117 research outputs found
Functional expression of the MHC class I-related receptor, FcRn, in endothelial cells of mice
Our recent data indicate that the MHC class I-related receptor, FcRn, plays a role in regulating serum IgG levels, in addition to its known role in transferring IgG from mother to young. In the current study, the distribution of FcRn in adult mice has been investigated using several approaches. First, tissue distribution of anti-FcRn F(ab')2, murine IgG1 and recombinant, IgG1-derived Fc-hinge fragments has been analyzed, and these FcRn binding proteins localize predominantly in skin and muscle with lesser amounts in liver and adipose tissue. Second, histochemical analyses of muscle and liver with anti-FcRn F(ab')2 indicate that FcRn is expressed in the endothelium of small arterioles and capillaries, but not in larger vessels such as the central vein and portal vasculature. Third, immunoprecipitation and immunofluorescence studies of cultured murine endothelial cells show that functional FcRn is expressed in these cells, and is located within vesicular structures in the cytosol and not on the membrane. Taken together the data demonstrate that FcRn is expressed in functionally active form in endothelial cells, indicating that these cells are a possible site at which serum IgG homeostasis is maintained.</p
Endothelial Specific Binding Sites for Permeant Plasma Macromolecules: Albumin Binding Proteins
Proatherosclerotic events: pathobiochemical changes occurring in the arterial wall before monocyte migration
Diabetes-induced structural changes of venous and arterial endothelium and smooth muscle cells
The structural alterations of endothelium and smooth muscle cells of the hind limb and heart veins and arteries were investigated in Golden Syrian hamsters subjected to streptozotocin induced diabetes. Animals were examined at 5, 10, and 15 weeks after induction of diabetes. At each time point body weight and plasma glucose concentrations were recorded. Anesthetised animals were washed out of blood, fixed in situ, and the femoral vein and artery saphenous rein and artery, and heart veins and coronaries were dissected out, and processed for electron microscopical examination. Anionic sites of the endothelial plasmalemma were visualized by in situ perfusion of cationized ferritin. The endothelial localization of von Willebrand factor was carried out by immunocytochemistry. The results showed that induction of experimental diabetes generated morphological changes of the endothelium and smooth muscle cells of both hind limb and heart vessels. The common alterations developed in endothelial cells of venous and arterial origin consisted in: 1) the development of a secretory phenotype, enriched in biosynthetic and degradative organelles; 2) the abundance of cytoskeletal elements, especially intermediary filaments; 3) the increase in number of fused plasmalemmal vesicles and transendothelial channels, and 4) the hyperplasia of the basal lamina. In contradistinction to the arterial endothelium, the peculiarities of the venous endothelium in the diabetic hamsters examined were: 1) the uniform distribution of the anionic sites exposed on the luminal plasma lemma las in normal animals), and 2) the increased number of copies of Weibel-Palade bodies (up to 13 copies per endothelial cell in the hind limb). Von Willebrand factor was immunodetected in Weibel-Palade bodies, Golgi cisternae and some vesicles of normal and diabetic hamsters. With time, and especially pronounced at 15 weeks of diabetes, the smooth muscle cells of veins and arteries examined exhibited a characteristic secretory phenotype, and were surrounded by a reticulated basal lamina and a hyperplasic extracellular matrix (especially pronounced in arteries. These data indicate that diabetes affects both heart and hind limb veins and arteries, producing structural changes of the endothelium and smooth muscle cells which may account, at least in part, for the specific vascular complications.484475100,687Q
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