Skeletal keratan sulfate chain molecular weight calibration by high-performance gel-permeation chromatography

A method has been developed for the molecular sizing of skeletal keratan sulfate chains using an HPLC gel-permeation chromatography system. Keratan sulfate chains and keratanase-derived oligosaccharides were prepared from the nucleus pulposus of bovine intervertebral disc (6-year-old animals). A Bio-Gel TSK 30 XL column eluted in 0.2 M NaCl and at 30 degrees C was calibrated with keratan sulfate oligosaccharides of known size as well as 3H-end-labeled keratan sulfate chains to yield the relationship.     

Amino acid sequence of a peptide from keratan sulfate II-core protein linkage regions

Keratan sulfate II was prepared from the proteolytic digest of pig nucleus pulposus proteoglycan. The polysaccharide chains containing the fragment peptides of the core protein at their reducing terminal were subjected to anhydrous HF-solvolysis reaction and one of the glycopeptides from the keratan sulfate II-core protein linkage regions was isolated. The amino acid sequence of the peptide was deduced to be Ala-Pro-Ser-Pro-Gly, which is different from those reported for the attachment sites of chondroitin sulfate on core proteins from various sources. The results provided the first solid amino acid sequence for the keratan sulfate II-core protein linkage regions and suggested that the amino acid sequence of the core protein might determine the distribution of chondroitin sulfates and keratan sulfates along the core protein of the proteoglycan molecule.     

Liver alcohol dehydrogenase subunit equivalence studied by rapid sampling of alcohol product formed from sequentially bound [4alpha-3H]NADH.

Proteoglycans of calf and steer articular cartilage were studied with a view of assessing structure and changes occurring as a result of the aging process. The average reduction in hydrodynamic size noted in steer was associated with a diminution in size of the chondroitin sulfate-rich region of the core protein as well as the chondroitin sulfate chains themselves. By contrast the keratan sulfate-rich region was hydrodynamically larger in steer although the keratan sulfate chains were only slightly longer than in calf. The proteoglycans showed a maturation-related decrease in chondroitin sulfate content (shorter chains, fewer chains, smaller chondroitin sulfate-rich region) and an enrichment in keratan sulfate chains in both the chondroitin sulfate-rich and keratan sulfate-rich regions. Proteoglycans from both age groups contained an oligosaccharide which was recovered mainly from outside of the keratan sulfate-rich region. There were no significant differences in size between keratan sulfate chains recovered from the keratan sulfate-rich region and the chondroitin sulfate-rich region.     

The keratan sulfate-enriched region of bovine cartilage proteoglycan consists of a consecutively repeated hexapeptide motif

We have determined the sequence of a cDNA clone encoding the keratan sulfate-rich domain of the large aggregating cartilage proteoglycan core protein. The C-terminal portion of the deduced amino acid sequence is homologous to the chondroitin sulfate-rich region (domain CS1) of the rat chondrosarcoma proteoglycan, and the N-terminal portion is homologous to the second globular domain (G2) of the rat proteoglycan (Doege, K., Sasaki, M., Horigan, E., Hassell, J. R., and Yamada, Y. (1987) J. Biol. Chem. 262, 17757-17767). We could identify, inserted between these regions, a region absent in the rat proteoglycan. This domain corresponds to the keratan sulfate-enriched region of the bovine proteoglycan. It consists of a highly conserved hexapeptide motif consecutively repeated 23 times. Transfer blot analysis of genomic DNA indicated a single gene. The coding region for the keratan sulfate-enriched region was present both in human and bovine DNA, whereas the coding region for this domain appears to be absent in the rat genome. Transfer blot analysis of RNA showed that the keratan sulfate-rich region is present in proteoglycans from fetal as well as adult sources. Furthermore, RNA protection assays of RNA isolated from adult and fetal bovine articular cartilage showed that no alternative splicing occurs within this keratan sulfate-enriched region. These experiments show that the fetal bovine cartilage proteoglycan contains the keratan sulfate attachment domain, although it lacks the keratan sulfate side chains.     

Maturation-related changes in proteoglycans of fetal articular cartilage

Proteoglycans of the articulating and growing zones of maximum and minimum contact of bovine fetal articular cartilage were studied and compared to proteoglycans of immature calf and adult steer. During fetal maturation, localized changes were observed as early as the second trimester of fetal life but were restricted to the most superficial zones. Proteoglycans extracted from the growing zones were purified by density-gradient ultracentrifugation. The majority of proteoglycan monomers were able to interact with endogenous hyaluronate to form aggregates. Monomers had, at all fetal stages, similar elution profiles on Sepharose 2B and similar ratios of chondroitin sulfate chains/keratan sulfate chains/O-glycosidically linked oligosaccharides. Keratan sulfate chains were of similar size at all stages, but chondroitin sulfate chain size decreased markedly with fetal maturation. In the first and second trimesters of fetal life, the proteoglycans were poorly substituted with glycosaminoglycans. A major increase in the absolute number of glycosaminoglycans and oligosaccharides attached to core protein was detected during the third trimester of fetal life. No further changes in substitution occurred in early postnatal life. Enzymatic digestion of proteoglycan monomer demonstrated that the increase in substitution with keratan sulfate occurred to the same extent in the main polysaccharide attachment region and in the keratan sulfate-rich region.     

Isolation and characterization of an asparagine-linked keratan sulfate from the skin of a marine teleost, Scomber japobicus

Keratan sulfate was isolated from the skin of Pacific mackerel (Scomber japonicus) after exhaustive digestion with pronase followed by ethanol precipitation and fractionation on a cellulose column with 0.3% recovery of dried material. The keratan sulfate preparation was separated into four major fractions by Dowex-1 column chromatrography. The chemical and infrared spectrum analyses of the four fractions showed a high degree of heterogeneity in sulfation. Since the carbohydrate-peptide linkage in the teleost skin keratan sulfate was found to be stable in alkali, and asparagine was the predominant amino acid, the asparagine residue in the peptide backbone was most likely to be involved in the N-glycosyl linkage with the carbohydrate moiety. Besides the type of carbohydrate-peptide linkage, the teleost skin keratan sulfate is very similar to corneal keratan sulfate, (keretan sulfate I) in two respects: (1) The teleost skin and bovine corneal keratan sulfates were hydrolyzed much faster by endo-β-galactosidase that the whale nasal cartilage keratan sulfate (keratan sulfate II). (2) Although the teleost skin keratan sulfate showed considerable polydispersity, the molecular weight was in the same range as the corneal keratan sulfate, and it was relatively higher than that of the cartilage keratan sulfate.     

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.     

Identification of a monoclonal antibody that specifically recognizes corneal and skeletal keratan sulfate. Monoclonal antibodies to cartilage proteoglycan

Monoclonal antibodies were raised against proteoglycan core protein isolated after chondroitinase ABC digestion of human articular cartilage proteoglycan monomer. Characterization of one of the monoclonal antibodies (1/20/5-D-4) indicated that it specifically recognized an antigenic determinant in the polysaccharide structure of both corneal and skeletal keratan sulfate. Enzyme immunoassay analyses indicated that the mouse monoclonal IgG1 recognized keratan sulfate in native proteoglycan aggregate and proteoglycan monomer preparations isolated from hyaline cartilages of a wide variety of animal species (human, monkey, cow, sheep, chicken, and shark cartilage). The 1/20/5-D-4 monoclonal antibody did not recognize antigenic determinants on proteoglycan isolated from Swarm rat chondrosarcoma. This finding is consistent with several biochemical analyses showing the absence of keratan sulfate in proteoglycan synthesised by this tissue. A variety of substructures isolated after selective cleavage of bovine nasal cartilage proteoglycan (Heineg?rd, D., and Axelsson, J. (1977) J. Biol. Chem. 252, 1971-1979) were used as competing antigens in radioimmunoassays to characterize the specificity of the 1/20/5-D-4 immunoglobulin. Substructures derived from the keratan sulfate attachment region of the proteoglycan (keratan sulfate peptides) showed the strongest inhibition. Both corneal and skeletal keratan sulfate peptides as competing antigens in radioimmunoassays showed similar inhibition when compared on the basis of their glucosamine content. Therefore, the 1/20/5-D-4 monoclonal antibody appears to recognize a common determinant in their polysaccharide moieties. Chemical desulfation of the keratan sulfate reduced the antigenicity of the glycosaminoglycan. The antibody did not recognize determinants present in dermatan sulfate, heparin, heparin sulfate, or hyaluronic acid.     

Distribution of proteoglycans antigenically related to corneal keratan sulfate proteoglycan

Three antibodies reacting with corneal keratan sulfate proteoglycan were used to detect antigenically related molecules in 11 bovine and 13 embryonic chick tissues. Two monoclonal antibodies recognized sulfated epitopes on the keratan sulfate chain and a polyclonal antibody bound antigenic sites on the core protein of corneal keratan sulfate proteoglycan. Competitive immunoassay detected core protein and keratan sulfate antigens in guanidine HCl extracts of most tissues. Keratan sulfate antigens of most bovine tissues were only partially extracted with guanidine HCl, but the remainder could be solubilized by CNBr treatment of the guanidine-extracted residue. Keratan sulfate and core protein antigens co-eluted with purified corneal keratan sulfate proteoglycan on ion exchange high-performance liquid chromatography (HPLC). Endo-beta-galactosidase digestion of the HPLC-purified keratan sulfate antigens eliminated the binding of monoclonal anti-keratan sulfate antibodies in enzyme-linked immunosorbent assay. Extracts of all 11 bovine tissues, except those from brain and cartilage, could bind both anti-keratan sulfate monoclonal antibodies and anti-core protein polyclonal antibody simultaneously. Binding was sensitive to competition with keratan sulfate and to digestion with endo-beta-galactosidase. These results suggest widespread occurrence of a proteoglycan or sulfated glycoprotein bearing keratan sulfate-like carbohydrate and a core protein resembling that of corneal keratan sulfate proteoglycan.     

Cartilage keratan sulphate: changes in chain length with ageing

Keratan sulphate from sheep nasal cartilage of five different ages was isolated by a combination of methods. The mean length of the chains progressively increased with ageing, as assessed by the molar ratio of glucosamine to galactosamine or galactosaminitol. The mean length ranges from eight monosaccharides for the younger to seventeen monosaccharides for the older animals. The results suggest that the increase in keratan sulphate content of cartilage may be due to the increase in the length and not in the number of chains.     

Proteoglycans of the intervertebral disc. Homology of structure with laryngeal proteoglycans.

The structure of the proteoglycans from normal pig nucleus pulposus and relatively normal human annulus fibrosus and nucleus pulposus was investigated in detail and the results were compared with the current structural model of proteoglycans of hyaline cartilage. Like proteoglycans of cartilage, those of intervertebral disc contain keratan sulphate and chondroitin sulphate attached to a protein core; they are able to aggregate to hyaluronic acid; the protein core likewise has three regions, one lacking glycosaminoglycans, another rich in keratan sulphate and a third region rich in chondroitin sulphate. However, disc proteoglycans contain more keratan sulphate and protein and less chondroitin sulphate and are also considerably smaller than cartilage proteoglycans. In proteoglycans of human discs, these differences appeared to be due principally to a shorter region of the core protein bearing the chondroitin sulphate chains, whereas in proteoglycans of pig discs their smaller size and relatively low uronic acid content were due to shorter chondroitin sulphate chains. There were subtle differences between proteoglycans from the nucleus and annulus of human discs. In the latter a higher proportion of proteoglycans was capable of binding to hyaluronate.     

Changes in the chondroitin sulfate-rich region of articular cartilage proteoglycans in experimental osteoarthritis

The chondroitin sulfate-rich region was cleaved from cartilage proteoglycans of experimental osteoarthritic canine joints to establish whether changes in this region of the molecule contribute to the well-documented increase in the chondroitin sulfate to keratan sulfate ratio in osteoarthritis. Experimental osteoarthritis was induced in eight dogs by severance of the right anterior cruciate ligament, the left joint serving as a control. Proteoglycans were extracted from the femoral cartilage of both joints, isolated as A1 fractions by associative density gradient centrifugation and cleaved with hydroxylamine. The chondroitin sulfate-rich region was isolated by either gel chromatography or dissociative density gradient centrifugation. The chondroitin sulfate-rich region from the proteoglycans of the experimental osteoarthritic joints was slightly larger in hydrodynamic size and had both a higher uronate/protein weight ratio and galactosamine/glucosamine molar ratio than the corresponding control. We conclude that the chondroitin sulfate-rich region of proteoglycans in articular cartilage of experimental osteoarthritic joints is larger and has more chondroitin sulfate than that of proteoglycans of normal cartilage.     

Two subpopulations of differentiated chondrocytes identified with a monoclonal antibody to keratan sulfate

We have prepared a monoclonal antibody, named MZ15, that specifically binds keratan sulfate. Immunofluorescence studies showed that the distribution of keratan sulfate in articular cartilage was not uniform: the amount of keratan sulfate increased with distance from the articular surface. Two subpopulations of chondrocytes could be distinguished after isolation from cartilage by the presence or absence of cell surface keratan sulfate. Keratan sulfate-negative chondrocytes were shown to come from the upper cartilage layers. There was therefore a direct correlation between biochemical heterogeneity of cartilage matrix and heterogeneity within the chondrocyte population. During growth in monolayer culture, superficial chondrocytes began to synthesize keratan sulfate, but the cells could still be distinguished from cultures of deep or unfractionated chondrocytes by their reduced substrate adhesiveness and tendency to remain rounded.     

Aggregated proteoglycan synthesis in organ cultures of human nucleus pulposus.

Proteoglycans isolated under associative conditions in the presence of protease inhibitors from human nucleus pulposus contained 17% aggregate and 83% non-aggregating monomer (Kav = 0.5 on Sepharose CL-2B). Isolated aggregate after reduction and alkylation was resolved into two components (Kav = 0.15 and 0.43) on Sepharose CL-2B. Labeled proteoglycans isolated from parallel samples pulsed with [35S]sulfate and chased for up to 18 h were present largely as aggregated material (up to 78%). Reduction and alkylation of the labeled samples gave a labeled proteoglycan monomer with Kav = 0.15. Both the labeled and unlabeled chondroitin sulfate chains had the same distribution on Sepharose CL-6B and equivalent molecular weights (Mr = 2.0 x 10(3)). After chondroitinase ABC digestion, the unlabeled keratan sulfate-protein core was polydisperse with a Kav = 0.38 on Sepharose CL-4B while the labeled keratan sulfate-protein core had a Kav = 0.05. This indicates that the newly synthesized proteoglycan had a large core protein and suggests that the proteoglycans present in nucleus pulposus are originally synthesized as large molecular weight, aggregating proteoglycans.     

The structure and composition of cartilage keratan sulphate

Keratan sulphate was isolated from bovine intervertebral disc and bovine nasal septum after hydrolysis with proteinases and treatment with dilute alkali. Each preparation was found to contain, per keratan sulphate chain: (a) 1 residue of mannose; (b) 3 residues of N-acetylneuraminic acid (2 residues after alkali treatment); (c) 1 residue of N-acetylgalactosamine (lost after alkali treatment); (d) 1 residue or less of fucose. N-Acetyl-neuraminic acid residues were at non-reducing termini and were bonded to keratan sulphate through galactose residues. Evidence is presented for two different types of linkage between skeletal keratan sulphate and protein. Consideration of molecular parameters and compositions leads to a proposed structure for keratan sulphate-protein as found in skeletal proteoglycans.     

The occurrence of low buoyant density proteoglycans in embryonic chick cartilage

Two proteoglycan fractions, PCS-H and PCS-L, have previously been isolated from 4 M guanidine HCl extract of embryonic chick cartilages. This communication reports further studies with PCS-L indicating that this fraction contains several different forms, of which one differs from hitherto known cartilage proteoglycans in 1) markedly lower buoyant density, 2) susceptibility to reduction with 2-mercaptoethanol, 3) aggregate-forming ability in 4 M guanidine HCl, and 4) presence of dermatan sulfate-chondroitin sulfate copolymer chains. Also isolated from the PCS-L fraction is a keratan sulfate-rich proteoglycan which represents the smallest molecular size species in cartilage proteoglycan populations.     

Characterization of the keratan sulphate proteoglycans from bovine corneal stroma.

The keratan sulphate proteoglycans that can be prepared from bovine corneal stroma [Axelsson & Heineg?rd (1975) Biochem. J. 145, 491-500] were characterized by gel chromatography, gel electrophoresis and analytical ultracentrifugation in associative (0.6 M-NaCl) and dissociative (6M-guanidinum chloride) solvents. The proteoglycans aggreagated at low salt concentrations and pH. The weight-average molecular weight of the monomer proteoglycans was established. Keratan sulphate peptides and oligosaccharide peptides were isolated after proteolysis. Their composition indicated that both are linked to protein via asparagine residues. A tentative model for corneal keratan sulphate proteoglycans is suggested.     

Unique glycosylation of three keratan sulfate proteoglycan isoforms

Recent work demonstrates isoforms of bovine corneal keratan sulfate proteoglycan containing structurally unique core proteins of 25 and 37 kDa (Funderburgh, J., and Conrad, G. (1990) J. Biol. Chem. 265, 8297-8303). In the current study, two forms (37A and 37B) of the 37-kDa protein were separated by ion-exchange chromatography after removal of keratan sulfate with endo-beta-galactosidase. Keratan sulfate linkage sites in core proteins were labeled with UDP-[3H]galactose using galactosyltransferase. Labeled proteins were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and analyzed by tryptic digestion and reversed-phase chromatography. The 37A protein has three keratan sulfate-linkage sites, and the 37B and 25-kDa proteins each contain one linkage site. Reversed-phase tryptic maps of the three proteins differed in total peptide profile and in glycosylated peptides labeled with periodate-[3H]-NaBH4. Tryptic mapping of the two 37-kDa isoforms after deglycosylation showed differences in total tryptic peptides, in peptides labeled with [14C]iodoacetic acid, and in peptides recognized by antibodies to a mixture of the 37-kDa cores. Antibody to a synthetic peptide with N-terminal sequence obtained from mixed 37-kDa cores reacted exclusively with the 37B isoform. These results show that bovine corneal keratan sulfate proteoglycan has three different core proteins each with distinct glycosylation and unique primary structure.     

Distribution of keratan sulfate in cartilage proteoglycans.

After chondroitinase digestion of bovine nasal and tracheal cartilage proteoglycans, subsequent treatment with trypsin or trypsin followed by chymotrypsin yielded two major types of polypeptide-glycosaminoglycan fragments which could be separated by Sepharose 6B chromatography. One fragment, located close to the hyaluronic acid-binding region of the protein core, had a high relative keratan sulfate content. This fragment contained about 60% of the total keratan sulfate, but less than 10% of the total chondroitin sulfate present in the original proteoglycan preparation. The weight average molecular weight of the keratan sulfate-enriched fragment was 122,000, as determined by sedimentation equilibrium centrifugation. The chemical and physical data indicate that this fragment contains an average of 10 to 15 keratan sulfate chains, if the average molecular weight of individual chains is assumed to be about 8,000, and about 5 chondroitin sulfate chains attached to a peptide of about 20,000 daltons. The other population of fragments was derived from the other end of the proteoglycan molecule, the chondroitin sulfate-enriched region, and contained mainly chondroitin sulfate chains. About 90% of the total chondroitin sulfate, but only 20 to 30% of the total keratan sulfate was recovered in these fragments. On the average, approximately 5 chondroitin sulfate chains and 1 keratan sulfate chain could be linked to the same peptide. Another 10 to 20% of the total keratan sulfate, originally found in or near the hyaluronic acid-binding region, was not separated from the chondroitin sulfate-enriched fragments. Hydroxylamine could be used to liberate a large molecular size, chondroitin sulfate-enriched fragment (Kav 0.54 on Sepharose 2B) from the proteoglycan aggregates. The remainder of the protein core, containing the keratan sulfate-enriched region, was bound to hyaluronic acid with the link proteins and recovered in the void volume on the Sepharose 2B column.     

Heterogeneity of keratan sulfate substituted on human chondrocytic large proteoglycans.

Newly synthesized 35S-labeled chondrocytic keratan sulfate chains were generated by chondrocytes of human chondrosarcoma cell line 105KC and were analyzed for heterogeneity of regional substitution, hydrodynamic size, and charge density. After isolation of the high density large chondrocytic proteoglycans and sequential digestions with chondroitinase ABC, L-1-tosylamido-2-phenylethyl chloromethyl ketone-treated trypsin, and alpha-chymotrypsin, followed by Superose 6 chromatography, two populations of keratan sulfate-containing proteoglycan fragments were identified and pooled separately. Keratan sulfate chains from each of the regions were compared after release by Pronase digestion, and differences in substitution patterns were observed; keratan sulfate chains of greater polydispersity, as well as a population of larger hydrodynamic size, were present in only one of the two regions. Alkaline/borohydride treatment confirmed both the existence of a population of uniquely large keratan sulfate chains and its restriction to a single region of proteoglycan fragments. In addition to heterogeneity of hydrodynamic size, the keratan sulfate chains exhibited regional heterogeneity of charge density and hence, of sulfation patterns. Analysis by Mono Q chromatography identified distinct groups of keratan sulfate that segregated by charge density and whose proportionate composition differed between the proteoglycan regions. Furthermore, the most highly charged species were unique to a single region and encompassed the chains of larger hydrodynamic size. This suggests that there may be regional heterogeneity of keratan sulfate chains substituted along a single class of proteoglycans and identifies a novel population of large, highly sulfated chondrocytic keratan sulfate chains.