Insulin-like growth factor (IGF)-I, -II, IGF binding proteins (IGFBP)-3, -4, and -5 levels in the conditioned media of normal human bone cells are skeletal site-dependent.

The skeleton in its function of affording strength and support to the body is subject to differential mechanical loading which has been implicated to mediate some of its effects on bone formation via the insulin-like growth factors (IGFs), which are important regulators of bone metabolism. We, therefore, sought to conduct the present study with the hypothesis that the skeletal site-dependent differences in mechanical loading and other variables including stage of osteoblast differentiation would be associated with site-specific differences in the production of the IGF system components. To test this hypothesis, conditioned media (CM) from normal human bone cells (control and IGF-II-treated 48-h cultures) from five different skeletal sites were obtained and assayed for IGF-I, IGF-II (following separation of IGF binding proteins [IGFBPs]), IGFBP-3, IGFBP-4, and IGFBP-5 protein levels employing specific radioimmunoassays for each protein. IGF-I levels were lower than any other IGF system component but were significantly different between the various sites tested. IGF-II levels were greatest in the CM from mandibular cells, followed by calvarial and rib cells, and least in the marrow stromal cells. IGFBP-3 levels were highest in the CM of vertebral cells and lowest in the CM of rib and mandibular cells. The relative abundance of IGFBP-4 in decreasing order was observed in mandibular, calvarial, vertebral, rib, and stromal cells' CM. IGFBP-5 was produced maximally by the calvarial cells, followed by the mandibular, vertebral, stromal, and rib cells. IGFBP-4 appeared to be the IGF system component most abundantly produced by all the cell types from the skeletal sites tested. On a molar basis, the IGFBPs in general were estimated to be produced at a higher magnitude than the IGFs. These findings indicate that there are skeletal site-dependent differences in the production of IGF system components and suggest that the regulation of bone metabolism may vary at the various skeletal sites.