Binding between the Junctional Proteins Afadin and PLEKHA7 and Implication in the Formation of Adherens Junction in Epithelial Cells*

Background: Afadin is an important regulator of cell-cell adhesion. Results: PLEKHA7 binds to afadin and this binding is required for the proper formation of adherens junction (AJ). Conclusion: PLEKHA7 plays a cooperative role with nectin and afadin in the proper formation of AJ in epithelial cells. Significance: The result indicates a novel regulatory mechanism for the formation of cell-cell adhesion. Adherens junction (AJ) is a specialized cell-cell junction structure that plays a role in mechanically connecting adjacent cells to resist strong contractile forces and to maintain tissue structure, particularly in the epithelium. AJ is mainly comprised of cell adhesion molecules cadherin and nectin and their associating cytoplasmic proteins including β-catenin, α-catenin, p120ctn, and afadin. Our series of studies have revealed that nectin first forms cell-cell adhesion and then recruits cadherin to form AJ. The recruitment of cadherin by nectin is mediated by the binding of α-catenin and p120ctn to afadin. Recent studies showed that PLEKHA7 binds to p120ctn, which is associated with E-cadherin, and maintains the integrity of AJ in epithelial cells. In this study, we showed that PLEKHA7 bound to afadin in addition to p120ctn and was recruited to the nectin-3α-based cell-cell adhesion site in a manner dependent on afadin, but not on p120ctn. The binding of PLEKHA7 to afadin was required for the proper formation of AJ, but not for the formation of tight junction, in EpH4 mouse mammary gland epithelial cells. These results indicate that PLEKHA7 plays a cooperative role with nectin and afadin in the proper formation of AJ in epithelial cells.

Adherens junction (AJ) is a specialized cell-cell junction structure that plays a role in mechanically connecting adjacent cells to resist strong contractile forces and to maintain tissue structure, particularly in the epithelium. AJ is mainly comprised of cell adhesion molecules cadherin and nectin and their associating cytoplasmic proteins including ␤-catenin, ␣-catenin, p120 ctn , and afadin. Our series of studies have revealed that nectin first forms cell-cell adhesion and then recruits cadherin to form AJ. The recruitment of cadherin by nectin is mediated by the binding of ␣-catenin and p120 ctn to afadin. Recent studies showed that PLEKHA7 binds to p120 ctn , which is associated with E-cadherin, and maintains the integrity of AJ in epithelial cells. In this study, we showed that PLEKHA7 bound to afadin in addition to p120 ctn and was recruited to the nectin-3␣-based cell-cell adhesion site in a manner dependent on afadin, but not on p120 ctn . The binding of PLEKHA7 to afadin was required for the proper formation of AJ, but not for the formation of tight junction, in EpH4 mouse mammary gland epithelial cells. These results indicate that PLEKHA7 plays a cooperative role with nectin and afadin in the proper formation of AJ in epithelial cells.
Mono-layered columnar epithelial cells, which are simply referred here to as epithelial cells, in small intestine, for instance, form a sheet by adhering adjacent cells through cell-cell junctions, such as tight junction (TJ), 2 adherens junction (AJ), and desmosome (1). In epithelial cells, TJ is localized at the most apical side of the cell-cell adhesion site, and AJ is formed just at the basal side of TJ. TJ is crucial for the barrier function that prevents the passage of soluble molecules through the gaps between cells (2) and is thought to be involved in the fence function that keeps the cell surface lipids at the basolateral region separated from those at the apical region (3), although the latter function remains controversial (4). AJ plays a role in mechanically connecting adjacent cells to resist strong contractile forces and to maintain tissue structure particularly in epithelial cells. In addition, AJ regulates the formation and maintenance of TJ and desmosome (5).
AJ is formed by cell adhesion molecules (CAMs) cadherin and nectin and their associating molecules and is undercoated with the actin cytoskeleton associated with myosin (6,7). Cadherin is a key Ca 2ϩ -dependent CAM with a single transmembrane segment and comprises a family consisting of over 100 members. Cadherin directly binds ␤-catenin and p120 ctn (8). ␤-Catenin in turn interacts with ␣-catenin, which binds many peripheral membrane proteins, such as vinculin, ␣-actinin, and EPLIN (9). Nectin is a Ca 2ϩ -independent Ig-like CAM with a single transmembrane segment and comprises a family consisting of four members: nectin-1, -2, -3, and -4 (10,11). Nectin is associated with actin filaments (F-actin) through afadin, an F-actin-binding protein. Afadin has some splicing isoforms, and epithelial cells mainly express the longest one, l-afadin, hereafter referred to as afadin. Our series of studies have revealed that nectin first forms cell-cell adhesion and then recruits the cadherincatenin complex to the nectin-based cell-cell adhesion site at least through the direct binding of afadin to ␣-catenin and the indirect binding of afadin to p120 ctn to form AJ (6, 10 -14).
Nectin is also involved in the formation of TJ in addition to AJ (15). The major CAMs at TJ are claudin, occludin, and junctional adhesion molecule. Claudin is a Ca 2ϩ -independent CAM with four transmembrane segments and comprises a family consisting of ϳ24 members in humans and mice (3,16). Claudin forms TJ strands to seal the apposed plasma membranes of adjacent cells. The structure of occludin is similar to that of claudin, but its function has not yet been established. In addition to these CAMs, several peripheral membrane proteins, such as ZO-1, -2, and -3, are localized at TJ and interact with claudin, occludin, and junctional adhesion molecule to link these CAMs to F-actin. During and/or after the formation of AJ, nectin recruits first junctional adhesion molecule and then claudin and occludin to the apical side of AJ, resulting in the formation of TJ. It remains unknown how the trans-interactions of nectin lead to the recruitment of the TJ components, but afadin and ZO-1 and the interaction of these two proteins are necessary for the recruitment of CAMs to TJ (15).
A recent study showed that PLEKHA7, a protein originally identified as a member of pleckstrin homology (PH) domain containing, family A (17,18), binds to both p120 ctn and Nezha (19). p120 ctn binds to the juxtamembrane region of E-cadherin, whereas Nezha binds to the minus end of microtubules. Thus, PLEKHA7 connects the microtubule network to AJ through p120 ctn and Nezha in human colon carcinoma Caco2 cells. E-cadherin, ␤-catenin, ␣-catenin, p120 ctn , and EPLIN are localized not only at AJ but also at the basal side of AJ along the lateral plasma membranes of attached epithelial cells (9). In contrast, PLEKHA7 is strictly localized at AJ like the nectinafadin system in Caco2 cells (19). It was more recently shown that PLEKHA7 binds to paracingulin, which is known to interact with ZO-1, and is localized at AJ in Madin-Darby canine kidney (MDCK) cells (20). However, paracingulin is localized not only at AJ but also at TJ (21). It was proposed that paracingulin is localized at AJ and TJ by binding to PLEKHA7 and ZO-1, respectively (20). Thus, it still remains unknown how PLEKHA7 is localized strictly at AJ in epithelial cells.
Because the nectin-afadin system is strictly localized at AJ in epithelial cells, we examined here whether PLEKHA7 is recruited to AJ through this system and found that PLEKHA7 bound to afadin in addition to p120 ctn and was associated with nectin by binding to afadin. In addition, we found that this binding of PLEKHA7 to afadin was required for the proper formation of AJ, but not for the formation of TJ, in EpH4 mouse mammary gland epithelial cells. We show here this novel regulatory mechanism for the formation of AJ in epithelial cells.
Transfection and Retrovirus Infection-Transfection of cells with plasmids or siRNA was performed using Lipofectamine 2000 or Lipofectamine RNAiMAX reagent (Invitrogen), respectively, according to the manufacturer's instructions. To generate the retroviral supernatant, HEK293E cells were co-transfected with pGP (Takara Bio), pE-Ampho (Takara Bio), and either pCX4-puro or pSIREN-retroQ-GFP plasmid. After a 48-h culture period, the culture medium was centrifuged, and the viral supernatant with 8 g/ml polybrene was used for infection.
Knockdown Experiments-Stealth RNAi duplexes against mouse p120 ctn (5Ј-GAAGCAGUGUGGACCUGCAUCGUUU-3Ј) and mouse afadin (5Ј-CCCAAGACAUAAACCUGGAGCU-GUU-3Ј) were purchased from Invitrogen. As a control, we used stealth RNAi negative control medium GC duplex 2 (Invitrogen). To confirm the knockdown efficiency, the cells were washed with ice-cold PBS and lysed with a lysis buffer (20 mM Tris-HCl, pH 7.5, 150 mM NaCl, 5% glycerol, 0.5% Nonidet P-40, 1 mM MgCl 2 , 1 mM dithiothreitol, 1 mM Na 3 VO 4 , 10 mM sodium fluoride, 1 mM PMSF, and 10 g/ml leupeptin). The lysates were added with 5ϫ SDS sample buffer, boiled for 5 min, and subjected to SDS-PAGE, followed by Western blotting with appropriate Abs. For knockdown of PLEKHA7 in EpH4 cells, EpH4 cells were infected with the retrovirus encoding the shRNA sequence targeting PLEKHA7 for 24 h and cultured for 48 h. The cells were then plated on coverslips and further cultured for 24 h before fixation. In the rescue experiments, EpH4 cells were infected with the control retrovirus (mock) or the retrovirus coding for HA-sr-PLEKHA7-WT or HA-sr-PLEKHA7-⌬AfBR. Infected EpH4 cells were cultured for 24 h, washed, and selected by culturing with 2 g/ml puromycin for 4 -6 days. The selected EpH4 cells were infected with the shRNA retroviruses for 24 h and processed as described above.
Immunoprecipitation Assay-HEK293E cells were co-transfected with various combinations of plasmids. After incubation for 48 h, the cells were washed with ice-cold PBS and then lysed with the lysis buffer. The cell lysates were obtained by centrifugation at 20,000 ϫ g for 15 min. The cell lysates were incubated with the rabbit anti-GFP pAb-conjugated protein A-Sepharose at 4°C for 3 h. After the beads were extensively washed with the lysis buffer, the bound proteins were eluted by boiling the beads in SDS sample buffer. The samples were subjected to SDS-PAGE, followed by Western blotting with the rat anti-GFP, rat anti-HA, and mouse anti-FLAG mAbs.
GST Pulldown Assay-GST and GST-fused proteins were expressed in Escherichia coli, and the cells were sonicated in a sonication buffer (50 mM Tris-HCl, pH 7.5, 150 mM NaCl, 0.1% Triton X-100, 1 mM dithiothreitol, 1 mM PMSF, and 10 g/ml leupeptin). The homogenate was clarified by centrifugation, and the supernatant was then incubated with glutathione-Sepharose 4B (GE Healthcare) at 4°C for 1 h to immobilize GST-fused proteins. After being washed with the lysis buffer, the beads were incubated with the cell lysates prepared from HEK293E cells exogenously expressing proteins of interest. After 3 h of incubation, the beads were extensively washed with the lysis buffer, and bound proteins were subjected to SDS-PAGE, followed by Western blotting with the appropriate Abs and Amido Black staining.
Immunofluorescence Microscopy-Cells seeded on coverslips were fixed with 1% paraformaldehyde in Hanks' balanced salt solution and then permeabilized with 0.2% Triton X-100 in PBS. After being blocked with 2% goat serum in PBS, the samples were incubated with the primary Abs, followed by incubation with appropriate fluorophore-conjugated secondary Abs. The samples were then washed three times with PBS and mounted in ProLong Gold mount gel (Invitrogen). Fluorescence signals were visualized with a confocal laser scanning microscope (LSM510; Zeiss). The fluorescence intensity of E-cadherin at the cell-cell adhesion site was quantified in randomly chosen fields by ImageJ software, and the average intensity value of each image was calculated. Statistical significance was assessed by Tukey's multiple comparisons test.

Requirement of Afadin for the Recruitment of PLEKHA7 to the Cell-Cell Adhesion Site in Epithelial Cells-We first examined
whether afadin is required for the recruitment of PLEKHA7 to the cell-cell adhesion site in EpH4 cells that endogenously express PLEKHA7 (Fig. 1A). For this purpose, we knocked down afadin in EpH4 cells by using the retroviral shRNA vector and analyzed the localization of PLEKHA7. Infection of EpH4 cells with the retrovirus encoding the afadin shRNA significantly suppressed the expression of afadin but did not affect the expression of PLEKHA7 or E-cadherin (Fig. 1A). Because these retroviruses were engineered to simultaneously express shRNA and GFP, the infection of the retroviruses was confirmed by the expression of GFP. The immunofluorescence signals for afadin, PLEKHA7, E-cadherin, and p120 ctn were all concentrated at the cell-cell adhesion site between the control retrovirus-infected cells (Fig. 1B, control). In contrast, the signals for all of these molecules were significantly decreased at the cell-cell adhesion site between the afadin shRNA retrovirus-infected cells as compared with that at the cell-cell adhesion site between uninfected GFP-negative cells (Fig. 1B, afadin KD). The reductions of the signals for PLEKHA7 and E-cadherin at the cell-cell adhesion sites by the afadin knockdown were not caused by the reductions of the total amounts of these proteins as judged by Western blotting (Fig. 1A). The reduction of the signal for E-cadherin was consistent with the earlier observations in MDCK cells (15,27). These results indicate that afadin is required for the recruitment of PLEKHA7 as well as E-cadherin and p120 ctn to the cell-cell adhesion site in EpH4 cells. However, it cannot be evaluated from these experiments whether afadin is involved in the recruitment of PLEKHA7 to the cell-cell adhesion site in a p120 ctn -independent manner.
Afadin-dependent and p120 ctn -independent Recruitment of PLEKHA7 to the Nectin-3␣-based Cell-Cell Adhesion Site in L Cells Stably Expressing Nectin-3␣-We therefore next examined whether afadin recruits PLEKHA7 to the cell-cell adhesion site in a manner independent of p120 ctn and E-cadherin by using L fibroblasts, because this cell line lacks classical cadherins (28). Afadin and the small amounts of nectin-1 and -2 were expressed in L cells (29). ␣-Catenin and ␤-catenin were down-regulated because of the lack of cadherin in this cell line (13). When L cells stably expressing exogenous nectin-3␣ (nectin-3-L cells) were cultured, the nectin-3␣-based cell-cell adhesion was formed as described ( Fig. 2) (30). The immunofluorescence signals for both nectin-3␣ and afadin were concentrated at the cell-cell adhesion site (Fig. 2, arrowheads). To examine the recruitment of PLEKHA7 to the nectin-3␣-based cell-cell adhesion site, HA-PLEKHA7 was expressed in nectin-3-L cells in which endogenous PLEKHA7 was undetectable by Western blotting (data not shown). The signal for HA-PLEKHA7 was co-localized with the signals for nectin-3␣ and afadin (Fig. 2,  arrowheads). However, the signal for p120 ctn was not detected there (Fig. 2, arrows). These results indicate that PLEKHA7 is recruited to the nectin-3␣-based cell-cell adhesion site presumably in a p120 ctn -independent manner.
We further confirmed the p120 ctn -independent recruitment of PLEKHA7 to the nectin-3␣-based cell-cell adhesion site by knocking down p120 ctn in nectin-3-L cells. When p120 ctn was knocked down in nectin-3-L cells by using siRNA, the p120 ctn protein was markedly reduced as estimated by Western blot-  ting (Fig. 3Aa). In the p120 ctn knockdown (KD)-nectin-3-L cells, the signals for nectin-3␣, afadin, and HA-PLEKHA7 were concentrated at the cell-cell adhesion site to the extents similar to those in the control siRNA-transfected nectin-3-L cells and untransfected nectin-3-L cells (Fig. 3Ab, arrowheads; see also Fig. 2). In a quantitative analysis, the percentages of the nectin-3␣-based cell-cell adhesion site at which afadin or HA-PLEKHA7 accumulated were not reduced in the p120 ctn KD-nectin-3-L cells as compared with those in the control cells (Fig. 3Ac). These results further indicate that PLEKHA7 is recruited to the nectin-3␣-based cell-cell adhesion site in a p120 ctn -independent manner.
We then examined whether this recruitment of PLEKHA7 is dependent on afadin. For this purpose, we used nectin-3␣-⌬C, a mutant of nectin-3␣ lacking the C-terminal four aa residues necessary for the binding to afadin (31,32). When L cells stably expressing nectin-3␣-⌬C (nectin-3-⌬C-L cells) were transfected with HA-PLEKHA7, the signal for nectin-3␣-⌬C was concentrated at the cell-cell adhesion site as described previously (30), but the signal for afadin or HA-PLEKHA7 was not concentrated there (Fig. 3Ba, arrows). In a quantitative analysis, the percentages of the nectin-3␣-based cell-cell adhesion site at which afadin or HA-PLEKHA7 accumulated were markedly reduced in the nectin-3-⌬C-L cells as compared with those in the nectin-3-L cells (Fig. 3Bb). These results suggest that the recruitment of PLEKHA7 to the nectin-3␣-based cell-cell adhesion site is dependent on the binding of afadin to the cytoplasmic tail of nectin-3␣. Taken together, it is likely that PLEKHA7 is recruited to the nectin-3␣-based cell-cell adhesion site in a manner dependent on afadin but independent of p120 ctn .
Afadin-independent Recruitment of PLEKHA7 to the E-cadherin-based Cell-Cell Adhesion Site in L Cells Stably Expressing E-cadherin-We then examined whether PLEKHA7 is recruited to the E-cadherin-based cell-cell adhesion site in an afadin-dependent or -independent manner. When HA-PLEKHA7 was expressed in L cells stably expressing E-cadherin (EL cells), it was recruited to the E-cadherin-based cell-cell adhesion site where the immunofluorescence signals for p120 ctn and afadin were concentrated (Fig. 4A, arrowheads). When afadin was knocked down in EL cells by using siRNA, the afadin protein was markedly reduced as estimated by Western blotting (Fig.  4Ba). The signal for afadin was observed at the E-cadherinbased cell-cell adhesion site in the control cells (Fig. 4Bb, upper  panels, arrowheads), but not in the afadin KD-EL cells (Fig. 4Bb,  upper panels, arrows). Under these conditions, the signal for HA-PLEKHA7 was observed at the E-cadherin-based cell-cell adhesion site in the afadin KD-EL cells where the signal for afadin was not concentrated (Fig. 4Bb, upper panels, arrowheads). The signal for p120 ctn was concentrated at the E-cad- herin-based cell-cell adhesion site in both the control and afadin KD-EL cells (Fig. 4Bb, lower panels, arrowheads). In a quantitative analysis, the percentage of the E-cadherin-based cell-cell adhesion site at which afadin accumulated was clearly diminished in the afadin KD-EL cells as compared with that in the control EL cells, whereas HA-PLEKHA7 was still recruited to the E-cadherin-based cell-cell adhesion site in the afadin KD-EL cells with similar frequency in the control cells (Fig.  4Bc). These results indicate that PLEKHA7 is recruited to the E-cadherin-based cell-cell adhesion site in an afadinindependent manner. These results are apparently inconsistent with the results in Fig. 1 that the knockdown of afadin reduced the accumulations of the signals for E-cadherin and p120 ctn at the cell-cell adhesion site in the afadin KD-EpH4 cells. The reason for this apparent inconsistency is discussed under "Discussion." Binding of PLEKHA7 to Afadin-We next examined by the immunoprecipitation assay whether PLEKHA7 binds to afadin. When GFP-afadin and HA-PLEKHA7 were co-expressed in HEK293E cells and the cell lysates were immunoprecipitated with the anti-GFP pAb, HA-PLEKHA7 was co-immunoprecipitated with GFP-afadin (Fig. 5A). Under these conditions, endogenous p120 ctn was not co-immunoprecipitated with GFP-afadin (data not shown).  OCTOBER  To determine the afadin-binding region of PLEKHA7, a series of truncated mutants of PLEKHA7 shown in Fig. 5Bd were co-expressed with GFP-afadin in HEK293E cells, and GFP-afadin was immunoprecipitated with the anti-GFP pAb. In this assay, an N-terminal fragment (⌬CC), but not a C-terminal fragment (⌬WWPH), was co-immunoprecipitated with GFP-afadin (Fig. 5Ba). These results indicate that afadin binds the N-terminal region of PLEKHA7, which contains a WW domain and a PH domain. Therefore, we further examined whether the N-terminal fragment containing both the WW and PH domains and the fragments containing only the WW or PH domain bind to afadin. The fragment containing the WW and PH domains (WWPH) and the fragment containing only the PH domain (PH), but not the fragment containing only the WW domain (WW), were co-immunoprecipitated with GFP-afadin (Fig. 5Bb), indicating that the region containing the PH domain and its flanking residues of PLEKHA7 (120 -374 aa) is responsible for the binding to afadin. Consistent with these results, the amount of a mutant of PLEKHA7 lacking this region, which was co-immunoprecipitated with GFP-afadin, was markedly reduced as compared with that of full-length PLEKHA7 coimmunoprecipitated with GFP-afadin (Fig. 5Bc). These results indicate that the region of PLEKHA7 (120 -374 aa) is responsible for the binding to afadin. We hereafter refer to this region as the afadin-binding region (AfBR).

Cooperation between PLEKHA7 and Afadin in AJ Formation
We next mapped the PLEKHA7-binding region of afadin by GST pulldown assay by using GST-PLEKHA7-AfBR (GST-AfBR). FLAG-tagged afadin and deletion mutants of afadin shown in Fig. 5Ce were expressed in HEK293E cells, and the lysates of these cells were incubated with GST-AfBR immobilized on glutathione-Sepharose. Full-length afadin (WT) and an N-terminal half of afadin (N-PDZ) were specifically co-precipitated with GST-AfBR, but not with GST (Fig. 5Ca). In contrast, a C-terminal half of afadin (PDZ-C) was not co-precipitated with GST-AfBR. When the N-PDZ fragment was divided into two fragments (NN and NC; see Fig. 5Ce) and each fragment was incubated with GST-AfBR, both the NN and NC fragments were co-precipitated with GST-AfBR (Fig. 5Cb). When the NN fragment was divided into two fragments (RA and FHA; see Fig. 5Ce) and each fragment was incubated with GST-AfBR, the RA fragment, but not the FHA fragment, was co-precipitated with GST-AfBR (Fig. 5Cc). When the NC fragment was divided into two fragments (DIL and PDZ; see Fig. 5Ce) and each fragment was incubated with GST-AfBR, the PDZ fragment, but not the DIL fragment, was co-precipitated with GST-AfBR (Fig. 5Cd). These results indicate that afadin contains at least two PLEKHA7-binding regions (2-350 aa and 1001-1100 aa).
Binding of PLEKHA7-⌬AfBR to p120 ctn and Nezha-The afadin-binding region of PLEKHA7 is distinct from its p120 ctnand Nezha-binding regions (Fig. 5Bd). To exclude the possibility that the deletion of AfBR would affect the binding of PLEKHA7 to p120 ctn and/or Nezha, we examined whether PLEKHA7-⌬AfBR binds to p120 ctn and Nezha by GST pulldown assay. Because PLEKHA7 binds to an N-terminal region of p120 ctn and a C-terminal region of Nezha (19), we used GSTtagged PLEKHA7-binding region of p120 ctn (GST-p120-N) and that of Nezha (GST-Nezha-C). GST, GST-p120-N, or GST-Nezha-C was immobilized on beads and incubated with the lysates from HEK293E cells expressing HA-PLEKHA7-WT or -⌬AfBR. HA-PLEKHA7-WT was co-precipitated with both GST-p120-N and GST-Nezha-C, but not with GST, consistent with the previous observation that PLEKHA7-WT specifically bound to p120-N and Nezha-C (19) (Fig. 6). Under the same conditions, HA-PLEKHA7-⌬AfBR was also co-precipitated with both GST-p120-N and GST-Nezha-C (Fig. 6). These results indicate that the deletion of the afadin-binding region does not affect the binding of PLEKHA7 to p120 ctn and Nezha.

Requirement of the Binding of PLEKHA7 to Afadin for the Proper Formation of AJ, but Not for the Formation of TJ, in EpH4
Cells-We lastly examined whether the binding of PLEKHA7 to afadin is required for the formation of AJ and/or TJ. First, we knocked down PLEKHA7 in EpH4 cells by using retroviral shRNA vectors as in Fig. 1 and analyzed the junctional localizations of the AJ and TJ components. Infection of EpH4 cells with the retrovirus encoding the PLEKHA7 shRNA significantly suppressed the expression of PLEKHA7 without affecting those of afadin and E-cadherin (Fig. 7Aa). The signal for PLEKHA7 was concentrated at the cell-cell adhesion site between the control retrovirus-infected cells (Fig. 7Ab, control), but hardly observed at that between the PLEKHA7 shRNA retrovirus-infected cells (Fig. 7Ab, PLEKHA7 KD). In the control cells, the signals for nectin-2, afadin, E-cadherin, p120 ctn , ZO-1, and occludin were all concentrated at the cell-cell adhesion site (Fig.  7B). In this cell line, nectin-2␣ and -2␦ were expressed as judged by Western blotting (data not shown). When PLEKHA7 was knocked down by shRNA, the signals for E-cadherin and p120 ctn at the cell-cell adhesion site were markedly decreased as compared with those in the control cells, although they still remained to small extents (Fig. 7B). The reduction of the accumulation of the signal for E-cadherin at the cell-cell adhesion sites by the PLEKHA7 knockdown was not caused by the reduction of the total amount of the E-cadherin protein (Fig. 7Aa). In contrast, the signal for afadin, nectin-2, occludin, or ZO-1 was not markedly changed (Fig. 7B). These results are consistent with the earlier observations in Caco2 cells (19) and indicate that PLEKHA7 is required for the proper formation of AJ, but not for the formation of TJ. The residual signals for E-cadherin and p120 ctn at the cell-cell adhesion site in the PLEKHA7 KD cells might be caused by the recruitment of these molecules mediated by other linker molecules for the nectin-afadin and cadherin-catenin systems as described (10,13).
We then examined whether the mutant of PLEKHA7 incapable of binding to afadin (PLEKHA7-⌬AfBR) does not rescue the formation of AJ in the PLEKHA7 KD cells under the conditions where full-length PLEKHA7 rescues it. To perform this rescue experiment, we constructed an shRNA-resistant PLEKHA7 (sr-PLEKHA7) cDNA bearing three silent mutations in the shRNA target sequence. When EpH4 cells were infected with the HA-sr-PLEKHA7-WT retrovirus and the PLEKHA7 shRNA retrovirus, HA-sr-PLEKHA7-WT was expressed in the GFP-positive PLEKHA7 shRNA-expressing cells, and the signal for HA-sr-PLEKHA7-WT was concentrated at the cell-cell adhesion site between GFP-positive cells (Fig. 7Ca). The signal for E-cadherin was significantly increased at the cell-cell adhesion site in these cells as compared with that at the cell-cell adhesion site in the PLEKHA7 KD cells infected with mock retrovirus (Fig. 7C, a and b). In contrast, the mutant of PLEKHA7 incapable of binding to afadin (HA-sr-PLEKHA7-⌬AfBR) was localized in a punctate pattern in the cytosol and at the cell-cell adhesion site; however, its accumulation at the cellcell adhesion site was significantly weaker than that in the PLEKHA7 KD cells in which HA-sr-PLEKHA7-WT was expressed (Fig. 7Ca). The signal for E-cadherin was not significantly increased at the cell-cell adhesion site in these cells as compared with that at the cell-cell adhesion site in the PLEKHA7 KD cells infected with mock retrovirus (Fig. 7C, a  and b). These results indicate that the mutant of PLEKHA7 incapable of binding to afadin does not rescue the proper formation of AJ in the PLEKHA7 KD cells under the conditions where full-length PLEKHA7 rescues it. Taken together, these results indicate that the binding of PLEKHA7 to afadin is required at least partly for the proper formation of AJ, but not for the formation of TJ.

DISCUSSION
It was previously shown that PLEKHA7 binds to p120 ctn and is recruited to the E-cadherin-based cell-cell adhesion site in Caco2 cells (19). However, PLEKHA7 is more strictly localized at AJ, whereas E-cadherin and its associating proteins, such as ␤-catenin, p120 ctn , and ␣-catenin, are localized not only at AJ but also at the basal side of AJ along the lateral plasma membranes of attached epithelial cells, such as MDCK, Caco2, DLD-1, and MCF-10A cells and small intestinal absorptive epithelial cells, although all of them are more highly concentrated at AJ than at the basal side of AJ along the lateral plasma membranes of these attached epithelial cells (9,19,(33)(34)(35)(36). We have shown here that: 1) PLEKHA7 binds to afadin in addition to p120 ctn ; 2) PLEKHA7 is recruited to the nectin-3␣-based cellcell adhesion site by binding to afadin in a p120 ctn -independent manner; and 3) PLEKHA7 is recruited to the E-cadherin-based cell-cell adhesion site in an afadin-independent manner. Considering the previous result that nectin and afadin are strictly localized at AJ in epithelial cells (36), afadin is a likely candidate molecule that localizes PLEKHA7 strictly at AJ. However, the ability of PLEKHA7 to bind to afadin is not sufficient to explain its strict localization at AJ, because PLEKHA7 is able to bind to p120 ctn , which is localized at both AJ and the basal side of AJ along the lateral plasma membranes of attached cells, and PLEKHA7 is recruited to the E-cadherin-based cell-cell adhesion site in an afadin-independent manner in EL cells (Fig. 4). In addition, another PLEKHA7-binding protein paracingulin is localized at both AJ and TJ (20). These three PLEKHA7-binding proteins all are localized at AJ, although p120 ctn and paracingulin are distributed to other sites than AJ. Considering the previous result that E-cadherin, ␤-catenin, p120 ctn , and ␣-catenin are more highly concentrated at AJ than at the basal side of AJ along the lateral plasma membranes of attached epithelial cells, such as MDCK and MCF-10A cells (33,34), p120 ctn concentrated at AJ would contribute to the strict localization of PLEKHA7 at AJ cooperatively with afadin. This likely cooperative role of afadin and p120 ctn is supported by the results of the rescue experiment in which the mutant of PLEKHA7 incapable of binding to afadin did not rescue the proper formation of AJ, as estimated by E-cadherin accumulation at the cell-cell adhesion site, in the PLEKHA7 KD EpH4 cells under the conditions where full-length PLEKHA7 rescued it (Fig. 7C, a and b). In addition, the signal for this mutant of PLEKHA7 was observed at the cell-cell adhesion site, but its accumulation at the cell-cell adhesion site was significantly weaker as compared with wildtype PLEKHA7 (Fig. 7Ca). The weak localization of this mutant of PLEKHA7 at the cell-cell adhesion site was likely to be mediated by residual p120 ctn , which bound to residual E-cadherin at AJ, but not by afadin, in the PLEKHA7 KD EpH4 cells. The deletion of the afadin-binding region of PLEKHA7 did not affect its binding to p120 ctn (Fig. 6), and therefore PLEKHA7-⌬AfBR would be recruited to the cell-cell adhesion site where p120 ctn is localized through its binding to p120 ctn . Importantly, the depletion of afadin in EpH4 cells disrupted the accumulations of PLEKHA7, p120 ctn , and E-cadherin at the cell-cell OCTOBER 11, 2013 • VOLUME 288 • NUMBER 41 adhesion site (Fig. 1). This strongly supports the role for afadin in promoting the accumulations of these proteins at the cellcell adhesion site. However, another possible mechanism in which an unidentified factor(s) is involved in the strict localization of PLEKHA7 at AJ in addition to afadin and p120 ctn cannot be excluded. Further studies are needed to establish the mechanism that localizes PLEKHA7 strictly at AJ.

Cooperation between PLEKHA7 and Afadin in AJ Formation
We have then shown here the role of the binding of PLEKHA7 to the nectin-afadin system. The binding of PLEKHA7 to afadin was necessary for the proper formation of AJ probably by promoting the recruitment of the cadherincatenin complex to the nectin-based cell-cell adhesion site. Our previous series of studies have revealed that the nectin-afadin system first forms cell-cell adhesion and then recruits the cadherin-catenin complex to the nectin-based cell-cell adhesion site to form AJ (10). The association between the nectin-afadin and cadherin-catenin systems is mediated by afadin, ␣-catenin, and their binding proteins. Afadin binds to ␣-catenin directly (12,13) and indirectly through afadin-binding proteins including LIM domain only 7, afadin dilute domain-interacting protein, and ponsin (10). In the PLEKHA7 KD-EpH4 cells, the immunofluorescence signals for E-cadherin and p120 ctn at the cell-cell adhesion site were markedly reduced but still remained to small extents under the conditions where the signal for PLEKHA7 was mostly diminished (Fig. 7B). These residual signals for E-cadherin and p120 ctn at the cell-cell adhesion site might be caused by the recruitment of these molecules mediated by these afadin-binding proteins other than PLEKHA7. Taken together, it is likely that PLEKHA7 regulates at least partly the association of the nectin-afadin and cadherincatenin systems. However, the physical and functional associations of PLEKHA7 with other afadin-binding proteins remain unknown.
In contrast to the finding that the binding of PLEKHA7 to afadin is important to promote the accumulation of E-cadherin at cell-cell adhesion site in EpH4 cells (Fig. 7), the E-cadherinbased cell-cell adhesion was formed upon the knockdown of afadin in EL cells (Fig. 4). These apparently inconsistent results are probably attributed to the difference of the cell lines used in the experiments. Wild-type L cells, which lack cadherin, express nectin-1 and -2 to small extents but do not form cell aggregates in the cell aggregation assay (29). This result indicates that the amounts of nectins are not sufficient to form the nectin-based cell-cell adhesion in L cells. Despite this fact, when E-cadherin is exogenously expressed in L cells, these EL cells form the E-cadherin-based cell-cell adhesion under the condition where the endogenous nectin-afadin system would not work sufficiently, presumably because of the sufficient expression of E-cadherin. This is probably the reason why the E-cadherin-based cell-cell adhesion is formed in the afadin KD-EL cells. On the other hand, EpH4 cells endogenously express E-cadherin, nectin-2, occludin, p120 ctn , afadin, and ZO-1. Under this more physiological condition, the uncoupling of PLEKHA7 to afadin resulted in the failure to promote the accumulation of E-cadherin at the cell-cell adhesion site. These results indicate the significance of the recruitment of PLEKHA7 to the cell-cell adhesion site through afadin for the proper formation of AJ in epithelial cells.
It is currently unknown at which stage PLEKHA7 is recruited to AJ by afadin and p120 ctn and how it regulates the formation of AJ in epithelial cells. One possible mechanism is that when the nectin-afadin system first forms cell-cell adhesion, PLEKHA7 is recruited to this adhesion site through its binding to afadin and when the cadherin-catenin complex is recruited to the nectin-based cell-cell adhesion site where PLEKHA7 is localized, it is associated with PLEKHA7 through p120 ctn , resulting in the formation of AJ. Another possible mechanism is that after the cell-cell adhesion is formed by both the nectinafadin and cadherin-catenin systems, PLEKHA7 is recruited there cooperatively by afadin and p120 ctn . PLEKHA7 recruited in this way then would promote the further accumulation of the cadherin-catenin complex at the cell-cell adhesion site to establish AJ properly. The expression of PLEKHA7 is detected mainly in epithelial tissues and cultured epithelial cells (19,35), and the expression of PLEKHA7 in other nonepithelial cells is unknown. Therefore, the role for PLEKHA7 shown here in the proper formation of AJ may contribute to the formation of AJ specifically in epithelial cells. However, further studies are needed for our understanding of the precise molecular mechanisms for the formation of AJ in epithelial cells.
It was considered that the cadherin-based cell-cell adhesion is required for the formation of TJ (5), but recent studies have shown that the nectin-based cell-cell adhesion, but not the cadherin-based cell-cell adhesion, is necessary for the formation of TJ (37)(38)(39)(40)(41)(42). 3 Furthermore, we have shown that afadin is essential for the formation of TJ (15). We have shown here that the knockdown of PLEKHA7 reduces the accumulation of the cadherin-catenin complex at the cell-cell adhesion site but does not reduce the accumulation of TJ components, such as ZO-1 and occludin. These results are also consistent with the notion FIGURE 7. Requirement of the binding of PLEKHA7 to afadin for the proper formation of AJ, but not for the formation of TJ, in EpH4 cells. A, suppression of PLEKHA7 by shRNA. EpH4 cells infected with the control (control) or the PLEKHA7 shRNA retrovirus (PLEKHA7 KD) were cultured for 72 h. Expression of PLEKHA7 was analyzed by Western blotting (Aa) and immunostaining (Ab) with the indicated Abs. The cells infected with the retroviruses were marked by GFP fluorescence in Ab. IB, immunoblot. B, localization of the junctional proteins in the control and PLEKHA7 KD cells. EpH4 cells infected with retrovirus coding for the control or PLEKHA7 shRNA were cultured for 48 h and then replated on coverslips. Twenty-four hours after the replating, the cells were fixed and analyzed by immunostaining with the indicated Abs. Ca, restoration of the decrease of the signal for E-cadherin at the cell-cell adhesion site in PLEKHA7 KD cells by the re-expression of sr-PLEKHA7-WT, but not by the re-expression of sr-PLEKHA7-⌬AfBR. EpH4 cells were infected with the retrovirus encoding shRNA together with the retrovirus encoding HA-sr-PLEKHA7-WT or -⌬AfBR and then processed as described in B. Cb, quantitative analysis of the intensity of the signal for E-cadherin at the cell-cell adhesion site. The bar graph represents the relative fluorescence intensity of the signal for E-cadherin at the cell-cell adhesion site. The data are the means Ϯ S.E. of 15 images from three independent experiments, with the mean fluorescence in the cells infected with control shRNA and mock retroviruses normalized to 1.0. *, p Ͻ 0.05 with Tukey's multiple comparisons test. Scale bars, 20 m. The results shown are representative of three independent experiments.