Project description:Antibodies have been raised in rabbits to the hyaluronate-binding region and link-protein components of aggregated proteoglycans from pig laryngeal cartilage. The anti-(binding region) antibodies did not bind 125I-labelled link protein, nor was 125I-labelled binding region bound by the anti-(link protein) antibodies. The antisera were applied in sensitive inhibition radioimmunoassays to determine binding region and link protein in purified proteoglycan preparations. With intact proteoglycan aggregates, the antigenic sites of link protein, and to a lesser extent binding region, were masked. Heat treatment in the presence of sodium dodecyl sulphate (0.025%, w/v) was found to overcome this masking, thereby allowing the determination of link protein and binding region in aggregated proteoglycan preparations in pure and impure samples.

Project description:Proteoglycan fractions were prepared from pig laryngeal cartilage. The effect of link-protein on the properties of proteoglycan-hyaluronate aggregates was examined by viscometry and analytical ultracentrifugation. Aggregates containing link-protein were more stable than link-free aggregates at neutral pH, at temperatures up to 50 degrees C and in urea (up to 4.0M). Oligosaccharides of hyaluronate were able to displace proteoglycans from link-free aggregates, but not from the link-stabilized aggregates. Both types of aggregate were observed in the ultracentrifuge, but at the concentration investigated (less than 2 mg/ml) the link-free form was partially dissociated and the proportion aggregated varied with the pH and temperature and required more hyaluronate for saturation than did link-stabilized aggregate. The results showed that link-protein greatly strengthened the binding of proteoglycans to hyaluronate and suggest that under physiological conditions it 'locks' proteoglycans on to the hyaluronate chain.

Project description:Pig articular cartilage was maintained in culture for 3 days with and without porcine interleukin 1. The proteoglycans remaining in the cartilage and those released into the medium were analysed by using radioimmunoassays for the hyaluronate-binding region, link protein and keratan sulphate. In interleukin 1-treated cultures after 3 days there was 38% release of total glycosaminoglycans into the medium, 18% release of binding region, 14% release of link protein and 20% release of keratan sulphate epitope, whereas in control cultures the proportions released were much less (16, 9, 10 and 7% respectively). Characterization of the proteoglycans in the media after 1.5 days and 3 days of culture showed that interleukin 1 promoted the release of proteoglycan of large average size and also the release of link protein and of low-Mr binding region which was unattached to proteoglycan. Both the link protein and binding region released were able to bind to exogenously added hyaluronate, whereas the proteoglycan in the medium was not. The proteoglycans extracted from cultured cartilage were similar to those from fresh cartilage: they contained a high proportion of aggregating proteoglycans and some low-Mr binding region. The proportion of this binding region extracted from the interleukin 1-treated cartilage was increased. The presence of interleukin 1 in the cultures therefore appeared to increase the rate of proteolytic degradation of proteoglycan in the matrix and to lead to a more rapid loss of intact binding region, of link protein and of large proteoglycan fragments into the medium.

Project description:The hyaluronate-binding proteins from bovine nasal cartilage, i.e. the hyaluronate-binding region of the proteoglycan and the link protein, were labelled with 125I and separated from each other by gel chromatography. The proteins were characterized by molecular-weight determinations and their purity was established by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis and immunodiffusion. The binding properties of the two proteins by hyaluronate-substituted Sepharose gel were compared. It was found that both proteins behaved similarly. They bound with the same efficiency to the gel, they showed the same time course of binding, had slightly different pH optima for binding and both proteins had a decreasing affinity for the gel with increasing ionic strength. The binding to the gel could be inhibited by soluble hyaluronate, and the minimum size of a hyaluronate oligosaccharide required for inhibition was in both cases a decasaccharide (only even-numbered oligosaccharides were tested). The proteins did not show any co-operative binding in the system tested, which could be explained by the large number of binding sites in the hyaluronate-substituted gel. Binding constants for the protein-hyaluronate interaction were estimated. A value of 1.3 x 10(7) M-1 was obtained for the hyaluronate-binding region of the proteoglycan, in agreement with literature data. The corresponding value for the link protein was 0.7 x 10(7) M-1.

Project description:Cartilage proteoglycan aggregate formation was studied by zonal rate centrifugation in sucrose gradients. Proteoglycan aggregates, monomers and proteins could be resolved. It was shown that the optimal proportion of hyaluronic acid for proteoglycan aggregate formation was about 1% of proteoglycan dry weight. The reaggregation of dissociated proteoglycan aggregate A1 fraction was markedly concentration-dependent and even at 9 mg/ml only about 90% of the aggregates were reformed. The lowest proportion of link protein required for maximal formation of link-stabilized proteoglycan aggregates was 1.5% of proteoglycan dry weight. It was separately shown that link protein co-sedimented with the proteoglycan monomer. By competition with isolated hyaluronic acid-binding-region fragments, a proportion of the link proteins was removed from the proteoglycan monomers, indicating that the link protein binds to the hyaluronic acid-binding region of the proteoglycan monomer.

Project description:The interaction between proteoglycan and link protein extracted from bovine articular cartilage (15-18-month-old animals) was investigated in 0.5 M-guanidinium chloride. The proteoglycans, radiolabelled as the aggregate (A1 fraction), were fractionated by two 'dissociative' density-gradient centrifugations (A1D1D1) followed by a rate-zonal centrifugation (S1) to yield an A1D1D1S1 preparation. At least 65% of these proteoglycans were able to bind to hyaluronate, but only 52% were able to bind to link protein as assessed by chromatography on Sepharose CL-2B. Over 80% of the [3H]link-protein preparation, radiolabelled as the aggregate, was able to interact with proteoglycan as assessed by chromatography on Sepharose CL-4B. Equilibrium-boundary-centrifugation studies performed at low link-protein concentrations (2.42 x 10(-9) M-5.93 x 10(-8) M) were analysed by Scatchard-type plots and indicated a Kd of 1.5 x 10(-8) M and a stoichiometry, n = 0.56, i.e. approx. 56% of those proteoglycans capable of binding to link protein had a strong site for link protein if a 1:1 stoichiometry were assumed. However, experiments performed at higher link-protein concentrations (3.5 x 10(-7) M and 8 x 10(-7) M) yielded stoichiometry values which were link-protein-concentration-dependent. Non-equilibrium binding studies using chromatography on Sepharose CL-2B and rate-zonal centrifugation yielded apparent stoichiometries between 0.6 and 7.5 link-protein molecules per proteoglycan monomer as a function of increasing link-protein concentration. It was concluded that a proportion of the proteoglycan molecules had a strong site for binding a single link protein (Kd 1.5 x 10(-8) M) and that at high link-protein concentrations a weaker, open-ended, process of link-protein self-association nucleated upon the strong link-protein-proteoglycan complex occurred. Hyaluronate oligosaccharides appeared to abolish a proportion of this self-association (as observed by Bonnet, Dunham & Hardingham [(1985) Biochem. J. 228, 77-85] in a study of link-protein-hyaluronate-oligosaccharide interactions) so as to leave a link protein:proteoglycan stoichiometry of 2. It is not clear whether this second link-protein molecule binds directly to the proteoglycan or to the first link protein.

Project description:Human articular-cartilage link proteins are resolved into three components by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis, indicative of three different structures. The action of the proteinase clostripain yields a single link-protein component with electrophoretic properties analogous to those of the smallest (most mobile) native link protein, suggesting that this link protein may be derived naturally from one or both of the larger molecules by proteolytic cleavage in situ. Upon chemical deglycosylation of native link protein two components are resolved, suggesting that two of the link proteins differ only in their degree and/or type of oligosaccharide substitution. This pattern is compatible with a proteolytic origin for the smallest link protein. During aging further proteolytic fragmentation occurs, though it is only apparent on reduction of disulphide bonds. This fragmentation occurs at identical sites in all three native link proteins, indicating the existence of a large region common to all the link proteins, which appears to consist predominantly of the C-terminal half of the molecules. These observations are compatible with the variation in oligosaccharide and proteolytic heterogeneity occurring at the N-terminus of the link proteins.

Project description:Link proteins were identified immunologically in human articular-cartilage protein preparations from various individuals. Irrespective of age, all cartilages contained three link proteins of mol.wts. 48000, 44000 and 41000. However, with increasing age, multiple additional components of mol.wts. 26000-30000 were commonly observed under conditions where disulphide bonds were reduced.

Project description:Proteoglycan aggregates of cartilage are stabilized by the formation of a ternary complex between the G1 domain at the N-terminus of the proteoglycan monomer (aggrecan), link protein and hyaluronan polysaccharide. Both the G1 domain and link protein contain similar three-domain structures formed from an immunoglobulin fold and two proteoglycan tandem repeats, the arrangement of which had been investigated by neutron and synchrotron X-ray scattering [Perkins, Nealis, Dunham, Hardingham & Muir (1991) Biochemistry 30, 10708-10716]. Here, solution scattering was used to investigate the ternary complexes formed between a proteolytic fragment of proteoglycan monomer containing G1 (termed binding region), link protein and hyaluronan oligosaccharides containing either 34 or 450 saccharide units (HA34 and HA450). The ternary complex with HA34 had a neutron radius of gyration, RG, at infinite contrast not exceeding 5.5 nm. The ternary complex with HA34 had an X-ray cross-sectional radius of gyration Rxs of 2.4 nm and a neutron Rxs at infinite contrast of 2.00 nm. Since both were similar or larger than the Rxs for binding region (X-rays, 2.04 nm; neutrons, 1.84 nm) and link protein (neutrons, 0.8 nm), analyses showed that the cross-sectional mean width of the ternary complex is greater than those in each of the free proteins, i.e. the two proteins associated side-by-side. Similar results were obtained with HA450 complexed with binding region and with both binding region and link protein. This structural model was verified by hydrodynamic simulations of the experimental sedimentation coefficient of 5.5 S, which showed that a compact ternary-complex structure was formed. Although scattering curve simulations using small spheres were limited for the ternary complex with HA34 because of its approximate RG value, the scattering data were compatible with the formation of a compact complex formed by side-by-side contacts between G1 and link protein.

Project description:Seven genomic clones for mouse aggrecan core protein have been isolated including 3 kb of 5'- and 7 kb of 3'-flanking sequences. All exon sequences and their intron boundary sequences in these clones were identified and mapped by DNA sequencing. The gene spans at least 61 kb and contains 18 exons. Exon 1 encodes 5'-untranslated sequence and exon 2 contains a translation start codon, methionine. The coding sequence is 6545 bp for a 2132-amino-acid protein with calculated M(r) = 259,131 including an 18-amino-acid signal peptide. There is a strong correlation between structural domains and exons. Notably, the chondroitin sulphate domain consisting of 1161 amino acids is encoded by a single exon of 3.6 kb. Although link protein has similar structural domains and subdomains, the sequence identity and the organization of exons encoding the subdomains B and B' of G1 and G2 domains revealed a strong similarity of mouse aggrecan to both human versican and rat neurocan. Primer extension analysis identified four transcription start sites which are close together. The promoter sequence showed high G/C content (65%) and contained several consensus binding motifs for transcription factors including Sp-1 and the glucocorticoid receptor. There are stretches of sequences similar to the promoter region of both the type-II collagen and link protein genes. These sequences may be important for cartilage gene expression.