Mechanisms of human neutrophil‐mediated cartilage damage in vitro: The role of lysosomal enzymes, hydrogen peroxide and hypochlorous acid

Abstract

Cartilage is a focal point of attack by cellular and molecular elements of the inflammatory response which occurs in arthritic diseases. Neutrophils damage articular cartilage by degrading matrix components and inhibiting their synthesis. The aim of this study was to elucidate mechanisms of this damage. Human neutrophils were isolated from blood by centrifuging through Ficoll-Hypaque and granule extract prepared from them. Articular cartilage from adult humans and cattle was maintained in organ culture. Cartilage degradation (release of ³⁵S-labelled proteoglycan) or synthesis (incorporation of ³⁵S into proteoglycan) was determined after various treatments. Human neutrophils and neutrophil granule extract degraded proteoglycan and inhibited proteoglycan synthesis. The specific leucocyte elastase inhibitor N-methoxysuccinyl-(ala)₂-pro-val-chloromethylketone (MAAPVCMK) partially reversed these effects. H₂O₂, a product of the neutrophil respiratory burst, when added directly at 10^-6 mol/L, or generated by glucose oxidase (GO)/glucose inhibited proteoglycan synthesis but had no effect on degradation. Hypochlorous acid (OHCl), a product of the myeloperoxidase (MPO)/H₂O₂/Cl system at 50 mol/L degraded proteoglycan and inhibited its synthesis. OHCl, produced by granule extract (as a source of MPO) + GO-generated H₂O₂ + Cl^- degraded proteoglycan. The results indicate that neutrophil-mediated proteoglycan degradation and inhibition of synthesis is largely attributable to elastase and secondarily to OHCl, whereas H₂O₂ impairs synthesis without affecting degradation of proteoglycan.