Cellular polarization involves the generation of asymmetry along an intracellular axis. In a multicellular tissue, the asymmetry of individual cells must conform to the overlying architecture of the tissue. However, the mechanisms that couple cellular polarization to tissue morphogenesis are poorly understood. Here, we report that orientation of apical polarity in developing Madin-Darby canine kidney (MDCK) epithelial cysts requires the small GTPase Rac1 and the basement membrane component laminin. Dominant-negative Rac1 alters the supramolecular assembly of endogenous MDCK laminin and causes a striking inversion of apical polarity. Exogenous laminin is recruited to the surface of these cysts and rescues apical polarity. These findings implicate Rac1-mediated laminin assembly in apical pole orientation. By linking apical orientation to generation of the basement membrane, epithelial cells ensure the coordination of polarity with tissue architecture.
Many organ systems are composed of networks of epithelial tubes. Recently, molecules that induce development of epithelial tubules and regulate sites of branching have been identified. However, little is known about the mechanisms regulating cell rearrangements that are necessary for tubule formation. In this study we have used a scatter factor/hepatocyte growth factor-induced model system of MDCK epithelial cell tubulogenesis to analyze the mechanisms of cell rearrangement during tubule development. We examined the dynamics of cell polarity and cell-cell junctions during tubule formation and present evidence for a multistep model of tubulogenesis in which cells rearrange without loss of cell-cell contacts and tubule lumens form de novo. A three-dimensional analysis of markers for apical and basolateral membrane subdomains shows that epithelial cell polarity is transiently lost and subsequently regained during tubulogenesis. Furthermore, components of cell-cell junctional complexes undergo profound rearrangements: E-cadherin is randomly distributed around the cell surface, desmoplakins I/II accumulate intracellularly, and the tight junction protein ZO-1 remains localized at sites of cell-cell contact. This suggests that differential regulation of cell-cell junctions is important for the formation of tubules. Therefore, during tubulogenesis, cell-cell adhesive contacts are differentially regulated while the polarity and specialization of plasma membrane subdomains reorganize, enabling cells to remain in contact as they rearrange into new structures.
β-Catenin is essential for the function of cadherins, a family of Ca2+-dependent cell–cell adhesion molecules, by linking them to α-catenin and the actin cytoskeleton. β-Catenin also binds to adenomatous polyposis coli (APC) protein, a cytosolic protein that is the product of a tumor suppressor gene mutated in colorectal adenomas. We have expressed mutant β-catenins in MDCK epithelial cells to gain insights into the regulation of β-catenin distribution between cadherin and APC protein complexes and the functions of these complexes. Full-length β-catenin, β-catenin mutant proteins with NH2-terminal deletions before (ΔN90) or after (ΔN131, ΔN151) the α-catenin binding site, or a mutant β-catenin with a COOH-terminal deletion (ΔC) were expressed in MDCK cells under the control of the tetracycline-repressible transactivator. All β-catenin mutant proteins form complexes and colocalize with E-cadherin at cell–cell contacts; ΔN90, but neither ΔN131 nor ΔN151, bind α-catenin. However, β-catenin mutant proteins containing NH2-terminal deletions also colocalize prominently with APC protein in clusters at the tips of plasma membrane protrusions; in contrast, full-length and COOH-terminal– deleted β-catenin poorly colocalize with APC protein. NH2-terminal deletions result in increased stability of β-catenin bound to APC protein and E-cadherin, compared with full-length β-catenin. At low density, MDCK cells expressing NH2-terminal–deleted β-catenin mutants are dispersed, more fibroblastic in morphology, and less efficient in forming colonies than parental MDCK cells. These results show that the NH2 terminus, but not the COOH terminus of β-catenin, regulates the dynamics of β-catenin binding to APC protein and E-cadherin. Changes in β-catenin binding to cadherin or APC protein, and the ensuing effects on cell morphology and adhesion, are independent of β-catenin binding to α-catenin. These results demonstrate that regulation of β-catenin binding to E-cadherin and APC protein is important in controlling epithelial cell adhesion.
Epithelial tubulogenesis involves complex cell rearrangements that require control of both cell adhesion and migration, but the molecular mechanisms regulating these processes during tubule development are not well understood. Interactions of the cytoplasmic protein, β-catenin, with several molecular partners have been shown to be important for cell signaling and cell–cell adhesion. To examine if β-catenin has a role in tubulogenesis, we tested the effect of expressing NH2-terminal deleted β-catenins in an MDCK epithelial cell model for tubulogenesis. After one day of treatment, hepatocyte growth factor/scatter factor (HGF/ SF)-stimulated MDCK cysts initiated tubulogenesis by forming many long cell extensions. Expression of NH2-terminal deleted β-catenins inhibited formation of these cell extensions. Both ΔN90 β-catenin, which binds to α-catenin, and ΔN131 β-catenin, which does not bind to α-catenin, inhibited formation of cell extensions and tubule development, indicating that a function of β-catenin distinct from its role in cadherin-mediated cell–cell adhesion is important for tubulogenesis. In cell extensions from parental cysts, adenomatous polyposis coli (APC) protein was localized in linear arrays and in punctate clusters at the tips of extensions. Inhibition of cell extension formation correlated with the colocalization and accumulation of NH2-terminal deleted β-catenin in APC protein clusters and the absence of linear arrays of APC protein. Continued HGF/ SF treatment of parental cell MDCK cysts resulted in cell proliferation and reorganization of cell extensions into multicellular tubules. Similar HGF/SF treatment of cysts derived from cells expressing NH2-terminal deleted β-catenins resulted in cells that proliferated but formed cell aggregates (polyps) within the cyst rather than tubules. Our results demonstrate an unexpected role for β-catenin in cell migration and indicate that dynamic β-catenin–APC protein interactions are critical for regulating cell migration during epithelial tubulogenesis.
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