Thyroid hormones increase insulin-like growth factor I content in the medium of rat bone tissue

Abstract

The mechanism of action of thyroid hormones on bone is still not clear. At low concentrations, they stimulate bone formation; at high concentrations, they elicit bone resorption in vitro and in vivo. In the present study we investigated the effect of T₃ and T₄ as well as their active and inactive analogs (TRIAC, SKF L-94901, rT₃, and DIT) on the IGF-I and TNF-α content in the medium of UMR-106 rat osteoblastic cells and fetal rat limb bones. In the dose-response studies, a biphasic increase in medium IGF-I was observed in both cells and limb bones, with peak stimulatory concentrations of 10⁻⁸ M for T₃ and 10⁻⁷ M for T₄ in both systems. At higher concentrations, at which thyroid hormones elicit bone resorption, the stimulatory effect diminished and finally was no longer detectable. The active analogs TRIAC and SKF L-94901 also enhanced IGF-I release in UMR-106 cells. The inactive compounds rT₃ and DIT failed to increase IGF-I in these cultures. The protein content of the cell culture wells exposed to high concentrations of thyroid hormones was similar to those containing low concentrations, indicating that the decrease in IGF-I content at high doses was not due to toxic effects. This was also confirmed by trypan blue exclusion. Time course studies with UMR-106 cells revealed a significant increase in medium IGF-I after 2 days of incubation. No significant further increase was observed after this up to 5 days of culture. In contrast, the medium of limb bone cultures showed a linear increase in IGF-I content up to 7 days of culture. No TNF-α production was observed in either UMR-106 cells or fetal limb bones. Also, no increase in medium TNF-α levels was seen in response to thyroid hormones. Based on our results, we conclude that IGF-I may be responsible for some of the anabolic effects of thyroid hormones in bone tissue, but TNF-α, at least in the models we used, does not play a role in the mediation of thyroid hormone action.