Expression patterns of matrix metalloproteinases and vascular endothelial growth factor during epiphyseal ossification.

UNLABELLED: In situ hybridization studies allowed for the localization of three MMPs and the angiogenic factor VEGF during secondary ossification. MMPs were widely expressed during ossification of the secondary center, whereas expression of VEGF was restricted to later stages. INTRODUCTION: The spatiotemporal expression patterns of the matrix metalloproteinases gelatinase-B (MMP-9), collagenase-3 (MMP-13), and membrane-type 1 metalloproteinase (MMP-14) and the angiogenic peptide vascular endothelial growth factor (VEGF) were studied during development of the proximal epiphysis of the rat tibia. MATERIALS AND METHODS: Cell expression was analyzed by in situ hybridization. Studies on osteoclastic activity, matrix mineralization, cell proliferation, and vascular progression were also performed. RESULTS: MMP-9, MMP-13, and MMP-14 were expressed in discrete perichondrial cells that gave way to sites of intrachondral canal formation. High expression levels for the three MMPs were found at the blind ends of advancing intrachondral canals and at the expanding borders of the marrow space. Signals for MMP-9 and MMP-13 were in close proximity but did not overlap, whereas MMP-14 was expressed in both MMP-9+ and MMP-13+ cells. VEGF was not expressed during formation of intrachondral vascular canals but was observed in hypertrophic chondrocytes during formation of the bone marrow cavity. CONCLUSIONS: Expression of MMPs and VEGF are constant events during development of the secondary ossification center. We propose that MMPs are involved in targeting proteolytic activity during epiphyseal development. VEGF is not expressed during early formation of vascular canals, but it may have a role in the formation of the bone marrow cavity.

Chondrocytes are released as viable cells during cartilage resorption associated with the formation of intrachondral canals in the rat tibial epiphysis.

The development of cartilage canals is the first event of the ossification of the epiphyses in mammals. Canal formation differs from vascular invasion during primary ossification, since the former involves resorption of resting cartilage and is uncoupled from bone deposition. To learn more about the fate of resorbed chondrocytes during this process, we have carried out structural, cell proliferation, and in situ hybridization studies during the first stages of ossification of the rat tibial proximal epiphysis. Results concerning the formation of the cartilage canals implied the release of resting chondrocytes from the cartilage matrix to the canal cavity. Released chondrocytes had a well-preserved structure, expressed type-II collagen, and maintained the capacity to divide. All these data suggested that chondrocytes released into the canals remained viable for a specific time. Analysis of the proliferative activity at different regions of the cartilage canals showed that the percentage of proliferative chondrocytes at areas of active cartilage resorption was significantly higher than that in zones of low resorption. These results are consistent with the hypothesis that resting chondrocytes surrounding canals have a role in supplying cells for the development of the secondary ossification center. Since released chondrocytes are at an early stage of differentiation greatly preceding their entry into the apoptotic pathway and are exposed to a specific matrix, cellular, and humoral microenvironment, they might differentiate to other cell types and contribute to the ossification of the epiphysis.