Metalloproteinases from rabbit bone culture medium degrade types IV and V collagens, laminin and fibronectin.

Gel-filtration chromatography of culture medium from rabbit bone explants separates three latent metalloproteinases with activities against collagen, proteoglycan and gelatin respectively. The fractions degrading proteoglycan also degrade laminin, fibronectin and the polymeric products of pepsin-solubilized type IV collagen and can also solubilize insoluble type IV collagen. The fractions degrading gelatin are capable of degrading solubilized type V and 1 alpha,2 alpha,3 alpha (cartilage) collagens, as well as the lower-molecular-weight products of pepsin-solubilized type IV collagen. All activities can be inhibited by 1,10-phenanthroline and occur in either partially or totally latent forms that can be activated by 4-aminophenylmercuric acetate.     

Stimulation of proteoglycan biosynthesis by serum and insulin-like growth factor-I in cultured bovine articular cartilage.

The addition of foetal calf serum to explant cultures of adult bovine articular cartilage is known to stimulate proteoglycan synthesis in a dose-dependent manner. We have now shown the activity in serum responsible for this effect to be heat- and acid-stable, to be associated with a high-Mr complex in normal serum but converted to a low-Mr form under acid conditions. The activity has an apparent Mr approximately 10,000 and isoelectric points similar to those reported for insulin-like growth factors (IGFs). Addition of a monoclonal antibody against insulin-like growth factor-I (IGF-I) prevented foetal calf serum from stimulating proteoglycan synthesis. Physiological concentrations of recombinant IGF-I or pharmacological levels of insulin when added to cartilage cultures mimicked the proteoglycan-stimulatory activity of serum. IGF-I appeared to act by increasing the rate of proteoglycan synthesis and did not change the nature of the proteoglycan synthesized nor the rate of proteoglycan catabolism by the tissue, suggesting that IGF-I may be important in the regulation of proteoglycan metabolism in adult articular cartilage. Furthermore, IGF-I can replace foetal calf serum in the culture medium, thereby allowing the use of a fully-defined medium which will maintain the synthesis and tissue levels of proteoglycan in adult articular cartilage explants for up to 5 days.     

Does protein kinase R mediate TNF-alpha- and ceramide-induced increases in expression and activation of matrix metalloproteinases in articular cartilage by a novel mechanism?

We investigated the role of the proinflammatory cytokine TNF-alpha, the second messenger C2-ceramide, and protein kinase R (PKR) in bovine articular cartilage degradation. Bovine articular cartilage explants were stimulated with C2-ceramide or TNF-alpha for 24 hours. To inhibit the activation of PKR, 2-aminopurine was added to duplicate cultures. Matrix metalloproteinase (MMP) expression and activation in the medium were analysed by gelatin zymography, proteoglycan release by the dimethylmethylene blue assay, and cell viability by the Cytotox 96(R) assay. C2-ceramide treatment of cartilage explants resulted in a significant release of both pro- and active MMP-2 into the medium. Small increases were also seen with TNF-alpha treatment. Incubation of explants with 2-aminopurine before TNF-alpha or C2-ceramide treatment resulted in a marked reduction in expression and activation of both MMP-2 and MMP-9. TNF-alpha and C2-ceramide significantly increased proteoglycan release into the medium, which was also inhibited by cotreatment with 2-aminopurine. A loss of cell viability was observed when explants were treated with TNF-alpha and C2-ceramide, which was found to be regulated by PKR. We have shown that C2-ceramide and TNF-alpha treatment of articular cartilage result in the increased synthesis and activation of MMPs, increased release of proteoglycan, and increased cell death. These effects are abrogated by treatment with the PKR inhibitor 2-aminopurine. Collectively, these results suggest a novel role for PKR in the synthesis and activation of MMPs and support our hypothesis that PKR and its activator, PACT, are implicated in the cartilage degradation that occurs in arthritic disease.     

A tissue-culture model of cartilage breakdown in rheumatoid arthritis. Quantitative aspects of proteoglycan release

1. The destruction of articular cartilage in human rheumatoid and other arthritides is the result of diverse mechanical, inflammatory and local cellular factors. A tissue-culture model for studying cartilage-synovial interactions that may be involved in the final common pathway of joint destruction is described. 2. Matrix breakdown was studied in vitro by using bovine nasal-cartilage discs cultivated in contact with synovium. Synovia were obtained from human and animal sources. Human tissue came from patients with ;classical' rheumatoid arthritis, and animal tissue from rabbits with antigen-induced arthritis. 3. Cartilage discs increased their proteoglycan content 2-3-fold during 8 days in culture. Proteoglycan was also released into culture medium, approx. 70% arising from cartilage breakdown. 4. Synovial explants from human rheumatoid and rabbit antigen-induced arthritis produced equivalent stimulation of proteoglycan release. After an initial lag phase, the breakdown rate rose abruptly to a maximum, resulting in a 2-fold increase of proteoglycan accumulation in culture medium after 8-10 days. 5. High-molecular-weight products shed into culture media were characterized chromatographically and by differential enzymic digestion. Proteoglycan-chondroitin sulphate accounted for 90% of the released polyanion, and its partial degradation in the presence of synovial explants was consistent with limited proteolytic cleavage. 6. Rheumatoid synovium applied to dead cartilage increased the basal rate of proteoglycan release. Living cartilage was capable of more extensive autolysis, even in the absence of synovium. However, optimal proteoglycan release required the interaction of living synovium with live cartilage. These findings support the view that a significant component of cartilage breakdown may be chondrocyte-mediated.     

Influence of the pericellular environment on the cells. The role of mucopolysaccharides in the protection of cartilage cells against immune reactions.

Problems related to rheumatoid arthritis have been investigated by a group at Cambridge using the organ culture technique. Since auto-allergic reactions may be concerned in the chronicity of the disease, the effects of reactive complement-sufficient antisera (AS+C') on embryonic and post-foetal cartilage were examined. The cartilaginous limb bone rudiments enlarged to several times their original volume in control medium, but in the presence of AS+C' they gradually disintegrated, owing to the breakdown of the cartilage matrix; only the superficial cells of the enveloping soft connective tissue were killed, however. Provided breakdown had not advanced too far, the effects of AS+C' were reversible. It was not clear how AS+C' produced these changes, since cartilage matrix is impermeable to molecules as large as the immunoglobulins. To find whether there was a difference in permeability between embryonic and post-foetal cartilage, similar experiments were made on the articular cartilage of young pigs. AS+C' had no effect on pure articular cartilage, and it was shown immunohistochemically that IgG did not penetrate beyond the most superficial layer of cartilage. When, however, the explant was associated with soft connective tissue either as invading marrow or as an adjacent explant of synovium, the cartilage matrix was depleted of proteoglycan; IgG antibodies then entered the cartilage and reacted with the chondrocytes. After a lapse of 8-10 days, collagen also began to break down. If the degradation of collagen was not too extensive, the changes were reversible. Pure cartilage was depleted of proteoglycan by trypsinization and then cultivated in AS+C'. All the chondrocytes reacted with the IgG antibodies. The peripheral cells were killed, but those in the interior survived and rapidly secreted pericellular capsules rich in proteoglycan, which shielded them from further contact with antibodies. In other experiments, pure cartilage was associated with a synovial explant and cultivated in AS+C' for 10 days; this caused severe depletion of the matrix. The synovial tissue was then removed and the isolated cartilage cultured for a further 10 days in either AS+C' or control medium. If mainly proteoglycan had been lost during the primary culture period, breakdown did not continue in AS+C', and sometimes a little new matrix was regenerated, though less than in control medium; if, however, the collagen had been extensively degraded, breakdown continued even in control medium. It is suggested that in both the embryonic and post-foetal cartilage, degradation of the cartilage matrix was due to the enzymatic activity of the associated soft connective tissue which caused a loss first of proteoglycan, which enabled antibodies to reach the chondrocytes, and then of collagen. The possible relevance of these results to the pathogenesis of rheumatoid arthritis is discussed.     

Regulation of immature cartilage growth by IGF-I,TGF-<Emphasis Type="Italic">β</Emphasis>1, BMP-7, and PDGF-AB: role of metabolic balance between fixed charge and collagen network

Cartilage growth may involve alterations in the balance between the swelling tendency of proteoglycans and the restraining function of the collagen network. Growth factors, including IGF-I, TGF-beta1, BMP-7, and PDGF-AB, regulate chondrocyte metabolism and, consequently, may regulate cartilage growth. Immature bovine articular cartilage explants from the superficial and middle zones were incubated for 13 days in basal medium or medium supplemented with serum, IGF-I, TGF-beta1, BMP-7, or PDGF-AB. Variations in tissue size, accumulation of proteoglycan and collagen, and tensile properties were assessed. The inclusion of serum, IGF-I, or BMP-7 resulted in expansive tissue growth, stimulation of proteoglycan deposition but not of collagen, and a diminution of tensile integrity. The regulation of cartilage metabolism by TGF-beta1 resulted in tissue homeostasis, with maintenance of size, composition, and function. Incubation in basal medium or with PDGF-AB resulted in small volumetric and compositional changes, but a marked decrease in tensile integrity. These results demonstrate that the phenotype of cartilage growth, and the associated balance between proteoglycan content and integrity of the collagen network, is regulated differentially by certain growth factors.     

Mechanical and biochemical characterization of cartilage explants in serum-free culture

Allografts of articular cartilage are both used clinically for tissue-transplantation procedures and experimentally as model systems to study the physiological behavior of chondrocytes in their native extracellular matrix. Long-term maintenance of allograft tissue is challenging. Chemical mediators in poorly defined culture media can stimulate cells to quickly degrade their surrounding extracellular matrix. This is particularly true of juvenile cartilage which is generally more responsive to chemical stimuli than mature tissue. By carefully modulating the culture media, however, it may be possible to preserve allograft tissue over the long-term while maintaining its original mechanical and biochemical properties. In this study juvenile bovine cartilage explants (both chondral and osteochondral) were cultured in both chemically defined medium and serum-supplemented medium for up to 6 weeks. The mechanical properties and biochemical content of explants cultured in chemically defined medium were enhanced after 2 weeks in culture and thereafter remained stable with no loss of cell viability. In contrast, the mechanical properties of explants in serum-supplemented medium were degraded by ( approximately 70%) along with a concurrent loss of biochemical content (30-40% GAG). These results suggest that long-term maintenance of allografts can be extended significantly by the use of a chemically defined medium.     

The effect of retinoic acid on proteoglycan turnover in bovine articular cartilage cultures

This paper describes proteoglycan catabolism by adult bovine articular cartilage treated with retinoic acid as a means of stimulating the loss of this macromolecule from the extracellular matrix of cartilage. Addition of retinoic acid (10(-12)-10(-6) M) to adult bovine articular cartilage which had been labeled with [35S]sulfate for 6 h after 5 days in culture, resulted in a dose-dependent increase in the rate of loss of 35S-labeled proteoglycans from the matrix of the tissue. Concomitant with this loss was a decrease in the proteoglycan content of the tissue. Incubation of cultures treated with 1 microM retinoic acid, at 4 degrees C, or with 0.5 mM cycloheximide, resulted in a significant decrease in the rate of retinoic acid-induced loss of proteoglycans and demonstrated cellular involvement in this process. Analysis of the 35S-labeled proteoglycans remaining in the matrix showed that the percentage of radioactivity associated with the small proteoglycan species extracted from the matrix of articular cartilage explants labeled with [35S]sulfate after 5 days in culture was 15% and this increased to 22% in tissue maintained in medium alone. In tissue treated with 1 microM retinoic acid for 6 days, the percentage of radioactivity associated with the small proteoglycan was 58%. Approximately 93% of the 35S-labeled proteoglycans released into the medium of control and retinoic acid-treated cultures was recovered in high density fractions after CsCl gradient centrifugation and eluted on Sepharose CL-2B as a broad peak with a Kav of 0.30-0.37. Less than 17% of these proteoglycans was capable of aggregating with hyaluronate. These results indicate that in both control and retinoic acid-treated cultures the larger proteoglycan species is lost to the medium at a greater rate than the small proteoglycan species. The effect of retinoic acid on proteoglycan turnover was shown to be reversible. Cartilage cultures maintained with retinoic acid for 1 day then switched to medium with 20% (v/v) fetal calf serum for the remainder of the culture period exhibited decreased rates of loss of 35S-labeled proteoglycans from the matrix and increased tissue hexuronate contents to levels near those observed in tissue maintained in medium with 20% (v/v) fetal calf serum throughout. Furthermore, following switching to 20% (v/v) fetal calf serum, the relative proportions of the 35S-labeled proteoglycan species remaining in the matrix of these cultures were similar to those of control cultures.     

Comparisons of antibody reactivity and enzyme sensitivity between small proteoglycans from bovine tendon, bone, and cartilage

Preparations of small proteoglycans from bovine tendon, bone, and cartilage have been compared for sensitivity to various enzymes and reactivity with different polyclonal antibodies. Chondroitinase ABC digestion of all proteoglycans generated a core protein preparation that migrated similarly in sodium dodecyl sulfate-polyacrylamide electrophoresis as a doublet band with Mr approximately equal to 45,000. The small proteoglycans of cartilage were divided into two populations based upon electrophoretic migration of the intact molecules (Rosenberg, L. C., Choi, H. U., Tank, L-H., Johnson, T. L., Pal, S., Webber, C., Reiner, A., and Poole, A. R. (1985) J. Biol. Chem. 260, 6304-6313). The core preparations of tendon, bone, and the faster-migrating (PG II) proteoglycans of cartilage all interacted in Western blot/enzyme-linked immunosorbent assay analysis with polyclonal antibody raised against either the tendon or bone proteoglycans. The slower-migrating (PG I) proteoglycans of cartilage did not react with these antibodies. Digestion of the tendon small proteoglycan with Staphylococcus aureus V8 protease released glycosaminoglycan chains from the molecule and generated a 40-kDa protein fragment that was resistant to further rapid degradation by the enzyme. This large digestion fragment was also prominent following V8 protease digestion of the faster-migrating (PG II) population of small cartilage proteoglycans, but not the small proteoglycan of bone. The N-terminal amino acid sequence of the tendon (PG II) proteoglycan was determined. These observations provide additional evidence for heterogeneity among the chemically similar small proteoglycans from different tissues.     

Does protein kinase R mediate TNF-α- and ceramide-induced increases in expression and activation of matrix metalloproteinases in articular cartilage by a novel mechanism?

We investigated the role of the proinflammatory cytokine TNF-α, the second messenger C₂-ceramide, and protein kinase R (PKR) in bovine articular cartilage degradation. Bovine articular cartilage explants were stimulated with C₂-ceramide or TNF-α for 24 hours. To inhibit the activation of PKR, 2-aminopurine was added to duplicate cultures. Matrix metalloproteinase (MMP) expression and activation in the medium were analysed by gelatin zymography, proteoglycan release by the dimethylmethylene blue assay, and cell viability by the Cytotox 96^® assay. C₂-ceramide treatment of cartilage explants resulted in a significant release of both pro- and active MMP-2 into the medium. Small increases were also seen with TNF-α treatment. Incubation of explants with 2-aminopurine before TNF-α or C₂-ceramide treatment resulted in a marked reduction in expression and activation of both MMP-2 and MMP-9. TNF-α and C₂-ceramide significantly increased proteoglycan release into the medium, which was also inhibited by cotreatment with 2-aminopurine. A loss of cell viability was observed when explants were treated with TNF-α and C₂-ceramide, which was found to be regulated by PKR. We have shown that C₂-ceramide and TNF-α treatment of articular cartilage result in the increased synthesis and activation of MMPs, increased release of proteoglycan, and increased cell death. These effects are abrogated by treatment with the PKR inhibitor 2-aminopurine. Collectively, these results suggest a novel role for PKR in the synthesis and activation of MMPs and support our hypothesis that PKR and its activator, PACT, are implicated in the cartilage degradation that occurs in arthritic disease.     

IL-17 derived from juxta-articular bone and synovium contributes to joint degradation in rheumatoid arthritis

The origin and role of IL-17, a T-cell derived cytokine, in cartilage and bone destruction during rheumatoid arthritis (RA) remain to be clarified. In human ex vivo models, addition of IL-17 enhanced IL-6 production and collagen destruction, and inhibited collagen synthesis by RA synovium explants. On mouse cartilage, IL-17 enhanced cartilage proteoglycan loss and inhibited its synthesis. On human RA bone explants, IL-17 also increased bone resorption and decreased formation. Addition of IL-1 in these conditions increased the effect of IL-17. Blocking of bone-derived endogenous IL-17 with specific inhibitors resulted in a protective inhibition of bone destruction. Conversely, intra-articular administration of IL-17 into a normal mouse joint induced cartilage degradation. In conclusion, the contribution of IL-17 derived from synovium and bone marrow T cells to joint destruction suggests the control of IL-17 for the treatment of RA.     

Passive loss of proteoglycan from articular cartilage explants

The addition of proteinase inhibitors (1 mM phenylmethylsulfonyl fluoride, 10 mM N-ethylmaleimide, 0.25 mM benzamidine hydrochloride, 6.25 mM EDTA, 12.5 mM 6-aminohexanoic acid and 2 mM iodoacetic acid) to explant cultures of adult bovine articular cartilage inhibits proteoglycan synthesis as well as the loss of the macromolecule from the tissue. Those proteoglycans lost to the medium of explant cultures treated with proteinase inhibitors were either aggregates or monomers with functional hyaluronic acid-binding regions, whereas proteoglycans lost from metabolically active tissue also included a population of monomers that were unable to aggregate with hyaluronate. Analysis of the core protein from proteoglycans lost into the medium of inhibitor-treated cultures showed the same size distribution as the core proteins of proteoglycans present in the extracellular matrix of metabolically active cultures. The core proteins of proteoglycans appearing in the medium of metabolically active cultures showed that proteolytic cleavage of these macromolecules occurred as a result of their loss from the tissue. Explant cultures of articular cartilage maintained in medium with proteinase inhibitors were used to investigate the passive loss of proteoglycan from the tissue. The rate of passive loss of proteoglycan from the tissue was dependent on surface area, but no difference in the proportion of proteoglycan aggregate to monomer appearing in the medium was observed. Furthermore, proteoglycans were lost at the same rate from the articular and cut surfaces of cartilage. Proteoglycan aggregates and monomer were lost from articular cartilage over a period of time, which indicates that proteoglycans are free to move through the extracellular matrix of cartilage. The movement of proteoglycans out of the tissue was shown to be temperature dependent, but was different from the change of the viscosity of water with temperature, which indicates that the loss of proteoglycan was not solely due to diffusion. The activation energy for the loss of proteoglycans from articular cartilage was found to be similar to the binding energies for electrostatic and hydrogen bonds.     

Release of neutral proteinases from mononuclear phagocytes and synovial cells in response to cartilaginous wear particles in vitro

Cartilaginous wear particles were retrieved from synovial fluid aspirates of human diarthrodial joints and added to cultures of human or murine mononuclear phagocytes or human synovial cells. In each case, addition of the wear particles elevated the production of proteinases active at neutral pH against collagen, gelatin, azocasein and the synthetic pentapeptide phenylazobenzyloxycarbonyl-L-Pro-L-Leu-Gly-L-Pro-D-Arg. Synovial cells secreted more than five times as much collagenase as the same number of the other cells. All types of cell secreted significant quantities of enzymes active against the noncollagenous substrates. Mild treatment of the spent media with trypsin stimulated all of these enzymic activities. The spent culture media of synovial cells which had been exposed to cartilaginous wear particles released hydroxyproline and glycosaminoglycan from powdered cartilage, indicating the production of enzymes which degrade both the collagen and proteoglycan of the cartilaginous matrix. Cultures of mononuclear phagocytes, in contrast, while solubilizing chondroitin sulphate from cartilage, released very little hydroxyproline. The ability of wear particles to elicit these effects suggests a role for them in the pathogenesis of oesteoarthritis and other types of joint deterioration.     

Loading-induced changes in synovial fluid affect cartilage metabolism

The object of this study was to determine whether changes in the synovial fluid (SF) induced by in vivo loading can alter the metabolic activity of chondrocytes in vitro, and, if so, whether insulin-like growth factor-I (IGF-I) is responsible for this effect. Therefore, SF was collected from ponies after a period of box rest and after they had been exercised for a week. Normal, unloaded articular cartilage explants were cultured in 20% solutions of these SFs for 4 days and chondrocyte bioactivity was determined by glycosaminoglycan (GAG) turnover (i.e., the incorporation of 35SO4 into GAG and the release of GAG into the medium). Furthermore, the extent to which the bioactivity is IGF-I-dependent was determined in a cartilage explant culture in 20% SF, in the presence and absence of anti-IGF-I antibodies. In explants cultured in post-exercise SF, GAG synthesis was enhanced and GAG release was diminished when compared to cultures in pre-exercise SF. SF analysis showed that IGF-I and IGFBP-3 levels were increased in post-exercise SF. There was a positive correlation between IGF-I levels and proteoglycan synthesis, but no correlation between IGF-I levels and proteoglycan release. Addition of anti-IGF-I antibodies significantly inhibited stimulation of proteoglycan synthesis in explants cultured in SF with 40%. However, there was no difference in inhibition of proteoglycan synthesis between pre- and post-exercise SF which indicated that the relative contribution of IGF-I in the stimulating effect of SF did not change. Proteoglycan release was not influenced by the presence of anti-IGF-I antibodies. It is concluded that chondrocyte metabolic activity is at least partially regulated by changes in the SF induced by in vivo loading. Exercise altered the SF in a way that it had a favourable effect on cartilage PG content by enhancing the PG synthesis and reducing the PG breakdown. IGF-I is an important contributor to the overall stimulating effect of SF on cartilage metabolism. It is, however, unlikely that IGF-I is the only mediator in the exercise-induced increase in this stimulating effect.     

Natural bovine osteogenin and recombinant human bone morphogenetic protein-2B are equipotent in the maintenance of proteoglycans in bovine articular cartilage explant cultures.

Osteogenin and related bone morphogenetic proteins are members of the transforming growth factor-beta superfamily, and were isolated by their ability to induce cartilage and bone formation in vivo. The influence of osteogenin, purified from bovine bone, and of recombinant human bone morphogenetic protein-2B (BMP-2B) has been examined in bovine articular cartilage explants. Both differentiation factors stimulated in a dose-dependent manner the synthesis of proteoglycans and decreased their rate of degradation. At a dose of 30 ng/ml, proteoglycan synthesis was increased to levels observed with either 20 ng/ml insulin-like growth factor I, 10 ng/ml transforming growth factor-beta, or 20% fetal bovine serum. This increase of biosynthetic rates above basal medium levels was observed in young, adolescent, and adult tissues. Analysis of the size of the newly synthesized proteoglycans, the glycosaminoglycan chain size, and the glycosaminoglycan type of explants treated with osteogenin or BMP-2B were very comparable to each other, and to proteoglycans isolated from cartilage treated with either insulin-like growth factor I or fetal bovine serum. These results demonstrate that osteogenin and BMP-2B alone are capable of stimulating and maintaining the chondrocyte phenotype in vitro.     

IL-6 and its soluble receptor augment aggrecanase-mediated proteoglycan catabolism in articular cartilage.

Elevated concentrations of interleukin-6 (IL-6) and soluble IL-6 receptor (sIL-6R) in the synovial fluids and serum of patients with arthritis have been implicated in the joint tissue destruction associated with these conditions, however studies conducted to date on the role and effects of IL-6 in the process of cartilage proteoglycan (aggrecan) catabolism are disparate. In the present study, bovine articular cartilage explants were maintained in a model organ culture system in the presence or absence of IL-1alpha or TNF-alpha, and under co-stimulation with or without IL-6 and/or sIL-6R. After measuring proteoglycan loss from the explants, the proteolytic activity and expression profiles of aggrecanase(s) was assessed for each culture condition. Stimulation of cartilage explants with IL-6 and/or sIL-6R potentiated aggrecan catabolism and release above that seen in the presence of IL-1alpha or TNF-alpha alone. This catabolism was associated with aggrecanase (but not MMP) activity, with correlative mRNA expression for aggrecanase-2.     

Characterization of catabolin, the major product of pig synovial tissue that induces resorption of cartilage proteoglycan in vitro

1. Pig synovium in organ culture produces material which induces living cartilage to resorb its proteoglycan in vitro. 2. The bioassay for this material was to measure glycosaminoglycan released from explants of bovine nasal-septal cartilage cultured for 8 days. The performance of the assay was greatly improved by adding cortisol succinate (0.1μg/ml). This decreased the release of glycosaminoglycan from unstimulated cartilage without inhibiting its response to catabolic factors from the synovium. 3. By using this improved assay it was shown that 90% of the active materials in synovial culture medium were retained by dialysis membrane. 4. An active protein was partially purified from synovial culture medium by (NH₄)₂SO₄ precipitation, ion-exchange chromatography, gel filtration and preparative isoelectric focusing. 5. This protein, called catabolin, had mol.wt. 17000 and pI4.6. 6. Synovial culture medium concentrated in dialysis tubing was subjected to gel chromatography and found to contain one major active component, which was eluted at the same position as the partially purified catabolin. 7. The synovial culture medium was not inactivated by heating (70°C for 10min), nor were diluted preparations of partially purified catabolin, but concentrated crude preparations were thermolabile. 8. These results suggest that catabolin is the major substance produced by the synovial tissue in culture which induces resorption of proteoglycan of living cartilage in vitro. 9. Other cultured soft connective tissues produced catabolin-like activity. The example of sclera is shown, and production was inhibited by cortisol succinate (0.1μg/ml). 10. It is suggested that catabolin may be a general product of soft connective tissues in culture, and its physiological function may be to induce resorption of connective-tissue matrix after injury.     

The extracellular processing and catabolism of hyaluronan in cultured adult articular cartilage explants.

Hyaluronan was shown to have the same turnover time as aggrecan in explant cultures of adult bovine articular cartilage. Inclusion of fetal calf serum in the culture medium resulted in a similar decrease in the rate of catabolism of both hyaluronan and proteoglycan. Less than 9% of the hyaluronan lost from the explants in the course of the experiment was recovered from the culture medium as hyaluronan, suggesting that the catabolism of hyaluronan involves the uptake of this glycosaminoglycan by the chondrocytes. Analysis of the molecular size of the newly synthesized hyaluronan in these cultures showed that the hyaluronan was initially synthesized as large macromolecules that were gradually depolymerized with time within the extracellular matrix. The resulting size distribution of newly synthesized hyaluronan molecules after 12 days in culture was similar to that determined for the endogenous hyaluronan. The kinetics of depolymerization of the newly synthesized hyaluronan was consistent with a random fragmentation of the macromolecule. The rate constants for the depolymerization of hyaluronan indicate that oxygen-derived radicals may be involved in the fragmentation of this macromolecule. Inclusion of either cycloheximide or proteinase inhibitors in the medium of the explant cultures resulted in a marked decrease in the rate of loss of hyaluronan from the tissue and in the inhibition of the depolymerization of the newly synthesized macromolecule. This suggests that both the catabolism and the depolymerization of hyaluronan are cell mediated and depend on metabolically active cells.     

Degradation of cartilage matrix proteoglycan by human neutrophils involves both elastase and cathepsin G

The granule proteases of human neutrophils are thought to be responsible for the connective tissue destruction associated with certain inflammatory diseases. Using a model system for the degradation of a macromolecular connective tissue substrate, purified neutrophil elastase and cathepsin G were both individually able to degrade cartilage matrix proteoglycan and this degradation was blocked by the appropriate specific inhibitors. Neutrophil granule lysate also produced cartilage matrix degradation but little inhibition of degradation occurred when either elastase or cathepsin G inhibitor was used alone. However, a combination of elastase and cathepsin G inhibitors each at 100 microM or each at 10 microM blocked cartilage matrix degradation by 89% +/- 1 and 65% +/- 9 (mean +/- SEM, n = 3), respectively. The magnitude of the cartilage degradation mediated by neutrophil lysate, and its sensitivity to specific inhibitors, was reproduced using purified elastase and cathepsin G at the concentrations at which they are present in neutrophil lysate. Human neutrophils stimulated with opsonized zymosan degraded cartilage matrix in a dose-dependent manner in the presence of serum antiproteases. Supernatants from stimulated neutrophils cultured in the presence of serum did not degrade cartilage matrix, indicating that neutrophil mediated degradation in the presence of serum was confined to the protected subjacent region between the inflammatory cell and the substratum. A combination of elastase and cathepsin G inhibitors each at 500 microM or each at 100 microM blocked subjacent cartilage matrix degradation by stimulated human neutrophils by 91% +/- 3 and 54% +/- 8 (mean +/- SEM, n = 5), respectively, whereas either the elastase or cathepsin G inhibitor alone was much less effective. These studies demonstrate that neutrophil-mediated cartilage matrix degradation is produced primarily by elastase and cathepsin G. Furthermore, these results support the hypothesis that inflammatory neutrophils form zones of close contact with substratum that exclude serum antiproteases and that this subjacent degradation of cartilage matrix by stimulated neutrophils can be blocked by a combination of synthetic elastase and cathepsin G inhibitors.     

Degradation of connective tissue proteins by serine proteases from Streptococcus pneumoniae.

The proteolytic activity of pneumococcal culture supernatants was investigated. Phenylmethylsulfonyl fluoride and diisopropylfluorophosphate inhibited the proteolytic activity by 94% indicating that the enzymes are serine proteases. Zymogram analysis with inhibitors utilizing a non-denaturing gelatin substrate gel revealed two classes of serine proteases; one sensitive to calcium chelators and one resistant. Enzymes from the culture supernatant cleaved fibronectin, fibrinogen, elastin, and laminin; whereas bovine albumin, and the human immunoglobulins, IgG, IgM, and IgA, were not cleaved. These results indicate that pneumococci produce previously unrecognized serine proteases that degrade several tissue and blood proteins.