Dynamic regulation of Na(+)-K(+)-2Cl(-) cotransporter surface expression by PKC-{epsilon} in Cl(-)--secretory epithelia.

In secretory epithelia, activation of PKC by phorbol ester and carbachol negatively regulates Cl(-) secretion, the transport event of secretory diarrhea. Previous studies have implicated the basolateral Na(+)-K(+)-2Cl(-) cotransporter (NKCC1) as a target of PKC-dependent inhibition of Cl(-) secretion. In the present study, we examined the regulation of surface expression of NKCC1 in response to the activation of PKC. Treatment of confluent T84 intestinal epithelial cells with the phorbol ester 12-O-tetradecanoylphorbol-13-acetate (PMA) reduced the amount of NKCC1 accessible to basolateral surface biotinylation. Loss of cell surface NKCC1 was due to internalization as shown by 1) the resistance of biotinylated NKCC1 to surface biotin stripping after incubation with PMA and 2) indirect immunofluorescent labeling. PMA-induced internalization of NKCC1 is dependent on the epsilon-isoform of PKC as determined on the basis of sensitivity to a panel of PKC inhibitors. The effect of PMA on surface expression of NKCC1 was specific because PMA did not significantly alter the amount of Na(+)-K(+)-ATPase or E-cadherin available for surface biotinylation. After extended PMA exposure (>2 h), NKCC1 became degraded in a proteasome-dependent fashion. Like PMA, carbachol reduced the amount of NKCC1 accessible to basolateral surface biotinylation in a PKC-epsilon-dependent manner. However, long-term exposure to carbachol did not result in degradation of NKCC1; rather, NKCC1 that was internalized after exposure to carbachol was recycled back to the cell membrane. PKC-epsilon-dependent alteration of NKCC1 surface expression represents a novel mechanism for regulating Cl(-) secretion.

E-cadherin binding modulates EGF receptor activation.

We found that E-cadherin and epidermal growth factor receptor (EGFR) are associated in mammary epithelial cells and that E-cadherin engagement in these cells induces transient activation of EGFR, as previously seen in keratinocytes (37). In contrast, EGFR does not associate with and is not activated by N-cadherin. Analysis of cells expressing chimeric cadherins revealed that the extracellular domain of E-cadherin is required for interaction with and activation of EGFR. This activation results in tyrosine phosphorylation of known EGFR substrates and reduction in focal adhesions. These interactions, however, are not necessary for suppression of cell motility by E-cadherin.

Two regions of cadherin cytoplasmic domains are involved in suppressing motility of a mammary carcinoma cell line.

E-cadherin has been termed an "invasion suppressor," yet the mechanism of this suppression is not known. In contrast, several reports indicate N-cadherin does not suppress but, rather, promotes cell motility and invasion. Here, by characterizing a series of chimeric cadherins we defined a previously uncharacterized region consisting of the transmembrane domain and an adjacent portion of the cytoplasmic segment that is responsible for the difference in ability of E- and N-cadherin to suppress movement of mammary carcinoma cells, as quantified from time-lapse video recordings. A mutation in this region enabled N-cadherin to suppress motility, indicating that both E- and N-cadherin can suppress, but the activity of N-cadherin is latent, presumably repressed by binding of a specific inhibitor. To define regions common to E- and N-cadherin that are required for suppression, we analyzed a series of deletion mutants. We found that suppression of movement requires E-cadherin amino acids 699-710. Strikingly, beta-catenin binding is not sufficient for and p120ctn is not involved in suppression of these mammary carcinoma cells. Furthermore, the comparable region of N-cadherin can substitute for this required region in E-cadherin and is required for suppression by the mutant form of N-cadherin that is capable of suppressing. Variations in expression of factors that bind to the two regions we have identified may explain previously observed differences in response of tumor cells to cadherins.

Galpha12 and Galpha13 negatively regulate the adhesive functions of cadherin.

Cadherins function to promote adhesion between adjacent cells and play critical roles in such cellular processes as development, tissue maintenance, and tumor suppression. We previously demonstrated that heterotrimeric G proteins of the G12 subfamily comprised of Galpha12 and Galpha13 interact with the cytoplasmic domain of cadherins and cause the release of the transcriptional activator beta-catenin (Meigs, T. E., Fields, T. A., McKee, D. D., and Casey, P. J. (2001) Proc. Natl. Acad. Sci. U. S. A. 98, 519-524). Because of the importance of beta-catenin in cadherin-mediated cell-cell adhesion, we examined whether G12 subfamily proteins could also regulate cadherin function. The introduction of mutationally activated G12 proteins into K562 cells expressing E-cadherin blocked cadherin-mediated cell adhesion in steady-state assays. Also, in breast cancer cells, the introduction of activated G12 proteins blocked E-cadherin function in a fast aggregation assay. Aggregation mediated by a mutant cadherin that lacks G12 binding ability was not affected by activated G12 proteins, indicating a requirement for direct G12-cadherin interaction. Furthermore, in wound-filling assays in which ectopic expression of E-cadherin inhibits cell migration, the expression of activated G12 proteins reversed the inhibition via a mechanism that was independent of G12-mediated Rho activation. These results validate the G12-cadherin interaction as a potentially important event in cell biology and suggest novel roles for G12 proteins in the regulation of cadherin-mediated developmental events and in the loss of cadherin function that is characteristic of metastatic tumor progression.