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Orthopaedic Proceedings
Vol. 85-B, Issue SUPP_I | Pages 1 - 1
1 Jan 2003
Roach H Shukunami C Hiraki Y
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Chondromodulin-I (ChM-I) is a bifunctional autocrine regulator of cartilage, initially isolated from fetal bovine epiphyseal cartilage1. ChM-I stimulates matrix synthesis of chondrocytes, but inhibits the growth of endothelial cells1,2 thus ChM-I may be one of the anti-angiogenic molecules present in cartilage. In fetal bovine bone, ChM-I was expressed by all epiphyseal and growth plate chondrocytes except hypertrophic chondrocytes and was present in the matrix throughout the epiphysis and the growth plate, except the hypertrophic zone 2,3, consistent with its proposed role as anti-angiogenic factor. To examine the possible role of chondromodulin-I in relation to angiogenesis at the vascular front, we studied the immunolocalisation in femoral growth plates from young and mature rats (2–16 weeks) as well as aged rats (62–80 weeks), using a rabbit polyclonal antibody raised against the entire region of mature human recombinant ChM-I.

In 2-week old rats, ChM-I was synthesised by all epiphyseal chondrocytes and strong immunostaining was found in the matrix. In the growth plates, ChM-I staining was present in chondrocytes and matrix of the reserve, proliferating and maturing zones with loss of staining in the hypertrophic zone. However, ChM-I was also present where cartilage canals had penetrated into the chondroepiphysis. In 4–16 week old rats, there was a progressive change in the localisation of ChM-I. Hypertrophic chondrocytes also became positive for ChM-I, while cellular staining gradually disappeared from the other zones. By 12–16 weeks, very strong immunostaining was present almost exclusively on the inner perimeter of the lacunae of hypertrophic chondrocytes. As lacunae were opened at the vascular front, ChM-I initially remained on the cartilage-side of the lacunae, and then disappeared completely. In aged rats, very little ChM-I was present in the cells and matrix of the growth plates, except where remodelling had occurred or chondrocytes had become re-activated.

The rate of longitudinal growth in rats is high between 1–5 weeks, then declines until skeletal maturity at approximately 12 weeks, after which a very slow rate of growth continues until 26 weeks. In young rats, the loss of ChM-I in the hypertrophic zone was as expected for an anti-angiogenic factor, i.e. loss was required before vascular invasion could take place. However, the same did not apply to cartilage canal formation, since there was no loss of ChM-I around cartilage canals. The change in the localisation of ChM-I in mature rats, in particular the very intense immunolocalisation around hypertrophic chondrocytes, might be related to the reduced rate of growth. It is possible that rapid vascular invasion must be slowed down in these growth plates and that ChM-I prevented vascular invasion until degraded by proteases, such as MMP-9.

The relative absence of ChM-I in the stationary growth plates of aged rats suggests that other anti-angiogenic factors prevent vascular invasion in these growth plates.