Aggrecanase versus matrix metalloproteinases in the catabolism of the interglobular domain of aggrecan in vitro

Aggrecan is the major cartilage hyalectan (1), which, together with the collagen network, provides this tissue with its unique mechanical properties of compressibility and stiffness (2-4). Extraction of aggrecan in its native form (5) and subsequent structural analysis (6) have revealed that the molecular organization of aggrecan is perfectly suited to its central functional role in articular cartilage. The N-terminal region of aggrecan is composed of two globular domains (G1 1 and G2) separated by the interglobular domain (IGD). G1 interacts with hyaluronan and link protein, thereby keeping the aggrecan molecule anchored within the cartilage tissue. Further interactions with other matrix components such as tenascin-R and fibulin-1 and fibulin-2 (7, 8) may occur through a third globular domain (G3) at the extreme C terminus of the core protein. The extended core protein between G2 and G3 is composed of a short keratan sulfate-rich region followed by a longer chondroitin sulfate-substituted domain. The charge repulsion and hydration of the long negatively charged glycosaminoglycan (GAG) chains are thought to maintain the C-terminal portions of aggrecan in an extended conformation (9). The swelling pressure of the aggrecan-link protein complex with hyaluronan is restrained by the tension in the collagen network; and together, these components form a fiber-reinforced concentrated gel within the cartilage, which transmits forces across the articular joint.In diseases characterized by cartilage degradation such as rheumatoid arthritis and osteoarthritis, increased aggrecan release from the cartilage occurs early (10, 11) and before the bulk of the collagen network is degraded (12). Proteolytic cleavage of aggrecan within the IGD separates the GAG-rich region from the hyaluronan-anchored G1 domain, resulting in GAG release from the cartilage matrix to the synovial fluid. Biomechanical tests on cartilage discs have shown that proteolysis within the IGD of aggrecan, and not cleavages near the C terminus, is primarily responsible for the loss of compressive resistance that accompanies interleukin-1-mediated degradation of the tissue (13). Identification of the proteinases responsible for this "destructive" cleavage of aggrecan has therefore been a major focus of experimentation in arthritis-related research.In this regard, two major cleavage sites that occur in vivo have been identified in the IGD of human aggrecan. One is a matrix metalloproteinase (MMP)-sensitive site at VDIPEN 341 2F 342 FGVGG, which can be cleaved at neutral pH by any one of a range of MMPs, including MMP-1-3, -7-9, -13,

Section: Discussionmentioning

confidence: 68%

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

Westling

Fosang

Thompson

et al. 2002

“…Aggrecanase-derived 374 ARGSV fragments are the major aggrecan products found in synovial fluids from arthritis patients (7,8). Furthermore, the aggrecanase-derived ITEGE 373 neoepitope at the C terminus of the G1 domain has been detected in human (9,10), bovine (11,12), pig (12), and rat (11) cartilage and in mice with experimental arthritis (13,14).…”

mentioning

confidence: 99%

“…The 342 FFGVG N-terminal neoepitope (Fig. 1c) has been found in human synovial fluids (16) and conditioned medium from porcine (22) and human osteoarthritic (12) cartilage cultures. The C-terminal neoepitope DIPEN 341 ( Fig.…”

mentioning

confidence: 99%

Generation and Novel Distribution of Matrix Metalloproteinase-derived Aggrecan Fragments in Porcine Cartilage Explants

Fosang

Stanton

Weeks

et al. 2000

We have studied aggrecan catabolism mediated by matrix metalloproteinases (MMPs) in a porcine cartilage culture system. Using antibodies specific for DIPEN 341 Aggrecan is the major proteoglycan present in articular cartilage, and it is the molecule that endows cartilage with its intrinsic capacity to bear load and resist compression. This weight-bearing capacity is dependent on the structure and organization of collagen and aggrecan within the extracellular matrix. Normal turnover of aggrecan is a conservative process in which the rate of breakdown and release of fragments from the tissue does not exceed the rate at which it is replaced by newly synthesized molecules. In pathology, an increased rate of degradation results in a net loss of aggrecan, and the tissue becomes thin and mechanically weak.Aggrecan is lost from cartilage following proteolysis of the core protein. Aggrecanases are thought to be the enzymes primarily responsible for this proteolysis. Two ADAM 1 proteins with thrombospondin motifs, ADAMTS-4 (aggrecanase-1) (1) and ADAMTS-5 (aggrecanase-2, also known as ADAMTS-11) (2, 3) have been purified from bovine cartilage, and the corresponding human enzymes have been cloned and shown to exhibit the same specificity for aggrecan substrates as the purified bovine enzymes. The most widely documented activity of aggrecanase is hydrolysis of the Glu 373 2Ala 374 bond (numbering based on the human sequence) (4) in the interglobular domain (IGD) (Fig. 1c); however aggrecanases also cleave within highly conserved regions of the chondroitin sulfate attachment region (5, 6). Fragments resulting from aggrecanase action and containing the 374 ARGSV N terminus (Fig. 1c) have been detected in conditioned culture medium by sequence analysis of isolated fragments or by detection with specific neoepitope antibodies. Aggrecanase-derived 374 ARGSV fragments are the major aggrecan products found in synovial fluids from arthritis patients (7,8). Furthermore, the aggrecanase-derived ITEGE 373 neoepitope at the C terminus of the G1 domain has been detected in human (9, 10), bovine (11, 12), pig (12), and rat (11) cartilage and in mice with experimental arthritis (13,14).In addition to cleavage by aggrecanase, there is convincing evidence for the direct involvement of the matrix metalloproteinase (MMP) family of enzymes in aggrecanolysis, albeit at much lower levels. The specific products of MMP activity have been detected in vivo (10, 15, 16) and in vitro (17-19) by sequencing and more recently by cleavage site-specific neo-

“…Cleavage of aggrecan is enhanced in inflammatory joint disease resulting in cartilage damage, indeed soluble products of aggrecan catabolism generated by aggrecanases and MMPs can be found in synovial fluid and cartilage extracts of patients with arthritis (14, 20 -22). In vitro culture systems have also demonstrated that a variety of inflammatory cytokines, such as IL-1␣ and TNF-␣ stimulate cleavage at these same sites (23)(24)(25)(26). The enzyme cleavage sites, and the minimal sequence lengths for recognition by target enzymes, have been previously documented (27)(28)(29)(30).…”

Section: Complement (C)mentioning

confidence: 99%

“…All of these reagents are known stimulators of cartilage catabolism. IL-1␣ and TNF-␣ are known to up-regulate the production of the aggrecanases and some MMPs, whereas retinoic acid is known to up-regulate the production of the aggrecanases but not the MMPs (23)(24)(25)(26)40). Following incubation of chondrocytes with these reagents and the DAF4-IGD75-IgG 4 prodrug, the neoepitopes generated by the aggrecanases and MMPs were detected using BC-3 and This generated a reagent with little Cregulatory activity until cleaved by MMPs at the site of inflammation, resulting in release of the active DAF moiety (C).…”

Section: Cleavage Of Prodrugs By Enzymementioning

confidence: 99%

Generation of Anti-complement “Prodrugs”

Harris

Hughes

Williams

et al. 2003

Self Cite

Expression of biologically active molecules as fusion proteins with antibody Fc can substantially extend the plasma half-life of the active agent but may also influence function. We have previously generated a number of fusion proteins comprising a complement regulator coupled to Fc and shown that the hybrid molecule has a long plasma half-life and retains biological activity. However, several of the fusion proteins generated had substantially reduced biological activity when compared with the native regulator or regulator released from the Fc following papain cleavage. We have taken advantage of this finding to engineer a prodrug with low complement regulatory activity that is cleaved at sites of inflammation to release active regulator. Two model prodrugs, comprising, respectively, the four short consensus repeats of human decay accelerating factor (CD55) linked to IgG 4 Fc and the three NH 2 -terminal short consensus repeats of human decay accelerating factor linked to IgG 2 Fc have been developed. In each, specific cleavage sites for matrix metalloproteinases and/or aggrecanases have been incorporated between the complement regulator and the Fc. These prodrugs have markedly decreased complement inhibitory activity when compared with the parent regulator in vitro. Exposure of the prodrugs to the relevant enzymes, either purified, or in supernatants of cytokine-stimulated chondrocytes or in synovial fluid, efficiently cleaved the prodrug, releasing active regulator. Such agents, having negligible systemic effects but active at sites of inflammation, represent a paradigm for the next generation of anti-C therapeutics.