Regulatory aspects of glycosaminoglycan biosynthesis

The control of glycosaminoglycan biosynthesis was investigated by studying the kinetic and regulatory properties of some enzymes involved in the formation of UDP-sugar precursors: UDP-N-acetylglucosamine 4'-epimerase, catalyzing the interconversion of hexosamine precursors and UDP-glucose dehydrogenase and UDP-glucose 4'-epimerase, utilizing UDP-glucose for the formation of uronic acid and galactose precursors. The study was carried out in tissues with different glycosaminoglycan production: bovine cornea, producing both chondroitin sulfate and keratan sulfate, and newborn-pig epiphysial-plate cartilage, producing mostly chondroitin sulfate. The biosynthesis of hexosamine precursors appeared to be regulated by the value of the NAD/NADH ratio. This control mechanism regulated also the activities of both UDP-glucose dehydrogenase and UDP-glucose 4'-epimerase and, therefore, it could correlate the biosynthesis of glycosaminoglycan precursors with the redox activity of the cell. At the level of UDP-glucose utilization two other control mechanisms were demonstrated: the different affinities of UDP-glucose dehydrogenase and UDP-glucose 4'-epimerase for UDP-glucose in tissues with different glycosaminoglycan production and the cellular concentration of UDP-xylose. This sugar-nucleotide inhibited UDP-glucose dehydrogenase, but did not affect the UDP-glucose 4'-epimerase activity; therefore, and increase of its cellular concentration may result in a decreased chondroitin sulfate synthesis and in an increased keratan sulfate formation.     

Effect of oxygen tension and lactate concentration on keratan sulphate and chondroitin sulphate biosynthesis in bovine cornea.

Calf cornea slices were incubated with [U-14C]glucose, in varying pO2 or lactate concentrations. Acid glycosaminoglycans were separated by ion-exchange chromatography after papain digestion. The percentage radioactivity incorporated into keratan sulphate increased markedly with decreased oxygen tension, whereas a concomitant relative decrease of the biosynthesis of glycosaminoglycuronans occurred. Similar results were obtained with increased lactate concentration. Our findings support the idea that keratan sulphate is a functional substitute for chondroitin sulphate in conditions of oxygen lack (Scott, J.E. and Haigh, M. (1988) J. Anat. 158, 95-108).     

The effect of benzyl beta-D-xyloside on keratan sulphate synthesis in ox articular cartilage

Cartilage from adult bovine hock joints was incubated with [3H]galactose or [35S]sulphate in the presence of benzyl beta-D-xyloside. Radioisotope incorporation into proteoglycan was inhibited by the xyloside; the magnitude of this inhibition depended on the concentration of xyloside used. With 0.2mM xyloside radioisotope incorporation into keratan sulphate was not altered but inhibition was observed at xyloside concentrations of 1.0mM or higher. The decrease in radioisotope incorporation into keratan sulphate in the presence of 1.0mM benzyl beta-xyloside was directly related to a reduction in the average length of the keratan sulphate chains. This effect of beta-xyloside on keratan sulphate biosynthesis was markedly different from its effect on chondroitin sulphate biosynthesis.     

The biosynthesis in vitro of keratan sulphate in bovine cornea

1. Bovine corneas were incubated in vitro with [U-(14)C]glucose. 2. The glycosaminoglycans of corneal stroma were isolated and fractionated on cetylpyridinium chloride-cellulose columns. The major components were keratan sulphate (71%), chondroitin 4-sulphate (17%) and chondroitin 6-sulphate (4%). 3. The acid-soluble nucleotides and intermediates of glycosaminoglycan biosynthesis of corneal stroma were separated on Dowex 1 (formate form) and the tissue content and cellular concentrations were determined. 4. The rates of synthesis of the intermediates of glycosaminoglycan biosynthesis in corneal stroma were determined. 5. The incorporation of radioactivity from [U-(14)C]glucose into the uronic acid and hexosamine components of the glycosaminoglycans present in corneal stroma were measured and the turnover rates of these polymers were calculated. It was found that keratan sulphate was turning over in about 723h and chondroitin 6-sulphate in 251h.     

Studies on the in vitro incubation procedure for [35]sulphate labelling of articular cartilage glycosaminoglycans

Articular cartilage from cow and calf femoral condyles was incubated in Tyrodes solution containing [³⁵S]sulphate for different periods up to 80 min. Glycosaminoglycans from the cartilage tissue and incubation medium were fractionated on Cetylpyridinium chloride and ECTEOLA cellulose microcolumns.The incorporation of [³⁵S]sulphate into all individual fractions of chondroitin sulphate and keratan sulphate was found to be linear from 20 to 80 min incubation time. As a rule the total specific activities of keratan sulphate and chondroitin sulphate were similar for both calves and cows.The proteoglycan material recovered from the medium amounted to about 1% of the tissue dry weight and was found to have a higher chondroitin sulphate: keratan sulphate ratio than the corresponding cartilage tissue for both calf and cow.The solubility profiles for the newly synthesised glycosaminoglycans, obtained from determination of the radioactivity in the individual fractions, were compared with those of glycosaminoglycans already present. These curves indicated that newly synthesised chondroitin sulphate had a higher average molecular size than that present in the tissue whereas the newly synthesised keratan sulphate had a smaller average molecular size. These newly synthesised components were also detected in the proteoglycans recovered from the incubation medium.     

Studies on the in vitro incubation procedure for [35S]sulphate labelling of articular cartilage glycosaminoglycans

Articular cartilage from cow and calf femoral condyles was incubated in Tyrodes solution containing [35S]sulphate for different periods up to 80 min. Glycosaminoglycans from the cartilage tissue and incubation medium were fractionated on Cetylpyridinium chloride and ECTEOLA cellulose microcolumns. The incorporation of [35S]sulphate into all individual fractions of chondroitin sulphate and keratan sulphate was found to be linear from 20 to 80 min incubation time. As a rule the total specific activities of keratan sulphate and chondroitin sulphate were similar for both calves and cows. The proteoglycan material recovered from the medium amounted to about 1% of the tissue dry weight and was found to have a higher chondroitin sulphate: keratan sulphate ratio than the corresponding cartilage tissue for both calf and cow. The solubility profiles for the newly synthesised glycosaminoglycans, obtained from determination of the radioactivity in the individual fractions, were compared with those of glycosaminoglycans already present. These curves indicated that newly synthesised chondroitin sulphate had a higher average molecular size than that present in the tissue whereas the newly synthesised keratan sulphate had a smaller average molecular size. These newly synthesised components were also detected in the proteoglycans recovered from the incubation medium.     

The structure of keratan sulphates from various sources.

Quantitative structural comparisons were made between keratan sulphates isolated from various sources, namely pig nucleus pulposus, bovine cornea, and the costal cartilages of children, a young adult with Marfan syndrome and of old human autopsies. In human costal cartilage the amount of keratan sulphate increases markedly with age, although total mucopolysaccharide decreases to some extent, concomitant with a decrease in chondroitin 4-sulphate and an increase in chondroitin 6-sulphate. Comparison of molecular weights estimated by gel chromatography with those calculated from the molar ratio of galactose to mannose indicates that keratan sulphates of human costal cartilages of children and of a young adult with Marfan syndrome, and of pig nucleus pulposus, contain one mannose residue per chain, whereas keratan sulphates of old human costal cartilage and of bovine cornea contain one to two, and two, per chain respectively. After mild acid-catalysed desulphation of pig nucleus pulposus keratan sulphate, approx. 12% of the mucopolysaccharide aggregates irreversibly once the water is removed from the polysaccharide. The following conclusions have been drawn from a methylation analysis of keratan sulphates of various sources, aided by g.l.c.-mass spectrometry. (1) Fucose and N-acetylneuraminic acid are non-reducing terminal residues and the sialic acid is linked to the 3-position of galactose residues. (2) Pig nucleus pulposus keratan sulphate has approximately 4 non-reducing terminal groups per molecule and appears to be slightly less branched than the costal-cartilage keratan sulphate of children. The branching in human costal-cartilage keratan sulphates decreases with age. Bovine corneal keratan sulphate appears to be unbranched. (3) Mannose residues are linked by 3 different substituents in human costal-cartilage and bovine corneal keratan sulphates, and by two different substituents in pig nucleus pulposus keratan sulphate. (4) The sulphate ester groups are all on the 6-position of N-acetyl-glucosamine and galactose residues. The degree of sulphation increases with age in costal keratan sulphates with the increase mainly of the galactose 6-sulphate residues.     

Studies on the incorporation of [U-14C]glucose and [35S]sulphate into the acid glycosaminoglycans of neonatal rat skin

1. The incorporation of [(35)S]sulphate in vivo into the acid-soluble intermediates extracted from young rat skin showed three sulphated hexosamine-containing components. 2. The rates of synthesis of these components were determined in vivo by measuring the incorporation of radioactivity from [U-(14)C]glucose into their isolated hexosamine moieties. 3. The incorporation of radioactivity from [U-(14)C]glucose into the isolated hexosamine and uronic acid moieties of the acid glycosaminoglycans was also measured. These results, combined with those obtained on the intermediary pathways of hexosamine and uronic acid biosynthesis previously determined in this tissue, indicated that the acid-soluble sulphated hexosamine-containing components were not precursors of the sulphated hexosamine found in the acid glycosaminoglycans. 4. The rates of synthesis of the acid glycosaminoglycan fractions were calculated from the incorporation of radioactivity from [U-(14)C]glucose into the hexosamine moiety. The sulphated components containing principally dermatan sulphate, chondroitin 6-sulphate and in smaller amounts, chondroitin 4-sulphate, heparan sulphate and heparin appeared to be turning over about twice as rapidly as hyaluronic acid and about four times as rapidly as the small keratan sulphate fraction. The relative rates of synthesis of the sulphated glycosaminoglycans were calculated from the incorporation of [(35)S]sulphate and were in agreement with those from (14)C-labelling studies.     

The molecular-weight distribution of glycosaminoglycans

1. A rapid and sensitive method for the accurate estimation of the molecular-weight distribution of keratan sulphate and chondroitin sulphate isolated from adult bovine nasal septum and intervertebral disc is described. The method utilizes gel chromatography of reductively labelled glycosaminoglycan and end-group estimation of number-average molecular weight for each fraction across the peak of eluted glycosaminoglycan. 2. Chain-length distribution data obtained by this procedure are used to evaluate mechanisms of chondroitin sulphate biosynthesis.     

The glycosaminoglycans of human tracheobronchial cartilage

1. The glycosaminoglycans of human tracheobronchial cartilages from subjects of various ages were liberated by proteolysis of the tissue and purified by ion-exchange chromatography. Purified glycosaminoglycans were fractionated on Dowex 1 resin and cetylpyridinium chloride was used to separate chondroitin sulphates and keratan sulphates occurring in the same fraction. 2. The total chondroitin sulphate content of the cartilages decreased linearly with increasing age. Age-dependent changes in the chemical heterogeneity of chondroitin sulphate were observed, a low-sulphated compound making up 25% of the total glycosaminoglycan at birth but rapidly diminishing in content during the first 6 months of life. Of the total chondroitin sulphate the 6-isomer became rather more prominent than the 4-isomer with increasing age. 3. The total keratan sulphate content of the cartilages increased from trace amounts only at birth to a plateau value by the beginning of the fifth decade. Of the total keratan sulphate approx. 70% was due to a high-molecular-weight compound with a sulphate/hexosamine ratio of 1.5-1.8: 1.0. The degree of sulphation varied between compounds isolated from different individuals. The remaining 30% of the keratan sulphate appeared to be intimately associated with chondroitin 6-sulphate and could only be separated from it after treatment with 0.45m-potassium hydroxide. The hybrid glycosaminoglycans were of lower molecular weight and had a lower sulphate/hexosamine ratio than the major keratan sulphate compound.     

Alterations in human gingival glycosaminoglycan pattern in inflammation and in phenytoin induced overgrowth

Glycosaminoglycans were extracted from normal, inflamed and phenytoin induced overgrowth of human gingival tissue by proteolysis and alcohol precipitation. Extracts were run in a Dowex-1 column and the fractions were treated with mucopolysaccharidases. Cellulose acetate electrophoresis was carried out with or without enzyme digestion for identification of individual glycosaminoglycans. Glycosaminoglycans were found to be decreased in inflammation but were observed to increase in the overgrowth. Hyaluronic acid was found to be increased in both the pathological conditions. Dermatan sulphate, chondroitin sulphate and heparan sulphate were observed to be decreased in inflammation. In overgrowth, dermatan sulphate and chondroitin sulphate were found to increase while the presence of heparan sulphate was not significant. The changes in the pattern of individual glycosaminoglycan in the two varied conditions are discussed.Abbreviations GAG glycosaminoglycan - MPS mucopolysaccharide - DS dermatan sulphate - HS heparan sulphate - CS chondroitin sulphate - HA hyaluronic acid - KS keratan sulphate     

Protein–polysaccharide of chicken cartilage and chondrocyte cell cultures

The nature of the matrix produced by embryonic chicken chondrocytes in cell culture was studied, and compared with adult and embryonic chicken cartilage. Adult chicken cartilage contains a protein-polysaccharide easily extracted with EDTA-sodium chloride at 4 degrees C. Purification of this macromolecule on Bio-Gel P-300 and Bio-Gel A-50m yielded a progressively more homogeneous species in the ultracentrifuge. It contained mostly chondroitin 4-sulphate, some chondroitin 6-sulphate, and keratan sulphate. Embryonic chicken cartilage was previously shown to contain mostly chondroitin 4-sulphate, some chondroitin 6-sulphate and essentially no keratan sulphate. The matrix produced in chondrocyte cell cultures was shown to contain a protein-polysaccharide with alkali-labile linkages of chondroitin 4-sulphate to the protein core. A fraction was isolated from the matrix with many properties of keratan sulphate.     

Altered proteoglycan synthesis by micromelial limbs induced by 6-aminonicotinamide. Appearance of abnormal forms of cartilage-characteristic proteoglycan (PG-H).

Since administration of 6-aminonicotinamide (10 micrograms) to day-4 chick embryos in ovo was shown to induce micromelial limbs, biosynthesis of cartilage-characteristic proteoglycan-H (PG-H) as an important index of limb chondrogenesis was examined in day-7 normal and micromelial hind limbs by biochemical and immunological methods. (1) Metabolic labelling of the micromelial limbs with [6-3H]glucosamine and either [35S]sulphate or [35S]methionine, followed by analyses of labelled PG-H by glycerol density-gradient centrifugation under dissociative conditions, showed a marked reduction in the PG-H synthesis. (2) PG-H synthesized by the micromelial limbs was much lower than that synthesized by the normal limbs in the biosynthetic ratio of chondroitin sulphate to keratan sulphate and glycoprotein-type oligosaccharide, although no significant difference was observed in the immunological properties of these proteoglycans. (3) The degree of sulphation of chondroitin sulphates of PG-H was lowered in the micromelial limbs as judged by the increase of unsulphated disaccharide (delta Di-OS) released by chrondroitinase ABC digestion, although there were no significant differences between the normal and the micromelial limbs in the average molecular size (Mr = 38,000) of labelled chondroitin sulphates of PG-H. (4) Addition of beta-D-xyloside, an artificial initiator for chondroitin sulphate synthesis, to the micromelial limbs in culture recovered the incorporation of labelled glucosamine into chondroitin sulphate to that comparable with the normal control with beta-D-xyloside, although the incorporation of [35S]sulphate was lower in the micromelia than in the control with beta-D-xyloside. These results suggest that the reduction in the biosynthesis of the PG-H as well as the production of altered forms of PG-H induced by 6-aminonicotinamide during a critical period of limb morphogenesis may be an important factor for the micromelia.     

Extracellular matrix components in uterine leiomyoma and their alteration during the tumour growth

It was found that both normal human myometrium and uterine leiomyoma contain several glycosaminoglycans. In contrast to many normal and tumour tissues the amount of hyaluronic acid is very low and the proportional amount of sulphated glycosaminoglycans is distinctly higher. It is of interest that heparan sulphate is the major glycosaminoglycan component both in normal myometrium, and in leiomyoma. The amount of hyaluronic acid in myometrium and in the leiomyoma is very low. No significant change in hyaluronate content was observed during the tumour growth. In contrast to that the amount of some sulphated glycosaminoglycans (heparan sulphate, keratan sulphate, chondroitin sulphates and heparin) distinctly increased. It is suggested that some of the GAGs participate in the creation of a storage depot for biologically active molecules (growth factors, enzymes) which are thereby stabilized and protected. Hydrolytic degradation of some GAGs may result in the release of some cytokines which may promote the tumour growth and stimulate collagen biosynthesis by tumour cells.     

The detection of substructures within proteoglycan molecules. Electron-microscopic immuno-localization with the use of Protein A-gold.

Proteoglycan monomers from pig laryngeal cartilage were examined by electron microscopy with benzyldimethylalkylammonium chloride as the spreading agent. The proteoglycans appeared as extended molecules with a beaded structure, representing the chondroitin sulphate chains collapsed around the protein core. Often a fine filamentous tail was present at one end. Substructures within proteoglycan molecules were localized by incubation with specific antibodies followed by Protein A-gold (diameter 4 nm). After the use of an anti-(binding region) serum the Protein A-gold (typically one to three particles) bound at the extreme end of the filamentous region. A small proportion of the labelled molecules (10-15%) showed the presence of gold particles at both ends. A monoclonal antibody specific for a keratan sulphate epitope (MZ15) localized a keratan sulphate-rich region at one end of the proteoglycan, but gold particles were not observed along the extended part of the protein core. This distribution was not changed by prior chondroitin AC lyase digestion of the proteoglycan. Localization with a different monoclonal antibody to keratan sulphate (5-D-4) caused a change in the spreading behaviour of a proportion (approx. 20%) of the proteoglycan monomers that lost their beaded structure and appeared with the chondroitin sulphate chains projecting from the protein core. In these molecules the Protein A-gold localized antibody (5-D-4) along the length of the protein core whereas in those molecules with a beaded appearance it labelled only at one end. Labelling with either of the monoclonal antibodies was specific, as it was inhibited by exogenously added keratan sulphate. The differential localization achieved may reflect structural differences within the proteoglycan population involving keratan sulphate and the protein core to which it is attached. The results showed that by this technique substructures within proteoglycan molecules can be identified by Protein A-gold labelling after the use of specific monoclonal or polyclonal antibodies.     

Control of chondroitin sulphate biosynthesis. beta-D-Xylopyranosides as substrates for UDP-galactose: D-xylose transferase from embryonic-chicken cartilage.

Embryonic-chicken epiphyseal cartilage was incubated in vitro with a variety of beta-xylosides and the amount of [3H]acetate incorporation into chondroitin sulphate was determined under conditions when normal protein core production was inhibited by cycloheximide. The ability of the different beta-xylosides to relieve thea cycloheximide-mediated inhibition of chondroitin sulphate synthesis was influenced by the nature of the aglycan group of te xyloside. beta-Xylosides with apolar and uncharged aglycan groups were most effective and produced a severalfold stimulation of chondroitin sulphate biosynthesis. beta-Xylosides with charged aglycan groups were less effective initiators of chondroitin sulphate synthesis. The rate of galactose transfer from UDP-galactose to each of the beta-xylosides, catalysed by a cell-free microsomal preparation from embryonic cartilage, was measured. This study showed that the nature of the aglycan group of the beta-xyloside was a factor determining the capacity of the xyloside to act as an acceptor for galactosyltransferase I, the enzyme that catalyses the first galactose transfer reaction of chondroitin sulphate synthesis. The aglycan group of the xyloside also appeared to influence other steps leading to chondroitin sulphate chain initiation in vitro.     

The nature of the non-ultrafilterable glycosaminoglycans of normal human urine

1. The non-ultrafilterable acidic glycosaminoglycans from pooled urine of normal men, aged about 20, were isolated and characterized. The isolation procedure included digestion with sialidase and pronase, and fractionation by stepwise elution from an ECTEOLA-cellulose column. The glycosaminoglycans in each fraction were separated from each other by preparative electrophoresis in sodium barbital buffer and in barium acetate. 2. Approximate relative amounts of the different glycosaminoglycans were: chondroitin sulphate 60%, chondroitin 2%, hyaluronic acid 4%, dermatan sulphate 1%, heparan sulphate 15% and keratan sulphate 18%. Chondroitin sulphate-dermatan sulphate hybrids seemed to occur in trace amounts. 3. Chondroitin sulphate, heparan sulphate and keratan sulphate were heterogeneous with respect to degree of sulphation. Two distinct groups of chondroitin sulphate fractions were found, with sulphate/hexosamine molar ratios of about 0.5 and 1 respectively. The sulphate/hexosamine molar ratios in the heparan sulphate fractions varied from 0.5 to 0.9; the N-sulphate/hexosamine ratio was about 0.5 in all fractions. The sulphate/hexosamine molar ratios in the keratan sulphate fractions varied from 0.2 to 0.7.     

Formation of UDP-Xylose and Xyloglucan in Soybean Golgi Membranes

Soybean (Glycine max) membranes co-equilibrating with Golgi vesicles in linear sucrose gradients contained UDP-glucuronate carboxy-lyase and xyloglucan synthase activities. Digitonin solubilized and increased the activity of the membrane-bound UDP-glucuronate carboxy-lyase. UDP-xylose did not inhibit the transport of UDP-glucuronate into the lumen of Golgi vesicles but repressed the decarboxylation of the translocated UDP-glucuronate. The results suggest that UDP-glucuronate is transported into the vesicles by a specific carrier and decarboxylated to UDP-xylose within the lumen. On incubation of UDP-[¹⁴C]glucuronate with Golgi membranes in the presence of UDP-glucose, [¹⁴C]xylose-labeled xyloglucan was formed. Although the K_m value of UDP-glucuronate for the decarboxylation was 240 micromolar, the affinity of UDP-glucuronate for xyloglucan formation (31 micromolar) was similar to that of UDP-xylose (28 micromolar), suggesting a high turnover of UDP-xylose. The biosynthesis of UDP-xylose from UDP-glucuronate probably occurs in Golgi membranes, where xyloglucan subsequently forms from UDP-xylose and UDP-glucose.     

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.     

Fractionation of proteoglycans from bovine corneal stroma.

Proteoglycans were extracted from bovine corneal stroma with 4M-guanidinum chloride, purified by DEAE-dellulose chromatography (Antonopoulos et al., 1974) and fractionated by precipitation with ethanol into three fractions of approximately equal weight. One of these fractions consisted of a proteoglycan that contained keratan sulphate as the only glycosaminoglycan. In the othertwo fractions proteoglycans that contained chondroitin sulphate, dermatan sulphate and keratan sulphate were present. Proteoglycans which had a more than tenfold excess of galactosaminoglycans over keratan sulphate could be obtianed by further subfractionation. The gel-chromatographic patterns of the glucosaminoglycans before and after digestion with chondroitinase AC differed for the fractions. The individual chondroitin sulphate chains seemed to be larger in cornea than in cartilage. Oligosaccharides, possibly covalently linked to the protein core of the proteoglycans, could be isolated from all fractions. The corneal proteoglycans were shown to have higher protein contents and to be of smaller molecular size than cartilage proteoglycans.