AI Article Synopsis
- MMP13 is a zinc-dependent protease responsible for breaking down type II collagen in cartilage, making it a key target in treating osteoarthritis.
- Previous MMP inhibitors caused painful musculoskeletal side effects due to their non-selectivity, but new inhibitors developed by researchers are designed to selectively target MMP13 without affecting other proteins.
- These new MMP13 inhibitors have shown promise in reducing cartilage damage in animal models without causing negative side effects, potentially leading to safer and more effective osteoarthritis treatments.
Article Abstract
Matrix metalloproteinase-13 (MMP13) is a Zn(2+)-dependent protease that catalyzes the cleavage of type II collagen, the main structural protein in articular cartilage. Excess MMP13 activity causes cartilage degradation in osteoarthritis, making this protease an attractive therapeutic target. However, clinically tested MMP inhibitors have been associated with a painful, joint-stiffening musculoskeletal side effect that may be due to their lack of selectivity. In our efforts to develop a disease-modifying osteoarthritis drug, we have discovered MMP13 inhibitors that differ greatly from previous MMP inhibitors; they do not bind to the catalytic zinc ion, they are noncompetitive with respect to substrate binding, and they show extreme selectivity for inhibiting MMP13. By structure-based drug design, we generated an orally active MMP13 inhibitor that effectively reduces cartilage damage in vivo and does not induce joint fibroplasias in a rat model of musculoskeletal syndrome side effects. Thus, highly selective inhibition of MMP13 in patients may overcome the major safety and efficacy challenges that have limited previously tested non-selective MMP inhibitors. MMP13 inhibitors such as the ones described here will help further define the role of this protease in arthritis and other diseases and may soon lead to drugs that safely halt cartilage damage in patients.
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| http://dx.doi.org/10.1074/jbc.M703286200 | DOI Listing |
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