaminoglycans remained unchanged during culture. (3) CSPGs released by PC12 cells into the culture medium were separated into two peaks (I and II) by column chromatography on DEAE-cellulose. The peak II fraction prepared from the medium with NGF after 3 days of culture consisted of CSPG with Kav = 0.22 on Sephacryl S-300 [40-84 kDa by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE)].(ABSTRACT TRUNCATED AT 250 WORDS)

Extraction and characterisation of the intact form of bovine vitreous type IX collagen

We provide the first biochemical characterisation of intact type IX collagen extracted from bovine vitreous. It possesses a shortened alpha 1(IX) chain (M(r) 64K) compared to its cartilage counterpart (M(r) 84K). All the vitreous type IX collagen is in a proteoglycan form, its glycosaminoglycan constituent being a chondroitin/dermatan sulphate component of M(r) 15-60K attached to the alpha 2(IX) chain. This contrasts with previous findings in chick vitreous where a very long glycosaminoglycan chain of M(r) approximately 350K was demonstrated.