The mechanism of initiation of chondroitin sulphate synthesis by beta-D-galactosides

Embryonic chicken cartilage was incubated in vitro with phenyl-beta-[6-3H]galactoside and cycloheximide. Free chondroitin sulphate chains initiated by galactoside were isolated and degraded to yield 3-O-beta-D-glucuronosyl D-galactose (GlcA-Gal) derived from the sequence, GlcA-Gal-Gal-Xyl-Ser, which links the polysaccharide to protein. This enabled the distribution of 3H into specific galactose residues within the linkage oligosaccharide to be determined. Most of the 3H label (65%) was released as free galactose although 35% was recovered as GlcA-Gal. Similar experiments performed with unlabelled phenyl-beta-galactoside and [14C]galactose yielded 14C-labelled GlcA-Gal as a major product. We conclude that beta-galactosides initiate chondroitin sulphate synthesis primarily by serving as substrates for galactosyl transferase II.     

The effect of D-xylose, beta-D-xylosides and beta-D-galactosides on chondroitin sulphate biosynthesis in embryonic chicken cartilage.

The incorporation of [3H]acetate into chondroitin sulphate was used as a measure of the rate of synthesis of this polysaccharide in whole tibias and femurs of embryonic chicken cartilage in vitro. The incorporation is inhibited by puromycin and by cycloheximide, but the inhibition is relieved by the addition of D-xylose, beta-D-xylosides and beta-D-galactosides to the incubation medium. Beta-D-Xylosides can stimulate the incorporation to 300% of that of controls incubated in the absence of cycloheximide or puromycin, D-Xylose, beta-D-xylosides and beta-D-galactosides appear to act as artificial initiators of chondroitin sulphate synthesis and enable polysaccharide-chain synthesis to be studied as an event separate from the synthesis of intact proteoglycan.     

Kurloff cell proteoglycans. Evidence for de novo synthesis of chondroitin sulphate proteoglycans by purified Kurloff cells

This paper reports the first direct demonstration of de novo synthesis of chondroitin sulphate proteoglycans by Kurloff cells. This was achieved using highly purified splenic Kurloff cells labelled in vitro with [35S]sulphate and D-[U-3H]glucosamine. A single population of sulphated proteoglycans was observed after dissociative extraction, DEAE-cellulose chromatography, Sepharose CL 6B chromatography and fluorography after electrophoresis. These were large, highly anionic proteoglycans and were completely digested by chondroitinase AC or ABC. Moreover, glycosaminoglycan extracted from Kurloff cells had the electrophoretic mobility of control chondroitin sulphate.     

The relation of protein synthesis to chondroitin sulphate biosynthesis in cultured bovine cartilage.

The effect of cycloheximide on chondroitin sulphate biosynthesis was studied in bovine articular cartilage maintained in culture. Addition of 0.4 mM-cycloheximide to the culture medium was followed, over the next 4h, by a first-order decrease in the rate of incorporation of [35S]sulphate into glycosaminoglycan (half-life, t 1/2 = 32 min), which is consistent with the depletion of a pool of proteoglycan core protein. Addition of 1.0 mM-benzyl beta-D-xyloside increased the rate of incorporation of [35S]sulphate and [3H]acetate into glycosaminoglycan, but this elevated rate was also diminished by cycloheximide. It was concluded that cycloheximide exerted two effects on the tissue; not only did it inhibit the synthesis of the core protein, but it also lowered the tissue's capacity for chondroitin sulphate chain synthesis. Similar results were obtained with chick chondrocytes grown in high-density cultures. Although the exact mechanism of this secondary effect of cycloheximide is not known, it was shown that there was no detectable change in cellular ATP concentration or in the amount of three glycosyltransferases (galactosyltransferase-I, N-acetylgalactosaminyltransferase and glucuronosyltransferase-II) involved in chondroitin sulphate chain synthesis. The sizes of the glycosaminoglycan chains formed in the presence of cycloheximide were larger than those formed in control cultures, whereas those synthesized in the presence of benzyl beta-D-xyloside were consistently smaller, irrespective of the presence of cycloheximide. These results suggest that beta-D-xylosides must be used with caution to study chondroitin sulphate biosynthesis as an event entirely independent of proteoglycan core-protein synthesis, and they also indicate a possible involvement of the core protein in the activation of the enzymes of chondroitin sulphate synthesis.     

The relation of RNA synthesis to chondroitin sulphate biosynthesis in cultured bovine cartilage.

Addition of actinomycin D (or cordycepin, an alternative inhibitor of RNA synthesis) to cartilage cultures resulted in a first-order decrease in the rate of incorporation of [35S]sulphate into proteoglycan (half-life = 7.5 +/- 1.1 h). Addition of 1.0 mM-benzyl beta-D-xyloside relieved the initial inhibition of glycosaminoglycan synthesis induced by actinomycin D; however, after a lag of about 10 h the rate of xyloside-initiated glycosaminoglycan synthesis also decreased with apparent first-order kinetics (half-life = 7.1 +/- 1.8 h), which paralleled the decrease in the rate of core-protein-initiated glycosaminoglycan synthesis. The hydrodynamic size of the proteoglycans formed in the presence of actinomycin D remained essentially constant (Kav. 0.21-0.23), whereas the constituent glycosaminoglycan chains were larger than those formed by control cultures, which suggested that the core protein was substituted with fewer but larger glycosaminoglycan chains. Proteoglycans formed in the presence of beta-D-xyloside were significantly smaller (Kav. approximately 0.33) than those synthesized by control cultures, and were further diminished in size after exposure of cultures to actinomycin D. Glycosaminoglycan chains synthesized by these same cultures on to both core-protein and xyloside acceptors were also smaller than those of control cultures. The decrease in synthesis observed after exposure to actinomycin D was not reflected by any significant decrease in the activities of several glycosyltransferases involved in chondroitin sulphate synthesis (galactosyltransferase-I, galactosyltransferase-II, N-acetylgalactosaminyltransferase and glucuronosyltransferase-II).     

Inhibition of hydroxyapatite formation in collagen gels by chondroitin sulphate.

Crystal growth in native collagen gels has been used to determine the role of extracellular matrix macromolecules in biological calcification phenomena. In this system, type I collagen gels containing sodium phosphate and buffered at pH 7.4 are overlayed with a solution containing CaCl2. Crystals form in the collagen gel adjacent to the gel-solution interface. Conditions were determined which permit the growth of crystals of hydroxyapatite [Ca10(PO4)6(OH)2]. At a Ca/P molar ratio of 2:1, the minimum concentrations of calcium and phosphate necessary for precipitation of hydroxyapatite are 10 mM and 5 mM, respectively. Under these conditions, precipitation is initiated at 18-24h, and is maximal between 24h and 6 days. Addition of high concentrations of chondroitin 4-sulphate inhibits the formation of hydroxyapatite in collagen gels; initiation of precipitation is delayed, and the final (equilibrium) amount of precipitation is decreased. Inhibition of hydroxyapatite formation requires concentrations of chondroitin sulphate higher than those required to inhibit calcium pyrophosphate crystal formation.     

Endocytosis and degradation of chondroitin sulphate by liver endothelial cells.

Intravenously administered chondroitin sulphate, chemically labelled by [3H]acetylation of partially deacetylated polysaccharide, was taken up and degraded by the non-parenchymal cells of the liver. Studies using primary monolayer cultures of pure Kupffer cells, liver endothelial cells and parenchymal cells revealed that [3H]chondroitin sulphate was taken up and degraded by the liver endothelial cells only. Binding studies at 4 degrees C with [3H]chondroitin sulphate and 125I-chondroitin sulphate proteoglycan indicated that the glycosaminoglycan and the proteoglycan are recognized by the same binding sites on the liver endothelial cells. The ability of hyaluronic acid to compete with the labelled ligands for binding suggested that the binding site is identical with the recently described hyaluronate receptor on the liver endothelial cells [Smedsrød, Pertoft, Eriksson, Fraser & Laurent (1984) Biochem. J. 223, 617-626]. Fluorescein-labelled chondroitin sulphate proteoglycan accumulated in perinuclear vesicles of the liver endothelial cells, indicating that the proteoglycan is internalized and transported to the lysosomes. The finding that [3H]chondroitin sulphate and 125I-chondroitin sulphate proteoglycan were degraded by the liver endothelial cells to low-molecular-mass radioactive products suggested that both the polysaccharide chain and the core protein were catabolized by the cells.     

Immunohistochemical staining for chondroitin sulphate and keratan sulphate. An evaluation of two monoclonal antibodies

Immunohistochemical staining with commercially available antibodies against chondroitin sulphate (clone CS-56) and keratan sulphate (clone 1/20/5-D-4) was compared with two conventional histochemical methods for the demonstration of glycosaminoglycans, namely Alcian Blue with varying pH and critical electrolyte concentrations, and a modified PAS stain. The antibodies were tested on sections from both frozen and fixed, paraffin embedded human material from umbilical cord, skin, and bronchus. The results showed immunostaining to function equally well on frozen and routine sections, and to be superior to Alcian Blue and PAS with regard to morphological detail. Thus, reactivity with anti-chondroitin sulphate was demonstrated in vessel walls, in small nerves, in the basal membrane zone of the skin, in perichondrium, and in and around chondrocytes. Reactivity with anti-keratan sulphate occurred in chondroid matrix and in perichondrial tissue; however, some cells of the bronchial epithelium and mucous glands also exhibited positivity.     

Immunohistochemical staining for chondroitin sulphate and keratan sulphate. An evaluation of two monoclonal antibodies

Summary Immunohistochemical staining with commercially available antibodies against chondroitin sulphate (clone CS-56) and keratan sulphate (clone 1/20/5-D-4) was compared with two conventional histochemical methods for the demonstration of glycosaminoglycans, namely Alcian Blue with varying pH and critical electrolyte concentrations, and a modified PAS stain. The antibodies were tested on sections from both frozen and fixed, paraffin embedded human material from umbilical cord, skin, and bronchus. The results showed immunostaining to function equally well on frozen and routine sections, and to be superior to Alcian Blue and PAS with regard to morphological detail. Thus, reactivity with anti-chondroitin sulphate was demonstrated in vessel walls, in small nerves, in the basal membrane zone of the skin, in perichondrium, and in and around chondrocytes. Reactivity with anti-keratan sulphate occurred in chondroid matrix and in perichondrial tissue; however, some cells of the bronchial epithelium and mucous glands also exhibited positivity.     

Inhibition of hyaluronan uptake in lymphatic tissue by chondroitin sulphate proteoglycan.

Stimulated neutrophils discharge large quantities of superoxide (O2.-), which dismutates to form H2O2. In combination with Cl-, H2O2 is converted into the potent oxidant hypochlorous acid (HOCl) by the haem enzyme myeloperoxidase. We have used an H2O2 electrode to monitor H2O2 uptake by myeloperoxidase, and have shown that in the presence of Cl- this accurately represents production of HOCl. Monochlorodimedon, which is routinely used to assay production of HOCl, inhibited H2O2 uptake by 95%. This result confirms that monochlorodimedon inhibits myeloperoxidase, and that the monochlorodimedon assay grossly underestimates the activity of myeloperoxidase. With 10 microM-H2O2 and 100 mM-Cl-, myeloperoxidase had a neutral pH optimum. Increasing the H2O2 concentration to 100 microM lowered the pH optimum to pH 6.5. Above the pH optimum there was a burst of H2O2 uptake that rapidly declined due to accumulation of Compound II. High concentrations of H2O2 inhibited myeloperoxidase and promoted the formation of Compound II. These effects of H2O2 were decreased at higher concentrations of Cl-. We propose that H2O2 competes with Cl- for Compound I and reduces it to Compound II, thereby inhibiting myeloperoxidase. Above pH 6.5, O2.- generated by xanthine oxidase and acetaldehyde prevented H2O2 from inhibiting myeloperoxidase, increasing the initial rate of H2O2 uptake. O2.- allowed myeloperoxidase to function optimally with 100 microM-H2O2 at pH 7.0. This occurred because, as previously demonstrated, O2.- prevents Compound II from accumulating by reducing it to ferric myeloperoxidase. In contrast, at pH 6.0, where Compound II did not accumulate, O2.- retarded the uptake of H2O2. We propose that by generating O2.- neutrophils prevent H2O2 and other one-electron donors from inhibiting myeloperoxidase, and ensure that this enzyme functions optimally at neutral pH.     

Physical properties of chondroitin sulphate/dermatan sulphate proteoglycans from bovine aorta.

Bovine aortic chondroitin sulphate/dermatan sulphate proteoglycans (PG-25, PG-35 and PG-50) were differentially precipitated with ethanol and analysed by a variety of chemical and physical techniques. The glycosaminoglycan chains of PG-25 and PG-35 contained a mixture of glucuronic acid and iduronic acid, whereas the uronic acid component of PG-50 was primarily glucuronic acid. In addition, various amounts of oligosaccharides containing small amounts of mannose, a galactose/hexosamine ratio of 1:1 and an absence of uronic acid were covalently linked to the core protein of all proteoglycans. The weight-average Mr (Mw) values of the proteoglycans determined by light-scattering in 4 M-guanidinium chloride were 1.3 X 10(6) (PG-25), 0.30 X 10(6) (PG-35) and 0.88 X 10(6) (PG-50). The s0 values of the proteoglycans were distributed between 7 and 8 S, and the reduced viscosities, eta sp./c, of all proteoglycans were dependent on the shear rate and polymer concentration. Electron microscopy of spread molecules revealed that PG-25 contained small structural units that appeared to self-associate into large aggregates, whereas PG-35 and PG-50 appeared mainly as monomers consisting of a core with various numbers of side projections. Hyaluronic acid-proteoglycan complexes occurred only with a small proportion of the molecules present in PG-35, and their formation could be inhibited by oligosaccharides. These results suggest the presence in the aorta of subspecies of chondroitin sulphate and dermatan sulphate proteoglycans, which show large variations in their physicochemical and inter- and intra-molecular association properties.     

The distribution of sulphate residues in the chondroitin sulphate chain

1. Electrophoresis of chondroitin sulphate, before and after partial degradation with testicular hyaluronidase, revealed charge heterogeneity of the degraded but not of the intact polymer. 2. Hyaluronidase-treated chondroitin sulphate was fractionated by gel chromatography. Two subfractions which were essentially monodisperse with regard to molecular weight (values of 8600 and 4800, respectively) were separated further by chromatography on Dowex 1. The resulting subfractions differed considerably with respect to their sulphate/disaccharide molar ratios. 3. Amino acid and neutral-sugar analyses of the Dowex 1 subfractions showed that the less sulphated fragments contained the carbohydrate-protein linkage region, whereas the high-sulphated fragments essentially lacked this constituent. It was concluded that chondroitin sulphate contains relatively less sulphate in the vicinity of the carbohydrate-protein linkage region than in the more peripheral portion of the polysaccharide chain.     

Biosynthesis of chondroitin sulfate: interaction between xylosyltransferase and galactosyltransferase

An affinity matrix consisting of the core protein of cartilage proteoglycan coupled to Sepharose was used to study the interaction between the glycosyltransferases which catalyze the first two reactions in the biosynthesis of chondroitin sulfate. Xylosyltransferase, for which the core protein is a substrate, is quantitatively adsorbed to the matrix. In contrast, UDP-galactose:xylose galactosyltransferase is not significantly adsorbed, but does bind to matrix which has been previously equilibrated with xylosyltransferase. By virtue of this enzyme-enzyme interaction, a 7-fold purification of galactosyltransferase can be obtained.     

Sequential synthesis of chondroitin oligosaccharides by immobilized chondroitin polymerase mutants

Escherichia coli strain K4 expresses a chondroitin (CH)-polymerizing enzyme (K4CP) that contains two glycosyltransferase active domains. K4CP alternately transfers glucuronic acid (GlcA) and N-acetyl-galactosamine (GalNAc) residues using UDP-GlcA and UDP-GalNAc donors to the nonreducing end of a CH chain acceptor. Here we generated two K4CP point mutants substituted at the UDP-sugar binding motif (DXD) in the glycosyltransferase active domains, which showed either glycosyltransferase activity of the intact domain and retained comparable activity after immobilization onto agarose beads. The mutant enzyme-immobilized beads exhibited an addition of GlcA or GalNAc to GalNAc or GlcA residue at the nonreducing end of CH oligosaccharides and sequentially elongated pyridylamine-conjugated CH (PA-CH) chain by the alternate use. The sequential elongation up to 16-mer was successfully achieved as assessed by fluorescent detection on a gel filtration chromatography and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) and MALDI potential lift tandem TOF mass spectrometry (MALDI-LIFT-TOF/TOF MS/MS) analyses in the negative reflection mode. This method provides exactly defined CH oligosaccharide derivatives, which are useful for studies on glycosaminoglycan functions.