Abstract
E-cadherin belongs to the classic cadherin subfamily of calcium-dependent cell adhesion molecules and is crucial for the formation and function of epithelial adherens junctions. In this study, we demonstrate that Vangl2, a vertebrate regulator of planar cell polarity (PCP), controls E-cadherin in epithelial cells. E-cadherin co-immunoprecipitates with Vangl2 from embryonic kidney extracts and this association is also observed in transfected fibroblasts. Vangl2 enhances the internalization of E-cadherin when overexpressed. Conversely, the quantitative ratio of E-cadherin exposed to the cell surface is increased in cultured renal epithelial cells derived from Vangl2Lpt/+ mutant mice. Interestingly, Vangl2 is also internalized through protein traffic involving Rab5- and Dynamin-dependent endocytosis. Taken together with recent reports regarding the transport of Frizzled3, MMP14 and nephrin, these results suggest that one of the molecular functions of Vangl2 is to enhance the internalization of specific plasma membrane proteins with broad selectivity. This function may be involved in the control of intercellular PCP signalling or in the PCP-related rearrangement of cell adhesions.
Similar content being viewed by others
Introduction
Planar cell polarity (PCP) is defined as uniform orientation of a group of cells within a plane of epithelium1,2,3 and it occurs during tissue morphogenetic events such as alignment of cochlear hair cells4, epidermal hair patterning5 and convergent extension movements of lateral mesoderm6. Planar polarization is mediated through patterned cell movements and coordinated transformation of the cell shapes and these changes depend, in part, on the extensive remodelling of cell-cell junctions7,8. Therefore, to understand the molecular mechanism underlying the establishment of PCP, it is important to reveal which cell adhesion molecules are involved and how they are regulated in a spatiotemporally precise manner.
Establishment of PCP is mediated by the Wnt/PCP pathway, a branch of noncanonical Wnt signalling, which controls gene expression changes and cytoskeletal dynamics in a transmembrane receptor Frizzled-dependent manner3. In the planar polarized epithelium, Frizzled and Dishevelled form a protein complex that confronts the other PCP complex composed of Strabismus/Vang and Prickle on the other side of the cell adhesion sites. These core PCP factors also regulate cell adhesion cooperatively with the Flamingo/Celsr atypical cadherins that mediate homophilic cell-cell adhesion9. The PCP regulators exhibit punctate localizations at the adherens junctions of Drosophila wing epithelia10. In addition, Celsr1 is enriched at the adherens junctions between the neuroepithelial cells of the neural plate to induce its polarized bending11. The PCP factors localize at adherens junctions, which are remodelled during planar polarization12,13. However, the link between adherens junction molecules and PCP factors is still obscure. For example, whether classic cadherins, which are the main cell adhesion molecules at adherens junctions, actively remodel the cell-cell junctions in response to the PCP signal or whether they are passively regulated by the Flamingo/Celsr-related rearrangement of cell adhesion is unknown.
We have recently reported that Vang-like-2 (Vangl2), a mammalian PCP regulator of Vang family proteins, associates with N-cadherin14, a neural subtype of classic cadherins crucial for the formation of the dendritic spines and synaptic junctions in the vertebrate CNS15,16. Vangl2 enhances endocytosis of postsynaptic N-cadherin through this molecular association and is also required for the normal development of dendritic spines. N-cadherin and Vangl2 form protein complex under negative regulation by their respective primary binding partner, β-catenin and Prickle2, suggesting that Vangl2 precisely controls the cell surface levels of N-cadherin by this conditional protein association to mediate accurate development of synaptic junctions. Although classic cadherins are structurally homologous17, certain subtype-specific properties have been reported18. In fact, whether Vangl2 is directly involved in the regulation of other classic cadherins has not been addressed.
Endocytic regulation of E-cadherin plays an important role in the PCP-related formation, rearrangement and maturation of cell adhesions. During the gastrulation of zebrafish embryos, intracellular trafficking of E-cadherin is controlled by the Wnt/PCP pathway stimulated by Wnt1119. In Drosophila, development of the wing or tracheal epithelia requires polarized trafficking of E-cadherin-containing vesicles during the PCP-dependent remodelling of cell-cell junctions20. Because Vangl2 directly controls N-cadherin trafficking14, this PCP-related endocytosis of E-cadherin may be also mediated by Vang family proteins. In the present study, we demonstrate complex formation and functional association of E-cadherin with Vangl2 in mammalian kidney epithelial cells. Vangl2-mediated regulation of E-cadherin transport may play a role in epithelial morphogenesis of renal tubules, which is under the control of PCP signalling21,22.
Results
Vangl2 Forms a Protein Complex with E-Cadherin
To determine whether Vangl2 forms protein complex only with N-cadherin or also with other classic cadherins, we analysed lysates of HEK293T cells transfected with E-cadherin and GFP-Vangl2 expression vectors using immunoprecipitation (IP). Western blot (WB) analysis indicated that GFP-Vangl2 coprecipitates with E-cadherin (Figure 1a) and vice versa (Figure 1b). The molecular association was not observed with YFP-tagged CD82, another tetraspanin highly expressed in the developing epithelia23 in the parallel experiment (Figure 1a and b). We confirmed the specificities of the antibodies (Abs) utilized in the IP experiments (see Supplementary Figure 1).
We next determined which region of the Vangl2 protein is required for the complex formation (Figure 1c and d). Deletion of the N-terminal intracellular domain did not affect the coprecipitation. In contrast, the C-terminal intracellular domain (ICD) was required. Further, deletion of the Prickle-binding region24 greatly diminished the association (28.4 ± 1.2%, compared to WT; n = 3 experiments). On the other hand, deletion of the ETSV PDZ-binding motif25 had a less significant effect (87.1 ± 1.5%, compared to WT; n = 3 experiments).
Because association with Vangl2 requires the normal β-catenin-binding region of N-cadherin26,27, we examined whether the corresponding region of the E-cadherin ICD is essential for the formation of the E-cadherin–Vangl2 complex (Figure 1e and f). Deletion of the β-catenin-binding region as well as alanine substitution of a stretch of serine residues within this region26,28 (Figure 1e) abolished the protein association (Figure 1f). We confirmed that the cell surface expression of the mutant forms of Vangl2 or E-cadherin was not greatly affected in comparison with that of the wild-type proteins (see Supplementary Figure 1).
These results indicate that the normal association of classic cadherins with Vangl2 requires the β-catenin-binding domain of E-cadherin as well as the Prickle-binding domains of Vangl2. These regions may be important for the molecular interaction or structural stability of the respective proteins.
We further evaluated whether purified recombinant E-cadherin and Vangl2 interact in vitro (Figure 1g). The GST fusion protein of the E-cadherin intracellular domain (ICD) (GST-Ecad) and the MBP-fused N-terminal (MBP-NT) and C-terminal ICDs (MBP-CT) of Vangl2 were bacterially expressed and purified using glutathione- and amylose-conjugated resins, respectively. GST-Ecad was mixed with MBP-NT, nonfused MBP or MBP-CT and subjected to co-IP using α-MBP Abs. GST-Ecad was precipitated only when incubated with MBP-CT. Although we cannot exclude the possibility that other factors influence this protein–protein interaction or that their transmembrane regions also play important roles in complex formation, these results suggest that the E-cadherin ICD is capable of directly binding to the Vangl2 C-terminus.
Complex Formation between E-cadherin and Vangl2 is Restricted by β-Catenin or Prickle2
Because normal association between E-cadherin and Vangl2 requires these respective binding domains, we determined whether cotransfection of β-catenin or Prickle2 affects the complex formation.
HEK293T cells were transfected with expression constructs of E-cadherin and FLAG-tagged Vangl2. The cell lysates were subjected to IP using α-FLAG Abs and subsequent WB (Figure 2a and c).
The amount of E-cadherin protein that coprecipitated with Vangl2 decreased as the amount of cotransfected GFP-β-catenin expression vector increased (Figure 2a and b; 0.2 μg: 0.49 ± 0.03 a.u.; p = 0.004, 0.5 μg: 0.27 ± 0.03 a.u.; p = 0.003, 1.0 μg: 0.18 ± 0.02 a.u.; p = 0.001; n = 3 experiments). Similarly, when cotransfected GFP-Prickle2 expression vector increased, a dose-dependent decrease in Vangl2-associated E-cadherin was observed (Figure 2c and d; 0.2 μg: 0.75 ± 0.05 a.u.; p = 0.049, 0.5 μg: 0.42 ± 0.04 a.u.; p = 0.007, 1.0 μg: 0.28 ± 0.05 a.u.; p = 0.008; n = 3 experiments).
Because β-catenin is expressed at a significant level in HEK293T cells, we also determined whether silencing of endogenous β-catenin affects the formation of the E-cadherin–Vangl2 complex (see Supplementary Figure 2). Co-introduction of the β-catenin–shRNA construct14 significantly increased the protein level of E-cadherin associated with Vangl2 (2.17 ± 0.22 a.u.; p = 0.03; n = 3 experiments). These results indicate that the association between E-cadherin and Vangl2 is suppressed by β-catenin or Prickle2. In other words, E-cadherin and Vangl2 are capable of forming protein complexes that are sensitive to the expression levels of their respective primary binding partners.
Vangl2 Enhances the Internalization of E-Cadherin
In the previous study, we demonstrated that internalization of N-cadherin is enhanced by Vangl2 in transfected cells as well as in cultured hippocampal neurons14. In the present study, we determined the effects of Vangl2 on cell surface expression of E-cadherin.
Cell surface proteins expressed on HEK293T cells transfected with the indicated expression vectors (Figure 3a) were biotinylated and precipitated using avidin-coated beads29. The protein samples included in the precipitates as well as in the total cell lysates were analysed by WB. Treatment of the cells with 4 mM EGTA, which chelates the extracellular calcium ions, induced a reduction in cell surface levels of E-cadherin30. Similarly, cotransfection of Vangl2 decreased the E-cadherin levels exposed to the cell surface (Figure 3a and b). In these experiments, the EGTA treatment, but not Vangl2 transfection, induced the internalization of transferrin receptors (TfR; Figure 3a and c), indicating the functional specificity of Vangl2.
The enhanced internalization of E-cadherin may be due to increased endocytosis, decreased exocytosis or toxic effects on protein transport. To address this issue, we further introduced dominant-negative forms of Rab531 (RFP-DN-Rab5) or Dynamin32 (DN-Dynamin1-GFP). Cotransfection of these constructs of endocytosis inhibitors clearly rescued the cell surface expression of E-cadherin (Figure 3a and b), demonstrating that enhanced internalization of E-cadherin by Vangl2 involves endocytic transport. In this experiment, Vangl2 was also internalized through a pathway involving Rab5 and Dynamin (Figures 3a and d). Reflecting the sensitivity to dnRab5, immunofluorescence (IF) microscopy revealed the vesicular co-localization of Rab5 with a portion of vesicles that were positive for both E-cadherin and Vangl2 (Figure 3e; 13.3%, n = 400 E-cadherin/Vangl2 double-positive dots). Because Rab5 is an early regulator of endocytosis and because Vangl2-mediated enhancement of E-cadherin internalization is highly sensitive to dnRab5 (Figures 3a and b), the relatively rare coincidence of Rab5 IF with E-cadherin/Vangl2 double-positive dots may indicate that their co-localization is transient.
Vangl2 transfection as well as EGTA treatment enhanced E-cadherin endocytosis. We therefore analysed whether colocalization of Vangl2 with E-cadherin is affected by the EGTA treatment (Figure 3f and g). We counted the E-cadherin puncta associated with Vangl2 IF. Without EGTA treatment, we found that 49.0 ± 1.6% (n = 40 cells) of the E-cadherin puncta are associated with Vangl2. Five minutes after the treatment, we observed a transient increase in the colocalization (57.8 ± 1.9%; p = 0.001; n = 40 cells), which then returned to the steady state (15 min: 47.5 ± 1.7%; p = 0.523, 30 min: 49.0 ± 1.8%; p = 0.984, 60 min: 45.2 ± 1.7%; p = 0.107). This transition in the ratio of their co-localization suggests that Vangl2 is, to a large extent, involved in the early phase of E-cadherin trafficking.
Vangl2 Associates with E-Cadherin In Vivo
To assess the significance of these transfection experiments, we examined the embryonic kidneys where the branching morphogenesis of epithelia is dependent of Vangl233. Embryonic day 19 rat kidney extracts were prepared as described in the “Methods” and subjected to IP using either α-Vangl2 Abs or normal goat IgG14. The immunoprecipitates (IPs) were analysed by WB using the indicated Abs (Figure 4a). E-cadherin was specifically detected in the IPs of α-Vangl2, suggesting that a small portion of E-cadherin associates with Vangl2 in vivo. In this experiment, as expected from the IP data in HEK293T cells (Figures 2a and b), β-catenin was not detected in the α-Vangl2 IPs even when the blots were overexposed. Although Plakoglobin can substitute for β-catenin34, it was not included in the IPs. These results suggest that E-cadherin is dissociated from the catenins when it is associated with Vangl2.
Using IF microscopy, we analysed the localizations of these proteins on the horizontal section of a renal tubule from the kidney of a postnatal day 0 (P0) mouse (Figure 4b). E-cadherin and Vangl2 were highly accumulated at the lateral borders between the epithelial cells (Figures 4b and c). When the intensities of the IF of the enlarged images were plotted along the border (Figure 4c; white line), the signal peaks of both fluorophores were correlated to some extent. On this plot, the signal peaks of phalloidin, which primarily stain the apico-lateral region of the epithelial cells, were less significantly associated with each IF signal (Figure 4d; blue). When the IF intensities were plotted transversely to the apico-basal axis of the cell (Figure 4c; yellow line), we found that Vangl2 was distributed more intracellularly with punctate signals (Figure 4e; red). Taken together, these results indicate that, at least, the subpopulations of E-cadherin and Vangl2 co-localize in the epithelia of embryonic kidneys, primarily at cell–cell junctions.
Cell Surface Expression of E-Cadherin Is Abnormal in Epithelial Cells Derived from Vangl2Lpt/+ Mutant Kidneys
Homozygous Loop-tail (Lpt) mutation in the mouse Vangl2 gene results in embryonic lethality due to incomplete closure of the neural tube35. To determine the role of Vangl2 in the regulation of the cell surface expression of E-cadherin, we analysed cultured epithelial cells derived from the neonatal kidneys of Vangl2Lpt/+ or wild-type littermate mice. Because Vangl2 with the Lpt mutation is highly unstable36,37, the total protein level of Vangl2 was significantly decreased in the mutant cultures (Figure 5a and c; 0.46 ± 0.05 a.u.; p = 0.002; n = 4 experiments). It is also possible that the function of the wild-type Vangl2 protein is affected by the residual Lpt mutant form of Vangl2 through its dominant-negative action38.
Using the same method employed for HEK293T cells (Figure 3a), we assessed the cell surface expression of E-cadherin in these primary cultures. Consistent with the data obtained by the transfection experiments (Figures 3a and b), the surface fraction of the cell lysate derived from the mutant cells, which was purified using biotin–avidin affinity, contained a significantly increased level of E-cadherin (Figures 5a and b; 139%, 95% CI: 118–164%; p = 0.0079; n = 5 experiments). In this experiment, the cell surface level of Vangl2 was also decreased in the mutant cells (Figure 5d; 0.51 ± 0.07 a.u.; p = 0.005; n = 4 experiments) and the quantitative ratio of Vangl2 expressed on the cell surface was not significantly different between these two genotypes (Figure 5e; 109%, 95% CI: 73.3–162%; p = 0.829; n = 4 experiments).
The cell surface levels of E-cadherin were also assessed by IF intensity39. The primary cultures were fixed using 4% paraformaldehyde (PFA) and stained with a rat DECMA-1 monoclonal Ab, which was raised against the extracellular domain (ECD) of E-cadherin40. Cells were then washed extensively, permeabilized with Triton X-100 and then incubated with mouse α-E-cadherin intracellular domain (ICD) Abs. These primary Abs were detected using Alexa-594-conjugated α-rat and Alexa-488-conjugated α-mouse IgG secondary Abs, respectively. By this procedure, while α-ECD Abs almost solely recognize cadherin molecules exposed to the cell surface, α-ICD Abs detected both the cell surface and intracellular populations14,39. We calculated the ratio of total signal intensity of Alexa-594 to that of Alexa-488 for each image pair as the quantitative ratio of E-cadherin molecules exposed to the cell surface. We then calculated the geometric means of the ratios for both genotypes and compared them. By this image analysis, we found that the cell surface ratio of E-cadherin on the Vangl2Lpt/+ epithelial cultures significantly increased (Figure 5f and g; 117%, 95% CI: 108–126%; p = 0.008; n = 5 experiments), as shown for the cell surface levels of N-cadherin on the cultured neurons14.
In the control experiments, α-ICD Abs did not detect the ICD epitope at a comparative level without permeabilization (Figure 5h and i; 14.8%, 95% CI: 9.1–24.3%; p < 0.0001), indicating that membrane permeabilization is required for sufficient penetration of the Abs. Further, in the experiments in which both α-ECD and α-ICD were applied after permeabilization, the average ratio of both IF signals was not greatly different between the two genotypes (Figure 5j and k; 95.5%, 95% CI: 69.1–132%; p = 0.802; n = 5 experiments), indicating that the permeabilization significantly enhances the penetration of not only α-ICD but also α-ECD Abs in these experiments.
Taken together, these results indicate that Vangl2 is required for maintaining the normal cell surface levels of E-cadherin in the kidney epithelial cells.
Discussion
The PCP factors localize to and regulate adherens junctions11,20. A possible mechanism of this regulation was shown by a genetic study of Vangl241. Transgenic overexpression as well as genetic ablation of Vangl2 in mice resulted in aberrant formation of adherens junctions between embryonic neuroepithelial cells. In addition, MDCK cells transfected with a Vangl2 expression vector displayed decreased cell–cell adhesion in hanging drop cultures, suggesting that precise regulation of Vangl2 levels is required for the appropriate formation of adherens junctions. Although Rac1-mediated cytoskeletal rearrangement is suggested to play an important role in this regulation, whether cell adhesion molecules are directly affected by Vangl2 has not been addressed. In the present study, we have demonstrated that Vangl2 associates with E-cadherin to enhance its internalization in the developing epithelial cells. The bacterially expressed E-cadherin ICD directly bind C-terminal ICD of Vangl2. It is therefore possible that this control is one of the causes of the impaired adherens junction formation in these transgenic animals41. The cell surface levels of E-cadherin on the Vangl2Lpt/+-derived renal epithelial cells were indeed significantly increased in our analysis. Similarly, in Drosophila, the PCP pathway controls recycling and turnover of E-cadherin during junctional remodelling and E-cadherin levels increase at junctions between tracheal epithelial cells of the Strabismus/Vang mutant20,42. Although the detailed molecular mechanism is unknown, similar protein interactions shown in our mammalian studies might be involved in the Drosophila phenotype of the E-cadherin regulation.
Vangl2 is also known to induce endocytosis of several other membrane proteins. At the growing axonal tips, Vangl2 antagonizes Dishevelled1-mediated phosphorylation of Frizzled3 and enhances its endocytosis43. Through this regulation of Wnt signalling, Vangl2 mediates the precise extension of filopodia in response to chemoattractants. During the gastrulation of zebrafish embryos, the PCP pathway regulates endocytosis of the metalloproteinase MMP14 to control remodelling of the extracellular matrix44. Loss of Vangl2 in trilobite mutants leads to increased cell surface amounts of MMP14, abnormal remodelling of extracellular matrix and disturbance of convergent extension movements45. Further, a cell adhesion molecule expressed in the kidney podocyte, nephrin, is regulated by Vangl246. Activation of the PCP pathway promotes nephrin endocytosis in a clathrin- and β-arrestin-dependent manner. Depletion of Vangl2 increases the cell surface amount of nephrin and disturbs the maturation of glomeruli. How is the endocytosis of these structurally unrelated molecules enhanced by Vangl2? We deduce that Vangl2 regulates their internalization with selectivity, as the cell surface expression of TfR was not significantly affected by Vangl2 in our study (Figure 3a and c). It should be noted that TfR is a single-pass type II membrane protein with a cytosplasmic N-terminal domain and classic cadherins, nephrin, MMP14 and Frizzled are all single-pass type I membrane proteins with intracellular C-terminal domains. This difference in membrane topology may affect the sensitivity of transmembrane proteins to Vangl2-mediated internalization. With regard to the molecular interactions organized by Vangl2, it is suggested that MAGI2, a podocyte scaffold protein, forms a link between nephrin and Vangl2, the interaction of which may be involved in the endocytosis of nephrin47. By contrast, classic cadherins can directly bind Vangl2 dependently on their β-catenin- and Prickle-binding sites14. Taken together, these results suggest that the molecular mechanism of the Vangl2-promoted endocytosis is context-dependent. Interestingly, the assembly of extracellular matrix during zebrafish gastrulation, which is controlled by the cell surface levels of MMP14, seems to be influenced by the cadherin-mediated cell adhesion48. Given that the E-cadherin ICD can directly associate with Vangl2, we propose the hypothesis that regulation of the cell surface expression of classic cadherin by Vangl2 plays a primary role in multiple aspects of PCP-related remodelling of cell adhesion.
From the viewpoint of molecular evolution, a predominant role for the cadherin superfamily in the establishment of the PCP signalling pathway should be noted. There are three classes of regulators of PCP signalling: the upstream activators, the core factors and the downstream effectors49. Other than Wnt proteins, Fat (Ft) and Dachsous (Ds) protocadherins are known to function as the upstream activators of PCP signalling. Whereas Ft is expressed uniformly, Ds is expressed in a gradient in the Drosophila eye and wing. Because Ds acts as the ligand for Ft, Ft is activated in a gradient, providing the long-range cue for PCP activation in these tissues to establish the polarized distributions of the core PCP factors within each cell50. In mammals, Fat1, Fat4 and Dachsous1 control tubular elongation of renal epithelia through PCP signalling, preventing the development of polycystic kidney diseases51. Interestingly, both Ft and Ds harbour homologous regions to the intracellular β-catenin-binding domain of classic cadherins52, with which Vangl2 may physically interacts. Therefore, whether Vangl2 also associates Ft and/or Ds to form feedback loops in the PCP pathway is an issue to be addressed. As for the core PCP regulators, Fmi/Celsr proteins are serpentine receptor-like atypical cadherins9. Further, we have shown that classic cadherin is one of the effectors of Vangl214. We therefore conclude that cadherin superfamily proteins are included in all three classes of PCP regulators. This strong correlation suggests a crucial role for calcium-dependent cell adhesion in the appearance of tissue polarity during evolution. We propose that advancement of cell-cell interaction in complexity or elaboration by gene evolution of cadherin motif-containing molecules is a plausible mechanism for creating multicellular organisms with PCP-like tissue organization.
In conclusion, we observed physical and functional associations of Vangl2 with E-cadherin, which are essentially similar to that with N-cadherin. Vangl2 positively regulates endocytosis of both N- and E-cadherin in a Rab5-dependent manner. Microscopically, the vesicular colocalization of cadherins with Vangl2 is approximately 50% in common14 (53.1% for N-cadherin; 49.0% for E-cadherin). On the other hand, we noticed a significant difference in the ratio of Rab5-colocalization. While 71% of the Vangl2-colocalized N-cadherin puncta are associated with Rab5 IF14, only 13% of those of E-cadherin are Rab5-positive (Figure 3c). The high ratio of Rab5 association with the N-cadherin–Vangl2 complex may explain why N-cadherin undergoes a high rate of endocytosis at the postsynapse, where Vangl2 is enriched. N-cadherin, but not E-cadherin, is known to interact with the fibroblast growth factor receptor through the fourth cadherin domain (EC4)53. The associated fibroblast growth factor receptor signalling may enable Vangl2 to recruit Rab5 to N-cadherin more efficiently than to E-cadherin. Future comparative analysis of the constituents of the cadherin–Vangl2 protein complexes would reveal the subtype-specific features of the cadherin transport during PCP-related tissue morphogenesis.
Methods
Animals
Loop-tail mutants of the LPT/Le stock54 were purchased from the Jackson Laboratory (Bar Harbor, ME) and backcrossed to C57BL/6J strain for at least 8 generations. The Animal Use and Care Committee of Niigata University authorized all animal experiments, which were performed in accordance with the NIH Guidelines for Care and Use of Laboratory Animals.
Plasmids and Antibodies
Expression constructs of Vangl2, FLAG-Vangl2, dominant-negative Rab5, GFP-β-catenin and GFP-Prickle2 are as described14. The supplemental Excel file contains detailed information on other plasmid constructs (sheet #1) and Abs (sheet #2) used in this study. The plasmid constructs were sequenced to confirm the absence of sequence errors.
Tissue Culture
HEK293T cells (ATCC, Manassas, VA) were maintained in standard conditions using DMEM containing GlutaMAX (Life Technologies, Carlsbad, CA) supplemented with 10% foetal bovine serum (BioWest, Kansas City, MO) at 37°C in the presence of 5% CO2 in a water-jacketed incubator. Transfections of the plasmid DNA were performed using Lipofectamine 2000 (Life Technologies) or polyethylenimine (Polysciences Inc., Warrington, PA: #23966) according to the manufacturer's instructions. 24 h after transfection, cells were either treated or untreated with the indicated reagents and then either harvested for biochemical analysis or fixed for microscopic analysis.
Primary Culture of the Mouse Kidney Cells
Both kidneys were dissected out from each P0 Vangl2Lpt/+ mutant mouse or their control littermate of wild-type, minced using razor blades and incubated with 200 μl of 0.25% trypsin in HBSS for 15 min at 37°C. Loosened tissues were washed with HBSS and then passed through the P-200 pipet tips. Dissociated cells were seeded onto either coverslips coated with poly-L-lysine for IF or 6-well plates for the biotinylation assay. Cells were cultured for 4 days before analysis.
Immunofluorescence Microscopy and Image Analysis
Immunostaining and image analysis of cultured cells were performed essentially as described14. Cells were fixed with 4% paraformaldehyde in phosphate-buffered saline (PBS). 20 image pairs were analysed for measurement of total IF intensity in each experiment unless otherwise stated.
Immunoprecipitation and Western Blot Analysis
IP and WB analysis were performed essentially as described14. Cell lysis buffer (1% NP-40, 150 mM NaCl, 50 mM Tris–Cl pH 7.5, 2 mM EDTA and 10% glycerol, supplemented with 20 μg/ml leupeptin) was used for all steps of cell lysis and bead washing. For preparation of kidney tissue extracts, ~24 kidneys dissected out from E19 SD rats (Japan SLC, Hamamatsu, Shizuoka) were lysed in 2.4 ml of cell lysis buffer by sequential passages through P-1000 pipet tips, 21-gauge needles and 25-gauge needles. The lysates were centrifuged at 14,000 × g for 10 min at 4°C and the supernatants were used as the kidney extracts. To prepare recombinant proteins of the E-cadherin ICD and Vangl2 ICDs, cDNA encoding these protein regions were PCR-amplified and ligated into pGEX-4T-1 and pMAL-c2X vectors in frame, respectively. Bacterial expression and purification of the fusion proteins were performed according to the manufacturer's instructions. For IP of the purified proteins, approximately 1.5 μg of each recombinant was added to 300 μl of cell lysis buffer, incubated overnight at 4°C with rotation and treated with α-MBP Abs and 10 μl of a slurry of protein G Mag Sepharose Xtra (GE Healthcare, Waukesha, WI) overnight at 4°C.
Cell Surface Biotinylation Assay
Cells, seeded at 8 × 105 per well of 6-well plates and grown for 4 days (primary kidney) or for 24 hr after transfection (HEK293T), were washed 3 times with ice-cold PBS and treated with 0.4 mM NHS-PEG4-Biotin (Thermo, Waltham, MA) for 30 min on ice. The biotinylation reaction was quenched and excess reagents were washed out using PBS containing 0.1 M glycine. Cells were then lysed in 700 μl of cell lysis buffer. Three hundred μl of the cell lysate were incubated with 5 μl of High Capacity NeutrAvidin agarose resin (Thermo) for 2 h at 4°C with rotation. The resins were washed 3 times with cell lysis buffer and boiled in 2× Laemmli SDS sample buffer (Bio-Rad, Hercules, CA) supplemented with 0.1 M DTT.
Immunofluorescent Quantification of E-Cadherin Exposed on the Cell Surface
Image analysis of the cell surface expression of cadherin was performed essentially as described14. After culturing for 4 days, the primary kidney cells were fixed with 4% PFA in PBS at 37°C for 15 min, incubated with the blocking solution for 1 h and incubated at 4°C for 1 h with the rat monoclonal Abs raised against α-E-cadherin ECD (DECMA-1). The unbound Abs were removed by washing five times with PBS for 10 min each and the plasma membranes were permeabilized using 0.1% Triton X-100 for 10 min. The cells were blocked again and incubated at 4°C for 1 h with mouse Abs against E-cadherin ICD (clone#36). The α-ECD and α-ICD Abs bound to the primary cultures were detected using secondary Abs conjugated to different fluorophores (Alexa-594 for α-rat IgG and Alexa-488 for α-mouse IgG). The cell-surface and total populations of E-cadherin were identified by red and green fluorescence, respectively. All images were captured when more than 10 E-cadherin-expressing cells were clustered in the field of view using an ×40 objective lens. For each series of experiments and for each fluorophore, images were captured using the same exposure time and gain without saturation using MetaMorph (Molecular Devices, Sunnyvale, CA) and the signal strength of each image was quantitatively analysed using ImageJ (NIH, Bethesda, MD).
Immunofluorescence Analysis of Mouse Kidney
Mouse kidneys were dissected out from P0 C57BL/6J mice and freshly frozen in OCT compound (Sakura Finetek, Tokyo, Japan) using dry ice. The kidneys were sectioned at 5-μm thickness along the dorsal-ventral axis using a cryostat (CM1850, Leica Biosystems, Nussloch, Germany) and dried on MAS-coated glass slides (Matsunami Glass, Osaka, Japan). The sectioned tissues were fixed using 4% PFA in PBS, blocked using 10% FBS in PBS and sequentially incubated with the indicated antibodies accompanied by intervening washing procedures. IF images were captured and analysed as described14. To profile the signal intensity of IF along lines, Plot Profile analysis was conducted using ImageJ. The signal intensity of each plot (0.1 μm/plot) was statistically analysed.
Statistical Analysis
All counts and measurements were conducted in blind fashion. Each experiment was repeated at least twice and produced consistent results. The measured values from three independent experiments were used for each statistical analysis unless otherwise stated. The average ratio of one of the control samples was set as one arbitrary unit to represent the relative amounts and used as the standard for the statistical analysis. Data are presented as mean + SEM or geometric mean ± 95% CI unless otherwise stated.
References
Simons, M. & Mlodzik, M. Planar cell polarity signaling: from fly development to human disease. Annu Rev Genet 42, 517–540, 10.1146/annurev.genet.42.110807.091432 (2008).
Vladar, E. K., Antic, D. & Axelrod, J. D. Planar cell polarity signaling: the developing cell's compass. Cold Spring Harb Perspect Biol 1, a002964, 10.1101/cshperspect.a002964 (2009).
Wallingford, J. B. Planar cell polarity and the developmental control of cell behavior in vertebrate embryos. Annu Rev Cell Dev Biol 28, 627–653, 10.1146/annurev-cellbio-092910-154208 (2012).
Montcouquiol, M. et al. Identification of Vangl2 and Scrb1 as planar polarity genes in mammals. Nature 423, 173–177, 10.1038/nature01618 (2003).
Devenport, D. & Fuchs, E. Planar polarization in embryonic epidermis orchestrates global asymmetric morphogenesis of hair follicles. Nat Cell Biol 10, 1257–1268, 10.1038/ncb1784 (2008).
Wallingford, J. B. et al. Dishevelled controls cell polarity during Xenopus gastrulation. Nature 405, 81–85, 10.1038/35011077 (2000).
Bertet, C., Sulak, L. & Lecuit, T. Myosin-dependent junction remodelling controls planar cell intercalation and axis elongation. Nature 429, 667–671, 10.1038/nature02590 (2004).
Walck-Shannon, E. & Hardin, J. Cell intercalation from top to bottom. Nat Rev Mol Cell Biol 15, 34–48, 10.1038/nrm3723 (2014).
Usui, T. et al. Flamingo, a seven-pass transmembrane cadherin, regulates planar cell polarity under the control of Frizzled. Cell 98, 585–595 (1999).
Strutt, H., Warrington, S. J. & Strutt, D. Dynamics of core planar polarity protein turnover and stable assembly into discrete membrane subdomains. Dev Cell 20, 511–525, 10.1016/j.devcel.2011.03.018 (2011).
Nishimura, T., Honda, H. & Takeichi, M. Planar cell polarity links axes of spatial dynamics in neural-tube closure. Cell 149, 1084–1097, 10.1016/j.cell.2012.04.021 (2012).
Rauzi, M., Lenne, P. F. & Lecuit, T. Planar polarized actomyosin contractile flows control epithelial junction remodelling. Nature 468, 1110–1114, 10.1038/nature09566 (2010).
Zallen, J. A. & Blankenship, J. T. Multicellular dynamics during epithelial elongation. Semin Cell Dev Biol 19, 263–270, 10.1016/j.semcdb.2008.01.005 (2008).
Nagaoka, T. et al. The Wnt/Planar Cell Polarity Pathway Component Vangl2 Induces Synapse Formation through Direct Control of N-Cadherin. Cell Rep 6, 916–927, 10.1016/j.celrep.2014.01.044 (2014).
Togashi, H. et al. Cadherin regulates dendritic spine morphogenesis. Neuron 35, 77–89 (2002).
Uchida, N., Honjo, Y., Johnson, K. R., Wheelock, M. J. & Takeichi, M. The catenin/cadherin adhesion system is localized in synaptic junctions bordering transmitter release zones. J Cell Biol 135, 767–779 (1996).
Yagi, T. & Takeichi, M. Cadherin superfamily genes: functions, genomic organization and neurologic diversity. Genes Dev 14, 1169–1180 (2000).
Suyama, K., Shapiro, I., Guttman, M. & Hazan, R. B. A signaling pathway leading to metastasis is controlled by N-cadherin and the FGF receptor. Cancer Cell 2, 301–314 (2002).
Ulrich, F. et al. Wnt11 functions in gastrulation by controlling cell cohesion through Rab5c and E-cadherin. Dev Cell 9, 555–564, 10.1016/j.devcel.2005.08.011 (2005).
Warrington, S. J., Strutt, H. & Strutt, D. The Frizzled-dependent planar polarity pathway locally promotes E-cadherin turnover via recruitment of RhoGEF2. Development 140, 1045–1054, 10.1242/dev.088724 (2013).
Karner, C. M. et al. Wnt9b signaling regulates planar cell polarity and kidney tubule morphogenesis. Nat Genet 41, 793–799, 10.1038/ng.400 (2009).
Lienkamp, S. S. et al. Vertebrate kidney tubules elongate using a planar cell polarity-dependent, rosette-based mechanism of convergent extension. Nat Genet 44, 1382–1387, 10.1038/ng.2452 (2012).
Odintsova, E., Sugiura, T. & Berditchevski, F. Attenuation of EGF receptor signaling by a metastasis suppressor, the tetraspanin CD82/KAI-1. Curr Biol 10, 1009–1012 (2000).
Jenny, A., Darken, R. S., Wilson, P. A. & Mlodzik, M. Prickle and Strabismus form a functional complex to generate a correct axis during planar cell polarity signaling. EMBO J 22, 4409–4420, 10.1093/emboj/cdg424 (2003).
Wolff, T. & Rubin, G. M. Strabismus, a novel gene that regulates tissue polarity and cell fate decisions in Drosophila. Development 125, 1149–1159 (1998).
Ozawa, M., Baribault, H. & Kemler, R. The cytoplasmic domain of the cell adhesion molecule uvomorulin associates with three independent proteins structurally related in different species. EMBO J 8, 1711–1717 (1989).
Stappert, J. & Kemler, R. A short core region of E-cadherin is essential for catenin binding and is highly phosphorylated. Cell Adhes Commun 2, 319–327 (1994).
McEwen, A. E., Maher, M. T., Mo, R. & Gottardi, C. J. E-cadherin phosphorylation occurs during its biosynthesis to promote its cell surface stability and adhesion. Mol Biol Cell 25, 2365–2374, 10.1091/mbc.E14-01-0690 (2014).
Suzuki, M. et al. Defective membrane expression of the Na(+)-HCO(3)(-) cotransporter NBCe1 is associated with familial migraine. Proc Natl Acad Sci U S A 107, 15963–15968, 10.1073/pnas.1008705107 (2010).
Le, T. L., Yap, A. S. & Stow, J. L. Recycling of E-cadherin: a potential mechanism for regulating cadherin dynamics. J Cell Biol 146, 219–232 (1999).
Bohdanowicz, M., Balkin, D. M., De Camilli, P. & Grinstein, S. Recruitment of OCRL and Inpp5B to phagosomes by Rab5 and APPL1 depletes phosphoinositides and attenuates Akt signaling. Mol Biol Cell 23, 176–187, 10.1091/mbc.E11-06-0489 (2012).
Lee, E. & De Camilli, P. Dynamin at actin tails. Proc Natl Acad Sci U S A 99, 161–166, 10.1073/pnas.012607799 (2002).
Yates, L. L. et al. The planar cell polarity gene Vangl2 is required for mammalian kidney-branching morphogenesis and glomerular maturation. Hum Mol Genet 19, 4663–4676, 10.1093/hmg/ddq397 (2010).
Fukunaga, Y. et al. Defining the roles of beta-catenin and plakoglobin in cell-cell adhesion: isolation of beta-catenin/plakoglobin-deficient F9 cells. Cell Struct Funct 30, 25–34 (2005).
Kibar, Z. et al. Ltap, a mammalian homolog of Drosophila Strabismus/Van Gogh, is altered in the mouse neural tube mutant Loop-tail. Nat Genet 28, 251–255, 10.1038/90081 (2001).
Gravel, M., Iliescu, A., Horth, C., Apuzzo, S. & Gros, P. Molecular and cellular mechanisms underlying neural tube defects in the loop-tail mutant mouse. Biochemistry 49, 3445–3455, 10.1021/bi902180m (2010).
Guyot, M. C. et al. A novel hypomorphic Looptail allele at the planar cell polarity Vangl2 gene. Dev Dyn : an official publication of the American Association of Anatomists 240, 839–849, 10.1002/dvdy.22577 (2011).
Yin, H., Copley, C. O., Goodrich, L. V. & Deans, M. R. Comparison of phenotypes between different vangl2 mutants demonstrates dominant effects of the Looptail mutation during hair cell development. PloS One 7, e31988, 10.1371/journal.pone.0031988 (2012).
Willingham, M. C. Fluorescence labeling of surface antigens of attached or suspended tissue-culture cells. Methods Mol Biol 588, 143–151, 10.1007/978-1-59745-324-0_17 (2010).
Vestweber, D. & Kemler, R. Identification of a putative cell adhesion domain of uvomorulin. EMBO J 4, 3393–3398 (1985).
Lindqvist, M. et al. Vang-like protein 2 and Rac1 interact to regulate adherens junctions. J Cell Sci 123, 472–483, 10.1242/jcs.048074 (2010).
Classen, A. K., Anderson, K. I., Marois, E. & Eaton, S. Hexagonal packing of Drosophila wing epithelial cells by the planar cell polarity pathway. Dev Cell 9, 805–817, 10.1016/j.devcel.2005.10.016 (2005).
Shafer, B., Onishi, K., Lo, C., Colakoglu, G. & Zou, Y. Vangl2 promotes Wnt/planar cell polarity-like signaling by antagonizing Dvl1-mediated feedback inhibition in growth cone guidance. Dev Cell 20, 177–191, 10.1016/j.devcel.2011.01.002 (2011).
Williams, B. B. et al. VANGL2 regulates membrane trafficking of MMP14 to control cell polarity and migration. J Cell Sci 125, 2141–2147, 10.1242/jcs.097964 (2012).
Jessen, J. R. et al. Zebrafish trilobite identifies new roles for Strabismus in gastrulation and neuronal movements. Nat Cell Biol 4, 610–615, 10.1038/ncb828 (2002).
Babayeva, S. et al. Planar cell polarity pathway regulates nephrin endocytosis in developing podocytes. J Biol Chem 288, 24035–24048, 10.1074/jbc.M113.452904 (2013).
Babayeva, S., Zilber, Y. & Torban, E. Planar cell polarity pathway regulates actin rearrangement, cell shape, motility and nephrin distribution in podocytes. Am J Physiol Renal Physiol 300, F549–560, 10.1152/ajprenal.00566.2009 (2011).
Dohn, M. R., Mundell, N. A., Sawyer, L. M., Dunlap, J. A. & Jessen, J. R. Planar cell polarity proteins differentially regulate extracellular matrix organization and assembly during zebrafish gastrulation. Dev Biol 383, 39–51, 10.1016/j.ydbio.2013.08.027 (2013).
Benzing, T., Simons, M. & Walz, G. Wnt signaling in polycystic kidney disease. J Am Soc Nephrol : JASN 18, 1389–1398, 10.1681/ASN.2006121355 (2007).
Matis, M. & Axelrod, J. D. Regulation of PCP by the Fat signaling pathway. Genes Dev 27, 2207–2220, 10.1101/gad.228098.113 (2013).
McNeill, H. Planar cell polarity and the kidney. J Am Soc Nephrol : JASN 20, 2104–2111, 10.1681/ASN.2008111173 (2009).
Clark, H. F. et al. Dachsous encodes a member of the cadherin superfamily that controls imaginal disc morphogenesis in Drosophila. Genes Dev 9, 1530–1542 (1995).
Kim, J. B. et al. N-Cadherin extracellular repeat 4 mediates epithelial to mesenchymal transition and increased motility. J Cell Biol 151, 1193–1206 (2000).
Smith, L. J. & Stein, K. F. Axial elongation in the mouse and its retardation in homozygous looptail mice. J Embryol Exp Morphol 10, 73–87 (1962).
Acknowledgements
The authors are grateful to Motomi Tamura for assistance and to Dr. Michihiro Igarashi for support for laboratory equipment.
Author information
Authors and Affiliations
Contributions
T.N. performed all experiments. A.I., K.B. and K.M. contributed to molecular biological experiments. M.K. and T.N. conceived the experiments and wrote the paper.
Ethics declarations
Competing interests
The authors declare no competing financial interests.
Electronic supplementary material
Supplementary Information
Supplementary Figures
Supplementary Information
Dataset 1
Rights and permissions
This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International License. The images or other third party material in this article are included in the article's Creative Commons license, unless indicated otherwise in the credit line; if the material is not included under the Creative Commons license, users will need to obtain permission from the license holder in order to reproduce the material. To view a copy of this license, visit http://creativecommons.org/licenses/by-nc-nd/4.0/
About this article
Cite this article
Nagaoka, T., Inutsuka, A., Begum, K. et al. Vangl2 Regulates E-Cadherin in Epithelial Cells. Sci Rep 4, 6940 (2014). https://doi.org/10.1038/srep06940
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/srep06940
- Springer Nature Limited
This article is cited by
-
Non-canonical Wnt signalling regulates scarring in biliary disease via the planar cell polarity receptors
Nature Communications (2020)
-
Vangl2 interaction plays a role in the proteasomal degradation of Prickle2
Scientific Reports (2019)
-
Planar cell polarity signalling coordinates heart tube remodelling through tissue-scale polarisation of actomyosin activity
Nature Communications (2018)
-
PDZ interaction of Vangl2 links PSD-95 and Prickle2 but plays only a limited role in the synaptic localisation of Vangl2
Scientific Reports (2015)