Generation and Characterization of Aggrecanase
A SOLUBLE, CARTILAGE-DERIVED AGGRECAN-DEGRADING ACTIVITY*

Elizabeth C. ArnerDagger , Michael A. Pratta, James M. Trzaskos, Carl P. Decicco§, and Micky D. Tortorella

From the Inflammatory Diseases Research and § Chemical and Physical Sciences, The DuPont Pharmaceutical Company, Wilmington, Delaware 19880-0400

    ABSTRACT
Top
Abstract
Introduction
References

A method was developed for generating soluble, active "aggrecanase" in conditioned media from interleukin-1-stimulated bovine nasal cartilage cultures. Using bovine nasal cartilage conditioned media as a source of the aggrecanase enzyme, an enzymatic assay was established employing purified aggrecan monomers as a substrate and monitoring specific aggrecanase-mediated cleavage products by Western analysis using the monoclonal antibody, BC-3 (which recognizes the new N terminus, ARGS, on fragments produced by cleavage between amino acid residues Glu373 and Ala374). Using this assay we have characterized cartilage aggrecanase with respect to assay kinetics, pH and salt optima, heat sensitivity, and stability upon storage. Aggrecanase activity was inhibited by the metalloprotease inhibitor, EDTA, while a panel of inhibitors of serine, cysteine, and aspartic proteinases had no effect, suggesting that aggrecanase is a metalloproteinase. Sensitivity to known matrix metalloproteinase inhibitors as well as to the endogenous tissue inhibitor of metalloproteinases, TIMP-1, further support the notion that aggrecanase is a metalloproteinase potentially related to the ADAM family or MMP family of proteases previously implicated in the catabolism of the extracellular matrix.

    INTRODUCTION
Top
Abstract
Introduction
References

The aggregating cartilage proteoglycan, aggrecan, along with type II collagen, is responsible for the mechanical properties of articular cartilage. Aggrecan molecules are composed of two N-terminal globular domains, G1 and G2, which are separated by an interglobular domain (IGD),1 followed by a long central glycosaminoglycan (GAG) attachment region and a C-terminal globular domain, G3 (1-2). These aggrecan monomers interact through the G1 domain with hyaluronic acid and link protein to form large molecular weight aggregates which are trapped within the cartilage matrix (3-5). Aggrecan provides normal cartilage with it properties of compressibility and resilience, and is one of the first matrix components to undergo measurable loss in arthritis. This loss appears to be due to an increased rate of aggrecan degradation that can be attributed to proteolytic cleavage within the IGD of the core protein. Cleavage within this region generates large C-terminal, GAG-containing aggrecan fragments lacking the G1 domain which are unable to bind to hyaluronic acid and thus diffuse out of the cartilage matrix.

Two major sites of proteolytic cleavage have been identified within the IGD: one between amino acid residues Asn341 and Phe342 and the other between amino acid residues Glu373 and Ala374. Matrix metalloproteinases (MMP-1, -2, -3, -7, -8, -9, and 13) have been shown in vitro to cleave within the IGD predominately at the Asn341-Phe342 site (6-10). Identification of G1 fragments formed by cleavage at the Asn341-Phe342 site within human articular cartilage (7, 11) and in synovial fluids (12) suggest a role for MMPs in proteoglycan degradation in vivo.

The second cleavage site was first described a number of years ago based upon identification of aggrecan fragments with an ARGS N terminus (13-15), however, the enzyme responsible for cleavage at the Glu373-Ala374 bond has not yet been identified. This uncharacterized activity has been given the name "aggrecanase" based on its ability to cleave the aggrecan core protein. Four other potential aggrecanase sites have been identified within the C-terminal region of aggrecan between G2 and G3 (14, 16), although the Glu373-Ala374 cleavage site within the IGD has been most widely studied. C-terminal fragments with the N terminus, ARGSV ... , formed by cleavage between amino acid residues Glu373 and Ala374 have been identified in media from chondrocyte monolayer and cartilage explant cultures undergoing matrix degradation (13-19). This sequence was found to be present on a number of different size fragments, indicating that aggrecanase was cleaving at the Glu373-Ala374 bond within the IGD to generate products with a single N terminus which possessed variable C termini. N-terminal sequence analyses have identified aggrecan fragments in synovial fluids of patients with osteoarthritis, inflammatory joint disease, and joint injury (20, 21) which have the ARGSV N terminus, and G1 fragments have also been identified within the cartilage matrix with the NITEGE C terminus (11) indicating that aggrecanase plays an important role in human aggrecan catabolism.

Although evidence for induction of cleavage at the aggrecanase site within the IGD has been demonstrated in a number of in vitro tissue and cell culture studies (13-19), attempts to identify aggrecanase proteolytic activity in culture media or cell/tissue extracts from these models have been largely unsuccessful. Recent work using an artificial recombinant protein comprising the IGD sequence of aggrecan, rAgg1, as a substrate, has identified activity in media from retinoic acid-stimulated rat chondrosarcoma cell cultures which cleaves at the Glu373-Ala374 bond (22). However, the protease responsible for this cleavage remains unidentified and uncharacterized.

In this paper we describe the generation of soluble, active aggrecanase activity in conditioned media from interleukin-1 (IL-1)-stimulated bovine nasal cartilage. Using this source of aggrecanase, we have developed an enzymatic assay employing purified native aggrecan monomers as the substrate and detection of specific products of aggrecanase-mediated cleavage by Western analysis with the monoclonal antibody, BC-3 (23), which recognizes the new N terminus ARGSV on fragments produced by cleavage at the aggrecanase site. We have performed initial enzymatic characterization of the soluble cartilage aggrecanase activity generated in response to IL-1. The work described herein provides a method for generating soluble aggrecanase activity and an assay for monitoring this activity which should serve as important tools to enable the isolation, purification, and molecular characterization of the enzyme.

    EXPERIMENTAL PROCEDURES

Materials-- Dulbecco's modified Eagle's medium and fetal bovine serum were from Life Technologies, Inc. (Grand Island, NY). The IL-1 used was a soluble, fully active recombinant human IL-1beta produced as described previously (24). The specific activity was 1 × 107 units/mg of protein, with 1 unit being defined as the amount of IL-1 that generated half-maximal activity in the thymocyte proliferation assay. Antibody BC-3 (23) which recognizes the new N terminus ARGSV ... on aggrecan degradation produced by aggrecanase was provided by Dr. Bruce Caterson (University of Wales, Cardiff, United Kingdom). Chondroitinase ABC lyase (Proteus vulgaris) (EC 4.2.2.4), keratanase (Pseudomonas sp.) (EC 3.2.1.103), and keratanase II (Bacillus sp.) were from Seikuguku (Kogyo, Japan). Full-length bovine tissue inhibitor of metalloproteases-1 (TIMP-1) was from Calbiochem (Cambridge, MA). The protease inhibitors, antipain dihydrochloride, aprotinin, bestatin, chymotrypsin, E-64, EDTA, leupeptin, Pefabloc, pepstatin, and phosphoramidon were from Boehringer-Mannheim (Indianapolis, IN). The hydroxamic acid MMP inhibitors, BB-16 ((2S,3R)-2-methyl-3-(2-methylpropyl)-1-(N-hydroxy)-4-(o-methyl)-L-tyrosine-N-methyl amide), XS309 ([3S-[3R*, 2-[2R*,2-(R*,S*)]-hexahydro-2-[2-[2-(hydroxyamino)-1-methyl-2-oxoethyl]-4-methyl-1-oxopentyl]-N-methyl-3-pyridazinecarboxamide), and SA751 (N-[1(R)-Carboxyethyl]-a-(S)-(4-phenyl-3-butynyl)glycyl-L-O-methyltyrosine, N-methylamide) were synthesized at DuPont Pharmaceuticals as described previously (25, 26). BB-16 and XS309 are potent nanomolar inhibitors of a number of MMPs, including MMP-1, -2, -3, -8, and -9, while SA751 is a selective MMP-8 inhibitor with a Ki of 2 nM against MMP-8 and a Ki of >10,000 nM against MMP-3 and MMP-1.

Cartilage Preparation-- Bovine nasal cartilage septa were removed from bovine noses obtained fresh at the time of slaughter. Uniform cartilage disks (1 mm thick, 8 mm in diameter) were prepared. Prior to organ culture studies, disks were equilibrated in tissue culture for at least 3 days in Dulbecco's modified Eagle's medium supplemented with 5% heat-inactivated fetal calf serum, penicillin, streptomycin, amphotericin B, and neomycin (100 IU/ml, 100 µg/ml, 0.25 µg/ml, and 50 µg/ml, respectively).

Cartilage Cultures-- Cartilage slices were incubated in serum-free Dulbecco's modified Eagle's medium supplemented with antibiotics as above at 37 °C in an atmosphere of 95% air, 5% CO2 in the presence of 500 ng/ml IL-1beta . Media were replaced every 2 days for the first 6 days of culture and saved at -70 °C for analysis. Cartilage was then incubated with IL-1 (500 ng/ml) from days 6 to 18 without media change to allow accumulation of aggrecanase activity in the media. Media were sampled every 2 days and saved at -70 °C for analysis. In some cases, at the end of incubation cartilage was digested with papain and the GAG content of the digest determined.

Glycosaminoglycan Assay-- Sulfated GAG in culture media or cartilage digests were monitored by the amount of polyanionic material reacting with 1,9-dimethylmethylene blue (27), using shark chondroitin sulfate as a standard. GAG release is reported as micrograms of GAG per mg wet weight cartilage or as percent of total GAG.

Gelatin Zymography-- Culture media were diluted 1:20 with water and 15 µl mixed with an equal volume of sample buffer (0.5 M Tris-HCl, pH 6.8, 4% SDS, 0.005% bromphenol blue, 20% glycerol) (Novex, San Diego, CA), incubated at room temperature for 10 min, and run on a 10% SDS-PAGE gels containing 0.1% gelatin in running buffer (0.24 M Tris, 2 M glycine, 35 mM SDS, pH 8.3) for 90 min at 125 volts. The gels were renatured in 2.5% Triton X-100 in water for 30 min at room temperature and then incubated at 37 °C overnight in developing buffer (50 mM Tris, 0.2 M NaCl, 5 mM CaCl2, 0.02% Brij 35, pH 7.6). After incubation, gels were stained in 0.25% Coomassie Brilliant Blue R-250 for 4 h at room temperature and destained in distilled water containing 30% methanol and 10% glacial acetic acid to reveal zones of lysis within the gelatin matrix. EDTA (5 mM), E64 (10 µg/ml), pepstatin (1 µg/ml), or benzamidine HCl (10 mM) or XS309 (1 µM) were added to the developing buffer to identify which classes of proteinases were responsible for lysis of the gelatin.

Caseinase Enzymatic Assay-- Casein labeled with resorufin (43.5 µM) was incubated with protease-containing media in a final volume of 200 µl of 50 mM Tris-HCl, 5 mM CaCl2 at pH 7.8 at 37 °C as described previously (29). The reactions were stopped and unclipped substrate precipitated by adding trichloroacetic acid to a final concentration of 5%. Samples were filtered through a 96-well filtration plate (Millipore Co., Bedford, MA) and filtrates collected and neutralized by addition of 2 M Tris to each well. The absorbance was then read at 575 nm. The concentration of the resorufin-labeled peptides in the filtrate, as determined from a standard curve, was used as a measure of proteolytic activity. Some conditioned medium samples were assayed in the presence of 2 mM 4-aminophenylmercuric acetate (APMA) to activate latent matrix metalloproteinases. With some samples EDTA was included to inhibit metalloproteinase activity or XS309 was included to inhibit matrix metalloproteinase activity.

Analysis of Aggrecan Catabolites-- For analysis of aggrecan fragments generated by specific cleavage at the Glu373-Ala374 site, proteoglycans and proteoglycan metabolites were enzymatically deglycosylated with chondroitinase ABC (0.1 units/10 µg of GAG) for 2 h at 37 °C and then with keratanase (0.1 units/10 µg of GAG) and keratanase II (0.002 units/10 µg of GAG) for 2 h at 37 °C in buffer containing 50 mM sodium acetate, 0.1 M Tris/HCl, pH 6.5 (23). The digests were monitored by measuring the decrease in dimethylmethylene blue reactivity. After digestion, the samples were precipitated with 5 volumes of acetone and reconstituted in an appropriate volume of SDS-PAGE sample buffer.

BC-3 Western Blot Analysis-- Equivalent amounts of GAG from each sample were loaded on 4-12% gradient gels and then separated by SDS-PAGE under nonreducing conditions, transferred overnight to nitrocellulose, and immunolocated with 1:1000 dilution of the monoclonal antibody BC-3 (22). Overnight transfer resulted in complete transfer of low and high molecular weight standards and samples as determined by evaluating the gel by colloidal Coomassie analysis (Novex, San Diego, CA) following protein transfer; no detectable levels of protein remained in the gel. Subsequently, membranes were incubated with goat anti-mouse IgG alkaline phosphatase conjugate and aggrecan catabolites visualized by incubation with the appropriate substrate (Promega Western blot alkaline phosphatase system) for 10-30 min to achieve optimal color development. BC-3-reactive aggrecan fragments were then quantified by scanning densitometry. For quantitation, the stained blots were captured on a UVP Imagestore 7500 Camera System (Cambridge, UK) with GelBase Pro system software. The integrated pixel density of the bands was quantified using IPLAB GEL software and data obtained only in the 10-fold linear detection range and reported as sum total pixels.

Preparation of Aggrecan Substrate-- Bovine nasal cartilage septa were removed from bovine noses obtained fresh at slaughter. The aggrecan was isolated from the cartilage by extraction at 4 °C for 48 h with 4 M guanidine-HCl, 0.05 M sodium acetate, pH 5.8, containing the protease inhibitors disodium EDTA, 6-aminohexanoic acid, phenymethanesulfonyl fluoride, and benzamidine HCl. The aggrecan monomers were isolated by equilibrium density gradient centrifugation in cesium chloride (30) and the bottom of this gradient (d > 1.54 g/ml) containing the monomers was dialyzed at 4 °C against water using Mr 10,000 cutoff membranes, lyophilized, and stored at -20 °C. Aggrecan substrate was prepared by dissolving lyophilized aggrecan monomers in buffer at a concentration based on the assumption of a molecular weight of 1 × 10-6.

Aggrecanase Enzymatic Assay-- Conditioned medium from bovine nasal cartilage stimulated with IL-1 were filtered to remove any particulate matter using a Corning 0.45-micron filter prior to use in the enzymatic assay. Medium was then incubated with purified native bovine aggrecan monomers with intact GAG chains in a final volume of 200 µl in 20 mM Tris, 100 mM NaCl, 10 mM CaCl2 buffer at pH 7.5. At the end of the incubation the reaction was quenched with 20 mM EDTA, the aggrecan was deglycosylated with chondroitinase ABC, keratanase, and keratanase II, and the aggrecanase-generated products were detected by BC-3 Western blot analysis as described above. In initial enzymatic assays, product generation was quantitated by scanning all BC-3-reactive bands. However, under the conditions used for the enzymatic assay, quantitation of the predominant 250-kDa band, which represents the initial product detected, gave equivalent results to quantitation of both this band and the minor lower molecular mass bands. Therefore, product generation was routinely assessed by quantitation of the 250-kDa band. Based on kinetic analysis, the following conditions were established for the assay: 50 µl of aggrecanase-containing medium was incubated with 500 nM aggrecan substrate in a final volume of 200 µl at 37 °C for 4 h as indicated above. pH activity profiles were performed in 50 mM MES, 100 mM NaCl, 10 mM CaCl2 buffer and pH was adjusted using 5 N HCl. Inhibitors were dissolved in dimethyl sulfoxide as a 10 mM stock and added to the reaction mixture immediately prior to enzyme addition. Dimethyl sulfoxide concentrations in the enzyme assay never exceeded 1%; this concentration of dimethyl sulfoxide had no effect on aggrecanase activity.

    RESULTS

Aggrecanase Generation in Bovine Nasal Cartilage Culture-- Incubation of bovine nasal cartilage with 500 ng/ml IL-1 for 6 days, with media replaced every 2 days, induced the degradation and release of aggrecan from the cartilage (Fig. 1). By monitoring the amount of GAG remaining in the cartilage at the end of the incubation, percent release of GAG from the tissue was determined at each time period; greater than 95% release of GAG was achieved by day 6. Cartilage was then incubated with IL-1 for an additional 10-12 days without media change to allow aggrecanase to accumulate in the media. To evaluate the time course of aggrecanase activity generation, samples of conditioned media were taken from cultures at various times during incubation with IL-1 and evaluated for aggrecanase activity. Incubation of this conditioned media with aggrecan substrate for 4 h resulted in the generation of fragments cleaved at the Glu373-Ala374 site as detected by BC-3 Western analysis (Fig. 2). Media quenched with EDTA prior to incubation with aggrecan served as assay blanks to control for fragments present in the media prior to enzymatic assay. Incubation of the aggrecan substrate alone did not result in the generation of BC-3-reactive fragments (data not shown).


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Fig. 1.   Time course of IL-1-induced proteoglycan release from bovine nasal cartilage. Bovine nasal cartilage slices were incubated in media containing 500 ng/ml IL-1 and media were replaced every 2 days and assayed for aggrecan release using the dimethylmethylene blue assay for GAG. Data are plotted as cummulative micrograms of GAG released/mg of cartilage wet weight.


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Fig. 2.   Time course of aggrecanase generation in media from IL-1-stimulated bovine nasal cartilage. Bovine nasal cartilage slices were incubated with 500 ng/ml IL-1 for 18 days with media being replaced every 2 days for the first 6 days of culture. Samples of media taken at various times during culture were assayed for aggrecanase activity by incubating with aggrecan substrate (500 nM) for 4 h at 37 °C and evaluating products by BC-3 Western blot analysis. Media quenched with EDTA prior to incubation with substrate served as assay blanks (lanes labeled B at each time point).

Although BC-3 Western blot analysis was routinely used to monitor aggrecan fragments produced by cleavage at the Glu373-Ala374 bond, initially digests generated by aggrecanase cleavage of exogenous aggrecan monomers were also analyzed by NITEGE Western blot and by biotinylated hyaluronic acid binding to confirm results with the BC-3 antibody. Time course analyses showed that the G1-NITEGE fragment was generated simultaneously with the BC-3 epitope supporting cleavage at the Glu373-Ala374 bond by aggrecanase.2 The band of aggrecan fragments expressing the NITEGE epitope appeared as a doublet between 64 and 70 kDa, consistent with the G1-NITEGE products previously obtained following IL-1beta treatment of bovine chondrocytes (18).

High background levels of BC-3-reactive fragments produced in response to IL-1-induced degradation of the cartilage matrix were observed in media on day 2 and day 4 (Fig. 2). However, subtraction of background levels of BC-3 from the levels present following the enzymatic assay indicated that aggrecanase activity was present even at these early time periods. By day 6 of culture, BC-3-reactive fragments were no longer detected in conditioned media. Incubation of day 6 media with 500 nM aggrecan substrate for 4 h resulted in the formation of a BC-3-reactive, aggrecanase-generated product of ~250 kDa. Aggrecanase activity accumulated in the media as the enzyme activity was monitored from days 6 to 16. In media from cultures stimulated for 10 days or greater, additional minor BC-3- reactive bands that migrated between 100 and 250 kDa were detected.

Aggrecanase Enzymatic Assay Development-- In order to establish appropriate assay conditions and evaluate aggrecanase kinetic properties, the effect of incubation time, enzyme concentration, and substrate concentration on product formation were evaluated. Linearity of product formation was observed up to 4 h (Fig. 3A), and over enzyme concentrations between 25 and 80 µl of conditioned media (Fig. 3B). Aggrecanase activity appeared to approach saturation with respect to aggrecan substrate at 500-1000 nM (Fig. 3C). However, increasing viscosity precluded use of higher substrate concentrations.


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Fig. 3.   Aggrecanase assay kinetics. Aggrecanase-containing media was incubated with purified aggrecan substrate at 37 °C. Aggrecanase-mediated cleavage at the Glu373-Ala374 bond were monitored by BC-3 Western blot analysis and BC-3-epitope quantitated by scanning densitometry. Fifty microliters of media were incubated with 1 µM aggrecan substrate for various times (A), or various amounts of conditioned media were incubated with 1 µM aggrecan substrate for 4 h (B), or 50 µl of media were incubated for 4 h with various concentrations of aggrecan substrate (C). BC-3-reactive product was plotted versus time, media volume, or substrate concentration.

Stability-- Aggrecanase activity was found to be stable during storage at -70, -20, or 4 °C in culture media; greater than 90% of the activity was recovered after 14 days or longer storage at -70, -20, and 4 °C. Activity was also stable to repeated freeze-thaw cycles of -70 to 4 °C. Heating at 42 °C for 15 min did not affect activity, but activity was completely lost following 15 min heating at 56 °C or above.

Characterization of Aggrecanase Activity-- Using the assay conditions defined above, we studied the salt and pH optimum of crude aggrecanase present in conditioned medium. Optimal activity was achieved with 100 mM NaCl. At 250 mM NaCl, activity was decreased by ~50% and was completely lost at 500 mM NaCl or higher (Fig. 4). The pH optimum for aggrecanase was found to be at 7.5 (Fig. 5). However, a rather broad pH range between 6.5 and 9.5 supported greater than 75% of the activity seen at the pH optimum.


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Fig. 4.   Affect of salt concentration on aggrecanase activity. Aggrecanase-containing media were incubated with 500 nM aggrecan substrate at 37 °C for 4 h in the presence of various concentrations of NaCl and product generation was monitored by BC-3 Western blot analysis.


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Fig. 5.   Affect of pH on aggrecanase activity. Aggrecanase-containing media were incubated with 500 nM aggrecan substrate for 4 h in 50 mM MES, 100 mM NaCl, 10 mM CaCl2 buffer with pH adjusted using 5 N HCl. Product was monitored by BC-3 Western blot analysis and activity plotted as a percent of maximal activity versus pH.

Effect of Protease Inhibitors-- Aggrecanase activity was inhibited by the metalloprotease inhibitor, EDTA, while a panel of inhibitors of serine, cysteine, and aspartic proteinases had no effect (Table I). The ability of the endogenous inhibitor of matrix metalloproteinase, TIMP-1, to block aggrecanase activity was investigated using full-length recombinant bovine TIMP-1. TIMP-1 caused a concentration-dependent inhibition of aggrecanase activity (Fig. 6). The IC50 was estimated from the concentration-response curve to be 210 nM. However, TIMP-2 at concentrations up to 1 µM was inactive against aggrecanase (data not shown).

                              
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Table I
Effect of protease inhibitors on aggrecanase activity


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Fig. 6.   Inhibition of aggrecanase activity by TIMP-1. Aggrecanase-containing media were incubated with 500 nM aggrecan substrate for 4 h at pH 7.5 in the absence or presence of various concentrations of bovine TIMP-1 and product formation monitored by BC-3 Western blot analysis (A). Percent inhibition of product formation was plotted versus TIMP-1 concentration (B).

The peptidic hydroxamates, BB-16 (25) and XS309 (26), which are potent, synthetic inhibitors with broad specificity against MMPs were tested for their ability to block aggrecanase activity (Table II). BB-16 resulted in a concentration-dependent inhibition of aggrecanase activity, while XS309 was inactive at concentrations up to 10,000 nM. Previous studies from our laboratory suggested that although MMP-8 (neutrophil collagenase) has the ability to cleave native aggrecan at the Glu373-Ala374 bond, it does not represent the cartilage aggrecanase (31). To confirm this hypothesis we also evaluated SA751 (26), a potent, selective synthetic MMP-8 inhibitor, for its ability to inhibit aggrecanase activity. SA751 was inactive against aggrecanase at concentrations up to 10,000 nM (Table II), while it has a Ki of 2 nM for inhibition of MMP-8.

                              
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Table II
Effect of synthetic matrix metalloproteinase inhibitors on aggrecanase activity

To ascertain whether aggrecanase activity was associated with known metalloproteinase activities, gelatinolytic and caseinolytic activities were assayed in medium from IL-1-stimulated cartilage. Multiple bands of gelatinolytic activity were observed in conditioned medium by gelatin zymography. All of these gelatinases were shown to be metalloproteases by the complete loss of gelatinolytic activity when the zymogram was incubated with EDTA (Fig. 7), whereas E-64, pepstatin, or benzamidine hydrochloride (which inhibit the cysteine, aspartate, and serine protease classes, respectively) had no effect on gelatinase activity under similar conditions (data not shown). In contrast to its lack of effect on aggrecanase activity, XS309 resulted in a complete inhibition of the gelatinolytic activity (Fig. 7). Similarly, caseinolytic activity was also detected in the conditioned media. Both active and APMA-activated caseinolytic activity were blocked by EDTA (Table III), indicating that this activity was due to a metalloproteinase(s). Furthermore, this caseinolytic activity was completely blocked by XS309, the MMP inhibitor that was ineffective against aggrecanase.


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Fig. 7.   Gelatinolytic activity in media from IL-1-stimulated bovine nasal cartilage. Conditioned medium from day 16 of culture was analyzed for gelatinolytic activity by gelatin zymography without or with the inclusion of 5 mM EDTA or 1 µM XS309 in the developing buffer.

                              
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Table III
Effect of inhibitors on caseinolytic activity of conditioned media
Caseinolytic activity of active proteases in conditioned media was measured by monitoring media directly using casein-resorufin substrate and total caseinolytic activity was assayed by activating any latent MMPs by inclusion of APMA during the assay.


    DISCUSSION

Although several studies suggest that cleavage of the aggrecan core protein at the Glu373-Ala374 bond plays a key role in cartilage matrix degradation, the protease responsible for this cleavage remains unidentified. Therefore, our current study had three main goals: 1) to establish a method for generating active aggrecanase; 2) to develop an assay to assess and follow this activity; and 3) to characterize aggrecanase enzymatic activity.

Stimulation of chondrocyte cultures with retinoic acid or bovine nasal cartilage with IL-1 for short time periods has been shown to result in the production of aggrecan fragments formed by cleavage at the Glu373-Ala374 bond (18, 32, 33). However, aggrecanase activity as measured by cleavage of exogenous aggrecan was not detected in media from these cultures (34). We had previously found that induction of MMP-3 in cartilage cultures by IL-1 resulted in the elution of only the inactive zymogen into the culture media at early time points, although both the zymogen and active forms of the enzyme were present within the matrix (35). Only after depletion of aggrecan from the matrix or in the presence of an active-site inhibitor was the active form of MMP-3 protein detected in the culture media, suggesting that the active enzyme was bound to a matrix component, possibly aggrecan. We reasoned that this might also be the case for aggrecanase. Therefore, in an attempt to generate and release active aggrecanase from bovine nasal cartilage, we first stimulated the cartilage to deplete the aggrecan from the matrix and then restimulated and monitored the media for the presence of aggrecanase activity. This procedure resulted in the generation of readily detectable aggrecanase activity in conditioned media. In contrast to MMP-3, aggrecanase was present in the conditioned media as the active form at days 2 and 4 of incubation with IL-1. However, products generated during the enzymatic assay were much easier to detect following depletion of the matrix when background BC-3-reactive fragments were no longer present in the conditioned media.

The conditioned media exhibited aggrecanase activity (i.e. cleavage of aggrecan at the Glu-Ala bond) without activation. In fact, incubation with APMA or chymotrypsin, which are frequently used to activate pro-MMPs, did not increase this activity. In addition, XG076, an inhibitor of pro-MMP activation, which is effective in blocking aggrecanase-mediated cleavage in IL-1-stimulated bovine explant cultures (33), did not inhibit aggrecanase in the enzymatic assay,3 indicating that aggrecanase is not being activated in some manner during the assay. Although we cannot rule out that the active aggrecanase could be bound to matrix molecules, specific binding and orientation within the matrix is not required, since we observe activity using isolated aggrecan substrate in solution. Thus, aggrecanase generated in conditioned media from IL-1-stimulated bovine nasal cartilage is a soluble, activated enzyme, free of association with the chondrocyte cell surface. These characteristics are consistent with those reported in rat chondrosarcoma cell cultures stimulated with retinoic acid, where activity was detected in media using an artificial recombinant aggrecan interglobular domain protein substrate (22). In contrast to earlier studies (34), a recent publication demonstrated the ability of membranes isolated from stimulated chondrocytes to generate aggrecan fragments formed by cleavage at the Glu373-Ala374 bond (36). This recent identification of aggrecanase activity associated with chondrocyte membranes, in addition to our demonstration of soluble activity in culture media, open the possibility that aggrecanase may be an integral membrane protein that is subsequently cleaved to a soluble form or that it may be a soluble enzyme that is associated with a cell surface-binding protein on the chondrocyte membrane.

Although other matrix metalloproteases are induced in the aggrecanase-containing conditioned media from IL-1-stimulated cartilage, none of these appear to be responsible for the BC-3-reactive fragments produced by cleavage at the the Glu373-Ala374 bond. Studies using purified enzymes have shown that MMP-1, -2, -3, -7, -8, -9, and -13 cleave at the Asn341-Phe342 bond and do not readily cleave at the Glu373-Ala374 site (6-10). Furthermore, we have shown that 1 µM XS309, a potent MMP inhibitor with Ki values in the nanomolar range against MMP-1, -2, -3, -8, and -9 that was inactive at concentrations up to 10 µM in inhibiting aggrecanase, completely blocked all gelatinolytic activities in aggrecanase-containing media. These data indicate that aggrecanase does not cleave gelatin and that aggrecanase activity is not represented by these gelatinolytic MMPs induced in response to IL-1 stimulation. Caseinolytic activity, detected in the conditioned media, was inhibited almost completely by 1 µM XS309. Since at 1 µM XS309 does not inhibit aggrecanase, these data suggest that aggrecanase does not cleave casein and that the caseinolytic activity generated in response to IL-1 does not represent aggrecanase. Interestingly, XS309, which completely blocked both the gelatinolytic and caseinolytic activity generated in response to IL-1, was found to be inactive in blocking IL-1-induced aggrecan degradation in cartilage explant cultures,4 while BB-16, which is active against aggrecanase enzymatic activity, was effective (33).

The substrate in the enzymatic assays used to determine Ki values of the synthetic MMP inhibitors against the various MMPs was a fluorogenic peptide substrate. We have not determined the Ki values for these compounds using the natural substrates for the different MMPs or using aggrecan, to compare with the Ki values determined using the peptide substrate. Therefore, the possibility that this difference in substrate may confound the comparison of the potency of these compounds against MMPs with their potency in the aggrecanase assay, where native aggrecan is used as the substrate, must be considered. However, when XS309 and BB-16 were evaluated for inhibition of MMP-3 using the native aggrecan substrate, these compounds exhibited potency in the nanomolar range as was the case using the peptide substrate.

Using BC-3 Western blot analysis to monitor aggrecan fragments produced by cleavage at the Glu373-Ala374 bond, we have developed an enzymatic assay specific for aggrecanase-generated products. Although Western blot analysis does not provide a particularly rapid means of product evaluation, quantitation is possible, thus enabling characterization of aggrecanase activity. This assay was used to assess product formation with respect to incubation time and enzyme and substrate concentration dependence. Aggrecanase displayed a sensitivity to salt, with activity being lost at NaCl concentrations above 500 mM. A broad pH optimum extending into the alkaline range was observed, although maximum activity was seen at pH 7.5. Aggrecanase was also sensitive to elevated temperature with the activity being lost after treatment at 56 °C.

Inhibitor studies indicate that aggrecanase is a metalloendopeptidase as it is inhibited by the metalloprotease inhibitor EDTA, but not by inhibitors of the cysteine, serine, or aspartyl protease classes. Inhibition by TIMP-1 opens the possibility that this protease may be a member of the matrix metalloproteinase family of enzymes. However, the IC50 for inhibition of aggrecanase by TIMP-1 is more than 100-fold higher than that reported for MMPs (37, 38). In addition, we were not able to obtain inhibition with TIMP-2 at concentrations up to 1 µM. During the time this manuscript was in review, similar results were reported for inhibition of aggrecanase activity from chondrocytes using a recombinant aggregan interglobular domain substrate (39). Aggrecanase could represent a member of the MMP family that differs significantly from other MMPs in its interaction with TIMP-1 or which may lack the C-terminal region that has been shown to be important in binding to TIMP for some MMPs (40). Alternatively, aggrecanase may be a member of a closely related non-MMP class of metalloproteases.

Although the MMP inhibitor, BB-16, is capable of inhibiting the proteolytic activity of aggrecanase, not all MMP inhibitors are effective in blocking this activity. In addition, some hydroxamates have been shown to inhibit other related metalloproteases, such as TNF converting enzyme (41, 42), which is a member of the family of mammalian adamalysins or ADAM (a disintegrin and metalloproteinase domain) proteins (43). Our laboratory has recently demonstrated that atrolysin C, a snake venom metalloproteinase with homology to the ADAM proteins is capable of cleaving aggrecan at the Glu373-Ala374 aggrecanase site (44). This observation, taken together with the lack of inhibition by other potent MMP inhibitors and the high concentrations of TIMP-1 required for inhibition, support the hypothesis that aggrecanase may be a member of a related class of metalloproteinases such as the ADAM family. Although our data are consistent with aggrecanase representing a member of the metzincin family of metalloproteases, further characterization awaits purification and sequencing of the aggrecanase protein.

Time course studies indicated that aggrecanase activity accumulated in conditioned media from IL-1-stimulated bovine nasal cartilage with increasing time of incubation from day 6 through day 16. Although activity in conditioned media was difficult to observe due to high background levels of BC-3 fragments prior to day 6, quantitation of epitope by scanning densitometry and subtraction of background levels from levels present following the enzymatic assay indicated that active aggrecanase was present in media at days 2 and 4. The formation of BC-3-reactive products from endogenous aggrecan during the course of matrix depletion confirm that active aggrecanase is present within the tissue during the first 2 days of culture.

Upon incubation of aggrecanase with the aggrecan substrate an intense BC-3-reactive band migrating at approximately 250 kDa was detected. Subsequently, minor lower molecular mass BC-3-reactive bands were detected, indicating further cleavage at the C terminus of the molecule. In addition to the Glu373-Ala374 cleavage site within the IGD of the aggrecan core protein, four other potential sites for cleavage by aggrecanase have been identified within the C-terminal region of bovine aggrecan between G2 and G3 (14, 16). The mass of the secondary fragments produced by aggrecanase cleavage of the purified bovine aggrecan substrate, along with their BC-3 reactivity, are consistent with these fragments having undergone cleavage both within the IGD at the Glu373-Ala374 bond and at site(s) corresponding to those proposed for cleavage within the C-terminal region of the core protein. Lack of effect by the potent MMP inhibitor, XS309, on the appearance of the lower molecular mass BC-3-reactive bands at ~150 and 110 kDa3 indicate that they are not the result of further cleavage of the 250-kDa fragment by MMPs in the media.

Although the pattern of BC-3-reactive fragments produced upon cleavage of exogenous aggrecan substrate by the soluble aggrecanase in conditioned media is similar to that generated during IL-1-induced aggrecan degradation in cartilage cultures, in Fig. 2 the lower molecular weight bands are under-represented in the enzymatic assays due to the short incubation time (4 h) as compared with the 48-h periods during which cleavage of the endogenous substrate took place. In experiments where incubation of exogenous aggrecan with media is allowed to continue for longer times, the lower molecular mass bands at ~150 and 110 kDa increased in intensity so that the pattern seen looked extremely similar to that generated by cleavage of the endogenous substrate in response to IL-1. Interestingly, the two lowest molecular mass species (~75 and 64 kDa) are not generated upon digestion of the exogenous substrate by aggrecanase even with incubations of 48 h. We speculate that these bands are formed by further cleavage of aggrecanase-generated fragments toward the C terminus of the aggrecan molecule by MMPs. This hypothesis is supported by studies showing that although there was little effect on IL-1-induced aggrecan degradation in bovine nasal cartilage with the MMP inhibitor, XS309, which does not inhibit aggrecanase, the generation of these two BC-3-reactive bands was blocked.2

Isolation and purification of the aggrecanase enzyme requires a tissue source of the protease and an enzymatic assay to follow activity during purification. In the studies reported herein, we have developed a method for generating soluble aggrecanase activity from bovine nasal cartilage, performed initial characterization of this protease, and developed an assay for monitoring this activity which should lead to the isolation of the aggrecanase enzyme.

    ACKNOWLEDGEMENTS

We thank Robert Copeland for MMP Ki values and Liana Bauerle for expert technical assistance.

    FOOTNOTES

* The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Dagger To whom correspondence should be addressed: Principal Research Scientist, Inflammatory Diseases Research, The DuPont Pharmaceutical Co., Experimental Station E400/4239, P. O. Box 400, Wilmington, DE 19880-0400. Tel.: 302-695-7078; Fax: 302-695-7873.

2 M. D. Tortorella, M. A. Pratta, and E. C. Arner, unpublished data.

3 E. C. Arner and M. D. Tortorella, unpublished data.

4 E. C. Arner and M. A. Pratta, unpublished data.

    ABBREVIATIONS

The abbreviations used are: IGD, interglobular domain; GAG, glycosaminoglycan; MMP, matrix metalloproteinase; PAGE, polyacrylamide gel electrophoresis; IL, interleukin; TIMP-1, tissue inhibitor of metalloproteinases; APMA, 4-aminophenylmercuric acetate; MES, 4-morpholineethanesulfonic acid.

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Abstract
Introduction
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