Interglobular Domain Research Articles

Gene expression and matrix proteinase activity in osteochondrosis dessicans

Introduction Osteochondrosis dessicans (OCD) is a disorder of unknown aetiology where often a fragment of cartilage and subchondral bone separates from the articular surface. Previous studies have shown histological changes in glycosaminoglycan content in OCD cartilage compared to normal cartilage (Koch et al. 1997). It has also been shown in equine OCD cartilage that there is excessive degradation of type‐II collagen compared to normal cartilage (Laverty et al. 2002). The present study was undertaken to examine the gene expression in human OCD cartilage compared to its normal autologous articular cartilage and human osteoarthritic (OA) cartilage.Methods Cartilage from five OCD patients (18–34 years) was obtained at the time of surgery. Pieces of cartilage were either snap‐frozen (in preparation for RNA isolation) or the proteoglycans extracted with 4 m GuHCl. Total RNA was isolated from the cartilage using RNeasy minicolumns and reagents (Qiagen) according to the manufacturer's protocol. RT‐PCR was performed using an RNA PCR kit (Perkin‐Elmer) using a number of oligonucleotide primers. GuHCl‐extracted proteoglycan fragments were analysed using Western blotting with a number of antibodies to aggrecan metabolites, collagen metabolites and the small leucine‐rich proteoglycans.Results and discussion When OCD cartilage was compared to normal and human OA cartilage, there was an increase in aggrecan, collagen type‐II and collagen type‐X RNA expression. There was no change in RNA expression of link protein or type‐I collagen. The RNA expression of the aggrecanases (ADAMTS enzymes) was also different in the three different cartilage samples. Neither ADAMTS‐1, ‐4 or ‐5 was present in the normal cartilage. In contrast, in the OCD cartilage, there was expression of both ADAMTS‐1 and ‐4, whereas in the OA cartilage, there was expression of ADAMTS‐4 and ‐5. In the case of MMP RNA expression, MMP‐3 was decreased and MMP‐13 increased in OCD cartilage compared to both normal and OA samples. In addition, the expression of all three TIMP isoforms was increased in the OCD cartilage. Although inflammatory components are not expected in OCD pathology, expressions of inflammatory mediators such as COX‐2, IL‐1‐α and TNF‐α were all increased in the OCD cartilage when compared to normal, but expression of these mRNAs in the OA cartilage was higher. Analysis of proteoglycan fragments in the OCD cartilage by Western blotting showed the presence of aggrecan fragments containing the G1 domain, interglobular domain and the C‐terminal neoepitope generated by aggrecanase cleavage. There was also immunoreactivity for biglycan and link protein.Conclusion These results suggest that the phenotypic expression of chondrocytes at the site of the OCD lesion are markedly different from ‘normal’ articular cartilage and also pathological OA cartilage. Interestingly, the expression patterns of matrix proteinases and their natural inhibitors were also markedly different in OCD cartilage, again suggesting that there are specific biochemical expression patterns in OCD pathology, which may potentially be biomarkers of the disease process. Further studies are necessary to elucidate how the differences in gene expression and matrix protease activity may be involved in the aetiology of OCD.

Variations in aggrecan structure modulate its susceptibility to aggrecanases.

Proteoglycan aggregates and purified aggrecan from adult and fetal bovine cartilage and adult and neonatal human cartilage were subjected to in vitro degradation by recombinant aggrecanase-1 and aggrecanase-2. The ability of the aggrecanases to cleave within the aggrecan IGD (interglobular domain) and CS2 domain (chondroitin sulphate-rich domain 2) was monitored by SDS/PAGE and immunoblotting. Aggrecanase-2 showed a similar ability to cleave within the IGD of adult and immature aggrecan, whereas aggrecanase-1 was less efficient in cleavage in the IGD of immature aggrecan, for both the bovine and the human substrates. Both aggrecanases showed a similar ability to cleave within the CS2 domain of bovine aggrecan irrespective of age, but showed a much lower ability to cleave within the CS2 domain of human aggrecan. Equivalent results were obtained whether aggrecan was present in isolation or as part of proteoglycan aggregates. When proteoglycan aggregates were used, neither aggrecanase was able to cleave link protein. Thus, for aggrecan cleavage by aggrecanases, variations in cleavage efficiency exist with respect to the species and age of the animal from which the aggrecan is derived and the type of aggrecanase being used.

Thyroid hormone enhances aggrecanase-2/ADAM-TS5 expression and proteoglycan degradation in growth plate cartilage.

Effects of thyroid hormone on proteoglycan degradation in various regions of cartilage were investigated. In propylthiouracil-treated rats with hypothyroidism, proteoglycan degradation in epiphyseal cartilage during endochondral ossification was markedly suppressed. However, injections of T(4) reversed this effect of propylthiouracil on proteoglycan degradation. In pig growth plate explants, T(3) also induced breakdown of proteoglycan. T(3) increased the release of aggrecan monomer and core protein from the explants into the medium. Accordingly, the level of aggrecan monomer remaining in the tissue decreased after T(3) treatment, and the monomer lost hyaluronic acid-binding capacity, suggesting that the cleavage site is in the interglobular domain. The aggrecan fragment released from the T(3)-exposed explants underwent cleavage at Glu(373)-Ala(374), the major aggrecanase-cleavage site. The stimulation of proteoglycan degradation by T(3) was less prominent in resting cartilage explants than in growth plate explants and was barely detectable in articular cartilage explants. Using rabbit growth plate chondrocyte cultures, we explored proteases that may be involved in T(3)-induced aggrecan degradation and found that T(3) enhanced the expression of aggrecanase-2/ADAM-TS5 (a disintegrin and a metalloproteinase domain with thrombospondin type I domains) mRNA, whereas we could not detect any enhancement of stromelysin, gelatinase, or collagenase activities or any aggrecanase-1/ADAM-TS4 mRNA expression. We also found that the aggrecanse-2 mRNA level, but not aggrecanase-1, increased at the hypertrophic stage during endochondral ossification. These findings suggest that aggrecanse-2/ADAM-TS5 is involved in aggrecan breakdown during endochondral ossification, and that thyroid hormone stimulates the aggrecan breakdown partly via the enhancement of aggrecanase-2/ADAM-TS5.

Cleavage site specificity of cathepsin K toward cartilage proteoglycans and protease complex formation.

Cathepsin K is a potent extracellular matrix-degrading protease that requires interactions with soluble glycosaminolycans for its collagenolytic activity in bone and cartilage. The major sources of glycosaminoglycans in cartilage are aggrecan aggregates. Therefore, we investigated whether cathepsin K activity is capable to hydrolyze aggrecan into fragments allowing the formation of glycosaminoglycan-cathepsin K complexes and determined the cleavage site specificity of cathepsin K toward the cartilage-resident link protein and aggrecan. The cleavage site specificity was compared with those of cathepsins S and L. All three cathepsins released glycosaminoglycans from native bovine cartilage at lysosomal pH and to a lesser degree at neutral extracellular pH. Cathepsin-predigested aggrecan complexes and cartilage provided suitable glycosaminoglycan fragments that allowed the formation of collagenolytically active cathepsin K complexes. A detailed analysis of the degradation of aggrecan aggregates revealed two cathepsin K cleavage sites in the link protein and several sites in aggrecan, including one site within the interglobular domain E1. In summary, these results demonstrate that cathepsin K is capable to degrade aggrecan complexes at specific cleavage sites and that cathepsin K activity alone is sufficient to self-provide the glycosaminoglycan fragments required for the formation of its collagenolytically active complex.

Measurement of aggrecanase-generated interglobular domain catabolites in the medium and extracts of cartilage explants using Western blot analysis.

Cartilage explant cultures and chondrocyte cultures have been routinely used to study the degradative mechanisms involved in joint destruction that lead to disease states such as osteoarthritis and rheumatoid arthritis. Stimulation of these culture systems with catabolic cytokines or chemical agents such as retinoic acid leads to an increase in the release of catabolites and enzymes into the culture medium. Detection of these catabolites using neoepitope antibodies can be used as indicators for the activity of degradative enzymes responsible for the breakdown of the tissue. Catabolites released include aggrecan interglobular domain (IGD) fragments, whereas enzymes include the aggrecanases (ADAMTS-4, TS-5, and-TS-1) as well as a number of matrix metalloproteinases. Monoclonal antibodies have been developed that specifically recognize the new N- and C-terminal amino acid sequences generated by aggrecanase cleavage of the IGD in aggrecan between 373E-374A (human sequence enumeration). These mouse monoclonal antibodies have been named BC-3 and BC-13 (1,2). BC-3 recognizes the new N-terminal sequence ARGSVIL... and BC-13 recognizes the new C-terminal...NITEGE in the IGD of aggrecan. These same amino acid sequences are not recognized in the intact molecule. Furthermore, the specific N- or C-terminal amino acid is essential for epitope recognition by these antibodies. Catabolites are separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and transferred to a nitrocellulose membrane, which are then immuno-blotted with either the N- or C-terminal neoepitope antibodies.

ADAMTS4 Cleaves at the Aggrecanase Site (Glu373-Ala374) and Secondarily at the Matrix Metalloproteinase Site (Asn341-Phe342) in the Aggrecan Interglobular Domain

Two major proteolytic cleavages, one at NITEGE(373)/A(374)RGSVI and the other at VDIPEN(341)/F(342)FGVGG, have been shown to occur in vivo within the interglobular domain of aggrecan. The Glu(373)-Ala(374) site is cleaved in vitro by aggrecanase-1 (ADAMTS4) and aggrecanase-2 (ADAMTS5), whereas the other site, at Asn(341)-Phe(342), is efficiently cleaved by matrix metalloproteinases (MMPs) and by cathepsin B at low pH. Accordingly, the presence of the cleavage products globular domain 1 (G1)-NITEGE(373) and G1-VDIPEN(341) in vivo has been widely interpreted as evidence for the specific involvement of ADAMTS enzymes and MMPs/cathepsin B, respectively, in aggrecan proteolysis in situ. We show here, in digests with native human aggrecan, that purified ADAMTS4 cleaves primarily at the Glu(373)-Ala(374) site, but also, albeit slowly and secondarily, at the Asn(341)-Phe(342) site. Cleavage at the Asn(341)-Phe(342) site in these incubations was due to bona fide ADAMTS4 activity (and not a contaminating MMP) because the cleavage was inhibited by TIMP-3 (a potent inhibitor of ADAMTS4), but not by TIMP-1 and TIMP-2, at concentrations that totally blocked MMP-3-mediated cleavage at this site. Digestion of recombinant human G1-G2 (wild-type and cleavage site mutants) confirmed the dual activity of ADAMTS4 and supported the idea that the enzyme cleaves primarily at the Glu(373)-Ala(374) site and secondarily generates G1-VDIPEN(341) by removal of the Phe(342)-Glu(373) peptide from G1-NITEGE(373). These results show that G1-VDIPEN(341) is a product of both MMP and ADAMTS4 activities and challenge the widely held assumption that this product represents a specific indicator of MMP- or cathepsin B-mediated aggrecan degradation.

ADAMTS1 cleaves aggrecan at multiple sites and is differentially inhibited by metalloproteinase inhibitors

ADAMTS1 is a secreted protein that belongs to the recently described ADAMTS (a disintegrin and metalloprotease with thrombospondin repeats) family of proteases. Evaluation of ADAMTS1 catalytic activity on a panel of extracellular matrix proteins showed a restrictive substrate specificity which includes some proteoglycans. Our results demonstrated that human ADAMTS1 cleaves aggrecan at a previously shown site by its mouse homolog, but we have also identified additional cleavage sites that ultimately confirm the classification of this protease as an `aggrecanase'. Specificity of ADAMTS1 activity was further verified when a point mutation in the zinc-binding domain abolished its catalytic effects, and latency conferred by the prodomain was also demonstrated using a furin cleavage site mutant. Suppression of ADAMTS1 activity was accomplished with a specific monoclonal antibody and some metalloprotease inhibitors, including tissue inhibitor of metalloproteinases 2 and 3. Finally, we developed an activity assay using an artificial peptide substrate based on the interglobular domain cleavage site (E 373–A) of rat aggrecan.

Matrix metalloproteinases are involved in C-terminal and interglobular domain processing of cartilage aggrecan in late stage cartilage degradation.

Monoclonal antibody (MAb) technology was used to examine aggrecan metabolites and the role of aggrecanases and matrix metalloproteinases (MMPs) in proteolysis of the interglobular domain (IGD) and C-terminus of aggrecan. An in vitro model of progressive cartilage degradation characterized by early proteoglycan loss and late stage collagen catabolism was evaluated in conjunction with a broad-spectrum inhibitor of MMPs. We have for the first time demonstrated that IGD cleavage by MMPs occurs during this late stage cartilage degeneration, both as a primary event in association with glycosaminoglycan (GAG) release from the tissue and secondarily in trimming of aggrecanase-generated G1 metabolites. Additionally, we have shown that MMPs were responsible for C-terminal catabolism of aggrecan and generation of chondroitin sulfate (CS) deficient aggrecan monomers and that this aggrecan truncation occurred prior to detectable IGD cleavage by MMPs. The onset of this later stage MMP activity was also evident by the generation of MMP-specific link protein catabolites in this model culture system. Recombinant MMP-1, -3 and -13 were all capable of C-terminally truncating aggrecan with at least two cleavage sites N-terminal to the CS attachment domains of aggrecan. Through analysis of aggrecan metabolites in pathological synovial fluids from human, canine and equine sources, we have demonstrated the presence of aggrecan catabolites that appear to have resulted from similar C-terminal processing of aggrecan as that induced in our in vitro culture systems. Finally, by developing a new MAb recognizing a linear epitope in the IGD of aggrecan, we have identified two novel aggrecan metabolites generated by an as yet unidentified proteolytic event. Collectively, these results suggest that C-terminal processing of aggrecan by MMPs may contribute to the depletion of cartilage GAG that leads to loss of tissue function in aging and disease. Furthermore, analysis of aggrecan metabolites resulting from both C-terminal and IGD cleavage by MMPs may prove useful in monitoring different stages in the progression of cartilage degeneration.

Cathepsin D cleaves aggrecan at unique sites within the interglobular domain and chondroitin sulfate attachment regions that are also cleaved when cartilage is maintained at acid pH.

Bovine aggrecan was digested with bovine cathepsin D at pH 5.2 under conditions of partial digestion and the resulting aggrecan core protein fragments were separated by electrophoresis on gradient polyacrylamide gels. The fragments were characterized by their reactivity to specific antibodies and by N-terminal amino acid sequencing. It was also demonstrated that cathepsin D cleaved bovine aggrecan at five sites within the core protein, between residues Phe(342)-Phe(343) in the interglobular domain, Leu(1462)-Val(1463) between the chondroitin sulfate attachment regions 1 and 2 and Leu(1654)-Val(1655), Phe(1754)-Val(1755) and Leu(1854)-Ile(1855) that are located within the chondroitin sulfate attachment region 2 of the core protein. The time course of digestion showed that there was a continued degradation of aggrecan and there was no preferential cleavage of the core protein at any one site. It was shown that cathepsin D digested aggrecan over the pH range 5.2-6.5 resulting in the same products. When bovine cartilage was maintained in explant culture at pH 5.2 there was a rapid loss of both radiolabeled and chemical pools of sulfated glycosaminoglycans into the culture medium and this loss was inhibited by the inclusion in the medium of the aspartic proteinase inhibitor, pepstatin A. The aggrecan core protein fragments appearing in the medium of cultures maintained at pH 5.2 were characterized and it was shown that the fragments had N-terminal sequences starting at Phe(343), Ile(1855), and Val(1755) or Val(1463). This work demonstrates that cathepsin D present within the extracellular matrix of articular cartilage has the potential to contribute to the proteolytic processing of the core protein of aggrecan in this tissue.

Anti-Inflammatory and Chondroprotective Effect of TSG-6 (Tumor Necrosis Factor-α-Stimulated Gene-6) in Murine Models of Experimental Arthritis

Tumor necrosis factor-alpha (TNF-alpha)-stimulated gene-6 (TSG-6) is up-regulated by various cytokines and growth factors. TSG-6 binds to hyaluronan in inflamed synovial tissue and forms a complex with a serine protease inter-alpha-trypsin inhibitor (IalphaI), increasing the protease inhibitory effect of IalphaI >100-fold. The TSG-6/IalphaI complex then blocks serine proteases, including the plasminogen-plasmin activation, probably the most important component in the activation processes of matrix metalloproteinases. To gain insight into the mechanisms of TSG-6 action in arthritis, we have used an autoimmune murine model (proteoglycan-induced arthritis) for systemic, and a monoarticular form of arthritis (antigen-induced arthritis) for local treatment of arthritis with recombinant mouse TSG-6 (rmTSG-6). Intravenous injection of rmTSG-6 induced a dramatic reduction of edema in acutely inflamed joints by immobilizing CD44-bound hyaluronan and, in long-term treatment, protected cartilage from degradation and blocked subchondral and periosteal bone erosion in inflamed joints. The intra-articular injection of a single dose (100 microg) of rmTSG-6 exhibited a strong chondroprotective effect for up to 5 to 7 days, preventing cartilage proteoglycan from metalloproteinase-induced degradation. In contrast, rmTSG-6 did not postpone the onset, nor reduce the incidence of arthritis. We were unable to detect any significant differences between control and rmTSG-6-treated animals when various serum markers (including pro- and anti-inflammatory cytokines, auto- and heteroantibody productions) or antigen-specific T-cell responses were compared, nor when the expressions of numerous cell surface receptors or adhesion molecules were measured. TSG-6 seems to play a critical negative regulatory feed-back function in inflammation, especially in arthritic processes.

Roles of aggrecan domains in biosynthesis, modification by glycosaminoglycans and product secretion

Aggrecan is a member of the chondroitin sulphate (CS) proteoglycan family, which also includes versican/PG-M, neurocan and brevican. Members of this family exhibit structural similarity: a G1 domain at the N-terminus and a G3 domain at the C-terminus, with a central sequence for modification by CS chains. A unique feature of aggrecan is the insertion of three additional domains, an inter-globular domain (IGD), a G2 domain and a keratan sulphate (KS) domain (sequence modified by KS chains), between the G1 domain and the CS domain (sequence modified by CS chains). The G1 and G3 domains have been implicated in product secretion, but G2, although structurally similar to the tandem repeats of G1, performs an unknown function. To define the functions of each aggrecan domain in product processing, we cloned and expressed these domains in various combinations in COS-7 cells. The results indicated that the G3 domain enhanced product secretion, alone or in combination with the KS or CS domain, and promoted glycosaminoglycan (GAG) chain attachment. Constructs containing the G1 domain were not secreted. Addition of a CS domain sequence to G1 reduced this inhibition, but GAG chain attachment was still decreased. The potential GAG chain attachment site in the IGD was occupied by GAGs, and IGD product was secreted efficiently. The KS domain was modified by GAG chains and secreted. Finally, the G2 domain was expressed but not secreted, and inhibited secretion of the IGD when expressed as an IGD–G2 combination.

Roles of aggrecan domains in biosynthesis, modification by glycosaminoglycans and product secretion.

Aggrecan is a member of the chondroitin sulphate (CS) proteoglycan family, which also includes versican/PG-M, neurocan and brevican. Members of this family exhibit structural similarity: a G1 domain at the N-terminus and a G3 domain at the C-terminus, with a central sequence for modification by CS chains. A unique feature of aggrecan is the insertion of three additional domains, an inter-globular domain (IGD), a G2 domain and a keratan sulphate (KS) domain (sequence modified by KS chains), between the G1 domain and the CS domain (sequence modified by CS chains). The G1 and G3 domains have been implicated in product secretion, but G2, although structurally similar to the tandem repeats of G1, performs an unknown function. To define the functions of each aggrecan domain in product processing, we cloned and expressed these domains in various combinations in COS-7 cells. The results indicated that the G3 domain enhanced product secretion, alone or in combination with the KS or CS domain, and promoted glycosaminoglycan (GAG) chain attachment. Constructs containing the G1 domain were not secreted. Addition of a CS domain sequence to G1 reduced this inhibition, but GAG chain attachment was still decreased. The potential GAG chain attachment site in the IGD was occupied by GAGs, and IGD product was secreted efficiently. The KS domain was modified by GAG chains and secreted. Finally, the G2 domain was expressed but not secreted, and inhibited secretion of the IGD when expressed as an IGD-G2 combination.

Age-related Changes in Aggrecan Glycosylation Affect Cleavage by Aggrecanase

Aggrecan degradation involves proteolytic cleavage of the core protein within the interglobular domain. Because aggrecan is highly glycosylated with chondroitin sulfate (CS) and keratan sulfate (KS), we investigated whether glycosylation affects digestion by aggrecanase at the Glu(373)-Ala(374) bond. Treatment of bovine aggrecan monomers to remove CS and KS resulted in loss of cleavage at this site, suggesting that glycosaminoglycans (GAGs) play a role in cleavage at the Glu(373)-Ala(374) bond. In contrast, MMP-3 cleavage at the Ser(341)-Phe(342) bond was not affected by glycosidase treatment of aggrecan. Removal of KS, but not CS, prevented cleavage at the Glu(373)-Ala(374) bond. Thus, KS residues may be important for recognition of this cleavage site by aggrecanase. KS glycosylation has been observed at sites adjacent to the Glu(373)-Ala(374) bond in steer aggrecan, but not in calf aggrecan (Barry, F. P., Rosenberg, L. C., Gaw, J. U., Gaw, J. U., Koob, T. J., and Neame, P. J. (1995) J. Biol. Chem. 270, 20516-20524). Interestingly, although we found that aggrecanase degraded both calf and steer cartilage aggrecan, the proportion of fragments generated by cleavage at the Glu(373)-Ala(374) bond was higher in steer than in calf, consistent with our observations using aggrecan treated to remove KS. We conclude that the GAG content of aggrecan influences the specificity of aggrecanase for cleavage at the Glu(373)-Ala(374) bond and suggest that age may be a factor in aggrecanase degradation of cartilage.

Truncation of the amino-terminus of the recombinant aggrecan rAgg1mut leads to reduced cleavage at the aggrecanase site. Efficient aggrecanase catabolism may depend on multiple substrate interactions.

Aggrecanase cleavage at the Glu(373)-Ala(374) site in the interglobular domain of the cartilage proteoglycan aggrecan is a key event in arthritic diseases. The observation that substrates representing only the aggrecanase cleavage site are not catabolized efficiently by aggrecanase prompted us to investigate the requirement of aggrecanase for additional structural elements of its substrate other than the actual cleavage site. Based on the recombinant substrate rAgg1mut we constructed deletion mutants with successively truncated N- or C-termini of the interglobular domain. Catabolism by aggrecanase activities induced in rat chondrosarcoma cells, porcine chondrocytes, and by human recombinant ADAMTS4 showed a gradually decreasing catabolism of progressively shortened, N-terminal deletion mutants of the substrate rAgg1mut. A reduction to 32 amino acids N-terminal to the aggrecanase site resulted in a decrease of at least 42% of aggrecanase cleavage products as compared with the wild-type substrate. When only 16 amino acids preceded the Glu(373)-Ala(374) site, aggrecanase cleavage was completely inhibited. In contrast, C-terminal deletions did not negatively affect aggrecanase cleavage up to the reduction to 13 amino acids C-terminal to the cleavage site. Unlike aggrecanase(s), membrane type 1-matrix metalloprotease (MT1-MMP), able to cleave rAgg1mut both at the aggrecanase and the MMP site, was insensitive to N-terminal deletions regarding aggrecanase cleavage, indicating that the importance of the N-terminus is characteristic for aggrecanase(s). Taken together, the results demonstrate that the amino-terminus of rAgg1mut, containing the MMP site, plays an important role for efficient cleavage by aggrecanase(s), possibly by serving as a further site of interaction between the enzyme and its substrate.

Mutations in the Interglobular Domain of Aggrecan Alter Matrix Metalloproteinase and Aggrecanase Cleavage Patterns: EVIDENCE THAT MATRIX METALLOPROTEINASE CLEAVAGE INTERFERES WITH AGGRECANASE ACTIVITY

We have expressed G1-G2 mutants with amino acid changes at the DIPEN(341) downward arrow(342)FFGVG and ITEGE(373) downward arrow(374)ARGSV cleavage sites, in order to investigate the relationship between matrix metalloproteinase (MMP) and aggrecanase activities in the interglobular domain (IGD) of aggrecan. The mutation DIPEN(341) to DIGSA(341) partially blocked cleavage by MMP-13 and MMP-8 at the MMP site, while the mutation (342)FFGVG to (342)GTRVG completely blocked cleavage at this site by MMP-1, -2, -3, -7, -8, -9, -13, -14. Each of the MMP cleavage site mutants, including a four-amino acid deletion mutant lacking residues ENFF(343), were efficiently cleaved by aggrecanase, suggesting that the primary sequence at the MMP site had no effect on aggrecanase activity in the IGD. The mutation (374)ARGSV to (374)NVYSV completely blocked cleavage at the aggrecanase site by aggrecanase, MMP-8 and atrolysin C but had no effect on the ability of MMP-8 and MMP-13 to cleave at the Asn(341) downward arrowPhe bond. Susceptibility to atrolysin C cleavage at the MMP site was conferred in the DIGSA(341) mutant but absent in the wild-type, (342)GTRVG, (374)NVYSV, and deletion mutants. To further explore the relationship between MMP and aggrecanase activities, sequential digest experiments were done in which MMP degradation products were subsequently digested with aggrecanase and vice versa. Aggrecanase-derived G1 domains with ITEGE(373) C termini were viable substrates for MMPs; however, MMP-derived G2 fragments were resistant to cleavage by aggrecanase. A 10-mer peptide FVDIPENFFG, which is a substrate analogue for the MMP cleavage site, inhibited aggrecanase cleavage at the Glu(373) downward arrowAla bond. This study demonstrates that MMPs and aggrecanase have unique substrate recognition in the IGD of aggrecan and suggests that sequences at the C terminus of the DIPEN(341) G1 domain may be important for regulating aggrecanase cleavage.

The intermediates of aggrecanase-dependent cleavage of aggrecan in rat chondrosarcoma cells treated with interleukin-1.

We have examined the abundance and structure of intermediates in the chondrocyte-mediated degradation of aggrecan by aggrecanase(s). Degradation products were identified by Western-blot analysis with antibodies to cleavage-site neoepitopes and to peptides within the globular domains. Rat chondrosarcoma tumour contained full-length aggrecan and all of the individual peptides expected from single independent cleavages at each of the four aggrecanase sites in the chondroitin sulphate (CS) domain. Kinetic analysis of the products present in rat chondrosarcoma cell cultures treated with interleukin-1b showed that the first aggrecanase-mediated cleavages occurred at the four sites within the CS attachment region to generate two stable intermediates, Val(1)-Glu(1459) and Val(1)-Glu(1274). These species were subsequently cleaved at the Glu(373) site in the interglobular domain to form the terminal products, Val(1)-Glu(373), Ala(374)-Glu(1274) and Ala(374)-Glu(1459). It therefore appears that the aggrecanase-mediated processing of native aggrecan by chondrocytes in situ is initiated within the CS-attachment region and completed by cleavage within the interglobular domain. Since it has been shown that digestion of aggrecan monomer in solution with recombinant ADAMTS-4 [Tortorella, Pratta, Liu, Austin, Ross, Abbaszade, Burn and Arner (2000) Sites of aggrecan cleavage by recombinant human aggrecanase-1 (ADAMTS-4). J. Biol. Chem. 275, 18566-18573] exhibits similar kinetics, it appears that preferential proteinase cleavage in the CS-rich region is determined by properties inherent in the aggrecan monomer itself, such as preferred peptide sequences for enzyme binding or enhanced accessibility to the core protein at these sites.

The intermediates of aggrecanase-dependent cleavage of aggrecan in rat chondrosarcoma cells treated with interleukin-1

We have examined the abundance and structure of intermediates in the chondrocyte-mediated degradation of aggrecan by aggrecanase(s). Degradation products were identified by Western-blot analysis with antibodies to cleavage-site neoepitopes and to peptides within the globular domains. Rat chondrosarcoma tumour contained full-length aggrecan and all of the individual peptides expected from single independent cleavages at each of the four aggrecanase sites in the chondroitin sulphate (CS) domain. Kinetic analysis of the products present in rat chondrosarcoma cell cultures treated with interleukin-1b showed that the first aggrecanase-mediated cleavages occurred at the four sites within the CS attachment region to generate two stable intermediates, Val1–Glu1459 and Val1–Glu1274. These species were subsequently cleaved at the Glu373 site in the interglobular domain to form the terminal products, Val1–Glu373, Ala374–Glu1274 and Ala374–Glu1459. It therefore appears that the aggrecanase-mediated processing of native aggrecan by chondrocytes insitu is initiated within the CS-attachment region and completed by cleavage within the interglobular domain. Since it has been shown that digestion of aggrecan monomer in solution with recombinant ADAMTS-4 [Tortorella, Pratta, Liu, Austin, Ross, Abbaszade, Burn and Arner (2000) Sites of aggrecan cleavage by recombinant human aggrecanase-1 (ADAMTS-4). J. Biol. Chem. 275, 18566–18573] exhibits similar kinetics, it appears that preferential proteinase cleavage in the CS-rich region is determined by properties inherent in the aggrecan monomer itself, such as preferred peptide sequences for enzyme binding or enhanced accessibility to the core protein at these sites.

Mutations in the interglobular domain of aggrecan alters matrix metalloproteinase and aggrecanase cleavage patterns: Evidence that matrix metalloproteinase cleavage interfers with aggrecanase activity

Mutations in the interglobular domain of aggrecan alters matrix metalloproteinase and aggrecanase cleavage patterns: Evidence that matrix metalloproteinase cleavage interfers with aggrecanase activity

Sites of Aggrecan Cleavage by Recombinant Human Aggrecanase-1 (ADAMTS-4)

Aggrecan, the major proteoglycan of cartilage that provides its mechanical properties of compressibility and elasticity, is one of the first matrix components to undergo measurable loss in arthritic diseases. Two major sites of proteolytic cleavage have been identified within the interglobular domain (IGD) of the aggrecan core protein, one between amino acids Asn(341)-Phe(342) which is cleaved by matrix metalloproteinases and the other between Glu(373)-Ala(374) that is attributed to aggrecanase. Although several potential aggrecanase-sensitive sites had been identified within the COOH terminus of aggrecan, demonstration that aggrecanase cleaved at these sites awaited isolation and purification of this protease. We have recently cloned human aggrecanase-1 (ADAMTS-4) (Tortorella, M. D., Burn, T. C., Pratta, M. A., Abbaszade, I., Hollis, J. M., Liu, R., Rosenfeld, S. A., Copeland, R. A., Decicco, C. P., Wynn, R., Rockwell, A., Yang, F., Duke, J. L., Solomon, K., George, H., Bruckner, R., Nagase, H., Itoh, Y., Ellis, D. M., Ross, H., Wiswall, B. H., Murphy, K., Hillman, M. C., Jr., Hollis, G. F., Newton, R. C., Magolda, R. L., Trzaskos, J. M., and Arner, E. C. (1999) Science 284, 1664-1666) and herein demonstrate that in addition to cleavage at the Glu(373)-Ala(374) bond, this protease cleaves at four sites within the chondroitin-sulfate rich region of the aggrecan core protein, between G2 and G3 globular domains. Importantly, we show that this cleavage occurs more efficiently than cleavage within the IGD at the Glu(373)-Ala(374) bond. Cleavage occurred preferentially at the KEEE(1667-1668)GLGS bond to produce both a 140-kDa COOH-terminal fragment and a 375-kDa fragment that retains an intact G1. Cleavage also occurred at the GELE(1480-1481)GRGT bond to produce a 55-kDa COOH-terminal fragment and a G1-containing fragment of 320 kDa. Cleavage of this 320-kDa fragment within the IGD at the Glu(373)-Ala(374) bond then occurred to release the 250-kDa BC-3-reactive fragment from the G1 domain. The 140-kDa GLGS-reactive fragment resulting from the preferential cleavage was further processed at two additional cleavage sites, at TAQE(1771)-(1772)AGEG and at VSQE(1871-1872)LGQR resulting in the formation of a 98-kDa fragment with an intact G3 domain and two small fragments of approximately 20 kDa. These data elucidate the sites and efficiency of cleavage during aggrecan degradation by aggrecanase and suggest potential tools for monitoring aggrecan cleavage in arthritis.

Mannosamine Inhibits Aggrecanase-Mediated Changes in the Physical Properties and Biochemical Composition of Articular Cartilage

The enzymatic processes underlying the degradation of aggrecan in cartilage and the corresponding changes in the biomechanical properties of the tissue are an important part of the pathophysiology of osteoarthritis. Recent studies have demonstrated that the hexosamines glucosamine (GlcN) and mannosamine (ManN) can inhibit aggrecanase-mediated cleavage of aggrecan in IL-1-treated cartilage cultures. The term aggrecanase describes two or more members of the ADAMTS family of metalloproteinases whose glutamyl endopeptidase activity is known to be responsible for much of the aggrecan degradation seen in human arthritides. In this study we examined the effect of ManN and GlcN on aggrecanase-mediated degradation of aggrecan induced by IL-1α and the corresponding tissue mechanical properties in newborn bovine articular cartilage. After 6 days of culture in 10 ng/ml IL-1 plus ManN, mechanical testing of explants in confined compression demonstrated that ManN inhibited the IL-1α-induced degradation in tissue equilibrium modulus, dynamic stiffness, streaming potential, and hydraulic permeability, in a dose-dependent fashion, with peak inhibition (∼75–100% inhibition) reached by a concentration of 1.35 mM. Aggrecan from explants cultured in IL-1 was found by Western analysis to be almost entirely processed down to the G1-NITEGE373 end product. Addition of ManN or GlcN was found to produce 75–90% inhibition of this cleavage, but the proportion of aggrecan remaining in the tissue which was cleaved at aggrecanase sites in the chondroitin sulfate (CS)-rich region (Glu1501 and Glu1687) was higher than with IL-1 alone. This result suggests that the preservation of mechanical properties by hexosamines in explants is primarily due to inhibition of cleavage at the Glu373 site in the interglobular domain. While the precise mechanism by which hexosamines function in this system is unclear, the present analysis suggests that the mechanical properties examined may be predominantly a function of electrostatic repulsion due to the charged CS chains in the tightly packed repetitive sequences of the CS-1 region.