Altered postnatal expression of insulin-like growth factor-I (IGF-I) and type X collagen preceding the Perthes' disease-like lesion of a rat model

The spontaneously hypertensive rat (SHR) is a widely used animal model for the study of hypertension. It also exhibits an osteonecrosis of the femoral epiphysis that resembles the clinical features of Perthes' disease in humans. In this rat model, occlusion of the epiphyseal vessels occurs as a result of a breakdown of the mechanically vulnerable epiphysis. The postnatal development of the epiphysis recapitulates the serial events of the endochondral ossification (i.e., cartilage formation), chondrocyte hypertrophy, cartilage mineralization, vascularization, and introduction of osteoblasts that form the secondary ossification center within the epiphysis. In the present study, a detailed radiographic and histological analysis demonstrates that the osteonecrosis is preceded by a disturbance of the cartilage mineralization and a disturbance of the ossification, despite a normal hypertrophy of the epiphyseal cartilage. These observations suggest that abnormal development of the femoral epiphysis occurs much earlier than manifestation of the osteonecrosis. They lead us to a hypothesis that yet-unclarified transitional events between the cartilage hypertrophy and the cartilage mineralization may be affected in SHRs. Type X collagen is a developmentally regulated matrix molecule that is implicated in the mineralization of the hypertrophied chondrocytes. We show that the expression of type X collagen during epiphyseal ossification is delayed in SHRs (vs. normal controls), suggesting disturbed growth and/or differentiation of the epiphyseal chondrocytes. Postnatal growth and differentiation of the chondrocytes at least partly depend on insulin-like growth factor-I (IGF-I), which is produced by the chondrocytes in response to the pituitary growth hormone and stimulates cartilage growth in situ. The present study demonstrates an altered IGF-I expression during early postnatal life in SHRs and suggests that the altered IGF-I expression as well as the following delay in upregulation of type X collagen may cause the mechanical vulnerability of the femoral epiphysis in SHRs.