An assay for bacterial and eukaryotic chondroitinases using a chondroitin sulfate-binding protein.

A simple, rapid, and reproducible microtiter-based chondroitinase (CSase) assay is reported here, based on the competition of chondroitin sulfate (CS) with immobilized hyaluronan (HA) for the binding of TSG-6 protein, the product of TNF-inducible gene 6. Although the catabolic reaction of bacterial and other prokaryotic CSase enzymes, often referred to as the chondroitin lyases, can be followed by tracking the generation of unsaturated bonds by the spectrophotometrical determination of the absorbance at 232 nm, no rapid, sensitive, and simple assay has been devised to date for measuring the activity of the vertebrate enzymes that cleave their substrate exclusively by hydrolysis. We provide data demonstrating that the CSase assay described here is suitable for the determination of the activities of both classes of enzymes. For the bacterial enzyme CSase ABC, both the determination of the absorbance at 232 nm and the assay based on TSG-6 binding are suitable using the same range of enzyme activities. However, for testicular hyaluronidase, considerably higher enzyme activities were needed to cleave CS than to cleave HA. Using the HA-binding domain of aggrecan for a comparison, we determined that the interaction between TSG-6 and chondroitin sulfate is uniquely suited for this CSase assay.

TSG-6 protein binding to glycosaminoglycans: formation of stable complexes with hyaluronan and binding to chondroitin sulfates.

TSG-6 protein, up-regulated in inflammatory lesions and in the ovary during ovulation, shows anti-inflammatory activity and plays an essential role in female fertility. Studies in murine models of acute inflammation and experimental arthritis demonstrated that TSG-6 has a strong anti-inflammatory and chondroprotective effect. TSG-6 protein is composed of the N-terminal link module that binds hyaluronan and a C-terminal CUB domain, present in a variety of proteins. Interactions between the isolated link module and hyaluronan have been studied extensively, but little is known about the binding of full-length TSG-6 protein to hyaluronan and other glycosaminoglycans. We show that TSG-6 protein and hyaluronan, in a temperature-dependent fashion, form a stable complex that is resistant to dissociating agents. The formation of such stable complexes may underlie the activities of TSG-6 protein in inflammation and fertility, e.g. the TSG-6-dependent cross-linking of hyaluronan in the cumulus cell-oocyte complex during ovulation. Because adhesion to hyaluronan is involved in cell trafficking in inflammatory processes, we also studied the effect of TSG-6 on cell adhesion. TSG-6 binding to immobilized hyaluronan did not interfere with subsequent adhesion of lymphoid cells. In addition to immobilized hyaluronan, full-length TSG-6 also binds free hyaluronan and all chondroitin sulfate isoforms under physiological conditions. These interactions may contribute to the localization of TSG-6 in cartilage and to its chondroprotective and anti-inflammatory effects in models of arthritis.