Increase In Osteogenesis Research Articles

Osteogenic growth peptide regulates proliferation and osteogenic maturation of human and rabbit bone marrow stromal cells

The recently discovered osteogenic growth peptide (OGP) has been shown to regulate proliferation in fibroblastic and osteoblastic cell lines derived from rats and mice and also alkaline phosphatase activity in the latter was found to be affected. In vivo the OGP enhances bone formation and trabecular bone density. The results of the current study indicate that the OGP is also a potent regulator of marrow stromal cells from man and rabbit, as well as rabbit muscle fibroblasts. The main OGP activity in both marrow systems is a marked stimulation of alkaline phosphatase activity and matrix mineralization. In the rabbit-derived cell culture this enhancement is accompanied by a reciprocal inhibition of proliferation. On the other hand, the human cells show a concomitant increase of both parameters. The proliferative effect of the OGP is similar to that of growth hormone (GH) and basic fibroblast growth factor (bFGF). The combined activity of the OGP with GH is smaller than that of each of the polypeptides alone. The OGP and bFGF potentiate each other. Of the three polypeptides tested, OGP is the most potent enhancer of alkaline phosphatase activity and mineralization. bFGF has no influence on these characteristics of osteogenic maturation. The OGP maturational activity is unaffected by either GH or bFGF. These data suggest that the marrow stromal cells serve as targets for the OGP that mediate the OGP-induced increase in osteogenesis. The effect on the human cells implies a role for the OGP in clinical situations where the osteogenic potential of bone marrow is involved.

The effects of oophorectomy on skeletal metabolism

The effects of oophorectomy on the biological indices of bone remodelling and the time-course of their changes are described. In the first few months following surgical menopause the measurement of the markers of bone remodelling indicates that the increase in osteogenesis is delayed compared with that of bone resorption; this prevalence of destruction over new bone depositon justifies the deficiency of skeletal balance, shortly after acute oestrogen deficiency. The changes in bone remodelling are accompanied by an increase in serum calcium while serum immunoreactive parathyroid hormone levels remain unchanged or even decrease, suggesting a shift to right of the parathyroid gland set-point. The reasons for the negative skeletal balance after oophorectomy might be sought therefore at bone tissue level, even if changes in responsiveness and/or of the parathyroid gland set-point could also be contributory.

Regenerating Marrow Induces Systemic Increase in Osteo- and Chondrogenesis

Marrow ablation in long bones induces an increase in osteogenesis in distant skeletal sites. To test the role of marrow regeneration in this phenomenon, rat mandibular condyles were evaluated histomorphometrically during postablation healing of tibial marrow and after inhibition of healing. Ten days after removal of tibial marrow all bone formation parameters in the condylar subchondral bone were markedly elevated, indicating an enhanced osteoblastic activity. The thickness of the cartilaginous zone of calcification was also augmented. These changes were absent when postablation healing was inhibited in the tibia and after massive liver injury. Extensive periosteal injury induced only a slight increase in osteoblast activity. Except for a fall on day 7, the [methyl-3H]thymidine labeling index in the condylar cartilage and oral mucosa remained at control levels 3-18 days after ablation. These findings imply that stimulation of cell proliferation has only a secondary role in the skeletal response to marrow ablation. It is concluded that the systemic increase in osteogenesis occurs preferentially during marrow regeneration and is not a nonspecific skeletal reaction to tissue injury. Apparently, the systemic osteogenic response is mediated by circulating factors produced by the healing marrow; conceptually it is related to other instances where local repair in extraskeletal sites is accompanied by generalized alterations in respective tissues.

Regenerating bone marrow produces a potent growth-promoting activity to osteogenic cells.

It is well documented that injury to bone marrow is followed by an osteogenic phase that precedes the complete tissue regeneration. We have recently shown that postablation healing of bone marrow in rat tibiae is associated with a systemic increase in osteogenesis. It was hypothesized that a growth factor(s) with an effect on osteogenic cells is produced in the healing limb, is transferred to the blood circulation, and enhances osteogenesis systemically. To test growth factor production, healing bone marrow-conditioned medium was prepared with tissue separated from rat tibias during the osteogenic phase and assayed for enhancement of mitogenic activity in culture of osteogenic rat osteosarcoma cells (ROS 17/2). Partial purification of healing bone marrow-conditioned medium-derived growth factor(s) consisted of gel filtration on Sephadex G-25, boiling, chromatography on heparin-Sepharose, and gel filtration on Sephadex G-75. Mitogenic activity eluted in the void volume of the Sephadex G-25 column (mol wt greater than 5,000). Potent activity resolved from heparin-Sepharose with PBS, and on filtration by Sephadex G-75 this activity recovered in 3 peaks with mol wt estimates of 35,000, 19,000, and less than 10,000. The partially purified factor also showed considerable stimulatory effect on DNA synthesis in osteoblastic fetal rat calvarial cells and on in vitro elongation of fetal long bone; it had only a small effect on nonosteoblastic ROS and fetal rat calvarial cells. These data indicate that healing bone marrow produces growth factor activity with a preferential effect on osteogenic cells. It is suggested that local growth factors have a role as mediators in the sequence of events whereby bone marrow expresses its osteogenic potential. During postablation healing of bone marrow these factors may also function as systemic promoters to osteogenic cells.