In osteoarthritis (OA), articular chondrocytes undergo a phenotypic change and acquire a gene expression repertoire that is characterized by the aberrant expression of numerous catabolic genes including matrix metalloproteinases 3, 9 and 13, ADAMTS-4 and interleukin-1beta (IL1B = gene, IL-1b=protein). Previous studies (Arthritis Rheum 52;3110-24) have shown that epigenetic DNA demethylation at specific CpG sites in the relevant promoters accounts for the aberrant expression and that inflammatory cytokines (TNF-alpha, oncostatin M, IL-1b) can cause both aberrant expression and loss of DNA methylation, at least in vitro (Arthritis Rheum. 2009, 60,3303-3313). If the mechanisms of DNA de-methylation were understood, they might provide a new molecular target for therapeutic intervention. We hypothesize that nuclear translocation of the transcription factor NF-kB is involved in de-methylation because 1) we and others have demonstrated that cytokine-induced expression of IL1B in healthy chondrocytes requires NF-kB and 2) DNA de-methylation during B cell maturation was crucially dependent on the rel/NF-kB family (Nat Genet. 1996, 13,435-441). The aims of the study were to determine whether the NF-kB inhibitor BAY 11-7082 (BAY) could prevent the cytokine-induced loss of DNA de-methylation and thereby show that NF-kB is required for DNA de-methylation.

Chondrocytes at the lower zone of the growth plate must be eliminated to facilitate longitudinal growth; this is generally assumed to involve apoptosis. We attempted to provide definitive electron-microscopic evidence of apoptosis in chondrocytes of physes and chondroepiphyses in the rabbit. We were, however, unable to find a single chondrocyte with the ultrastructure of ‘classical’ apoptosis in vivo, although such a cell was found in vitro. Instead, condensed chondrocytes had a convoluted nucleus with patchy chromatin condensations while the cytoplasm was dark with excessive amounts of endoplasmic reticulum. These cells were termed ‘dark chondrocytes’. A detailed study of their ultrastructure combined with localisation methods in situ suggested a different mechanism of programmed cell death. In addition, another type of death was identified among the immature chondrocytes of the chondroepiphysis. These cells had the same nucleus as dark chondrocytes, but the lumen of the endoplasmic reticulum had expanded to fill the entire non-nuclear space, and all cytoplasm and organelles had been reduced to dark, worm-like inclusions. Since these cells appeared to be ‘in limbo’, they were termed ‘paralysed’ cells. It is proposed that ‘dark chondrocytes’ and ‘paralysed cells’ are examples of physiological cell death which does not involve apoptosis. It is possible that the confinement of chondrocytes within their lacunae, which would prevent phagocytosis of apoptotic bodies, necessitates different mechanisms of elimination.

Growth plates taken from five- to 20-week-old Japanese white rabbits were immunostained for c-Myc protein. This was localised both in the proliferating zone and upper hypertrophic zone at five weeks, whereas after ten weeks it was found mostly in the lower hypertrophic zone. The proliferating chondrocytes tended to show nuclear staining and the hypertrophic cells cytoplasmic staining, although the terminal hypertrophic chondrocytes sometimes expressed the protein in their nuclei. In the younger rabbits, c-Myc co-localised with proliferating cell nuclear antigen, whereas in the hypertrophic zone of older rabbits, it was present in some chondrocytes the nuclei of which also contained DNA breaks.

Our study suggests that, in the rabbit growth plate, c-Myc is associated with different cellular processes, depending on the age and the developmental stage of the chondrocytes.

Chondrocytes of the growth plate are generally assumed to undergo apoptosis, but the mechanisms which induce this cell death are not known. The Fas receptor is a mediator of the apoptotic signal in some systems. We studied its expression in situ in growth plates of rabbits aged from five to 20 weeks. In addition, we investigated the immunolocalisation in the growth plates of the bone proteins, osteonectin and osteocalcin, and the changes in their expression with age.

The Fas-positive chondrocytes were found mostly in the hypertrophic zone, as were the osteonectin-positive and osteocalcin-positive cells. The percentage of Fas-positive cells increased with age whereas little change was found in the number of osteonectin-positive and osteocalcin-positive chondrocytes.

Many of the Fas-positive chondrocytes were also TUNEL-positive. This strongly suggests that apoptosis in the growth plate is mediated through the Fas system.

Double immunostaining for osteocalcin and Fas showed that not all hypertrophic chondrocytes were of the same cell type. Some chondrocytes stained for osteocalcin only, others for Fas only, while some were positive for both.