Coronary heart disease (CHD) is the leading cause of death in postmenopause. Estrogen administration in postmenopause lowers the risk of CHD by 50%. A variety of estrogen preparations are currently used in postmenopausal hormone replacement therapy. It is unknown, however, if structural differences in the estrogen molecule influence the cardioprotective effects of estrogens. In this communication we have shown that equine estrogens (especially equilin) exhibit higher antioxidant potency (as measured by fatty acids and sterols oxidation) when compared to estrone and estradiol-17 beta.
Growth hormone (GH) has been implicated in the pathogenesis of proliferative diabetic retinopathy. We sought to determine whether this could be mediated by an effect of GH on proliferation of endothelial cells, and, for this purpose, established long-term cultures of human retinal microvascular endothelial cells (hREC) from normal postmortem human eyes. High-purity (>95%) hREC preparations were selected for experiments, based on immunofluorescence with acetylated low density lipoprotein (LDL) and anti-factor VIIIrelated antigen. Growth requirements for these cells were complex, including serum for maintenance at slow growth rates and additional mitogens for more rapid proliferation. Exposure ofhREC to physiologic doses ofhuman GH (hGH) resulted in 100% greater cell number vs. control (P < 0.01) but could be elicited only in the presence of serum. When differing serum conditions were compared, hGH stimulated [3H]thymidine incorporation up to 1.6-to 2.2-fold under each condition and increased DNA content significantly in the presence of human, horse, and fetal calf serum. Depending on the culture conditions used, the threshold hGH concentration for significant stimulation of hREC proliferation was 0.4-4 pg/liter. In contrast, proliferation of human umbilical vein endothelial cells was not significantly altered by hGH added to concentrations as high as 200 pzg/liter. In summary, hREC respond to physiologic concentrations of hGH in vitro with enhanced proliferation. This specific effect of GH on retinal microvascular endothelial cells supports the hypothesis of a role for GH in endothelial cell biology.
Cell culture systems have commonly been used to study mechanisms implicated in the pathogenesis of diabetic retinopathy, but the great majority of cell preparations used have been either of nonhuman retinal origin or nonretinal human origin. Because of questions of species and organ specificity in the function of cells of vascular origin, in this study, cultured microvascular endothelial cells (HREC), pericytes (HRPC), and pigment epithelial cells from the postmortem human retina, and endothelial cells from human umbilical vein (HUVEC) were evaluated with respect to cell proliferation, and secretory products potentially important in diabetic retinopathy, i.e., prostaglandins (PG) and plasminogen activators (PA), normalized to DNA content/well, under both basal (5 mM) and high (25 mM) glucose conditions. Glucose (25 mM) reduced DNA content similarly in both types of endothelial cells, had a lesser effect on HRPC, and did not significantly alter the proliferation of pigment epithelial cells. Basal secretion of PGI2 (measured as 6-keto-PGF1 alpha) was in the order HRPC much greater than HREC greater than HUVEC, whereas PGE2 secretion was in the order HREC much greater than HRPC greater than HUVEC. Glucose (25 mM) stimulated PGI2 secretion by HRPC, but not by either type of endothelial cell, and enhanced PGE2 secretion by HREC, but not by HUVEC or HRPC. Release of plasminogen activator activity differed between HUVEC and HREC under basal conditions and addition of 25 mM glucose stimulated release only from HREC. Glucose (25 mM) stimulated PA secretion by HREC, but not by HUVEC. These findings provide evidence that human retinal pericytes are an important source of prostacyclin, and that there are differences between HREC and HUVEC with respect to secretory functions and their modulation by glucose, indicating regional specificity of these functions. Extrapolation to human retinal vascular cells from experiments using cells from heterologous vascular beds to draw inferences about the pathophysiology of diabetic retinopathy are not valid for these cellular functions.
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