Introduction: In a previous study (Hayes et al., 2007)we reported that novel chondroitin sulphate (CS) sulphation motifs on cell-associated proteoglycans (PGs) may be putative biomarkers of progenitor/stem cell sub-populations resident within the superficial zone of articular cartilage (Dowthwaite et al., 2005). In this study, using the same panel of antibodies, we examine the distribution of novel CS sulphation epitopes in a more clinically relevant model – the developing human knee joint.
Methods: Twelve-14 week human foetal knee joint rudiments were processed into paraffin wax then de-waxed and immunoperoxidase-stained with mAbs 3B3(−), 7D4 and 4C3 using the Vector Universal Elite kit with Nova Red, Mayers Haematoxylin, mounted under coverslips and then photographed.
Results: All three CS sulphation motif epitopes localised prominently at sites of incipient articular cartilage formation at a stage before there was any histological evidence of secondary ossification at the epiphysis. Interestingly, these CS epitopes were also detectable in very defined regions within the perichondrium; growth plate; the fibrocartilage of both meniscus and enthesis; vasculature; and at sites of capillary invasion, with subtle differences in their distribution; for example, 3B3(−) identified the cellular lining of cartilage canals within the epiphyses, whereas 7D4 labelled more their cellular contents.
Discussion: The results of this study show that novel CS sulphation motifs on cell and matrix PGs play important and diverse roles in the development of a wide range of musculoskeletal connective tissues, including articular cartilage. We hypothesize that the unique sulphation sequences on CS-containing PGs are involved in regulating cell proliferation and differentiation events, through interaction with soluble signalling molecules (e.g. growth factors) in the extracellular milieu. These antibodies show considerable promise for uses in tissue engineering applications for identifying and sorting stem/progenitor cells for regeneration of musculoskeletal tissues.