Depletion of E-Cadherin Disrupts Establishment but Not Maintenance of Cell Junctions in Madin-Darby Canine Kidney Epithelial Cells

Christopher T. Capaldo, and Ian G. Macara

Center for Cell Signaling, University of Virginia School of Medicine, Charlottesville, VA 22908-0577

Submitted June 19, 2006; Revised October 16, 2006; Accepted October 26, 2006
Monitoring Editor: Asma Nusrat

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

E-cadherin forms calcium-dependent homophilic intercellularadhesions between epithelial cells. These contacts regulatemultiple aspects of cell behavior, including the organizationof intercellular tight junctions (TJs). To distinguish betweenthe roles of E-cadherin in formation versus maintenance of junctions,Madin-Darby canine kidney (MDCK) cells were depleted of E-cadherinby RNA interference. Surprisingly, reducing E-cadherin expressionhad little effect on the protein levels or localization of adherensjunction (AJ) or TJ markers. The cells underwent morphologicalchanges, as the normally flat apical surface swelled into adome. However, apical–basal polarity was not compromised,transmembrane resistance was normal, and zonula occludin protein1 dynamics at the TJs were unchanged. Additionally, an E-cadherin/Cadherin-6double knockdown also failed to disrupt established TJs, although $beta$ -catenin was lost from the cell cortex. Nevertheless, cellsdepleted of E-cadherin failed to properly reestablish cell polarityafter junction disassembly. Recovery of cell–cell adhesion,transepithelial resistance, and the localization of TJ and AJmarkers were all delayed. In contrast, depletion of ${alpha}$ -catenincaused long-term disruption of junctions. These results indicatethat E-cadherin and Cadherin-6 function as a scaffold for theconstruction of polarized structures, and they become largelydispensable in mature junctions, whereas ${alpha}$ -catenin is essentialfor the maintenance of functional junctions.

INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The cadherins are a large family of transmembrane glycoproteinsthat form homophilic, calcium-dependent interactions with neighboringcells (Takeichi, 1988; Gumbiner, 2000; Nollet et al., 2000).Cadherin family members include type I cadherins (E-, N-, P-,and R-cadherin), type II cadherins (Cadherin-6 and VE-cadherin),desmosomal cadherins (desmocollins and desmogleins), and a largesubfamily of cadherin-like molecules (Nollet et al., 2000).The predominant epithelial isoform, E-cadherin, localizes tothe lateral membrane of differentiated epithelia, providingthe structural foundation for adherens junctions (AJs), a multiproteincomplex that links cell–cell contacts to the actin cytoskeletonand various signaling molecules (Perez-Moreno et al., 2003).The extracellular domain is composed of five ectodomain modules(ECs), with the most membrane-distal module (EC1) mediatingbinding with the E-cadherin on the adjacent cell (Boggon etal., 2002). Calcium ions bind between the EC domains to promotea rod-like conformation required for transinteractions (Gumbiner,1996; Patel et al., 2006). The cytoplasmic tail of E-cadherinbinds to the armadillo repeat protein $beta$ -catenin, an importanttarget of the Wnt signaling pathway and a cofactor for TCF/LEF-mediatedtranscription (Gavard and Mege, 2005). The $beta$ -catenin in turnbinds ${alpha}$ -catenin, which interacts with actin, as well as severalactin-binding proteins: vinculin, formins, ${alpha}$ -actinin, zonulaoccludin protein (ZO)-1, and afadin (Bershadsky, 2004). Cell–celladhesions also contain desmosomes, which link cell contactsto intermediate filaments as well as nectin-based, calcium-independentadhesions, which are linked to actin (Takai and Nakanishi, 2003;Yin and Green, 2004).

Assembly of adhesions de novo is a highly organized, hierarchicalprocess (Adams and Nelson, 1998; Braga, 2002; Jamora and Fuchs,2002). During cell junction biogenesis, cadherin-based adhesionsform rapidly, recruit actin, and stimulate phosphatidylinositol3-kinase and the activities of the small GTPases Rac1 and Cdc42(Yap and Kovacs, 2003). These events enhance E-cadherin recruitmentto cell–cell contact sites, strengthen the cadherin–catenincomplex, and promote actin reorganization into belts aroundthe cell periphery (Vasioukhin and Fuchs, 2001). Importantly,stable epithelial adhesions require the F-actin network, becausetreatment with latruculin A or cytochalasin D causes loss ofAJs as well as desmosomes and tight junctions (TJs) (Shen andTurner, 2005).

E-cadherin engagement promotes epithelial apical–basalpolarization, including the formation of TJs (Gumbiner et al.,1988). TJs are the most apical junction complex and providea barrier to pericellular diffusion (gate function) as wellas a diffusion barrier between apical and basal–lateralmembrane compartments (fence function) (Matter and Balda, 2003).TJs are composed of transmembrane proteins occludin, and claudin,which anchor scaffolding proteins, including ZO-1, ZO-2, andZO-3, at the cell periphery (Gonzalez-Mariscal et al., 2003).These proteins in turn bind actin and regulatory complexes suchas the PAR proteins and the apical Crb complex. In a poorlyunderstood process, TJ proteins are initially recruited to cadherincontacts when cells touch, possibly through ${alpha}$ -catenin–mediatedrecruitment of ZO-1 (Muller et al., 2005), and only later moveaway to form the TJ.

Regulation of cell adhesions through cadherins is essentialfor embryonic development, and coordinated adhesion restructuringis necessary during epithelial-to-mesenchymal transitions (D'Souza-Schorey,2005). This remodeling can occur through regulated transportof cadherin–catenin-containing vesicles to and from themembrane. Cadherin endocytosis is a potent mechanism for junctionremodeling and involves the ARF6 complex, Scr-mediated ubiquitination,or p120 catenin-regulated degradation (Davis et al., 2003; Bryantand Stow, 2004). Loss of cadherin-based adhesions is a hallmarkof carcinogenesis and correlates with tumor progression. Inmany epithelial-derived tumors, E-cadherin expression is down-regulated,leading to loss of cell adhesions, increased proliferation,and tumor invasiveness (Takeichi, 1991; Van Aken et al., 2001;Cowin et al., 2005). Other examples of adhesion loss includeE-cadherin EC domain mutants, or disruption of the link to actinthrough catenins (Shimoyama et al., 1992). Not surprisingly,E-cadherin knockout mice are embryonic lethal, failing to developpast the trophoectoderm, 32-cell stage (Larue et al., 1994;Ohsugi et al., 1997). Postnatal lethality in mice with a conditionalE-cadherin knockout in skin is due to failure of the epidermisto prevent water loss (Tinkle et al., 2004; Tunggal et al.,2005). Although illustrative of the importance of E-cadherinin cell–cell contacts, the functions of E-cadherin hasremained unclear in these models, because of either residualmaternal transcript or compensation by other cadherin familymembers. Particularly, it is uncertain whether these defectsarise from loss of the ability to maintain proper junctionsor to form them in the first place.

To distinguish between the roles of cadherins in the initialformation versus maintenance of junctions, we suppressed E-cadherinexpression in Madin-Darby canine kidney (MDCK) cells by RNAinterference (RNAi). This resulted in a reduction in E-cadherinlevels without observable increase in related cadherin isoformexpression. Surprisingly, E-cadherin knockdown had little effecton the protein levels or localization of either TJ or AJ proteinsin confluent MDCK monolayers, and cell polarity was maintained.Even the codepletion of E-cadherin with Cadherin-6, which ledto a marked loss of $beta$ -catenin from the cell cortex, did not seemto disrupt TJs. In contrast, cells depleted of E-cadherin wereunable to repolarize properly after TJ disassembly. Depletionof ${alpha}$ -catenin, in contrast, disrupted both the establishment andmaintenance of junctions. These studies indicate that cadherinsfunction as a scaffold for the establishment of cell polaritybut that they are largely dispensable for the maintenance ofpreformed cell–cell junctions and apical/basal polarity.

MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Cell Culture and Transfection
MDCK T23 and MDCK T23 yellow fluorescent protein (YFP)-ZO-1cells were cultured in DMEM with 10% fetal calf serum (FCS)and 100 U/ml penicillin-streptomycin (Invitrogen, Carlsbad,CA). MDCK T23 cells were nucleofected (Amaxa Biosystems, Gaithersburg,MD) with 2.5 x 10⁶ cells per transfection, by using 3 µgof DNA, (2 µg of pSuper plus 1 µg of pKseYFP (Venus,a superenhanced yellow fluorescent protein) or pKmRFP (monomericred fluorescent protein) as a transfection marker. Experimentswere performed 2–3 d posttransfection.

Immunostaining and Antibodies
Cells were fixed in either 4% paraformaldehyde-phosphate-bufferedsaline (PFA-PBS) or methanol/acetone as described previously(Qin et al., 2005). PFA-fixed cells were permeabilized with0.5% Triton X (TX)-100 for 10 min. All samples were blockedin 10% FCS-PBS for 1 h before staining. Primary antibodies usedwere mouse anti-E-cadherin and anti- $beta$ -catenin (1:500; BD Biosciences,San Jose, CA), mouse anti-IQGAP (1:100; Upstate BiotechnologyCharlottesville, VA), rabbit anti-green fluorescent protein(GFP) (1:200; Invitrogen), rabbit anti- ${alpha}$ -catenin (1:2000; Sigma-Aldrich,St. Louis, MO), rabbit anti-Claudin 1 (1:20; Zymed Laboratories,South San Francisco, CA), mouse anti-gp135 (1:300; clone 3F21D8),and mouse anti-ZO-1 (1:100; Zymed Laboratories). Mouse anti-Na⁺/K⁺-ATPaseH6 (1:250) was a gift from Michael Caplan (Yale University,New Haven, CT). Par3 (1:100) and Pals1 (1:50) antibodies wereproduced in rabbits against recombinant proteins (Cocalico Biologicals,Reamstown, PA). Alexa 594-phalloidin (1:50; Invitrogen) wasused to visualize F-actin. Secondaries were goat anti-mouseor anti-rabbit antibodies conjugated to Alexa 488, Alexa 594,and 7-amino-4-methylcoumarin-3-acetic acid (AMCA) (1:1000; Invitrogen).Images were captured on a TE200 widefield microscope (Nikon,Tokyo, Japan) using a 60x water immersion lens (1.2 numericalaperture [NA]) and a Orca charge-coupled device camera (Hamamatsu,Bridgewater, NJ) or for confocal images a 510 Meta/FCS laser-scanningconfocal microscope (Carl Zeiss, Thornwood, NY), by using a100x oil immersion lens (1.3 NA). Widefield images were processedusing the Adobe Photoshop 7.0 Levels tool (Adobe Systems, MountainView, CA) to enhance contrast. Confocal image stacks were processedusing Volocity software (Improvision, Warwick, United Kingdom).

Western Blots and Immunoprecipitations
Whole cell lysates were collected by adding SDS sample bufferor, for Cadherin-6 lysates, a 1% SDS buffer (1% SDS [wt/vol],10 mM Tris, pH 7.5, and 1 mM EDTA), and boiled for 10 min beforeanalysis by SDS-PAGE. Immunoprecipitations were performed asfollows: cells were lysed in lysis buffer (0.5% Triton X-100,25 mM Tris, pH 7.4, 300 mM sucrose, 25 mM NaF, 150 mM NaCl,2 mM Na₃VO₄, 10 µg/ml leupeptin, 10 µg/ml aprotinin,and 1 mM phenylmethylsulfonyl fluoride) and centrifuged for10 min at 10,000 x g. Supernatants were immunoprecipitated (anti- $beta$ -catenin,GammaBind-Plus Sepharose beads; GE Healthcare, Little Chalfont,Buckinghamshire, United Kingdom) for 1 h at 4°C. Sampleswere washed three times in lysis buffer with 500 mM NaCl andonce with lysis buffer then eluted in SDS sample buffer. Primaryantibodies were rabbit anti- $beta$ -tubulin (1:100; Santa Cruz Biotechnology,Santa Cruz, CA), rabbit anti-ZO-1 (1:1000; Zymed Laboratories),mouse anti-E-cadherin and $beta$ -catenin (1:1000; BD Biosciences),rabbit anti- ${alpha}$ -catenin (1:2000; Sigma-Aldrich), rabbit anti-Pals1(1:1000) and mouse anti-Ran (1:5000; BD Transduction Laboratories,Lexington, KY), and mouse anti-Rac (1:1000; Upstate Biotechnology).Rabbit anti-Pan-cadherin and rabbit anti-Cadherin-6 were giftsfrom Barry Gumbiner (Department of Cell Biology, Universityof Virginia School of Medicine) and James Nelson (BiologicalSciences, Stanford University School of Medicine, Stanford,CA), respectively. Quantitative Westerns were performed usingan Odyssey detector (LI-COR, Lincoln, NE). Secondary antibodiesfor Odyssey detection included Alexa Fluor IRDye 800-conjugatedgoat anti-mouse (Rockland, Gilbertsville, PA) and Alexa Fluor680-conjugated goat anti-rabbit (Invitrogen).

Constructs
Canine E-cadherin, Cadherin-6, and ${alpha}$ -catenin sequences from theBroad Institute Reference Dog Assembly Boxer library were screenedfor candidate small interfering RNA primers by using rationaldesign criteria (Reynolds et al., 2004). Oligonucleotides forshort hairpin RNA (shRNA) are as follows: E-cadherin primerA sense strand, 5'-gatccccGGACGTGGAAGATGTGAATttcaagagaATTCACATCTTCCACGTCCtttttggaaa-3'and antisense, 5'-agcttttccaaaaaGGACGTGGAAGATGTGAATtctcttgaaATTCACATCTTCCACGTCCggg-3';primerB sense strand, 5'gatccccGTCTAACAGGGACAAAGAAttcaagagaTTCTTTGTCCCTGTTAGACtttttggaaa-3'and antisense, 5'-agcttttccaaaaaGTCTAACAGGGACAAAGAAtctcttgaaTTCTTTGTCCCTGTTAGACggg-3'.Cadherin-6 primers are as follows: sense strand, 5'-gatccccGCGGCTACAGTCAGAATTAttcaagagaTAATTCTGACTGTAGCCGCtttttggaaa-3'and antisense, agcttttccaaaaaGCGGCTACAGTCAGAATTAtctcttgaaTAATTCTGACTGTAGCCGCggg-3'.Primers designed for ${alpha}$ -catenin are as follows: primer 1 sensestrand, 5'-gatccccTGAACAAGACTTAGGAATAttcaagagaTATTCCTAAGTCTTGTTCAtttttggaaa-3'and antisense, 5'-agcttttccaaaaaTGAACAAGACTTAGGAATAtctcttgaaTATTCCTAAGTCTTGTTCAggg-3';primer 2 sense strand, 5'-gatccccGGCTAACAGAGACCTGATAttcaagagaTATCAGGTCTCTGTTAGCCtttttggaaa-3'and antisense, 5'-agcttttccaaaaaGGCTAACAGAGACCTGATAtctcttgaaTATCAGGTCTCTGTTAGCCggg-3'.Annealed primers were cloned using BglII and HindIII restrictionsites into pSuper, as described previously (Brummelkamp et al.,2002). A sequence targeting luciferase (pSLuc) was used as anegative control (Malliri et al., 2004).

Transepithelial Resistance (TER) Measurements
Calcium switch and TER were performed as described previously(Gao et al., 2002). MDCK T23 cells were nucleofected as describedabove with control or E-cadherin pSuper plasmids. Cells werethen plated onto 0.4-µm pore, 12-mm Transwell filters(Corning Glassworks, Corning, NY) at 5.5 x 10⁵ cells per filter.Resistance measurements were performed 2–3 d later, andvalues listed are the average of three trials with backgroundresistance subtracted.

Fluorescence Recovery after Photobleaching (FRAP)
An MDCK stable line expressing YFP-ZO-1 was established by cotransfectionof pKYFP-ZO-1 and a vector expressing a hygromycin resistancegene, pHyg (McNeil et al., 2006). Cells were then selected byhygromycin and screened for expression of pKYFP-ZO-1. For FRAPassays, cells were nucleofected with pKmRFP as a transfectionmarker and either control or E-cadherin pSuper plasmid. After48 h, cells were subjected to photobleaching and imaged by confocalmicroscopy (Meta LSM510; Carl Zeiss), by using a 100x oil lens(1.3 NA). Cells were imaged with a 488-nm laser line at 75%power, 0.1% transmission, and 543-nm laser line at 59% transmission.For photobleaching, regions of interest (ROIs) were selectedbetween two adjacent transfected cells (marked with monomericred fluorescent protein [mRFP]), and bleached with the 488-nmlaser line, at 75% power, 100% transmission for two iterations.Recovery within the ROI was monitored for 400 s. For each sample,two images were recorded prebleach, and postbleach images arerepresented as a percentage of total YFP-ZO-1 in the cell. Forall images, mean intensities were adjusted for bleaching duringimaging.

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Knockdown of E-Cadherin in MDCK Cells
To investigate the role of E-cadherin in cell polarity, we depletedE-cadherin from MDCK cells by RNAi. Two shRNAs, pSEcad-A and-B, were created against canine E-cadherin sequences. Cellswere transiently transfected with pSuper plasmids expressingeither the E-cadherin target sequences or, as a control, shRNAscomplementary to the Luciferase gene (pSLuc). Efficiency ofknockdown was assayed by immunoblots of cell lysates 2 d posttransfection(Figure 1A). Both shRNAs depleted E-cadherin in MDCK cells,with pSEcad-B exhibiting most effective. In subsequent experiments,cells referred to as knockdown (KD) cells were transfected withpSEcad-B or a mixture of pSEcad-A and -B. Figure 1A also showsthat protein levels of ZO-1 and Pals1 are similar between knockdownand control lysates. $beta$ -tubulin was used as a protein loadingcontrol. pSEcad vector concentrations were titrated to optimizeE-cadherin suppression (Figure 1B). By quantitative immunoblot,E-cadherin depletion to 15–20% of control values was achievedwith 1–2 µg of plasmid. Importantly, the immunoblotswere from transient transfections in which the efficiency oftransfection was estimated to be 70–80%. This suggeststhat gene silencing in transfected cells approaches 100%. EfficientE-cadherin suppression in transfected cells was confirmed byimmunofluorescence (Figure 1C). MDCK cells were transfectedwith the shRNAs plus pK-YFP as a transfection marker. Imageswere obtained after 48 h and selected to include both transfectedand nontransfected cells. Little or no E-cadherin was detectedin the transfected cells.

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Figure 1. E-cadherin knockdown in MDCK cells. E-cadherin shRNAs were generated against canine E-cadherin sequence and expressed in MDCK cells. Control samples expressed shRNAs against luciferase (pSLuc). (A). Immunoblot of cell lysates 2 d posttransfection. $beta$ -tubulin was used as a loading control. (B). Western blot of cell lysates from control cells, and cells transfected with increasing amounts of pS-EcadB. The bottom panel shows quantitative measurements of E-cadherin depletion, adjusted for differences in gel loading. (C) Immunofluorescence staining of fixed control and KD cells. E-cadherin is silenced in cells coexpressing the YFP marker.

Cell–Cell Contracts Are Maintained in E-Cadherin Knockdown Cells
To determine the effects of E-cadherin knockdown on cell polarity,we analyzed TJ and AJ marker proteins by immunofluorescence.MDCK cells were transfected in suspension then plated onto Lab-Tekslides at sufficient density to immediately form a confluentmonolayer. Cells were fixed and stained after 48 h, the timepoint at which we observed maximum E-cadherin knockdown (Figure 3A).This protocol allows the reformation of cell–cell junctions(complete by $~$ 5 h after trypsinization; Chen and Macara, 2005

)before any significant loss of E-cadherin and enables us toask whether E-cadherin is required for maintenance of cell polarityafter mature cell–cell contacts have formed.

In differentiated epithelia, ZO-1, Pals1, Par3, and the transmembraneprotein claudin1 all localize to the apical TJ complex (Gonzalez-Mariscalet al., 2003). Unexpectedly, loss of E-cadherin had no effecton this localization (Figure 2A). Both control and knockdowncells (marked by YFP expression) showed TJ marker proteins atcell–cell contacts. Remarkably, E-cadherin silencing alsofailed to disrupt peripheral localization of AJ proteins (Figure 2B).Despite a reduction of E-cadherin in transfected cells to almostundetectable levels, adherens components $beta$ -catenin and ${alpha}$ -cateninstill localized to cell–cell contacts (Figure 2B), andcortical actin bundles were still localized to the cell periphery.

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Figure 2. Cell–cell contacts are maintained in cells depleted of E-cadherin. Immunofluorescence staining of MDCK cells fixed 2 d posttransfection with E-cadherin pSEcad or pSLuc shRNAs. YFP expression is a transfection marker. (A) TJ marker proteins ZO-1, Pals1, Par3, and the transmembrane protein Claudin1 localize to cell–cell contacts in control and knockdown cells. (B) Adherens junction proteins E-cadherin, $beta$ -catenin, ${alpha}$ -catenin, and actin localization at cell–cell contacts in both control and knockdown cells.

E-Cadherin–depleted Cells Retain Apical–Basal Polarity
Tight junctions seem intact in the knockdown cells, but theydo they function properly? To answer this question, we measuredthe pericellular permeability of control and knockdown cellsby TER. Resistance was measured over 4 d posttransfection (Figure 3A).An immunoblot, of cell lysates over this period (Figure 3A,right), with E-cadherin and pan-cadherin antibodies shows cadherinlevels were lowest at 2 d posttransfection. Strikingly, depletionhad no apparent effect on pericellular permeability as measuredby TER. Therefore, epithelial gate function was preserved inthe E-cadherin knockdown cells.

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Figure 3. TJs are not disrupted in cells depleted of E-cadherin. (A) TER was measured up to 4 d posttransfection. Results are plotted for control ( ${blacksquare}$ ) and knockdown cells ( ${blacktriangleup}$ ), as means of three independent experiments after background subtraction. Below is a representative Western blot of Cadherin expression over this time period. (B) Cell polarity is maintained in cells depleted of E-cadherin. MDCK cells grown on filters were fixed and stained 2 d posttransfection. Cells were imaged by confocal microscopy with 20 x 1 µm z-sections. Assembled images are viewed in cross-section, stained with the apical marker gp135 (green), or the basal–lateral marker Na⁺/K⁺ATPase (green). mRFP or YFP marks transfected cells. (C) 3-D–assembled confocal sections of control or E-cadherin knockdown cells. Apical surfaces are stained with gp135 (green), with mRFP as a transfection marker. (D) FRAP analysis of TJ stability in YFP-ZO-1 MDCK stable cell line. Confocal sections of cells expressing YFP-ZO-1 are shown before and at various time points after photobleaching. mRFP expression marks transfected cells and boxed areas at time point 1 indicate bleached region. (E) Quantification of FRAP in control (n = 6) and knockdown cells (n = 5).

Another measure of TJ integrity is whether cells can maintaindistinct apical and basal membrane surfaces. To determine whetherfence function is maintained, MDCK cells were grown to confluenceon filters and assayed by immunofluorescence for the apicalmarker gp135, or the lateral marker Na⁺/K⁺ ATPase (Figure 3B).mRFP was introduced to identify cells depleted of E-cadherin.The images shown are cross-sections of compiled confocal layers.In both control and knockdown cells gp135 was confined to theapical surface and Na⁺/K⁺ATPase was limited to the lateral surface.Taken together, these data suggest that endogenous levels ofE-cadherin are not required for the maintenance of cell polarity.We noticed, however, that the apical surfaces of cells lackingE-cadherin were bulbous rather than being flat, as in the controlcells (Figure 3B). The domed shapes of these cells were particularlyevident in three-dimensional (3-D) reconstruction of confocalsections (Figure 3C). Control cells consistently have flat apicalsurfaces. The reason for this morphological change remains unclear.The level of gp135, an apical marker, was not increased relativeto total cell protein or basolateral markers by E-cadherin silencing(data not shown), suggesting that the apical/lateral surfaceratio was not increased. Moreover, changing the osmotic pressureof the media in the apical compartment of the filter did notreverse the effect, showing that the domed shape of the cellswas not caused by a defect in cellular osmotic regulation (datanot shown).

Previously, we had reported that suppression of E-cadherin byRNAi in MDCK cells increased cell migration and promoted a morefibroblast-like phenotype in subconfluent cells (Qin et al.,2005). Increased junction remodeling may be required for motilecells and this could be reflected in increased turnover of junctionproteins. These considerations led us to ask whether TJ dynamicswere altered by E-cadherin depletion. FRAP was used to assessthis possibility. MDCK cells stably expressing a YFP–ZO-1construct were subjected to photobleaching and imaged by confocalmicroscopy (Figure 3E). The YFP-ZO1 fusion behaves similarlyto endogenous protein, because it localizes to TJs and is capableof compensating functionally for ZO1 depletion by RNAi (McNeilet al., 2006). This cell line was transfected with pSEcad orcontrol plasmid and imaged 48 h posttransfection. Regions withinthe junctions between two adjacent transfected cells were selectedfor bleaching (yellow box Figure 3D), and average intensitywas monitored during recovery (Figure 3E). In both control andE-cadherin–depleted cells, YFP ZO-1 fluorescence intensitiesrecovered from photobleaching to $~$ 50% of initial values, indicatingthat both mobile and immobile populations of ZO-1 exist withinthe TJ. In both cases, the half-time for recovery of the mobilefraction was $~$ 50 s. These results show that E-cadherin levelsare not important for ZO-1 turnover at the membranes of polarizedMDCK cells and that TJ stability is probably not regulated bythe dynamics of proteins in these junctions.

E-Cadherin–depleted Cells Exhibit Increased Calcium Sensitivity
Cell–cell contacts in MDCK cells are composed of bothcalcium-dependent and calcium-independent adhesions. Importantly,neither type of junction can be maintained when cells are incubatedin media containing <10 µM extracellular calcium (Gonzalez-Mariscalet al., 1990). To determine the requirement for E-cadherin injunction maintenance during calcium withdrawal, YFP-ZO-1–expressingMDCK cells were imaged by time-lapse microscopy in either 2or 100 µM extracellular calcium. After $~$ 30-min incubationin 2 µM calcium, control and KD cells both began to losejunctions, and YFP-ZO-1 accumulated near remaining cell–cellcontacts as punctate dots (Figure 4A). By 60 min, YFP-ZO-1 wasno longer localized at the junction, instead showing up as ahazy ring in the cytoplasm. Previous studies have shown MDCKcells can maintain junctions in calcium concentrations as lowas 100 µM (Gonzalez-Mariscal et al., 1990). Strikingly,this concentration was sufficient to displace YFP-ZO-1 fromcell–cell contacts in E-cadherin–depleted cell butnot in control cells, indicating an increased sensitivity toextracellular calcium concentration. A similar sensitivity wasobserved when cells, incubated in 100 µM calcium for 15min, were fixed and stained with phalloidin to observe actinstructures (Figure 4B). In E-cadherin–depleted cells,actin was released from the cortex and occurred as a ring inthe cytoplasm, whereas the untransfected and control cells retainedcortical actin structures. Interestingly, cortical actin disassociationoccurred at a time when most of the YFP-ZO-1 was still retainedat the junctions (Figure 4A, 30 min). This result shows thatE-cadherin is required for the attachment of the actin ringto the cortex in low calcium.

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Figure 4. Increased calcium sensitivity in E-cadherin–depleted cells. (A) YFP-ZO-1 becomes mislocalized at 100 µM extracellular calcium in cells depleted of E-cadherin. MDCK T23 cells stably expressing YFP-ZO-1 were transfected with vectors for mRFP plus pSLuc or pSEcad shRNAs. After 2 d, cells were switched to medium containing either 2 or 100 µM calcium (t = 0), and YFP-ZO-1 localization was monitored for up to 60 min. (B) MDCK cells expressing control (pSLuc) or E-cadherin shRNA along with YFP, were incubated in medium containing 100 µM calcium for 15 min. Fixed cells were stained with phalloidin to visualize actin structures. (C) E-cadherin depletion causes loss of TER at 100 µM calcium. Control (pS) and E-cadherin knockdown cells (KD) were plated on Transwell filters and allowed to grow to confluence. Cells were then incubated in medium containing 2 or 100 µM calcium. TER was measured for 60 min.

As an alternative approach, MDCK T23 cells were incubated inmedia with either 2 or 100 µM calcium, and junction integritywas measured by TER (Figure 4C). Again, 2 µM calcium mediadisrupted cell–cell contacts in both control and E-cadherinsuppressed cultures. The rate of resistance loss was similarbetween the two samples. Incubation with 100 µM calcium,however, caused a slight drop in resistance in control cultures,but decreased the resistance of E-cadherin–suppressedcells in a manner similar to incubation with 2 µM calcium.

E-Cadherin– $beta$ -Catenin Complex Is Disrupted in E-Cadherin Knockdown Cells
By quantitative Western blot analysis, a reduction of E-cadherinby 85% (±5%), caused a drop of only 40% (±8%)in $beta$ -catenin, and ${alpha}$ -catenin remained essentially unchanged (Figure 5A).E-cadherin binds $beta$ -catenin in a 1:1 stoichiometric complex (Ozawaand Kemler, 1992; Huber and Weis, 2001). Therefore, one explanationfor $beta$ -catenin stability and for its continued peripheral localizationin E-cadherin depleted cells is that E-cadherin exists in largeexcess over $beta$ -catenin, and the reduction in E-cadherin by RNAiwould then be insufficient to disrupt the complex. To test forthis possibility, MDCK cell lysates were subjected to serialimmunodepletion with anti-E-cadherin antibody. The resultingsupernatants were blotted for E-cadherin, $beta$ -catenin, and $beta$ -tubulin(Figure 5B). By the third round of immunoprecipitation, supernatantswere almost completely devoid of E-cadherin, yet a considerablefraction of the $beta$ -catenin remained in the supernatant. To controlfor disassociation of the complex over the course of the experiment,MDCK cell lysates were immunoprecipitated after either 1- or5-h incubations on ice. The E-cadherin– $beta$ -catenin complexremained stable during this period (data not shown). If we assumethat the $beta$ -catenin normally associated with E-cadherin is destroyedin the knockdown cells, we can calculate that there is roughlya twofold excess of $beta$ -catenin over E-cadherin in MDCK cells.Most of this $beta$ -catenin is at the lateral cell cortex in confluentmonolayers (Figure 2B). Also, in day 2 lysates most of the E-cadherinoccurs in the Triton X-100–soluble fraction, and thisfraction does not change with depletion of E-cadherin by RNAi(Figure 5C). Additionally, when the supernatants were immunoprecipitatedfor $beta$ -catenin, the amount of E-cadherin bound to $beta$ -catenin wasfound to be at similar ratios to the protein levels in celllysates. Together, these data indicate that there is an excessof $beta$ -catenin in MDCK cells relative to E-cadherin. Thus, thecontinued stability of $beta$ -catenin in cells depleted of E-cadherincannot be due to binding to residual E-cadherin.

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Figure 5. $beta$ -catenin is in excess of E-cadherin in MDCK cells. (A) Western blot analysis of whole cell lysates 2 d posttransfection with pSLuc or pSEcad vectors. Lysates were blotted for E-cadherin, $beta$ -catenin, and ${alpha}$ -catenin to determine relative protein abundances. (B) $beta$ -catenin is in excess of E-cadherin in MDCK cells. TX-100 lysates from untransfected cells were analyzed by immunoblot after serial E-cadherin immunodepletion. (C) MDCK cells were lysed in a TX-100 lysis buffer, and samples of the insoluble (pellet) and soluble (sup) fractions were analyzed by immunoblot. The fraction of $beta$ -catenin in the insoluble pool does not change in cells after E-cadherin depletion. Soluble lysate fractions were immunoprecipitated with $beta$ -catenin antibody or mouse nonimmune antibody (NIIgG) as a control. Samples were blotted for $beta$ -catenin. (D) Immunoblot of cell lysates from control (pSLuc) or pS-Ecad–transfected cells. Lysates were blotted for E-cadherin and Pan-cadherin. $beta$ -tubulin is a loading control. (E) Whole cell lysates of control (pSLuc) and pSEcad cells blotted for Cadherin-6, E-cadherin, and $beta$ -tubulin.

$beta$ -Catenin Is Stabilized by Cadherin-6
Free $beta$ -catenin will be degraded or imported into the nucleus.Therefore, the surplus protein is presumably bound to othercadherin family members or to ${alpha}$ -catenin. In conditional E-cadherinknockout mice, an increased expression of P-cadherin is thoughtto compensate for the loss of the E-cadherin (Tinkle et al.,2004

; Tunggal et al., 2005

). MDCK cells express several classicalcadherins, although most are expressed at low levels (Geigeret al., 1990

). We first asked whether these cadherins are up-regulatedin E-cadherin–depleted MDCK cells, by blotting lysateswith a pan-cadherin antibody, which detects the highly conservedcytoplasmic domain of classical cadherins. However, the reductionin band intensities in pan-cadherin immunoblots was similarto that for the E-cadherin blot (Figure 5E), suggesting thatno up-regulation occurs, and confirming that the majority oftype I cadherin in MDCK cells is the E isoform. Cadherin-6 (K-cadherin),a type II atypical cadherin, is also expressed in MDCK cells,although at low levels (Stewart et al., 2000

). However, Cadherin-6expression was not induced by E-cadherin knockdown (Figure 5E).Nonetheless, it seemed possible that Cadherin-6 contributesto cell–cell adhesions and $beta$ -catenin stability. To testthis possibility, we immunostained MDCK cells, and observedthat Cadherin-6 was retained at cell–cell contacts inE-cadherin-depleted cells (Figure 6A). But to what extent doesCadherin-6 stabilize cell–cell contacts in the absenceof E-cadherin? To address this question, shRNAs were producedto target the canine Cadherin-6 sequence. These shRNAs efficientlysilenced Cadherin-6 expression, as shown both by immunoblotsof whole cell lysates (Figure 6B, lanes 3 and 4), and by immunofluorescencestaining with anti-Cadherin-6 antibody (Figure 6C). (Whole celllysates were processed in the absence of $beta$ -ME, as described inMaterials and Methods, which may account for $beta$ -catenin resolvingas a double band). Cadherin-6 depletion alone had no visibleeffect on $beta$ -catenin localization, yet when E-cadherin was alsosuppressed, $beta$ -catenin was almost entirely lost from the cellperiphery, and the overall level of the protein was substantiallyreduced. Defects were also seen in the localization of ${alpha}$ -cateninand actin structures at the cell cortex. Strikingly, however,ZO-1 remained at the cell junctions in both the Cadherin-6 singleknockdown and the Cadherin-6/E-cadherin double knockdown (Figure 6C).

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Figure 6. Simultaneous suppression of Cadherin-6 and E-cadherin causes mislocalization of $beta$ -catenin, yet TJs are not disrupted. (A) Immunofluorescence of Cadherin-6 in MDCK cells fixed 2 d after transfection with E-cadherin (pSEcad) or pSLuc shRNA vectors. YFP is the transfection marker. (B) Immunoblot analysis of cell lysates from MDCK cells transfected with pSLuc or pSEcad, Cadherin-6 shRNA vector (pSCad6), or both pSEcad plus pSCad6. (C) Immunofluorescence images of MDCK cells depleted of Cadherin-6 or of both E-cadherin and Cadherin-6. Cells were fixed and stained with anti-Cadherin-6 or anti-E-cadherin to confirm cadherin suppression in transfected cells. Cellular localization of ZO-1, $beta$ -catenin, ${alpha}$ -catenin, and actin is shown for both Cadherin-6 and double knockdown conditions. Transfected cells express YFP.

${alpha}$ -Catenin Is Required for Cell Junction Stability
One mechanism that might provide cell junction stability incadherin-depleted cells is the continuing function of ${alpha}$ -catenin.In addition to being a component of the cadherin– $beta$ -catenincomplex, ${alpha}$ -catenin interacts with the actin network at AJs. Also, ${alpha}$ -catenin binds to Afadin, which is linked to nectin-based cell–celladhesions (Miyoshi and Takai, 2005

). Could these complexes serveto stabilize adhesions in the absence of cadherins? To answerthis question, we depleted MDCK cells of ${alpha}$ -catenin by RNAi. TwoshRNAs were generated against canine ${alpha}$ -catenin sequence and testedfor protein suppression 2 d after transfection. Primer 2 reduced ${alpha}$ -catenin expression as much as 80% compared with controls (Figure 7A).This reduction of ${alpha}$ -catenin levels did not alter the stabilityof $beta$ -catenin as assessed by Western blot. Nor did it furtherreduce $beta$ -catenin levels when E-cadherin was also depleted byRNAi. Therefore, ${alpha}$ -catenin levels do not contribute to $beta$ -cateninprotein stability.

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Figure 7. Suppression of ${alpha}$ -catenin disrupts confluent MDCK cells. (A) Immunoblot of cell lysates 2 d posttransfection with control, ${alpha}$ -catenin and/or E-cadherin shRNA vectors. (B) DIC image of MDCK cells at low confluence (top) or high confluence (bottom) transfected with either control or ${alpha}$ -catenin shRNA vectors. (C) Immunofluorescence images of ${alpha}$ -catenin–depleted MDCK cells stained for ${alpha}$ -catenin, ZO-1, $beta$ -catenin, and E-cadherin. YFP was a transfection marker. (D) Recompiled confocal sections of ${alpha}$ -catenin–depleted cells grown on filters. Cells were fixed and stained for the apical marker gp135 (green). mRFP was used as a transfection marker (red). The right-hand panels are cross-sections of the same image.

What effect does ${alpha}$ -catenin suppression have on MDCK cells? Normally,MDCK cells plated at low densities form tight colonies. Differentialinterference contrast (DIC) imaging revealed that cells depletedof ${alpha}$ -catenin failed to form colonies and retained a mesenchymalphenotype (Figure 7B). A similar effect was seen with E-cadherindepletion (Qin et al., 2005

). Interestingly, by immunofluorescence,cells transfected with ${alpha}$ -catenin shRNA2 exhibited severe defectsboth in their TJs and AJs, as determined by staining for ZO-1, $beta$ -catenin, and E-cadherin (Figure 7C). All three proteins exhibiteddiffuse cytoplasmic staining in transfected cells. Additionally,cells depleted of ${alpha}$ -catenin were rounded and lost cell–cellcontacts, particularly when adjacent to other transfected cells.Even when grown on filters, transfected cells remained roundedand failed to maintain cell–cell adhesions (Figure 7D).Distinct apical and lateral surfaces were not maintained, becausegp135 staining was seen along the lateral walls (Figure 7D,right). Overall, loss of ${alpha}$ -catenin causes a much more severedefect in epithelial adhesion and cell polarity than does theloss of E-cadherin, and these effects are not caused by instabilityof E-cadherin or $beta$ -catenin.

E-Cadherin Depletion Disrupts Cell Polarization in Response to Calcium Switch
To examine the effects of E-cadherin depletion on junction formation,MDCK cells were subjected to calcium switch. After readditionof calcium to the medium, control cells establish TJs withinthe first hour, as indicated both by the accumulation of theTJ marker ZO-1 and the initial increase in TER (Figures 8, Aand C). However, for cells depleted of E-cadherin, ZO-1 localizationremained incomplete even 8 h postcalcium switch. Nevertheless,after 24 h the knockdown cells had relatively normal TJs. Thisdisruption was not specific to calcium switch. When cells weretrypsinized and replated, control cells formed normal junctionsby 7 h, but knockdown cells were still disrupted (Figure 8D).Additionally, TJ recovery was monitored by TER measurementspostcalcium switch (Figure 8C). TER recovery was severely reduced,although samples did establish normal resistance after 24 h.Recruitment of $beta$ -catenin to cell adhesions was also delayed inE-cadherin–depleted cells (Figure 8B).

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Figure 8. TJ biogenesis is disrupted in cells depleted of E-cadherin. E-cadherin knockdown cells fail to polarize properly after calcium switch. (A) Immunofluorescence of MDCK cells 2 d after transfection with control shRNA and YFP. (B) E-cadherin–depleted cells fixed and stained 2 d after transfection. Cells were stained for ZO-1 and $beta$ -catenin. YFP marks transfected cells. (C) Average TER after calcium switch for control ( ${blacksquare}$ ) and knockdown cells ( ${blacktriangleup}$ ). (D) Trypsinized and replated cells were analyzed by immunofluorescence for TJ formation. Cells were fixed 7 h after replating and stained for E-cadherin and ZO-1.

Cell Polarization Defects Can Be Partially Rescued with E-Cadherin– ${alpha}$ -Catenin Fusion Protein
To further investigate the effects of cadherin depletion onepithelial polarization, cells were imaged by time-lapse videomicroscopy after calcium switch (Figure 9A), by using a stableYFP-ZO-1 cell line. Figure 9A shows pSuper-transfected cells,marked with mRFP, at various time points after readdition ofcalcium. In control cells, before readdition of calcium (time0), YFP-ZO-1 is located in both the cytoplasm and in apicalring structures (see Supplemental Video 1). Previously, we andothers have described these rings as containing actin, occludin,and other apical and TJ markers (Ivanov et al., 2006

; McNeilet al., 2006

). Strikingly, in samples with reduced cadherinlevels, YFP-ZO-1 seems entirely cytoplasmic (Figure 9A, middle,and Supplementary Video 2). After the addition of calcium, YFP-ZO-1accumulated along cell–cell contacts in control cellsas puncta and developed into a continuous band around the cellperimeter (Figure 9, A and B). This process was completed between30–60 min after addition of normal media. In contrast,very little YFP-ZO-1 localized to cell–cell contacts inE-cadherin–depleted cells. Several puncta were observed,but they failed to develop into mature ZO-1 bands. To show thatdisruption of cell–cell junction biogenesis was due toloss of E-cadherin, we performed rescue experiments. Althoughwe were unable to observe rescue with a wild-type E-cadherin–GFPfusion (which was expressed at subendogenous levels), we wereable to achieve partial rescue with an E-cadherin– ${alpha}$ -cateninfusion. This construct was also expressed at very low levels(Figure 9C), but it significantly increased the accumulationof YFP-ZO-1 at the cell periphery. The junctions seemed to matureand strengthen along cell–cell contacts but, as in knockdowncells, they were transient (Figure 9A, bottom, and SupplementaryVideo 3). These data were quantified by measuring the lengthof YFP-ZO-1 accumulation at cell–cell contacts per transfectedcell (Figure 9B).

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Figure 9. E-cadherin knockdown is partially rescued by E-cadherin– ${alpha}$ -catenin fusion protein. (A) Live cell time-lapse imaging of YFP-ZO-1 MDCK cells after calcium switch. Cells were transfected with vectors for control or E-cadherin shRNAs or the E-cadherin– ${alpha}$ -catenin fusion protein (Ecat). mRFP marks transfected cells. Videos are available in Supplementary Material. (B) Quantification of ZO-1 length as a measure of TJ recovery (pixels per cell). Average lengths are recorded up to 120 min after calcium switch for control cells ( ${blacksquare}$ ) E-cadherin depleted cells ( ${blacktriangleup}$ ) and depleted cells plus an E-cadherin– ${alpha}$ -catenin fusion protein ( ${blacktriangledown}$ ). (C) Immunoblot of cell lysates from YFP-ZO-1 cells transfected with pSLuc, pSEcadB, or pSEcadB vectors plus the E-cadherin– ${alpha}$ -catenin fusion protein.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

The E-cadherin–catenin complex plays pivotal roles inthe construction of epithelia. Knockout mouse models and geneticanalysis in Drosophila have demonstrated that it is essentialfrom early embryogenesis through the later stages of organogenesis(Larue et al., 1994

; Tepass et al., 1996

; Ohsugi et al., 1997

;Tinkle et al., 2004

; Tunggal et al., 2005

). In addition to providingadhesion between adjacent cells, E-cadherin, like the integrins,mediates outside-in signaling, and, during the initial stagesof cell–cell contact, E-cadherin engagement initiatesthe activation of Rho family GTPases, actin network restructuring,and recruitment of TJ proteins to the plasma membrane (Ando-Akatsukaet al., 1999

; Braga, 2002

; Bershadsky, 2004

). Expression ofRho mutants compromises apical–basal polarization andcan disrupt the formation of both AJs and TJs (Braga et al.,1997

; Jou and Nelson, 1998

). There is also evidence for inside-outsignaling, because perturbation of actin dynamics can disruptE-cadherin–mediated adhesions (Jaffe et al., 1990

; Angreset al., 1996

). But once the junctions have formed, is E-cadherinstill required? Cell–cell contacts are strengthened byother types of intercellular linkages that form after the initialtransdimerization of E-cadherin. Cadherin-6 is present at lowlevels in MDCK cells and might provide adhesions between cells.Desmosomes provide tensile strength to epithelial sheets. Nectins,junctional adhesion molecules, claudins, and occludin all provideadditional linkages that might stabilize adhesions.

Contrary to established ideas, recent data show that the corticalactin ring, which forms early after the initial E-cadherin contacts,is not coupled to E-cadherin through the catenins, because ${alpha}$ -catenincannot bind to actin when associated with E-cadherin through $beta$ -catenin; and ${alpha}$ -catenin dimers bound to actin cannot associatewith $beta$ -catenin (Drees et al., 2005; Yamada et al., 2005). Itis conceivable, therefore, that even if E-cadherin is essentialfor the initial organization of cortical actin, it is not requiredafter maturation of the AJs. Animal models have provided ambiguousevidence concerning this issue. For example, a conditional knockoutof E-cadherin in skin did not result in the loss of epithelialadhesions, but this was attributed, at least in the basal layer,to a compensatory up-regulation of P-cadherin (Tinkle et al.,2004; Tunggal et al., 2005). In the early embryo, the effectsof an E-cadherin knockout are not fully penetrant. Around one-halfthe embryos form blastocysts, and some cells possess apparentlynormal AJs, with $beta$ -catenin present at the cell cortex (Larueet al., 1994; Ohsugi et al., 1997). Again, this variabilityhas been attributed to the presence of residual maternal protein.However, it is also possible that junctions, once formed, mightpersist even in the absence of E-cadherin, so long as the cellsare not mechanically stressed.

To address this issue, we used shRNAs to silence E-cadheringene expression in MDCK epithelial cells. When plated at highdensity, these cells begin to form junctions within 1–2h, and they are polarized after 24 h, but depletion of the endogenousE-cadherin occurs very slowly, and it is not complete for 48h, long after the junctions have formed. This temporal delayprovides a way to ask whether preformed junctions require E-cadherinfunction. We estimate that our shRNAs can reduce E-cadherinin transfected cells by >90%; yet these cells remain polarized,and they have intact, functional TJs. Surprisingly, $beta$ -cateninand actin also remain at the cortex. We considered that thisretention might result from there being a large excess of E-cadherinover $beta$ -catenin in MDCK cells, so that even after knockdown therewould be sufficient to bind and stabilize the $beta$ -catenin. However,this proved not to be the case. To the contrary, we estimatethat MDCK cells contain about a twofold excess of $beta$ -catenin overE-cadherin.

We also wondered whether other members of the cadherin familymight compensate for the loss of E-cadherin. The drop in cadherinmeasured by immunoblot with a Pan-cadherin antibody was similarto that detected using an antibody specific for E-cadherin,consistent with previous data showing that E-cadherin is themajor type I isoform present in MDCK T23 cells (Stewart et al.,2000). Nonetheless, the type II cadherin, Cadherin-6, is expressedin MDCK cells, so to determine the contribution of this isoformto $beta$ -catenin and TJ stability at cell contacts, both cadherinswere depleted from the cells. Interestingly, the double knockdowncaused a substantial loss of $beta$ -catenin as measured by immunoblotsof cell lysates, and an almost complete disappearance from cell–celljunctions. Defects in ${alpha}$ -catenin and actin localization were alsoobserved, although they were not as dramatic as the displacementof $beta$ -catenin. Yet, TJs seemed intact, as measured by ZO-1 immunofluorescence.Therefore, TJs once formed are stable even in the absence offunctional AJs. Importantly, this stability does not resultfrom the static nature of TJs, because FRAP analysis shows thatat least 50% of the ZO-1 at junctions is dynamic, with a half-lifeof $~$ 30 s.

The loss of E-cadherin had a reproducible effect on the morphologyof the epithelial cells. As we showed previously, at low densitythey seem more fibroblastic than the control cells and migratemore rapidly, consistent with reduced adhesiveness (Qin et al.,2005). Moreover, the apical surfaces become domed. This phenotypewas not caused by increased apicalization, nor by an osmoticimbalance (data not shown). Rather, we suggest that doming resultsfrom reduced adhesiveness between cells, which reduces the contractiletension exerted by the cortical actin ring. A similar phenotypecan be induced by the addition of blebbistatin, which inhibitsmyosin (Chen and Macara, 2005; data not shown).

The effects of silencing E-cadherin expression were more profoundduring the assembly of junctions after a calcium switch. Calciumdepletion triggered the rapid loss of TJs and caused roundingin knockdown cells, presumably because it releases desmosomalattachments and those of other cadherins present at the lateralmembranes. When incubated in low calcium media, normal cellsretain an apical ring that contains actin, ZO-1, and E-cadherin.However, this ring was absent in cells depleted of E-cadherin,and the ZO-1 was diffuse through the cytoplasm. When calciumwas added back to the medium, the ZO-1 did not accumulate atcell contacts, and TJ assembly was severely delayed. Clearly,stable E-cadherin–mediated attachments are essential toenable TJ and other cell–cell contacts to form and mature.

Interestingly, silencing of ${alpha}$ -catenin expression disrupted cell–celljunctions even in polarized monolayers. The cells remained rounded, $beta$ -catenin and E-cadherin were dispersed from the cortex intothe cytoplasm, and TJs were lost. This result is consistentwith animal model studies, in which a conditional ${alpha}$ -catenin knockoutshowed a more severe phenotype than the equivalent E-cadherinknockout (Vasioukhin et al., 2001). One pivotal function of ${alpha}$ -catenin is likely the formation and maintenance of the corticalactin ring, either through direct binding to actin, or throughassociations with vinculin and other actin-binding proteins.Overall, our data support a model in which E-cadherin acts asa critical adhesive scaffold between cells early in junctionassembly, but once stable junctions have matured its adhesiveand signaling functions become largely dispensable.

ACKNOWLEDGMENTS

We thank Barry Gumbiner for the Ecad- ${alpha}$ cat fusion vector andPan-cadherin antibody, James Nelson for the Cadherin-6 antibody,Michael Caplan for the Na⁺/K⁺ ATPase antibody, Atsushi Miyawakifor the seYFP construct, and Roger Tsien for the mRFP construct.We also thank the members of the Macara laboratory for helpfulsuggestions. This work was supported by Grant GM-70902 fromthe Department of Health and Human Services, National Institutesof Health.

Footnotes

The online version of this contains supplemental material at MBC Online (http://www.molbiolcell.org).

This article was published online ahead of print in MBC in Press(http://www.molbiolcell.org/cgi/doi/10.1091/mbc.E06-05-0471)on November 8, 2006.

Address correspondence to: Ian G. Macara (igm9c{at}virginia.edu)

Abbreviations used: AJ, adherens junction; MDCK, Madin-Darby canine kidney; TJ, tight junction; YFP, yellow fluorescent protein; ZO, zonula occludin protein.

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RESULTS
DISCUSSION
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