engleski

Immunohistochemical and electronmicroscopic features of mesenchymal-to-epithelial transition in human developing, postnatal and nephrotic podocytes

Differentiation of human podocytes starts with mesenchymal-to-epithelial transition (MET) of the metanephric mesenchyme into the S-shaped nephrons. During further development, differentiating podocytes regain mesenchyme- like cell characteristics by epithelial-to – mesenchymal transition (MET), leading to formation of the terminally differentiated, non-dividing cell. Both MET and EMT processes involve changes in content and organization of cytoskeletal and actin filaments, accompanied by the increased glomerular vascularization. Here, we analyze and compare normal human developing, postnatal and nephrotic podocytes and glomeruli, using immunohistochemical and double immunofluorescent methods for detection of markers of cytoskeletal filaments (nestin, citokeratin10-CK10, vimentin and α –SMA), vasculogenesis (CD31 and VEGF) and podocyte function (receptor for advances glycation products RAGE). In addition, electron microscopy is used to detect ultrastructural changes of the podocytes. Early metanephric cup mesenchyme expresses all investigated markers except α –SMA, which characterizes only surface mesenchymal cells. In differentiating podocytes and cells of Bowman’s capsule (parietal podocytes) nestin decreases, vimentin increases while CK10 gradually disappears. Increase in α –SMA is associated with blood vessels development, appearance of podocyte pedicles and slit-diaphragm, and loss of intercellular connections (zonulae adherentes). Increase in CD31 characterizes vascular glomerular tufts development, while decrease in RAGE expression accompanies normal podocyte differentiation. In congenital nephrotic syndrome of the Finnish type (CNF), dedifferentiated podocytes display changes in cytoskeletal filaments and depletion of podocyte pedicles, while glomerular vascular supply is diminished. Our data also suggest high potential of metanephric mesenchyme and parietal podocytes in possible regeneration of the damaged podocytes.

human kidney development ; podocytes ; mesenchymal-to epithelial transition ; congenital nephrotic syndrome of the Finnish type ; cytoskeletal filaments

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