East Charlotte J, Stanton Heather, Golub Suzanne B, Rogerson Fraser M, Fosang Amanda J
Department of Paediatrics & Murdoch Childrens Research Institute, University of Melbourne, Royal Children's Hospital, Parkville 3052, Australia.
J Biol Chem. 2007 Mar 23;282(12):8632-40. doi: 10.1074/jbc.M605750200. Epub 2007 Jan 25.
In the mouse, proteolysis in the aggrecan interglobular domain is driven by ADAMTS-5, and mice deficient in ADAMTS-5 catalytic activity are protected against aggrecan loss and cartilage damage in experimental models of arthritis. Here we show that despite ablation of ADAMTS-5 activity, aggrecanolysis can still occur at two preferred sites in the chondroitin sulfate-rich region. Retinoic acid was more effective than interleukin-1alpha (IL) in promoting cleavage at these sites in ADAMTS-5-deficient cartilage. These results suggest that cleavage at preferred sites in the chondroitin sulfate-rich region is mediated by ADAMTS-4 or an aggrecanase other than ADAMTS-5. Following retinoic acid or IL-1alpha stimulation of cartilage explants, aggrecan fragments in medium and extracts contained SELE(1279) or FREEE(1467) C-terminal sequences. Some SELE(1279) and FREEE(1467) fragments were retained in the cartilage, with intact G1 domains. Other SELE(1279) fragments were released into the medium and co-migrated with the (374)ALGS neoepitope, indicating they were aggrecanase-derived fragments. In contrast none of the FREEE(1467) fragments released into the medium co-migrated with the (374)ALGS neoepitope, suggesting that, despite their size, these fragments were not products of aggrecanase cleavage in the interglobular domain. ADAMTS-5, but not ADAMTS-1, -4, or -9, was up-regulated 8-fold by retinoic acid and 17-fold by IL-1alpha treatment. The data show that whereas ADAMTS-5 is entirely responsible for cleavage in the interglobular domain, cleavage in the chondroitin sulfate-rich region is driven either by ADAMTS-4, which compensates for loss of ADAMTS-5 in this experimental system, or possibly by another aggrecanase. The data show that there are differential aggrecanase activities with preferences for separate regions of the core protein.
在小鼠中,聚集蛋白聚糖球间结构域的蛋白水解由ADAMTS-5驱动,在关节炎实验模型中,缺乏ADAMTS-5催化活性的小鼠可免受聚集蛋白聚糖丢失和软骨损伤的影响。在此我们表明,尽管ADAMTS-5活性缺失,但在富含硫酸软骨素的区域的两个优先位点仍可发生聚集蛋白聚糖分解。在促进ADAMTS-5缺陷软骨中这些位点的切割方面,视黄酸比白细胞介素-1α(IL)更有效。这些结果表明,富含硫酸软骨素区域优先位点的切割是由ADAMTS-4或除ADAMTS-5之外 的一种聚集蛋白聚糖酶介导的。在用视黄酸或IL-1α刺激软骨外植体后,培养基和提取物中的聚集蛋白聚糖片段含有SELE(1279)或FREEE(1467) C末端序列。一些SELE(1279)和FREEE(1467)片段保留在软骨中,G1结构域完整。其他SELE(1279)片段释放到培养基中,并与(374)ALGS新表位共同迁移,表明它们是聚集蛋白聚糖酶衍生的片段。相比之下,释放到培养基中的FREEE(1467)片段均未与(374)ALGS新表位共同迁移,这表明,尽管它们的大小合适,但这些片段不是球间结构域中聚集蛋白聚糖酶切割的产物。视黄酸处理使ADAMTS-5上调8倍,IL-1α处理使其上调17倍,而ADAMTS-1、-4或-9则未上调。数据表明,虽然ADAMTS-5完全负责球间结构域的切割,但富含硫酸软骨素区域的切割要么由在该实验系统中补偿ADAMTS-5缺失的ADAMTS-4驱动,要么可能由另一种聚集蛋白聚糖酶驱动。数据表明,存在不同的聚集蛋白聚糖酶活性,对核心蛋白的不同区域有偏好。
