BACKGROUND: Estrogen protects against cardiovascular disease in both patients and animal models and regulates insulin-like growth factor-I (IGF-I), an important cell-cycle progression factor. METHODS AND RESULTS: Smooth muscle cells and tissues were harvested from male recipient rabbits that 6 weeks earlier had received a cardiac allograft transplant consisting of a donor heart and ascending aorta. Segments of the ascending aorta from the native and allograft hearts from 9 placebo-treated and 8 estradiol-treated recipients were compared by using IGF-I-stimulated [3H]thymidine incorporation. The responses of the native vessel segments were similar (175.3+/-32% and 166.9+/-41%, respectively; P>.05) whether or not the recipients had been treated for 6 weeks with estradiol. In the grafts, however, estradiol markedly inhibited vascular cell thymidine incorporation (328.04+/-56% compared with 67.3+/-11%; P<.02). Smooth muscle cells were derived from the native aorta of the placebo-treated rabbits to study the effect of estradiol in vitro. IGF-I increased cell counts in a concentration-dependent manner. In serum-starved cells estradiol further decreased cell proliferation; this effect was blocked by the specific estrogen receptor antagonist ZK-119.010. Immunohistochemistry staining for IGF-I protein in the coronary arteries and ascending aorta of the cardiac allograft from the placebo-treated recipients revealed extensive IGF-I expression in the myointima. In contrast, IGF-I protein was not expressed in the coronary arteries and ascending aorta of the cardiac allograft from the estradiol-treated recipients. The IGF-I protein was extensively expressed only in the placebo-treated graft vessels. Myointimal thickening of the coronary arteries was significantly reduced by estradiol treatment (17.9+/-1.5% versus 44.3+/-3.7%; P<.02). CONCLUSIONS: In vivo estradiol treatment abolishes both IGF-I mitogenic effects and IGF-I protein expression in the vascular wall, which may be causally related to the inhibitory effect of estradiol on transplant arteriosclerosis.
BACKGROUND: Estrogen protects against cardiovascular disease in both patients and animal models and regulates insulin-like growth factor-I (IGF-I), an important cell-cycle progression factor. METHODS AND RESULTS: Smooth muscle cells and tissues were harvested from male recipient rabbits that 6 weeks earlier had received a cardiac allograft transplant consisting of a donor heart and ascending aorta. Segments of the ascending aorta from the native and allograft hearts from 9 placebo-treated and 8 estradiol-treated recipients were compared by using IGF-I-stimulated [3H]thymidine incorporation. The responses of the native vessel segments were similar (175.3+/-32% and 166.9+/-41%, respectively; P>.05) whether or not the recipients had been treated for 6 weeks with estradiol. In the grafts, however, estradiol markedly inhibited vascular cell thymidine incorporation (328.04+/-56% compared with 67.3+/-11%; P<.02). Smooth muscle cells were derived from the native aorta of the placebo-treated rabbits to study the effect of estradiol in vitro. IGF-I increased cell counts in a concentration-dependent manner. In serum-starved cells estradiol further decreased cell proliferation; this effect was blocked by the specific estrogen receptor antagonist ZK-119.010. Immunohistochemistry staining for IGF-I protein in the coronary arteries and ascending aorta of the cardiac allograft from the placebo-treated recipients revealed extensive IGF-I expression in the myointima. In contrast, IGF-I protein was not expressed in the coronary arteries and ascending aorta of the cardiac allograft from the estradiol-treated recipients. The IGF-I protein was extensively expressed only in the placebo-treated graft vessels. Myointimal thickening of the coronary arteries was significantly reduced by estradiol treatment (17.9+/-1.5% versus 44.3+/-3.7%; P<.02). CONCLUSIONS: In vivo estradiol treatment abolishes both IGF-I mitogenic effects and IGF-I protein expression in the vascular wall, which may be causally related to the inhibitory effect of estradiol on transplant arteriosclerosis.