Inhibition of branching morphogenesis and alteration of glycosaminoglycan biosynthesis in salivary glands treated with β-d-xyloside

The role of glycosaminoglycans (GAGs) in the branching morphogenesis of embryonic mouse salivary glands was investigated by culturing the glands in the presence of xylose derivatives which stimulate synthesis of the xyloselinked classes of GAGs. Branching morphogenesis is inhibited severely, but reversibly, by 0.5–1.0 mM π-nitrophenyl-β-d-xylopyranoside and the inhibition correlates with a stimulation of incorporation of [³H]glucosamine (1.8-fold) and [³⁵S]sulfate (almost 3-fold) into GAGs. The effect of β-xyloside on accumulation of newly synthesized GAG also occurs in the presence of the protein synthesis inhibitor cycloheximide, suggesting that the production of free GAG chains rather than proteoglycan-associated GAGs is being stimulated. The xyloside effects apparently do not result from general cytotoxicity of the derivatives, since similar concentrations of the α-anomer do not alter salivary branching or GAG synthesis, the rudiments resume morphogenesis when returned to control medium, and the effect on GAG synthesis is stimulatory rather than inhibitory. The study suggests that GAG biosynthesis plays an important role in salivary development, and that xylosides provide useful probes for characterizing the molecular events controlling branching morphogenesis.     

Exogenous addition of a C-xylopyranoside derivative stimulates keratinocyte dermatan sulfate synthesis and promotes migration

As C-Xyloside has been suggested to be an initiator of glycosaminoglycan (GAG) synthesis, and GAGs such as Dermatan sulfate (DS) are potent enhancers of fibroblast growth factor (FGF)--10 action, we investigated if a C-Xylopyranoside derivative, (C-β-D-xylopyranoside-2-hydroxy-propane, C-Xyloside), could promote DS production by cultured normal human keratinocytes, how this occurs and if C-Xyloside could also stimulate FGF-dependent cell migration and proliferation. C-Xyloside-treated keratinocytes greatly increased secretion of total sulfated GAGs. Majority of the induced GAG was chondroitin sulfate/dermatan sulfate (CS/DS) of which the major secreted GAG was DS. Cells lacking xylosyltransferase enzymatic activity demonstrated that C-Xyloside was able to stimulate GAG synthesis without addition to core proteins. Consistent with the observed increase in DS, keratinocytes treated with C-Xyloside showed enhanced migration in response to FGF-10 and secreted into their culture media GAGs that promoted FGF-10-dependent cellular proliferation. These results indicate that C-Xyloside may enhance epithelial repair by serving as an initiator of DS synthesis.     

Turnover of sulfated glycosaminoglycans in fibroblasts derived from patients with Werner''s syndrome

Fibroblasts derived from patients with Werner's syndrome (WS) were incubated with radioactive sulfate to study the incorporation of 35S into glycosaminoglycans (GAGs). The accumulation of cell-associated 35S radioactivity in the GAGs of WS fibroblasts was consistently higher than parallel accumulation in normal human fibroblasts, but was substantially less than in fibroblasts derived from patients with Hurler's syndrome (HS). However, when fibroblasts were labeled with 35SO4(2-), trypsinized to remove extracellular and pericellular radioactive GAGs, replated, and chased to follow the fate of the intracellular radioactivity, both WS and normal cells showed a rapid release of the intracellular 35S, while HS cells showed little or no loss of intracellular radioactivity. The radioactivity released from WS and normal cells was of low molecular weight (LMW), eluting from gel filtration columns at the same position as free sulfate. These results establish that WS cells degrade intracellular sulfated GAGs and argue against the hypothesis that a defect in GAG degradation pathways is the basis for the increased level of cell-associated GAGs. Other possible explanations for the increased cell-associated [35S]GAGs in WS cells as compared with normal cells were also considered: increased GAG sulfation; an increase in GAG chain length; an increased rate of GAG synthesis; and a decreased rate of shedding of cell surface proteoglycan into the medium. No difference between normal and WS fibroblasts in any of the above parameters was observed. These results strongly imply that the primary biochemical defect in WS fibroblasts does not involve sulfated GAG metabolism.     

A novel use of TAT-EGFP to validate techniques to alter osteosarcoma cell surface glycosaminoglycan expression

Several methods to alter cell surface glycosaminoglycan (GAG) expression have previously been described, including treatments with chlorate to reduce the addition of charged sulfate groups, xyloside compounds to displace GAGs from their core proteins, and GAG lyases, such as heparinase and chondroitinase, to release GAG fragments from the cell layer. While these methods are useful in identifying cellular mechanisms which are dependent on GAGs, they must be stringently validated to assess results in the appropriate context. To determine the most useful technique for the evaluation of GAG function in osteogenesis, MG-63 osteosarcoma cells were systematically treated with these agents and evaluated for changes in cell surface GAGs using a TAT-EGFP fusion protein. TAT, a protein transduction domain from the HIV-1 virus, requires cell surface GAGs to traverse cell membranes. The EGFP component provides a method to assess protein entry into cells in both qualitative and quantitative tests. Here, TAT-EGFP transduction analysis confirmed radiochemical and physiological data that chlorate effectively disrupts GAG expression. TAT-EGFP entry into cells was also inhibited by the exogenous application of commercial heparin and GAGs extracted from MG-63 cells as well as by the pre-treatment of cells with chondroitinase ABC. However, neither heparinase III treatment nor the addition of exogenous chondroitin-6-sulfate affected TAT-EGFP entry into cells. In addition, xyloside-β-D-naphthol and xyloside-β-D-cis/trans-decahydro-2-naphthol treatment could not induce significant phenotypic change in these cells, and the unaffected TAT-EGFP transduction confirmed that this was due to an inability to efficiently prime GAG synthesis. The use of TAT-EGFP is thus a useful technique to specifically evaluate cell surface GAG expression in a simple, quantifiable manner, and avoids the complications involved with conventional radiochemical assays or analytical chromatography.     

Hypoxia modifies the effect of PDGF on glycosaminoglycan synthesis by primary human lung cells

Hypoxia, a consequence of interstitial lung diseases, may lead to secondary pulmonary hypertension and pulmonary vascular remodeling. Hypoxia induces activation and proliferation of lung cells and enhances the deposition of extracellular matrix including glycosaminoglycans (GAGs). To elucidate the cell biological mechanisms underlying the development of secondary pulmonary hypertension, we studied the effect of hypoxia on GAG synthesis by human lung cells. GAG synthesis was measured by incorporation of [(3)H]glucosamine; GAGs were isolated, purified, and characterized with GAG-degrading enzymes. Fibroblasts and vascular smooth muscle cells (VSMCs) synthesized hyaluronic acid, heparan sulfate, and chondroitin sulfates, whereas dermatan sulfate was found only in fibroblasts. Hypoxia did not influence the size or charge of the individual GAGs. However, hypoxia inhibited platelet-derived growth factor-induced [(3)H]glucosamine incorporation in secreted GAGs, especially hyaluronic acid, in VSMCs. In contrast, it stimulated GAG secretion, specifically heparan sulfate, by fibroblasts. Our results indicate that hypoxia induces modifications in GAG synthesis by human lung VSMCs and fibroblasts that may be correlated to pathophysiological manifestations in lung diseases causing hypoxia.     

Comamonas testosteronan synthase, a bifunctional glycosyltransferase that produces a unique heparosan polysaccharide analog

Glycosaminoglycans (GAGs) are linear hexosamine-containing polysaccharides. These polysaccharides are synthesized by some pathogenic bacteria to form an extracellular coating or capsule. This strategy forms the basis of molecular camouflage since vertebrates possess naturally occurring GAGs that are essential for life. A recent sequence database search identified a putative protein from the opportunistic pathogen Comamonas testosteroni that exhibits similarity with the Pasteurella multocida GAG synthase PmHS1, which is responsible for the synthesis of a heparosan polysaccharide capsule. Initial supportive evidence included glucuronic acid (GlcUA)-containing polysaccharides extracted from C. testosteroni KF-1. We describe here the cloning and analysis of a novel Comamonas GAG synthase, CtTS. The GAG produced by CtTS in vitro consists of the sugars d-GlcUA and N-acetyl-D-glucosamine, but is insensitive to digestion by GAG digesting enzymes, thus has distinct glycosidic linkages from vertebrate GAGs. The backbone structure of the polysaccharide product [-4-D-GlcUA-α1,4-D-GlcNAc-α1-](n) was confirmed by nuclear magnetic resonance. Therefore, this novel GAG, testosteronan, consists of the same sugars as the biomedically relevant GAGs heparosan (N-acetyl-heparosan) and hyaluronan but may have distinct properties useful for future medical applications.     

Implementation of infrared and Raman modalities for glycosaminoglycan characterization in complex systems

Glycosaminoglycans (GAGs) are natural, linear and negatively charged heteropolysaccharides which are incident in every mammalian tissue. They consist of repeating disaccharide units, which are composed of either sulfated or non-sulfated monosaccharides. Depending on tissue types, GAGs exhibit structural heterogeneity such as the position and degree of sulfation or within their disaccharide units composition being heparin, heparan sulfate, chondroitine sulfate, dermatan sulfate, keratan sulfate, and hyaluronic acid. They are covalently linked to a core protein (proteoglycans) or as free chains (hyaluronan). GAGs affect cell properties and functions either by direct interaction with cell receptors or by sequestration of growth factors. These evidences of divert biological roles of GAGs make their characterization at cell and tissue levels of importance. Thus, non-invasive techniques are interesting to investigate, to qualitatively and quantitatively characterize GAGs in vitro in order to use them as diagnostic biomarkers and/or as therapeutic targets in several human diseases including cancer. Infrared and Raman microspectroscopies and imaging are sensitive enough to differentiate and classify GAG types and subtypes in spite of their close molecular structures. Spectroscopic markers characteristic of reference GAG molecules were identified. Beyond these investigations of the standard GAG spectral signature, infrared and Raman spectral signatures of GAG were searched in complex biological systems like cells. The aim of the present review is to describe the implementation of these complementary vibrational spectroscopy techniques, and to discuss their potentials, advantages and disadvantages for GAG analysis. In addition, this review presents new data as we show for the first time GAG infrared and Raman spectral signatures from conditioned media and live cells, respectively.     

Temporal and spatial differences in glycosaminoglycan synthesis by fetal lung fibroblasts

In studies of the ontogeny of fibroblast-epithelial interactions during late fetal lung rat lung development, we have identified two subpopulations of fibroblasts which differed in their ability to promote epithelial cell proliferation or differentiation. As glycosaminoglycans (GAGs) have been implicated in the regulation of these processes we have tested whether the two fibroblast populations synthesize different GAGs and whether the GAG pattern changes with development. Fibroblasts incorporate more [3H]glucosamine and Na2 35SO4 into GAGs than epithelial cells. Both cell types deposited a significant amount of newly synthesized GAGs in the cell-matrix layer. GAGs were lost faster from the cell-matrix layer of fibroblasts (t1/2 = 12 h) than from that of epithelial cells (t1/2 = 48 h). Total GAG synthesis by fibroblasts did not change with advancing gestation, but synthesis of sulfated GAGs by epithelial cells declined with advancing gestation. Independent of gestational age epithelial cells synthesized predominantly heparan sulfate. Depending on their proximity to the epithelium, fibroblasts differed in their production of GAGs. Fibroblasts in close proximity to the epithelium mainly produced and secreted hyaluronan. More distant fibroblasts, from the pseudoglandular stage of lung development synthesized primarily heparan sulfate and chondroitin sulfate. This same population of fibroblasts from the canalicular stage of lung development, produced more hyaluronan. As the shift to hyaluronan occurs with the thinning of the alveolar septal wall, this finding suggests that developmentally regulated GAG production by fibroblasts may facilitate epithelial-fibroblast interaction, thus influencing fetal lung growth and differentiation.     

Stimulation of sulfated glycosaminoglycan synthesis by the tripeptide-copper complex glycyl-L-histidyl-L-lysine-Cu2+.

Glycyl-L-histidyl-L-lysine-copper (II) complex (GHK-Cu) is a naturally occurring tripeptide with potential healing properties. We studied the effect of GHK-Cu on the synthesis of glycosaminoglycans (GAGs) by normal human fibroblasts in culture. Cells were incubated with 3H glucosamine and 35S sulfate and the radioactivity of isolated GAGs was determined. GHK-Cu induced a dose-dependent increase of the synthesis of total GAGs secreted into the culture medium and those associated with the cell layer. The effect of GHK-Cu was biphasic with a maximal stimulation at 10(-9) to 10(-8) M. At higher concentrations, the rate of synthesis returned progressively to that of control cultures. Electrophoretic analysis of the different GAG populations showed that GHK-Cu preferentially stimulated the synthesis of extracellular dermatan sulfate and cell layer associated heparan sulfate. No influence of GHK-Cu on the synthesis of hyaluronic acid was observed. GHK-Cu stimulation of GAG synthesis may be one of the phenomenons implicated in the wound healing properties of the peptide.     

Differential binding of platelet-derived growth factor isoforms to glycosaminoglycans

The platelet-derived growth factor (PDGF) family comprises disulfide-bonded dimeric isoforms and plays a key role in the proliferation and migration of mesenchymal cells. Traditionally, it consists of homo- and heterodimers of A and B polypeptide chains that occur as long (A_L and B_L) or short (A_S and B_S) isoforms. Short isoforms lack the basic C-terminal extension that mediates binding to heparin. In the present study, we show that certain PDGF isoforms bind in a specific manner to glycosaminoglycans (GAGs). Experiments performed with wild-type and mutant Chinese hamster ovary cells deficient in the synthesis of GAGs revealed that PDGF long isoforms bind to heparan sulfate and chondroitin sulfate, while PDGF short isoforms only bind to heparan sulfate. This was confirmed by digestion of cell surface GAGs with heparitinase and chondroitinase ABC and by incubation with sodium chloride to prevent GAG sulfation. Furthermore, exogenous GAGs inhibited the binding of long isoforms to the cell membrane more efficiently than that of short isoforms. Additionally, we performed surface plasmon resonance experiments to study the inhibition of PDGF isoforms binding to low molecular weight heparin by GAGs. These experiments showed that PDGF-AA_L and PDGF-BB_S isoforms bound to GAGs with the highest affinity. In conclusion, PDGF activity at the cell surface may depend on the expression of various cellular GAG species.     

Abrogation of apoptosis through PDGF-BB-induced sulfated glycosaminoglycan synthesis and secretion

Platelet-derived growth factor (PDGF)-BB-stimulated glycosaminoglycan (GAG) synthesis/secretion in fetal lung fibroblasts is dependent on sequential activation of the PDGF beta-receptor, phosphatidylinositol 3-kinase (PI3K), the serine/threonine kinase Akt-1,2, and the GTPase Rab3D. Because the Akt pathway has been implicated in cell survival mechanisms, we investigated whether the pathway regulating GAG synthesis/secretion was antiapoptotic. PDGF-BB treatment protected fetal lung fibroblasts against serum starvation-induced apoptosis, whereas wortmannin, an inhibitor of PI3K, abrogated this protective effect. Transfection of constitutively active Akt into fetal lung fibroblasts also safeguarded the cells from apoptosis induced by serum starvation. To determine whether the antiapoptotic response was due, at least in part, to GAGs, we treated lung fibroblasts with beta-D-xyloside as well as with topically applied GAGs, specifically those produced by fetal lung fibroblasts. beta-D-xyloside increased GAG synthesis/secretion and diminished apoptosis. Application of sulfated GAGs, chondroitin sulfate, and heparan sulfate, but not nonsulfated hyaluronan, also resulted in diminished apoptosis. Moreover, topically applied sulfated GAGs increased Bcl-associated death promoter phosphorylation and diminished caspase-3 and -7 cleavage, indicating an antiapototic response. These data are compatible with the PDGF-BB-GAG signaling pathway regulating programmed fibroblast death in the fetal lung.     

Biosynthesis of proteoglycans by proliferating and differentiating normal human keratinocytes cultured in serum-free medium

Normal human keratinocytes (NHK) were cultured in serum-free medium, containing low (0.1 mM) or high (2 mM) calcium, to obtain proliferating and differentiating cultures, respectively. Proteoglycan (PG) synthesis of proliferating and differentiating NHK was investigated. Cultures were labeled with 35S-sulfate, and the PGs were extracted from medium and cell layer. The newly synthesized PGs were isolated by ion-exchange chromatography on a column of DEAE-Sephacel. The molecular properties of the PGs and the size and composition of glycosaminoglycans (GAGs) were determined. In general, the PGs are relatively small size (Mr 70,000-120,000). The PGs of proliferating cultures are larger in molecular size than the PGs of differentiating cultures, and this is due to the degradation of the GAG chains. The molecular weight of the GAG chains of proliferating NHK ranged from 4,800 to 22,000, and the range for GAGs from differentiating cultures varied from 2,800 to 9,600. By compositional analysis, these PGs proved to contain heparan sulfate, chondroitin sulfate, and dermatan sulfate as determined by nitrous acid degradation, and chondroitinase ACII and ABC digestion. No significant differences were found in the overall GAG composition of the medium secreted PGs of proliferating and differentiating cultures. In contrast, cell-associated PGs of differentiating cells had higher levels of heparan sulfate than those of proliferating cells.     

Effects of thyroid-stimulating hormone and phorbol ester on glycosaminoglycan synthesis in porcine thyroid epithelial cells in primary culture

The effects of thyroid-stimulating hormone (TSH) and a tumor promoter: 12-0-tetradecanoyl-phorbol-13-acetate on glycosaminoglycan (GAG) synthesis were studied in porcine thyroid epithelial cells in primary culture. TSH is known to involve cyclic AMP mechanism and phorbol ester to act by protein kinase C pathway. Chronic treatment of cells with TSH increased the synthesis of heparan sulphate associated with the cell layer and hyaluronic acid in the culture medium. Phorbol ester increased the radioactivity of total GAGs in the culture medium but had no effect on GAGs associated with the cell layer. It inhibited the positive effect of TSH on heparan sulphate synthesis. These results suggest that in thyroid epithelial cells the synthesis of the GAGs associated with the cell layer and those secreted into the culture medium are regulated by different intracellular mechanisms.     

Glycosaminoglycan polysaccharide biosynthesis and production: today and tomorrow

Glycosaminoglycans [GAGs] are essential heteropolysaccharides in vertebrate tissues that are also, in certain cases, employed as virulence factors by microbes. Hyaluronan [HA], heparin, and chondroitin sulfate [CS] are GAGs currently used in various medical applications and together are multi-billion dollar products thus targets for production by animal-free manufacture. By using bacteria as the source of GAGs, the pathogen’s sword may be converted into a plowshare to help avoid potential liabilities springing from the use of animal-derived GAGs including adventitious agents (e.g., prions, pathogens), antigenicity, degradation of the environment, and depletion of endangered species. HA from microbes, which have a chemical structure identical to human HA, has already been commercialized and sold at the ton-scale. Substantial progress towards microbial heparin and CS has been made, but these vertebrate polymers are more complicated structurally than the unsulfated bacterial polysaccharide precursors thus require additional processing steps. This review provides an overview of GAG structure, medical applications, microbial biosynthesis, and the state of bacterial GAG production systems. Representatives of all glycosyltransferase enzymes that polymerize the sugar chains of the three main GAGs have been identified and serve as the core technology to harness, but the proteins involved in sugar precursor formation and chain export steps of biosynthesis are also essential to the GAG production process. In addition, this review discusses future directions and potential important issues. Overall, this area is poised to make great headway to produce safer (both increased purity and more secure supply chains) non-animal GAG-based therapeutics.     

Hyaluronic acid synthesis is absent in normal human endothelial cells irrespective of hyaluronic acid synthetase inhibitor activity, but is significantly high in transformed cells

The characteristics of glycosaminoglycan (GAG) synthesis in normal and transformed human endothelial cells were analyzed by the incorporation of [3H]glucosamine and by the activities of GAG synthetases. The GAG synthesized by normal endothelial cells consisted of mainly heparan sulfate (HS) and chondroitin sulfate/dermatan sulfate but little hyaluronic acid (HA) (less than 1%). The characteristics of GAG synthesis by normal cells reflected the synthetic enzyme activities for each individual GAG: the activity of HA synthetase was very low. In spite of this, the activity of HA synthetase inhibitor, induced in growth-retarded fibroblasts with low HA synthetase activity (Matuoka et al. (1987 J. Cell Biol., 104, 1105-1115), was very low in endothelial cells. In contrast to normal cells, transformed endothelial (ECV304) cells synthesized mainly HA (62% of total GAGs). These findings suggest that the regulatory system of GAG metabolism is cell type specific, and that transformation is accompanied by high levels of HA synthesis in endothelial cells.     

Mechanism of C. trachomatis attachment to eukaryotic host cells.

A novel trimolecular mechanism of microbial attachment to mammalian host cells was characterized for the obligate intracellular pathogen Chlamydia trachomatis. Using purified glycosaminoglycans (GAGs) and specific GAG lyases, we demonstrated that a heparan sulfate-like GAG present on the surface of chlamydia organisms is required for attachment to host cells. These observations were supported by inhibition of attachment following binding of heparan sulfate receptor analogs to chlamydiae and by demonstrating that chlamydiae synthesize a unique heparan sulfate-like GAG. Furthermore, exogenous heparan sulfate, as an adhesin analog, restored attachment and infectivity to organisms that had lost these attributes following treatment with heparan sulfate lyase. These data suggest that a GAG adhesin ligand mediates attachment by bridging mutual GAG receptors on the host cell surface and on the chlamydial outer membrane surface.     

Flow cytometric measurements and electron microscopy of cell surface glycosaminoglycans using Acridine Orange

Summary Cell surface glycosaminoglycans (GAGs) were measured, after various treatments, by their binding to Acridine Organge using flow cytometry. Using a critical electrolyte concentration and combining it with specific degradation of individual GAG elements, it was found possible to differentiate between GAG components. The technique was adapted for electron microscopy level to reveal characteristics of membrane-associated GAG. By this means, the cell membrane of the human leukaemic cell line K562 was shown to contain a large amount of GAG; 75% of it was highly sulphated GAG, mostly heparan sulphate. This component was evenly distributed in the outer plasma membrane layer. In the presence of other GAGs, the appearance of complex proteoglycan granules was detected.     

In Vitro Synthesis of Proteoglycans and Collagen in Primary Cultures of Mantle Cells from the Nacreous Mollusk, Haliotis tuberculata: A New Model for Study of Molluscan Extracellular Matrix

: In Mollusca, the mantle produces an organic matrix that mineralizes in time to make shell. Primary mantle cell cultures from the nacreous gastropod Haliotis tuberculata have been established as useful experimental model to investigate in vitro synthesis of both proteoglycans/glycosaminoglycans (PGs/GAGs) and collagen. First, we tested different enzymatic digestion procedures to find the method that gives the highest percentage of viable and adherent cultured cells. Enzymatic digestion with 0.1% pronase plus 0.1% collagenase was routinely used. Six days after the initiation of culture, about 80% of cells were viable, among which 20% were adherent as quantified by the MTT reduction assay. In addition, the protein synthesis estimated by [³H]leucine incorporation remained constant during this period. For the first time, we demonstrated a de novo synthesis of PGs/GAGs and collagen in primary cultures of mantle cells. After 48 hours of labeling, among the [³H]-d-glucosamine macromolecules synthesized, [³H]PGs/GAGs represented 43%, divided into 45% heparan sulfate, 37% chondroitin/dermatan sulfate, and 6% hyaluronic acid. Early elution on anion-exchange chromatography of these PGs/GAGs indicated that most of them appeared as undersulfated GAG molecules. De novo synthesis of collagen represents 4.52% - 0.84% (SD) with respect to the total protein synthesis. Such a model will facilitate studies on the synthesis of PGs/GAGs and collagen as components of the extracellular matrix and its regulation in Mollusca. Both PGs/GAGs and collagen participate in molecular events that regulate cell adhesion, migration, and proliferation. Further studies with this type of in vitro model should provide knowledge about novel aspects of molluscan cell signaling, in relation to extracellular matrix components.