The structure of a polysaccharide from infectious strains of Burkholderia cepacia.

The structure of an acidic exopolysaccharide (EPS) from eight strains of Burkholderia cepacia has been investigated by methylation and sugar analysis, periodate oxidation-Smith degradation, and partial acid-hydrolysis. An enzyme preparation obtained from the same organisms producing the EPS was also used to depolymerize the polysaccharide. Detailed NMR studies of the chemical and enzymatic degradation products showed that this EPS consists of a highly branched heptasaccharide-repeating unit with the following structure: [abstract: see text]. About three O-acetyl groups per repeating unit are present at undetermined positions.

Structure of succinoglycan from an infectious strain of Agrobacterium radiobacter.

The exopolysaccharide produced by a cystic fibrosis clinical isolate of Agrobacterium radiobacter was shown by monosaccharide and methylation analyses, degradation with succinoglycanase and NMR analysis to be a succinoglycan with the structure shown below. (S)-pyruvic acid is found stoichiometrically as 4,6-O-ketal substituent of terminal glucose. Succinic acid is present in 40% of the repeating units and it is attached to O-6 of the 3-linked glucose next to the pyruvate carrying sugar. Some evidence is found that a small amount of succinic acid (ca. 6% of the total) is linked to O-6 of another undetermined glucose. [structure: see text]

Heparan sulfate composition of alternatively spliced CD44 fusion proteins.

Prior analyses of recombinant CD44 fusion proteins have indicated that combinatorial splicing of variant exons exerts distal effects on chondroitin sulfate content and structure, which may regulate the biological properties of the respective CD44 isoforms. The consequences of splicing of variant exons V4-7 on the heparan sulfate moieties were therefore examined, utilizing recombinant chimeras containing exons V3 and V8-10, engineered with or without exons V4-7 and expressed as Ig fusion proteins in COS cells. Splicing of exons V4-7, though they contain no consensus motifs for glycosaminoglycan assembly, resulted in markedly increased polymer sulfation levels of the heparan sulfates. The sulfate groups of both the CD44 V3-10 and V3,8-10 isoforms occurred as di- and tri-sulfated dissacharide units and were restricted to one N-sulfated block domain within the polymers. Compared to native human keratinocyte CD44, the recombinant heparan sulfates were relatively low in sulfate content. Our data indicate that variant exon V4-7 splicing exerts distal effects on the composition of this glycosaminoglycan. These effects may regulate those functions that are mediated through the heparan sulfate moieties, such as the binding of growth factors.

Hyaluronidase activity in leeches (Hirudinea).

The leech hyaluronoglucuronidase (hyaluronidase I) was identified in Erpobdellidae (Nephelopsis obscura and Erpobdella punctata) and Glossiphoniidae (Desserobdella picta) and historically described from Hirudinidae (Hirudo medicinalis). A second leech hyaluronidase (hyaluronidase II) which hydrolyzed only a few bonds to for hyaluronan oligosaccharides larger than 6500 Da, was found in Glossiphoniidae (Helobdella stagnalis, Glossiphonia complanata, Placobdella ornata, and Theromyzon sp.) and in Haemopidae (Haemopis marmorata). The distribution of the two hyaluronidases in leech occurred in both orders (Arhynchobdellida and Rhynchobdellida) and in macrophagous and haematophagous feeding types whereas the liquidosomatophagous leeches only had hyaluronidase II.

Chondroitin sulphate composition and structure in alternatively spliced CD44 fusion proteins.

Previous studies have indicated that CD44 isoforms, spliced with variant exons, are heterogeneously glycanated with chondroitin sulphate and heparan sulphate chains. Because such alternative splicing may regulate divergent biological effects of the specific isoforms, we analysed the consequences of this process on the composition and structure of the chondroitin-sulphate chains. Recombinant chimaeras were engineered with and without exons V3-10 or V3,8-10 and expressed as Ig fusion proteins in COS cells. In addition, the chondroitin sulphates of wild-type isoforms were contrasted with those of isoforms mutated with serine-to-alanine codon substitutions at a putative Ser-Gly-Ser-Gly glycosaminoglycan acceptor site within exon V3. The chondroitin sulphates contained both 4- and 6-sulphated galactosamine residues, although there was a high content of non-sulphated galactosamine-containing repeat units. Splicing of exons V4-7, which contain no Ser-Gly consensus motifs, resulted in increased glycanation with chondroitin-sulphate chains, as well as increased sulphation levels of the polymers. Comparison of wild-type and acceptor-site mutant isoforms showed that chondroitin-sulphate content declined by more than 60-80% in the mutant, indicating that assembly of chondroitin-sulphate chains occurs there, and a general decrease in the sulphation level of the remaining chains was observed. Undersulphation of the recombinant chondroitin sulphates was shown by parallel analyses with native human keratinocyte CD44 molecules and is most probably an artifact of transient expression in COS cells. Our data indicate that combinatorial exon splicing exerts complex and distal effects on glycanation patterns and structure, which presumably modulate those functions that may be mediated though the chondroitin-sulphate moieties, such as motility and matrix invasion.

Divergent regulation of proteoglycan and glycosaminoglycan free chain expression in human keratinocytes and melanocytes.

Keratinocytes and melanocytes, which together form units of structure and function within human epidermis, are known to differ in expression of autocrine growth factors, particularly those with heparin binding affinity. Because such cytokines could be regulated by the endogenous heparinlike glycosaminoglycan, heparan sulfate, proteoglycan synthesis was compared between human keratinocytes and melanocytes cultured from a common donor. Following steady-state isotopic labeling under conditions of active growth (low density cultures) and growth inhibition (high density cultures), the sulfated polymers were isolated from conditioned media and cell extracts. We found that keratinocytes produced substantially more sulfated glycosaminoglycans than did the melanocytes. There was no evidence for hyaluronic acid synthesis by the melanocytes. The majority of [35S]-sulfate labeling was in the heparan sulfates of the keratinocytes and in the chondroitin sulfates of the melanocytes. During the transition from active growth to growth inhibition, there was increased heparan sulfate proteoglycan and free chain synthesis by keratinocytes but not by melanocytes, and chondroitin sulfate proteoglycan production declined in both cell lineages. The differences may reflect divergent evolution as each cell type came to exploit those complex polysaccharides in different ways to regulate molecular pathways of growth and differentiation. The coupling of growth inhibition with augmented synthesis of heparan sulfates observed for the keratinocytes suggests a regulatory role in growth factor signaling in that cell type.

Glycosaminoglycans in Anodonta californiensis, a Freshwater Mussel.

The synthesis of glycosaminoglycans (GAG) in a freshwater mussel was studied in organ culture using labeled precursors. The major GAGs synthesized were determined and characterized by chemical and enzymatic methods. They were shown to be heparin and an unusual type of heparan sulfate. Gills produced about 50% of each polymer; mantles synthesized little heparin and mostly the heparan-sulfate-like compound, which is similar to a GAG isolated previously from lobsters. No significant amounts of chondroitin sulfates were present. Histological data showed that the sulfate-labeled GAGs were present mainly in exterior pericellular and basement membrane locations of gills and mantle. That is, they would be in contact with the external aqueous environment, suggesting a potential role in calcium transport and storage.

Differentially expressed patterns of glycosaminoglycan structure in heparan sulfate proteoglycans and free chains.

The metabolic relationships between heparan sulfate proteoglycans, free chains, and oligosaccharides in different cell locations were evaluated by comparing their glycosaminoglycan structure. Metabolically labeled heparan sulfate proteoglycans of BALB/c 3T3 cell layers and in conditioned medium were compared with the heparan sulfate free chains (modal mass = 10 kDa) and oligosaccharides (modal mass = 3 kDa) of the cells. Nonlytic, in situ digestion with heparitinase I indicated that 90% of proteoglycans, 70% of the free chains, and 20% of the oligosaccharides were enzyme accessible, but there was no evidence using competitive ligands for binding of the products to the cell surface via the glycosaminoglycan moieties. Structurally, the membrane proteoglycans were the most O-/N-sulfated and yielded more tri- and tetra-sulfated di- and tetra-saccharides by nitrous acid degradation. In contrast, the side chains of medium proteoglycans were less sulfated and more polydisperse in mass, suggesting that most medium proteoglycans are not processed from membrane precursors. The heparan sulfate free chains were of lower mass, less sulfated, and more heterogeneous in distribution of the anionic groups than were proteoglycan side chains. Corroborating analytical heparitinase I digestion indicated that generation of di- and tetra-saccharides proportionately increased from membrane proteoglycan, to cell free chain, to medium proteoglycan categories. Because the structural patterns of the heparan sulfate free chains did not reveal a clear relationship with the side chains of the major proteoglycans, their origin was further probed by [3H]BH4-labeling of the reducing terminus under varying stringencies. The end-labeled residues obtained by nitrous or strong acid hydrolysis of the free chains showed insignificant amounts of galactose and xylose, but rather glucosamine N-sulfate and a residue likely generated from glucuronate. The effective labeling that was achieved with weak alkali indicated that covalent oligopeptide is not present. In summary, the heparan sulfate free chains, which in part are components of the cell surface, are of relatively low mass, are unassociated with covalent peptide, and most probably have a disaccharide motif of glucosamine N-sulfate and a uronate residue at the reducing end. Taken together, these observations suggest that the free chains originate by processing of precursor heparan sulfate proteoglycans on the cell surface via an endoglycosidase acting on an N-sulfated portion of the original polymer.

Topography of proteoglycan and glycosaminoglycan free chain expression in 3T3 fibroblasts and human keratinocytes.

Synthesis of heparan sulfate-free chains by human keratinocytes is upregulated during terminal differentiation. The cellular location of this product class and the significance of the differentiation effect are unknown. Differential plasma membrane shearing with cationized colloidal silica was used to evaluate the compartmentalization of the heparan and chondroitin sulfate free chains and their respective proteoglycans in 3T3 fibroblasts and human keratinocytes. The method exploits the topologic segregation of plasma membranes of adherent cells into ventral, dorsal, and intracellular domains and the selective binding of the silica to the dorsal membranes, which by shearing can be separated from ventral membranes adherent to the substratum. Analysis of membrane preparations from sheared cells that had been prelabeled with [35S]-sulfate revealed the proteoglycans to be predominantly ventral, at which location a matrix binding function could be accommodated. Proteoglycans were also recovered from dorsal and intracellular membranes, suggesting active trafficking between intra- and extra-cellular sites. In contrast, the major fraction of heparan and chondroitin sulfate free chains was either cytosolic or associated with intracellular membranes, with the remaining approximately 20% segregated to dorsal and ventral membranes. These results suggest different cellular functions for the proteoglycans and glycosaminoglycan free chains. The partial localization of the free chains to peripheral membranes is compatible with our prior hypothesis that they arise by processing of precursor proteoglycans on cell surfaces. Following this origin, the free glycosaminoglycan polymers could be available to bind ligands such as cytokines prior to transport to intracellular sites of action.

Proteoglycan and glycosaminoglycan free chain expression in keratinocytes, endothelium, and mesenchymal cells.

Cultured fibroblasts, bovine aortic endothelial cells, and human keratinocytes synthesize both proteoglycans and glycosaminoglycan free chains, the proportions varying between cell types. The major metabolic labeling is in proteoglycans, except for keratinocytes with approximately 60% of product as free chains. The proteoglycans range from approximately 50- greater than 1000 kDa, and the glycosaminoglycan side chains derived by alkaline elimination are approximately 30- greater than 100 kDa. The glycosaminoglycan free chains, in contrast, are smaller, from approximately 7-40 kDa in mass. The proteoglycans are both medium and cell layer constituents, whereas the glycosaminoglycan free chains are essentially confined to cells. The cellular proteoglycans and a portion of the free chains are accessible to in situ digestion by Flavobacterial glycosaminoglycan lyases, presumably reflecting localization to the cell surface. Collectively, the data show the free chains to be a common feature of all cells studied and to be partly expressed on cell surfaces. We hypothesize that the processing that creates these free chains occurs on cell surfaces, in which location they could serve ligand receptor functions.

Proteoglycan and glycosaminoglycan synthesis by cultured rat mesangial cells.

The synthesis of metabolically labeled proteoglycans and glycosaminoglycans from medium, cell layer and substrate attached material by rat glomerular mesangial cells in culture was characterized. The cellular localization of the labeled proteoglycans and glycosaminoglycans was determined by treating the cells with Flavobacterial heparinase. Of the total sulfated glycosaminoglycans, 33% were heparan sulfate; 55% of the cell layer material was heparan sulfate; 80% of sulfated proteins in the medium were chondroitin sulfate/dermatan sulfate. Putative glycosaminoglycan free chains of heparan sulfate and chondroitin sulfate were found in both the medium and cell layer; 95% of total proteoglycans and most (90%) of the putative heparan sulfate free chains were removed from the cell layer by the heparinase, whereas only 50% of the chondroitin sulfate and 25% of dermatan sulfate were removed. Large amounts of hyaluronic acid labeled with 3H glucosamine were found in the cell layer. In summary, approximately 60% of total sulfated glycoproteins was in the form of putative glycosaminoglycan free chains. Thus rat mesangial cells may synthesize large amounts of putative glycosaminoglycan free chains, which may have biological functions in the glomerulus independent of proteoglycans.

Inhibition of rat mesangial cell growth by heparan sulfate.

The ability of heparan sulfate, an endogenous component of the glomerulus, to regulate the growth of cultured rat mesangial cells was investigated. Heparan sulfate caused a dose-dependent inhibition of rat mesangial cell growth, 85% inhibition compared with controls at the highest dose (1,000 micrograms/ml). Chondroitin sulfate produced no inhibition. The low-sulfated fraction of heparan sulfate (9%) produced more inhibition than the high-sulfated fraction (13%), 90 +/- 1 vs. 71 +/- 2% (P = 0.002). The effects of the heparan sulfate were completely reversible. Treatment of heparan sulfate with heparitinase increased the degree of inhibition, 71 +/- 1 vs. 84 +/- 1% (P less than 0.001). Four different oligosaccharides derived from heparan sulfate and heparin were tested for their ability to inhibit growth. One of the oligosaccharides, low-sulfated (10%), caused significant inhibition, 76 +/- 2%. Heparan sulfate was also able to inhibit the growth of Swiss 3T3 fibroblasts (63 +/- 5%). This inhibition was less marked than that seen with mesangial cells. Thus heparan sulfate was able to significantly inhibit rat mesangial cell growth in culture. Alterations in glomerular heparan sulfate may play an important role in alterations in mesangial cell growth.

The distinctive pattern of proteoglycan and glycosaminoglycan free chain synthesis by cultured human epidermal keratinocytes.

The in vitro synthesis of proteoglycans and glycosaminoglycan free chains was studied in human epidermal keratinocytes. Preconfluent and confluent cultures established on 3T3 feeders were steady state labeled with [35S]-sulfate and [3H]-glucosamine after removal of the 3T3 cells. Products in nonionic detergent extracts of keratinocytes and in the medium were analyzed in the presence of protease inhibitors. Glycosaminoglycans as proteoglycans and as free chains were defined by susceptibility or resistance, respectively, to alkaline borohydride reduction. Products associated with the cells were approximately 30% proteoglycans and approximately 70% glycosaminoglycan free chains, whereas in the medium virtually all was proteoglycan. The heparan and chondroitin sulfate proteoglycans were small compared to those of many other cell types. Their Kav on Sepharose CL-4B was 0.56 (estimated 50 kDa), whereas the free chain Kav was 0.74 (estimated 12 kDa). Relative amounts of the sulfated products varied with confluence and differentiation; heparan and chondroitin sulfates were equally represented within the free chains and proteoglycans of the cells in preconfluent, proliferating cultures, whereas in postconfluent, differentiated cultures the major labeling was in the heparan sulfate products, consistent with our prior reports (J Invest Dermatol 88:215-9, 1987 and 91:492-8, 1988). The cellular localization of the products was probed with glycosaminoglycan degrading enzymes added to isotopically prelabeled cultures. The proteoglycans appeared to be located on the external surface of plasma membranes, whereas the glycosaminoglycan free chains resisted digestion and are either intracellular or membrane associated, but otherwise inaccessible. These data establish the distinctive pattern of low Mr proteoglycans and abundant cell-associated glycosaminoglycan free chains synthesized by keratinocytes.

Proteoglycans in the pathogenesis of amyloidosis.

Glycosaminoglycans, which occur in most organisms from bacteria to vertebrates, appear to be present in all amyloid deposits regardless of the protein involved. This, their early appearance, and their likely interaction with specific proteins imply that they play an essential role in the pathogenesis of amyloidosis.

Glycosaminoglycan free chains. External plasma membrane components distinct from the membrane proteoglycans.

Heparan sulfate and chondroitin sulfate glycosaminoglycans of BALB/c 3T3 fibroblasts, metabolically labeled with [3H]glucosamine and [35S]sulfate precursors, are resolved by preparative Sepharose CL-4B chromatography into distinct products, the proteoglycans and the glycosaminoglycan free chains, the latter resistant to appreciable molecular weight shift upon alkaline borohydride reduction. The in situ localization of these cell layer molecules was probed with glycosaminoglycan degrading enzymes (lyases) of bacterial origin, which were used to digest isotopically prelabeled monolayer cultures prior to extraction with a nonionic detergent in the presence of protease inhibitors. Most of the total cellular complement of glycosaminoglycan free chains, in addition to the proteoglycans, proved accessible to the lyases under conditions which did not appreciably affect cell viability or morphology. Because these results were also obtained under low temperature (4 degrees C) conditions and in the presence of phenylarsine oxide, a sulfhydryl reagent that irreversibly inhibits endocytosis, the effects of the lyases are not dependent upon internalization by the cells. The cellular production and cell surface expression of the glycosaminoglycan free chains were not materially altered when lysosomal function was pharmacologically inhibited, confirming that the free chains are not intracellular intermediates in the lysosomal degradation pathways of proteoglycans. Contrary to the prevailing model, our observations establish that, at least in the cell line under study, glycosaminoglycan free chains are located on the external leaflet of the plasma membrane, as such suggesting that these products are biologically active components of cell surfaces.

Glycosaminoglycan synthesis by human keratinocytes: cell growth and medium calcium effects.

The influences of cell density, differentiation, and medium calcium levels on glycosaminoglycan biosynthesis were evaluated in cultured human epidermal keratinocytes. Following metabolic labeling with [35S]-sulfate and [3H]-glucosamine under steady state conditions in "high" medium calcium (greater than 1.0 mMol), the majority of sulfated glycosaminoglycans remained associated with the cell layers, whereas hyaluronic acid, which was present in smaller amounts than the sulfated products, was about equally distributed between the medium and the cell layers. Of the sulfated glycosaminoglycans, heparan sulfate and chondroitin 4/6-sulfate were the major species and were present in roughly comparable amounts, whereas dermatan sulfate was quantitatively the lesser of the products. The effects of "low" medium calcium (0.3 and 0.025 mM) were complex, although a consistent decrease in the incorporation of the [3H]-glucosamine precursor was found at high cell density, probably reflecting a decrease in its intracellular specific activity. In "high" calcium cultures, there was a strong inverse correlation (r = -0.92) between keratinocyte cell number and cellular production of sulfated glycosaminoglycans, whereas no such relationship was evident in cultures grown in "low" calcium medium at comparable cell density. Because keratinocyte differentiation is inhibited in the low calcium conditions, the results suggest that the decrease in production of sulfated glycosaminoglycans by confluent keratinocytes may actually correlate with differentiation rather than with cell number.

Evidence for independent metabolism and cell surface localization of cell surface localization of cellular proteoglycans and glycosaminoglycan free chains.

The synthesis and turnover of metabolically labeled proteoglycans from medium, cell layer, and substratum-associated compartments were characterized in four cell lines of fibroblastic origin, including a fibrosarcoma line, and in the murine melanoma cell type, B16.F10. Substantial differences were apparent between the various cell types with regard to quantities, hydrodynamic sizes, and compartmentalization of labeled product. Such variations were greater between the different cell lines than between separately labeled cultures of the same cell type. Greater than 85% of cell-associated proteoglycans were accessible to glycosaminoglycan-degrading enzymes added to the medium of monolayer cultures, demonstrating their principal location to be external to the cell membrane. Apparent glycosaminoglycan free chains, determined by a lack of change in hydrodynamic size following alkaline elimination, were among the products from each cell line and were similarly found to be in a principally pericellular location. Results from label-chase studies demonstrated apparent independent kinetics for proteoglycans and glycosaminoglycan free chains, with little conclusive evidence for precursor-product relationships. Also, their processing by the cells was different, since the proteoglycans were shed largely unchanged into the medium for the three cell lines evaluated, whereas the free chains were not recoverable from the medium in significant amounts. The latter observation suggests the internalization of cell surface-associated free chains and their depolymerization at an intracellular site. The results, which indicate that the content, cellular disposition, and turnover of proteoglycans are quite variable between the cell lines studied, may reflect fundamental cell type-specific specialization in the metabolism of these complex substances. Furthermore, the data raise the interesting possibility that glycosaminoglycan free chains may have biological functions at the cellular level, independent of proteoglycans.

Changes in heparan sulfate correlate with increased glomerular permeability.

The glomerular capillary wall functions as both a size-selective and charge-selective barrier. Heparan sulfate is known to be an important component of the charge-selective barrier to filtration of polyanions. We studied the alterations in both the charge and size selectivity barriers in a model of experimental membranous nephropathy in the rabbit. The fractional clearance of both charged and uncharged dextrans compared to inulin was measured. Sulfate incorporation into glycosaminoglycans was measured and the glomerular heparan sulfate was isolated and biochemically characterized. Membranous nephropathy in the rabbit was induced with daily injections of cationic bovine serum albumin. After three weeks of injection animals had 735 +/- 196 mg/24 hours of protein excretion. There was no change in [35S] incorporation in 24 hours by experimental animals, 440 +/- 91 DPM/mg dry weight of glomeruli, N = 9 versus 410 +/- 98, N = 11 in controls. The percentage of [35S] incorporated into heparan sulfate versus chondroitin sulfate was decreased, 60% +/- 3 versus 79% +/- 2, P less than 0.001. Heparan sulfate from membranous nephropathy eluted from ion exchange chromatography in a lower molarity salt, indicating a lower effective charge. Fractional clearance of neutral dextrans was significantly increased in membranous nephropathy for dextrans greater than 48 A, while fractional clearance of dextran sulfates was significantly increased compared to controls for dextrans greater than 32 A. Thus, in membranous nephropathy there is loss of both charge selectivity and size selectivity. The loss of charge selectivity correlated with a change in the structure of the glomerular heparan sulfate.(ABSTRACT TRUNCATED AT 250 WORDS)

Presence and role of glycosaminoglycans in amyloidosis.

Though the presence of glycosaminoglycans in amyloid deposits has been recognized for a long time their role in the pathogenesis of the disorder has remained elusive. As shown here, liver and spleen of human patients with secondary amyloidosis contain 5 to 10 times the amount of glycosaminoglycans as normal organs. Of the three major glycosaminoglycans measured, the heparan sulfate fraction showed the largest increase. In mice where amyloidosis was induced by the injection of casein and enhancing factor (accelerated model) 35SO4-labeled, or Alcian blue stained glycosaminoglycans appeared as early as and at the same location as proteins detected by Congo red staining which was about 2 days after initiation of the procedure. When glycosaminoglycan synthesis was followed in liver and spleen slices of control and experimental animals a significant increase in rate was found in the spleen of the experimental mice. Though there was an increase in heparan sulfate synthesis the major contribution to the overall increase was made by the chondroitin sulfates in the accelerated as well as in the standard induction model. In addition, unlike in the human disorder the chondroitin sulfates were the major glycosaminoglycans which had accumulated in the spleens of animals which had amyloidosis induced by the long term standard procedure (6 weeks) as measured by isolation and uronic acid analysis. The data presented here show that glycosaminoglycans appear to play an important and perhaps direct role in the process of amyloid deposition in the human disease as well as in the experimentally induced disorder in animals.