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[摘要]:Aggrecan loss from mouse cartilage is predominantly because of ADAMTS-5 activity; however, the relative contribution of other proteolytic and nonproteolytic processes to this loss is not clear. This is the first study to compare aggrecan loss with aggrecan processing in mice with single and double deletions of ADAMTS-4 and -5 activity (Delta cat). Cartilage explants harvested from single and double ADAMTS-4 and -5 Delta cat mice were cultured with or without interleukin (IL)-1 alpha or retinoic acid and analyzed for (i) the kinetics of 35S-labeled aggrecan loss, (ii) the pattern of S-35-labeled aggrecan fragments released into the media and retained in the matrix, (iii) the pattern of total aggrecan fragments released into the media and retained in the matrix, and (iv) specific cleavage sites within the interglobular and chondroitin sulfate-2 domains. The loss of radiolabeled aggrecan from ADAMTS-4/-5 Delta cat cartilage was less than that from ADAMTS-4, ADAMTS-5, or wild-type cartilage under nonstimulated conditions. IL-1 alpha and retinoic acid stimulated radiolabeled aggrecan loss from wild-type and ADAMTS-4 Delta cat cartilage, but there was little effect on ADAMTS-5 cartilage. Proteolysis of aggrecan contributed most to its loss in wild-type, ADAMTS-4, and ADAMTS-5 Delta cat cartilage explants. The pattern of proteolytic processing of aggrecan in these cultures was consistent with that occurring in cartilage pathologies. Retinoic acid, but not IL-1 alpha, stimulated radiolabeled aggrecan loss from ADAMTS-4/-5 Delta cat cartilage explants. Even though there was a 300% increase in aggrecan loss from ADAMTS-4/-5 Delta cat cartilage stimulated with retinoic acid, the loss was not associated with aggrecanase cleavage but with the release of predominantly intact aggrecan consistent with the phenotype of the ADAMTS4/-5 Delta cat mouse. Our results show that chondrocytes have additional mechanism for the turnover of aggrecan and that when proteolytic mechanisms are blocked by ablation of aggrecanase activity, nonproteolytic mechanisms compensate to maintain cartilage homeostasis. |
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