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

Mapping the Human Chondroitin Sulfate Glycoproteome Reveals an Unexpected Correlation Between Glycan Sulfation and Attachment Site Characteristics

Chondroitin sulfate proteoglycans (CSPGs) control key events in human health and disease and are composed of chondroitin sulfate (CS) polysaccharide(s) attached to different core proteins. Detailed information on the biological effects of site-specific CS structures is scarce as the polysaccharides are typically released from their core proteins prior to analysis. Here we present a novel glycoproteomic approach for site-specific sequencing of CS modifications from human urine. Software-assisted and manual analysis revealed that certain core proteins carried CS with abundant sulfate modifications, while others carried CS with lower levels of sulfation. Inspection of the amino acid sequences surrounding the attachment sites indicated that the acidity of the attachment site motifs increased the levels of CS sulfation, and statistical analysis confirmed this relationship. However, not only the acidity but also the sequence and characteristics of specific amino acids in the proximity of the serine glycosylation site correlated with the degree of sulfation. These results demonstrate attachment site-specific characteristics of CS polysaccharides of CSPGs in human urine and indicate that this novel method may assist in elucidating the biosynthesis and functional roles of CSPGs in cellular physiology.

Glycosaminoglycans: A Link Between Development and Regeneration in the Lung

What can we learn from embryogenesis to increase our understanding of how regeneration of damaged adult lung tissue could be induced in serious lung diseases such as chronic obstructive pulmonary disease (COPD), idiopathic pulmonary fibrosis (IPF), and asthma? The local tissue niche determines events in both embryogenesis and repair of the adult lung. Important constituents of the niche are extracellular matrix (ECM) molecules, including proteoglycans and glycosaminoglycans (GAGs). GAGs, strategically located in the pericellular and extracellular space, bind developmentally active growth factors (GFs) and morphogens such as fibroblast growth factors (FGFs), transforming growth factor-β (TGF-β), and bone morphogenetic proteins (BMPs) aside from cytokines. These interactions affect activities in many cells, including stem cells, important in development and tissue regeneration. Moreover, it is becoming clear that the "inherent code," such as sulfation of disaccharides of GAGs, is a strong determinant of cellular outcome. Sulfation patterns, deacetylations, and epimerizations of GAG chains function as tuning forks in gradient formation of morphogens, growth factors, and cytokines. Learning to tune these fine instruments, that is, interactions between GFs, chemokines, and cytokines with the specific disaccharide code of GAGs in the adult lung, could become the key to unlock inherent regenerative forces to override pathological remodeling. This review aims to provide an overview of the role GAGs play during development and similar events in regenerative efforts in the adult lung.

Update on the role of molecular factors and fibroblasts in the pathogenesis of Dupuytren's disease

The mechanism by which the fibroblast is able to trigger palmar fibromatosis is still not yet fully understood. It would appear certain that the "abnormal" fibroblasts continuously synthesise profibrotic cytokines which are able to determine the activation to myofibroblasts, to stimulate them to the further proliferation and synthesis of other cytokines, to modify the cells' differentiation and ultrastructural characteristics, as well as the production of matrix and other proteins. Several fibroblast growth factors have been suggested to be responsible of an abnormal cell activation with an aberrantly elevated collagen synthesis and extracellular deposition in Dupuytren's disease, as TGF-Beta, TNF-Alfa, PDGF, GM-CSF, free radicals, metalloproteinases, sex hormones, gene modified expression, mechanical stimulation. The Authors review the current state of knowledge in the field, by analyzing the role of these cytokines in the palmar fibromatosis.

Elastase-producing Pseudomonas aeruginosa degrade plasma proteins and extracellular products of human skin and fibroblasts, and inhibit fibroblast growth

Leg ulcers of venous origin represent a disease affecting 0.1-0.2% of the population. It is known that almost all chronic ulcers are colonized by different bacteria, such as staphylococci, enterococci and Pseudomonas aeruginosa. We here report that P. aeruginosa, expressing the major metalloproteinase elastase, induces degradation of complement C3, various antiproteinases, kininogens, fibroblast proteins, and proteoglycans (PG) in vitro, thus mimicking proteolytic activity previously identified in chronic ulcer fluid in vivo. Elastase-producing P. aeruginosa isolates were shown to significantly degrade human wound fluid as well as human skin proteins ex vivo. Elastase-containing conditioned P. aeruginosa medium and purified elastase inhibited fibroblast cell growth. These effects, in conjunction with the finding that proteinase production was detected in wound fluid ex vivo, suggest that bacterial proteinases play a pathogenic role in chronic ulcers.

Dermatan sulphate is released by proteinases of common pathogenic bacteria and inactivates antibacterial alpha-defensin

Defensins represent an evolutionarily conserved group of small peptides with potent antibacterial activities. We report here that extracellular proteinases secreted by the human pathogens Pseudomonas aeruginosa, Enterococcus faecalis and Streptococcus pyogenes release dermatan sulphate by degrading dermatan sulphate-containing proteoglycans, such as decorin. Dermatan sulphate was found to bind to neutrophil-derived alpha-defensin, and this binding completely neutralized its bactericidal activity. During infection, proteoglycan degradation and release of dermatan sulphate may therefore represent a previously unknown virulence mechanism, which could serve as a target for novel antibacterial strategies.

Heparan sulfate chains from glypican and syndecans bind the Hep II domain of fibronectin similarly despite minor structural differences

Numerous functions of heparan sulfate proteoglycans are mediated through interactions between their heparan sulfate glycosaminoglycan chains and extracellular ligands. Ligand binding specificity for some molecules, including many growth factors, is determined by complex heparan sulfate fine structure, where highly sulfated, iduronate-rich domains alternate with N-acetylated domains. Syndecan-4, a cell surface heparan sulfate proteoglycan, has a distinct role in cell adhesion, suggesting its chains may differ from those of other cell surface proteoglycans. To determine whether the specific role of syndecan-4 correlates with a distinct heparan sulfate structure, we have analyzed heparan sulfate chains from the different surface proteoglycans of a single fibroblast strain and compared their ability to bind the Hep II domain of fibronectin, a ligand known to promote focal adhesion formation through syndecan-4. Despite distinct molecular masses of glypican and syndecan glycosaminoglycans and minor differences in disaccharide composition and sulfation pattern, the overall proportion and distribution of sulfated regions and the affinity for the Hep II domain were similar. Therefore, adhesion regulation requires core protein determinants of syndecan-4.

SECMA 1, a mitogenic hexapeptide from Ulva algeae modulates the production of proteoglycans and glycosaminoglycans in human foreskin fibroblast

SECMA 1 is a polypeptide purified from a green algeae of the Ulva species by several gel chromatographies, showing the following sequence (Glu-Asp-Arg-Leu-Lys-Pro). In order to determine the effect of SECMA 1 on human skin fibroblasts extracellular matrix, proteoglycans (PGs) and glycosaminoglycans (GAGs) were assayed after 24 h incubation of 20 day-old foreskin fibroblasts at the 2nd passage. The results revealed that most of [35S]sulphate was associated with fibroblast membranes, which contained (67%) of the total de novo synthesized sulphated PGs, in two distinct forms: one hydrophilic (39%), and one hydrophobic (28%). The remaining 'matrix' retained 5% of proteoglycans. The remaining 35S-label may represent the free label in the cytosol. After 24 h incubation of skin fibroblasts with different concentrations of SECMA 1 (2, 4 and 10 micrograms/ml), the [35S]sulphate incorporation into PGs of Salt-extract, sodium deoxycholate (DOC) extract and Guanidine hydrochloride (GuA-HCl)-extract was increased significantly (P < 0.005) with 4 micrograms/ml, as compared to untreated control. The most effective concentration (4 micrograms/ml) increased the different [35S]sulphate PGs extracts (NaCl, DOC and GuA-HCl) by respectively (66; 17 and 75%). The relative contents of iduronic and glucuronic acid in the GAG produced by skin fibroblasts were estimated. No effect of SECMA 1 on the incorporation of [35S]sulphate into Heparan sulphate was found. The incorporation of [35S]sulphate into (chondroïtine sulphate + heparan sulphate) and (chondroïtine sulphate + dermatan sulphate) was increased by respectively 37% and 11% by SECMA 1 (4 micrograms/ml).

Binding, internalization, and degradation of antiproliferative heparan sulfate by human embryonic lung fibroblasts

Binding, internalization, and degradation of 125I-labeled, antiproliferative, or nonantiproliferative heparan sulfate by human embryonic lung fibroblasts was investigated. Both L-iduronate-rich, antiproliferative heparan sulfate species as well as L-iduronate-poor, inactive ones were bound to trypsin-releasable, cell-surface sites. Both heparan sulfate types were bound with approximately the same affinity to one high-affinity site (Kd approximately 10(-8) M) and to one low-affinity site (Kd approximately 10(-6) M), respectively. Results of Hill-plot analysis suggested that the two sites are independent. Competition experiments with unlabeled glycosaminoglycans indicated that the binding sites had a selective specificity for sulfated, L-iduronate-rich heparan sulfate. Dermatan sulfate, which is also antiproliferative, was weakly bound to the cells. The antiproliferative effects of heparan and dermatan sulfate appeared to be additive. Hence, the two glycosaminoglycans probably exert their effect through different mechanisms. At concentrations above 5 micrograms/ml (approximately 10(-7) M), heparan sulfate was taken up by human embryonic lung fibroblasts, suggesting that the low-affinity site represents an endocytosis receptor. The antiproliferative effect of L-iduronate-rich heparan sulfate species was also exerted at the same concentrations. The antiproliferative species was taken up to a greater degree than the inactive one, suggesting a requirement for internalization. However, competition experiments with dextran sulfate suggested that both the high-affinity and the low-affinity sites are involved in mediating the antiproliferative effect. Structural analysis of the inactive and active heparan sulphate preparations indicated that although sulphated L-iduronate appears essential for antiproliferative activity, it is not absolutely required for binding to the cells. Degradation of internalized heparan sulfate was analyzed by polyacrylamide gel electrophoresis using a sensitive detection technique. The inactive species was partially degraded, whereas the antiproliferative one was only marginally affected.

Expression of the mouse mastocytoma glucosaminyl N-deacetylase/ N-sulfotransferase in human kidney 293 cells results in increased N-sulfation of heparan sulfate

The biosynthesis of heparin and heparan sulfate involves a series of polymer-modification reactions that is initiated by N-deacetylation and subsequent N-sulfation of N-acetylglucosamine residues. These reactions are catalysed by a combined N-deacetylase/N-sulfotransferase. Proteins expressing both activities have previously been purified from mouse mastocytoma, which generates heparin, and from rat liver, which produces heparan sulfate. In the present study, the mouse mastocytoma enzyme has been expressed in the human kidney cell line, 293, to investigate whether it could promote modification of the endogenous heparan sulfate precursor polysaccharide into a heparan-like molecule. The N-deacetylase activity of the stably transfected cell clones as approximately 8-fold higher, on a cell-protein basis, than that of control cells, while the N-sulfotransferase activity was increased approximately 2.5 fold. The amounts of glycosaminoglycans synthesized were the same in control and transfected cells, measured as incorporation of [3H]-glucosamine, whereas 35S-labeled glycosaminoglycans were approximately 50% increased in transfected cells, with an increased relative content of heparin sulfate. Structural analysis demonstrated the the glucosamine units of the "heparan sulfate" from transfected cells were almost exclusively N-sulfated, as expected for heparin, whereas more than half of the glucosamine units of the control polysaccharide remained N-acetylated. Notably, the increased N-sulfation was not accompanied by increased O-sulfation, not by C-5 epimerization of D-glucuronic to L-iduronic acid units. The implications of these findings are discussed with regard to the regulation of the biosynthetic process.

Sulphated and undersulphated heparan sulphate proteoglycans in a Chinese hamster ovary cell mutant defective in N-sulphotransferase

The Chinese hamster ovary cell mutant, pgsE-606, synthesizes undersulphated heparan sulphate glycosaminoglycans because of a deficiency in N-sulphotransferase activity [Bame and Esko (1989) J. Biol. Chem. 264, 8059-8065]. We compared the heparan sulphate proteoglycans synthesized by mutant and wild-type cells to determine what effect the undersulphation defect had on proteoglycan structure. The majority of heparan sulphate proteoglycans synthesized by pgsE-606 were undersulphated, but the mutant also synthesized a population of proteoglycans that were sulphated to the same extent as wild-type molecules. Anion-exchange analysis of the glycosaminoglycans in each proteoglycan population showed that they were all modified in the same way. The length of the glycosaminoglycans in each proteoglycan population were similar, suggesting that N-sulphation does not affect chain polymerization. To examine whether the sulphation state of the attached heparan sulphate glycosaminoglycans was dependent on the protein core, we purified syndecan-1 from mutant and wild-type cells using antibodies against the core protein. As with the unfractionated heparan sulphate proteoglycans, pgsE-606 synthesized both undersulphated and sulphated syndecan-1. Each pool contained either undersulphated or sulphated glycosaminoglycan chains respectively. Thus the modification of all heparan sulphate chains on a core protein occurs on a proteoglycan-wide basis (i.e. to the same extent).

Analysis of heparan-sulphate chains and oligosaccharides from proliferating and quiescent fibroblasts. A proposed model for endoheparanase activity

Human skin fibroblasts in different growth states were incubated with [3H]glucosamine and/or Na(2)35SO4 and extracted with Triton X-100 for various periods of time. Free heparan-sulphate oligosaccharides and protein-bound heparan-sulphate chains were separated by chromatography on octyl-Sepharose and analyzed. A pool of endogenously produced oligosaccharides, present in the cultured cells and isolated after brief extraction, contained fragments of uniform size (approximately 7-10 kDa corresponding to approximately 14-20 disaccharides). Analysis by heparinase I and heparinase III degradations followed by electrophoretic separation (oligosaccharide mapping) showed that the oligosaccharides were rich in glucuronic acid but had a few sulphated iduronic acid residues at the periphery of each molecule. These results indicated that endoheparanase cleavage points were located close to linkages between N-sulphated glucosamine and sulphated iduronic acid, generating fragments that comprise a major portion of the unmodified segments and a minor portion of the highly modified segments. Prolonged extraction (24-48 h) of cells with Triton X-100 at 4 degrees C in the presence of proteinase inhibitors resulted in further degradation. There was an increase in the amount of heparan-sulphate oligosaccharides and a concomitant decrease in the amount of protein-bound heparan-sulphate chains present in the same extract. The heparan-sulphate oligosaccharides obtained after prolonged extraction were more heterogeneous in size comprising, in addition to the major species of approximately 7-10 kDa, intermediate and larger fragments of approximately 17 kDa and 30-40 kDa. This observation suggests that endoheparanase acted at periodically appearing, specific regions in the intact heparan-sulphate chain. Furthermore, the enzyme and substrate should remain closely associated during cold Triton X-100 extraction. To determine if the endogenously produced heparan-sulphate oligosaccharides were derived from a particular heparan-sulphate species degraded during the growth phase, proteoglycan-derived heparan-sulphate chains obtained from proliferating or quiescent fibroblasts were also examined. These chains showed similar oligosaccharide maps, except for a small increase in the amount of glucuronic acid as cell growth was arrested. Hence, an endoheparanase with restricted specificity may generate slightly different oligosaccharides in the various growth states.

Modifications of proteoglycans produced by human skin fibroblast cultures during replicative senescence

The properties of proteoglycans (PGs) produced by normal human skin fibroblasts were investigated with increasing passage. The increase of subculture number was associated with a constant increase in PG molecular size, which was particularly evident in cell layer extracts. In the cell layer, the ratio of DS-PGs/HS-PGs was markedly higher in early passage cultures. Moreover, the cell layer from young cells contained lower amounts of radioactivity incorporated into the most hydrophobic PG populations, suggesting that the PG core protein might also undergo significant modification with increasing subcultures. There was no significant difference in energy charge value between early and late passage cultures, whereas the NAD/NADH ratio was found to decrease markedly in senescent cells.