Wnt proteins are required for induction of nephrons in mouse metanephric kidneys, but the downstream pathways that mediate tubule induction and epithelial differentiation have remained obscure. The intracellular mechanisms by which Wnt signaling mediates nephron induction in embryonic kidney mesenchymes were studied. First is shown that transient exposure of isolated kidney mesenchymes to structurally different glycogen synthase kinase-3 (GSK3) inhibitors lithium or 6-bromoindirubin-3-oxime results in abundant epithelial differentiation and full segregation of nephrons. Shown further by mice with genetically disrupted ureteric bud or Wolffian duct development is that this nephrogenic competence arises independent of the influence of Wolffian duct-derived epithelia. Analysis of the intracellular signaling cascades downstream of GSK3 inhibition revealed stabilization of -catenin and upregulation of Lef1 and Tcf1, both events that are associated with the active canonical Wnt signaling. Last, genetic evidence that metanephric mesenchyme-specific stabilization of -catenin is sufficient to induce nephron differentiation in isolated kidney mesenchymes, similar to that induced by GSK3 inhibitors, is provided. These data show that activation of canonical Wnt pathway is sufficient to induce nephrogenesis and suggest that this pathway mediates the nephron induction in murine kidney mesenchymes.
Glial cell line–derived neurotrophic factor (GDNF) and hepatocyte growth factor (HGF) are multifunctional signaling molecules in embryogenesis. HGF binds to and activates Met receptor tyrosine kinase. The signaling receptor complex for GDNF typically includes both GDNF family receptor α1 (GFRα1) and Ret receptor tyrosine kinase. GDNF can also signal independently of Ret via GFRα1, although the mechanism has remained unclear. We now show that GDNF partially restores ureteric branching morphogenesis in ret-deficient mice with severe renal hypodysplasia. The mechanism of Ret-independent effect of GDNF was therefore studied by the MDCK cell model. In MDCK cells expressing GFRα1 but no Ret, GDNF stimulates branching but not chemotactic migration, whereas both branching and chemotaxis are promoted by GDNF in the cells coexpressing Ret and GFRα1, mimicking HGF/Met responses in wild-type MDCK cells. Indeed, GDNF induces Met phosphorylation in several ret-deficient/GFRα1-positive and GFRα1/Ret-coexpressing cell lines. However, GDNF does not immunoprecipite Met, making a direct interaction between GDNF and Met highly improbable. Met activation is mediated by Src family kinases. The GDNF-induced branching of MDCK cells requires Src activation, whereas the HGF-induced branching does not. Our data show a mechanism for the GDNF-induced branching morphogenesis in non-Ret signaling.
Gain-of-function mutations of ret receptor tyrosine kinase, the signaling receptor for glial cell line-derived neurotrophic factor, cause sporadic thyroid and adrenal malignancies as well as endocrine cancer syndromes, such as multiple endocrine neoplasia types 2A and 2B (MEN 2A and MEN 2B) and familial medullary thyroid carcinoma. Loss-of-function mutations of ret cause Hirschsprung's disease (HSCR) or colonic aganglionosis. In 20-30% of families with a mutation at residues 609, 611, 618, or 620 of RET, MEN 2A and familial medullary thyroid carcinoma cosegregate with HSCR. These mutations constitutively activate RET due to aberrant disulfide homodimerization and diminish the level of RET at the plasma membrane. It is not known how these mutations simultaneously lead to both gain- and loss-of-function RET-associated diseases. We provide an explanation for the dual phenotypic Janus mutation at Cys620 of RET. In Madin-Darby canine kidney (MDCK) cells, the Janus mutation impairs the glial cell line-derived neurotrophic factor-induced effects of RET on cell migration, differentiation, and survival but simultaneously promotes rapid cell proliferation.
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