Replacement of proteoglycans in embryonic chick cartilage in organ culture after treatment with testicular hyaluronidase

Abstract

Explants of cartilage from tibiae of 11–12 days chick embryos were grown in organ culture. To one group hyaluronidase was added to the medium during the first 2 days of culture; the treated tissue was then cultured in medium without enzyme for a further 4 days. Control explants grown in hyaluronidase-free medium for 6 days grew rapidly in size and the total hexosamine content more than doubled during this time. After exposure to hyaluronidase, much of the hexosamine was lost from treated cartilage and appeared in the culture medium, but it was mostly replaced in the tissue during the subsequent recovery period. Analysis of cartilage and medium showed that net synthesis of hexosamine increased greatly in treated cartilage. The proteoglycans were extracted by two procedures from control and treated cartilage after 2, 4 and 6 days in culture. The hydrodynamic sizes of the purified proteoglycans were compared by gel chromatography and the composition of the gel-chromatographic fractions was determined. The proteoglycans from controls did not change during culture, but after exposure to hyaluronidase the proteoglycans from treated cartilage were of much smaller size and lower chondroitin sulphate content. During recovery, even though new proteoglycans were formed, they were nevertheless of smaller size and lower chondroitin sulphate content than control proteoglycans. They gradually became more like control proteoglycans during recovery from treatment, but even after 4 days they were not yet the same. After 2 days of treatment with the enzyme, the chondroitin sulphate in the cartilage was of shorter chain length than in controls but during recovery after 4 and 6 days in culture, the chain lengths in control and treated cartilage were similar. It is concluded that the proteoglycans formed in embryo cartilage in response to their depletion by enzyme treatment contained fewer chondroitin sulphate chains attached to the protein moiety of proteoglycans. This may have resulted from a failure under stress to glycosylate the protein moiety to the usual extent; alternatively the synthesis of normal proteoglycans of low chondroitin sulphate content may have increased, thus changing the proteoglycan population.