Abstract
The tight junction is the most apical intercellular junction of epithelial cells and regulates transepithelial permeability through the paracellular pathway. To examine possible functions for the tight junction-associated protein ZO-1, C-terminally truncated mutants and a deletion mutant of ZO-1 were epitope tagged and stably expressed in corneal epithelial cell lines. Only full-length ZO-1 and one N-terminal truncation mutant targeted to cell borders; other mutants showed variable cytoplasmic distributions. None of the mutants initially disrupted the localization of endogenous ZO-1. However, long-term stable expression of two of the N-terminal mutants resulted in a dramatic change in cell shape and patterns of gene expression. An elongated fibroblast-like shape replaced characteristic epithelial cobblestone morphology. In addition, vimentin and smooth muscle actin expression were up-regulated, although variable cytokeratin expression remained, suggesting a partial transformation to a mesenchymal cell type. Concomitant with the morphological change, the expression of the integral membrane tight junction protein occludin was significantly down-regulated. The localizations of endogenous ZO-1 and another family member, ZO-2, were disrupted. These findings suggest that ZO-1 may participate in regulation of cellular differentiation.
INTRODUCTION
Epithelial cells create selective permeability barriers between different physiological compartments. Selective permeability is the result of regulated transport of molecules through the cytoplasm (the transcellular pathway) and the regulated permeability of the spaces between the cells (the paracellular pathway) (Goodenough, 1999). Intercellular junctions are known to be involved in both the maintenance and regulation of the barrier function and cell–cell adhesion (Anderson and Van Itallie, 1995; Denker and Nigam, 1998). The tight junction (TJ) is the cell–cell junction that regulates the permeability of the paracellular pathway and also divides the cell surface into apical and basolateral compartments (Anderson et al., 1993; Citi, 1993; Denker and Nigam, 1998). Both integral and peripheral plasma membrane proteins are associated with the TJ (Fujimoto, 1995; Furuse et al., 1998a). The integral membrane proteins occludin (Furuse et al., 1993, 1996) and the claudins (Morita et al., 1999) restrict the intercellular space and presumably also generate regulated “channels” for the paracellular passage of ions and small molecules. Both occludin (Balda et al., 1996; McCarthy et al., 1996; Chen et al., 1997; Wong and Gumbiner, 1997) and claudin family members (Furuse et al., 1998b) have been directly demonstrated to be involved in the barrier function of TJs. One member of the claudin family, paracellin-1, has been implicated in the formation of selective Mg2+ channels in kidney distal tubules (Simon et al., 1999).
Although many nonintegral membrane proteins have been localized to the TJ by electron microscopy or immunofluorescence (Stevenson and Keon, 1998), their contributions to the structure and function of TJs are unknown. ZO-1 is the first such protein to be identified (Stevenson et al., 1986). In addition to its localization at the TJ, ZO-1 is also found at adherens junctions in cells lacking TJs (Itoh et al., 1991; Howarth et al., 1992). ZO-1 is the defining member of a family of ZO proteins that includes ZO-2 (Beatch et al., 1996) and ZO-3 (Haskins et al., 1998). All of the ZO proteins belong to a larger superfamily of proteins known as the membrane-associated guanylate kinase (MAGuK) family (Anderson and Van Itallie, 1995; Kim, 1995; Anderson, 1996). MAGuK proteins are composed of domains that include: 1) three PDZ domains, which are 90-amino-acid protein–protein binding domains with a repeating GLGF sequence (Cho et al., 1992); 2) an Src homology 3 domain shown in other proteins to bind proline-rich regions (Ren et al., 1993); and 2) a guanylate kinase (GuK) domain that may be enzymatically inactive (Willott et al., 1993). The ZO proteins also contain proline-rich C termini varying in length from 145 to 954 amino acids.
The function of ZO-1 is unknown. Other MAGuK family members have been shown to play roles in clustering receptors or channels in the plasma membrane (Kim et al., 1995), and some PDZ domains have been shown to bind to consensus motifs at the absolute C termini of polypeptides (Songyang et al., 1997). In vitro studies have suggested functions for various domains of ZO-1. For example, the N terminus containing the PDZ and GuK domains targets to cell borders when exogenously expressed in both epithelial and nonepithelial cells, whereas the proline-rich C terminus associates with actin filaments and actin-rich structures (Itoh et al., 1997; Fanning et al., 1998). In addition, these studies revealed domains of ZO-1 that are involved in interactions with ZO-2 and ZO-3 and that the GuK domain interacts with occludin (Itoh et al., 1997; Fanning et al., 1998). It remains unclear whether these interactions are necessary for TJ assembly or function.
Because ZO-1 contains multiple domains believed to be involved in protein–protein interactions, a reasonable approach to disrupting ZO-1 activity is exogenous expression of subsets of these domains. Therefore, we stably expressed epitope-tagged deletion mutants of ZO-1 in corneal epithelial cells. These stable cell lines were then assayed for changes in TJ sealing properties and for cellular localization of both mutants and endogenous ZO-1. After stable expression for >1 mo, two of these mutants induced a morphological change reminiscent of an epithelium-to-mesenchyme transition. These results suggest that N-terminal regions of ZO-1 are able to activate signaling pathways involved in cellular differentiation.
MATERIALS AND METHODS
Cell Culture
SV40 immortalized rabbit and human corneal epithelial (CE) cell lines were generously provided by Dr. K. Araki-Sasaki (Ehime University School of Medicine, Osaka, Japan) and were maintained as previously described (Araki et al., 1993; Araki-Sasaki et al., 1995). Cells were grown in growth medium (Ham's F-12/Dulbecco's modified Eagle's medium, 10% heat-inactivated fetal bovine serum [Hyclone Laboratories, Logan, UT], 5 μg/ml insulin, 0.1 μg/ml cholera toxin, 10 ng/ml epidermal growth factor, 0.5% dimethylsulfoxide, and 40 μg/ml gentamicin) and maintained in a humidified chamber with 5% CO2 at 37°C.
Mutants
To express mutants containing multiple c-myc epitope tags, each mutant was first subcloned into the pCS2+myc vector (generously provided by Dr. M. Klymkowsky, University of Colorado, Boulder, CO) and then subcloned into the expression vector pCDNA 3+ (Invitrogen, Carlsbad, CA). The cDNA containing the entire open reading frame of mouse ZO-1 was kindly provided by Dr. S. Tsukita (Kyoto University, Kyoto, Japan). Full-length ZO-11–1745, was ligated into the ClaI site of pCS2+myc. All other mutants were generated by PCR using mouse ZO-1 cDNA as a template. For ZO-11–263 the sense primer (5′AGCGGATCCATGTCCGCCAG-GGCCGCGGCCGCTAAGAGCACAGCAATGGAGGAAACAGCT-ATATGGGAAC-3′) introduced a BamHI site (bold italics), and an antisense primer (5′-AGCCCATCGATTCTCATCTCTTTGCACTA-CCAT-3′) introduced a ClaI site (bold italics) at the end of the ZO-1 open reading frame. All of the mutants used the same sense primer with different antisense primers introducing ClaI sites (bold italics) downstream of the ZO-1 open reading frame. The antisense primer for ZO-11–422 was 5′-AGCATCGATCCATGCTGGGCCTAAGTA-TCC-3′ and for ZO-11–794 was 5′-GATTATCGATCCTGTTGCTGCTGAATCGCTTCTTT-3′. Each amplified fragment was ligated into the BamHI and ClaI sites of pCS2+myc, released with multiple myc epitopes at their C terminus by digestion with BamHI and EcoRI, and ligated into the same sites of pCDNA 3+. ZO-1Δ615–812, with a missing GuK domain, was constructed by PCR amplification of two halves of ZO-1 using the same sense primer as above for the N-terminal half and an antisense primer (5′-AGCGTCGACGGAGCTGCGAAGACCTCGAAA-3′), which puts a SalI site (bold italics) on the 3′ end. The C-terminal half of this mutant was constructed using the sense primer (5′-AGCGTCGACATGGTGCTACAAGTGATGACC-3′) with a SalI site and an antisense primer (5′-AGCGAATTCTTACTTGTCATCGTCGTCCTTGTAGTCAAAG -TGGTCAATCAGGACAGA-3′) with an EcoRI site (bold italics) and a FLAG epitope (underline) at the end of the open reading frame. The two halves of ZO-1Δ615–812 were ligated together at their SalI sites and into the BamHI–EcoRI site of pCDNA 3+.
Transfection and Generation of Stable Lines
Corneal epithelial cells were transfected with 1 μg of each mutant using LipofectAMINE Plus reagent (Life Technologies, Rockville, MD) for 12 h in F-12/Dulbecco's modified Eagle's medium. After this incubation, the transfection medium was changed to growth medium (see above) and allowed to grow for 48 h. Cells were split into 60-mm dishes in the presence of 800 μg/ml geneticin (Life Technologies) to select stable transfectants. After three independent transfection experiments of the various truncation mutants into corneal epithelial cells, single cells were isolated by limiting dilution into 96-well plates. Clones were expanded and screened by immunofluorescence with either a c-myc mouse monoclonal antibody (Calbiochem, La Jolla, CA) or a mouse monoclonal FLAG antibody (Eastman Kodak, Rochester, NY). Six to 24 independent clones for each mutant were isolated and examined with similar results. Transfected cells were retrieved from frozen stocks on three separate occasions, recloned, and followed for 4–6 wk to ensure the reproducibility of the phenotypic change. Although both rabbit and human corneal epithelial cells were used for all experiments, the data shown are from rabbit epithelial cells.
Immunofluorescence
Cells plated on Nunc Lab Tek glass chamber slides (VWR, Boston, MA) were washed with PBS two times and fixed with 1% formaldehyde in PBS for 20 min. The fixed cells were blocked and permeabilized with 0.2% Triton-X 100 in 5% normal goat serum for 45 min. The samples were then treated with primary antibodies including ZO-1, ZO-2, and occludin rabbit polyclonal antibodies and vimentin, cytokeratin, and smooth muscle actin monoclonal antibodies (Zymed Laboratories, San Francisco, CA) and a pan-cadherin mouse monoclonal antibody (Sigma, St. Louis, MO) for 1 h in a moist chamber at room temperature. They were then washed three times in PBS followed by incubation for 45 min with CY-2- or CY-3-conjugated goat anti-rabbit immunoglobulin G or goat anti-mouse immunoglobulin G (Jackson Immunoresearch, West Grove, PA). Cells were washed three times with PBS and mounted in gel mount (Biomeda, Foster City, CA) and examined with a Nikon (Melville, NY) E800 fluorescence microscope.
Metabolic Labeling and Immunoprecipitation
Cultured monolayers of CE cells were plated at 50% confluence on 10-cm dishes. Twelve hours later, cells were washed with methionine-free medium containing dialyzed FBS and then incubated with methionine-free medium containing 150 μCi of [35S]methionine per dish for 18 h at 37°C. After this incubation, the medium was collected, and cells were washed two times with ice-cold PBS (with Ca2+ and Mg2+). One milliliter of ice-cold lysis buffer (1% Triton X-100, 0.4% sodium deoxycholate, 0.2% SDS, 150 mM NaCl, 10 mM HEPES, pH. 7.4, 1 mM phenylmethylsulfonylfluoride, 1 μg/ml pepstatin A, 1 μg/ml leupeptin, 4 μg/ml aprotinin, 1 mM dithiothreitol, and 20 mM benzamidine) was added to each dish, and dishes were rocked back and forth for 30 min at 4°C. Subsequently, cells were scraped into a microcentrifuge tube and centrifuged at 12,000 × g for 30 min at 4°C. The supernatants were then mixed with 50 μl of 50% slurry of protein A-Sepharose incubated for 1 h at 4°C and centrifuged for 2 min at 1200 × g. Supernatants were transferred to a new tube, and 2 μg of either anti-ZO-1 polyclonal antibody or normal rabbit serum were added and incubated overnight rotating at 4°C. After this incubation, 20 μl of 50% slurry of protein A-Sepharose beads were added to each sample and incubated for 3 h at 4°C. The beads were washed three times in lysis buffer and resuspended in 40 μl 2× sample buffer. The samples were resolved by SDS-PAGE, and the gel was fixed and dried and examined by autoradiography.
Western Blot
Cultured monolayers of CE cells on 10-cm dishes were trypsinized and counted using a hemocytometer. Equal cell numbers were lysed in lysis buffer (see above) and centrifuged at 6000 × g for 15 min at 4°C to separate insoluble components. The supernatants were harvested, mixed with 5× sample buffer, and resolved by SDS-PAGE. The separated proteins were electrophoretically transferred to nitrocellulose and incubated in blocking solution (5% dry milk in TBS with 0.2% Tween 20) for 60 min followed by sequential incubations of primary and secondary antibody for 60 min each at room temperature. Proteins were detected by the alkaline phosphatase substrates nitro blue tetrazolium and 5-bromo-4-chloro-3-indolyl phosphate.
RESULTS
Behavior of Truncation Mutants of ZO-1 in Corneal Epithelial Cells
We constructed truncation mutants of ZO-1 with myc or FLAG epitope tags at their C termini as shown in Figure 1. These mutants were stably transfected into rabbit and human corneal cell lines, and their subcellular localization as well as that of endogenous ZO-1 were determined by indirect immunofluorescence. As seen in Figure 2, full-length, epitope-tagged ZO-11–1745 targeted to cell borders (Figure 2A) and colocalized with endogenous ZO-1 (Figure 2B), confirming that the C-terminal epitope tag neither conferred unexpected localization properties on full length ZO-1 nor interfered with endogenous ZO-1 localization. ZO-11–794 also targeted to cell borders (Figure 2C) and colocalized with endogenous ZO-1 (Figure 2D), whereas the localization of ZO-11–422 was diffusely cytoplasmic (Figure 2E). ZO-11–263, with a molecular mass of ∼28 kDa, was concentrated in the nucleus (Figure 2G). ZO-1Δ615–812, which lacks the GuK domain previously implicated in occludin binding (Fanning et al., 1998), localized in a punctate manner, possibly in lysosomes (Figure 2I). The localization and expression of endogenous ZO-1 was not disrupted in any of these stable transfectants (Figure 2, B, D, F, H, and J). These results were consistent in 6–12 independent stable clones isolated for each mutant.
To demonstrate the mobilities and levels of expression of the mutant polypeptides, Western blots were performed on the stably transfected clones. Figure 3 shows the expression of the various mutant proteins, which had electrophoretic mobilities close to their predicted molecular masses as detected by antibodies against their epitope tags. Although all transfected lines displayed steady-state levels of protein, ZO-11–422 and ZO-11–263 cells consistently exhibited higher levels than the others.
N-terminal Regions of ZO-1 Caused a Change in Cell Morphology
Initially it appeared as though none of the mutants disrupted the localization of endogenous ZO-1. However, after ∼4–6 wk in culture, stable clones expressing ZO-11–422 and ZO-11–794 underwent a dramatic change in cell morphology, as seen in Figure 4. Although cells expressing ZO-11–1745 (Figure 4, left), ZO-11–263, and ZO-1Δ615–812 continued to display a cobblestone epithelial morphology, the cells expressing ZO-11–422 and ZO-11–794 became elongated and fibroblast-like in appearance (Figure 4, middle and right). The change in morphology was specific to the clones expressing ZO-11–422 and ZO-11–794, because the phenotype of the other transfectants did not change even after months in culture. The timing necessary for this morphological change was reproducible, because sibling cells retrieved from stocks frozen soon after transfection also required 4–6 wk for this phenotypic change to occur. Transfected cells were thawed on multiple occasions, and single-cell clones were isolated and examined for 4–6 wk to verify the reproducibility of the morphologic change observed. To ensure that this change did not result from the selection of a minor variant, cells were cultured for 1 wk after selection in geneticin. Clones were then isolated by limiting dilution into 96-well plates. The resulting colonies showed a more rapid phenotypic change in 3–5 wk, revealing that the time frame was not sensitive to subcloning.
Expression and Localization of Tight Junction Proteins Were Disrupted
The expression of other tight junction proteins was investigated to determine whether ZO-11–422 or ZO-11–794 altered endogenous ZO-1, ZO-2, or occludin levels. Equal cell numbers from cultures that had undergone a morphological change and mock-transfected cells that had not were analyzed by Western blot using antibodies against ZO-1, ZO-2, and occludin. Although there was some decrease in the levels of endogenous ZO-1 and ZO-2, the expression levels of occludin in the morphologically changed cells were dramatically down-regulated (Figure 5).
To examine the subcellular localization of tight and adherens junction proteins, immunofluorescence was performed using ZO-1, ZO-2, occludin, and pan-cadherin antibodies. As demonstrated in Figure 6, these proteins were appropriately localized at cell borders in the parental cells (Figure 6, top row). However, in ZO-11–422 clones, endogenous ZO-1 and ZO-2 were localized cytoplasmically, whereas occludin expression was not detectable above background. The localization of cadherins appeared more disorganized, with many cells showing cytoplasmic staining (Figure 6, middle row). In ZO-11–794 clones, endogenous ZO-1 and cadherins were expressed in a punctate manner at cell borders, suggesting a redistribution of endogenous ZO-1 to adherens junctions. ZO-2 was no longer located at the cell surface and was found in both the cytoplasm and nucleus. As with the ZO-11–422 clones, occludin expression in ZO-11–794 clones was also not detectable above background (Figure 6, bottom row).
Transformation to a Mesenchymal Phenotype
To determine whether the ZO-11–422 and ZO-11–794 clones had undergone an epithelial to mesenchymal transformation (EMT), the cells were immunostained with antibodies to cytokeratin, vimentin, and smooth muscle actin. As shown in Figure 7, first column, parental corneal epithelial cells expressed a uniform level of the epithelial cell marker cytokeratin (Moll et al., 1982), whereas the levels in clones ZO-11–422 and ZO-11–794 were variable from cell to cell. Expression of vimentin, the intermediate filament protein characteristic of mesenchymal cells (Denk et al., 1983), was absent in the parental cells but was abundantly expressed in clones ZO-11–422 and ZO-11–794 (Figure 7, middle column). Similarly, smooth muscle actin, although absent from parental cells, was highly expressed in clones ZO-11–422 and ZO-11–794 (Figure 7, third column). These data imply that ZO-11–422 and ZO-11–794 have undergone at least a partial transformation from an epithelial to a mesenchymal cell (Savagner et al., 1997).
Immunoprecipitation of Endogenous ZO-1 in Transformed and Parental Cells
A possible interaction of endogenous ZO-1 with novel proteins in the ZO-11–422 and ZO-11–794 cells was examined by metabolic labeling and immunoprecipitation in nondenaturing conditions. As shown in Figure 8, mock-transfected corneal epithelial cells displayed a pair of bands labeled with equal intensities. This doublet was confirmed to be ZO-1 by Western blot analysis of the immunoprecipitated samples probed with a ZO-1 antibody (our unpublished data). Although ZO-11–422 and ZO-11–794 cells also displayed doublets in their ZO-1 immunoprecipitates (Figure 8), there was a difference in the relative intensity of the two bands with a stronger lower band. There was also a unique band of ∼55 kDa (Figure 8, asterisk) that appeared in the immunoprecipitated samples of ZO-11–422 cells.
DISCUSSION
In the current study, we have identified two truncation mutants of ZO-1 (ZO-11–422 and ZO-11–794) that mediated a dramatic change in cell morphology 4–6 wk after transfection into corneal epithelial cells. These two N-terminal mutants of ZO-1 uniquely overlapped in the region between PDZ2 and -3, which was absent in the other truncation mutants that had no effect on cell morphology. After a 4- to 6-wk latent period, the cells transfected with ZO-11–422 and ZO-11–794 displayed a fibroblast-like, elongated appearance unlike either parental cells or clones transfected with ZO-11–1745, ZO-1Δ615–812, or ZO-11–263, which continued to show an epithelial cobblestone morphology. Upon observation of a phenotypic change in cells expressing ZO-11–422, constructs ZO-11–263 and ZO-1263–422 were generated to determine the smallest domain of ZO-1 that could induce this morphological change. As previously described, ZO-11–263 maintained an epithelial morphology, whereas attempts to stably express ZO-1263–422 were unsuccessful, because cells transfected with this construct died during selection. This suggests the possibility that this region of ZO-1, between the PDZ2 and -3 domains, may be responsible for inducing this mesenchymal-like transformation.
To characterize the phenotypic change from an epithelial to a fibroblast-like morphology caused by ZO-11–422 and ZO-11–794, these cells were examined for their expression of various epithelial and mesenchymal markers. The transformation observed was a partial transformation, as evidenced by the up-regulation of mesenchymal markers such as vimentin and smooth muscle actin and the inconsistent, variable expression of cytokeratins (Savagner et al., 1997). Cells expressing ZO-11–422 and ZO-11–794 lacked tight junctions and had no measurable transepithelial resistance compared with mock transfected parental cells and ZO-11–1745 (128.1 ± 3.8 Ω/cm2).
Tight junction-associated proteins such as ZO-1, ZO-2, and occludin no longer localized at cell borders but were found throughout the cytoplasm and were down-regulated in their expression. To examine whether endogenous ZO-1 in these transformed cells was altered, the transformed cells were metabolically labeled and immunoprecipitated with ZO-1 antibodies. As seen in Figure 8, immunoprecipitation of endogenous ZO-1 in cells expressing ZO-11–422 demonstrates coprecipitation of a novel band of ∼55 kDa. This suggests the possibility that endogenous ZO-1 interacted with a novel protein as a result of this transformation, which may have played a role in the induction of this mesenchymal-like phenotype. It is also of interest that the immunoprecipitated ZO-1 doublet had differing intensities compared with that of the mock-transfected cells. The lower band was more intense in the transformed cells, suggesting the possibility of less-phosphorylated ZO-1 in these cells. This is consistent with studies demonstrating that Madin–Darby canine kidney cells maintained in low calcium with no tight junctions have an altered distribution of ZO-1 as well as lower total phosphorylation of ZO-1 (Howarth et al., 1994).
Although ZO-11–422 and ZO-11–794 both caused a partial mesenchymal transformation, the morphologies of these transfected cells were different from each other. Cells transformed with ZO-11–422 were more elongated and spindle-like and lacked adherens junctions, as judged by immunostaining with a pan-cadherin antibody. However ZO-11–794-expressing cells, although fibroblast-like, were more rounded and demonstrated punctate cadherin expression, as has been shown in cultured fibroblasts (Itoh et al., 1991). Endogenous ZO-1 appeared to be colocalized with cadherins in the cells transfected with ZO-11–794.
The most puzzling aspect of this dramatic phenotypic change was the length of time necessary for the phenomenon to occur. After isolating single clones from stable transfections, the cells were cultured for ∼4–6 wk with passage twice weekly before they underwent their morphological change. This time frame was not sensitive to subcloning, in that transfectants that were allowed to expand in culture before subcloning required a proportionately shorter time to affect the phenotypic change.
The 4- to 6-wk time frame complicates an exploration into the mechanisms of action of the mutants. Transforming growth factor β3 (TGFβ3) has been demonstrated to promote a transformation from epithelium to mesenchyme of progenitor cells of the heart valves, which arise from the endothelial cells in the atrioventricular canal (Potts et al., 1991; Runyan et al., 1992). Similarly, TGFβ3 also promotes EMT of rodent (Kaartinen et al., 1997) and chicken palate medial edge epithelia within 24–72 h after addition to cultured palates (Sun et al., 1998). To investigate whether the transformed clones had become more susceptible to TGFβ3, the time course of TGFβ3-induced EMT was studied in the corneal cells by placing the parental cells in 100 ng/ml TGFβ3. We observed that the parental cells underwent EMT within 5 d of TGFβ3 application, indicating that this growth factor operated at a much more rapid time scale than that shown by the ZO-1 mutants (our unpublished data). However, when 0.1–10 ng/ml TGF β3 was added to cells immediately after transfection with ZO-11–422 and ZO-11–794, the cells did not undergo the morphological change within the 7 d they were treated (our unpublished data). These data imply that stable expression of ZO-11–422 and ZO-11–794 did not cause the cells to become more susceptible to the growth factor. Conditioned medium, harvested from ZO-11–422 and ZO-11–794 cells in culture for >1 mo, and okadaic acid, a potent phosphatase 2A inhibitor, did not cause EMT in the parental cells (our unpublished data), indicating that these agents were not active in inducing EMT in this cell type.
Another possible model to explain the delay in partial mesenchymal transformation was the necessity for the levels of endogenous ZO-1 to be greatly reduced before ZO-11–422 and ZO-11–794 were able to exert their effect. However, comparison of parental cells with stably transfected cells before and after the epithelial–mesenchymal transformation revealed no significant differences in endogenous ZO-1 levels (our unpublished data).
ZO-11–422 and ZO-11–794 cells were cocultured with parental corneal epithelial cells at a 4:1 ratio. The ZO-11–422 and ZO-11–794 cells grew on top of the parental cells and clumped together, whereas the parental cells proliferated rapidly and formed a confluent monolayer under the clumped cells after 4 d in culture. There was no reversion of the ZO-11–422 and ZO-11–794 cells back to an epithelial-like morphology, nor did they cause the parental cells to undergo a similar mesenchymal transformation (our unpublished data).
Epithelial cells transfected with constitutively active Ras become elongated and fibroblast-like but revert back to an epithelial cell morphology when the Ras pathway is inhibited (Y.-H. Chen, personal communication). An inhibitor of the Ras signaling pathway, PD 098059 (Alessi et al., 1995), was added to ZO-11–422 and ZO-11–794 cells to investigate whether the Ras pathway was involved in this morphological change and whether these cells would revert back to an epithelial cell phenotype. However, PD 098059, which acts within 24 h on Ras-transformed Madin–Darby canine kidney epithelial cells (Y.H. Chen, personal communication), had no detectable effect on ZO-11–422 and ZO-11–794 cells after 3 d in culture (our unpublished data). Similarly, okadaic acid and TGFβ3 did not cause a phenotypic reversion.
Although the length of time necessary between expression of ZO-11–422 and that of ZO-11–794 in corneal epithelial cells and the appearance of a transformed phenotype suggested a complex signaling pathway, the effect was specific to these two ZO-1 N-terminal mutants. The morphological change was not due to expression levels of the mutant proteins, because independent clones of ZO-11–422 and ZO-11–794 varied in their levels of expression up to threefold. ZO-11–422 and ZO-11–794 lacked the proline-rich C terminus of ZO-1 that has been shown to bind actin filaments (Itoh et al., 1997; Fanning et al., 1998). Without this cytoskeletal anchor, the mutants may have been free to interact with proteins normally not accessible to full-length ZO-1. Further studies will be necessary to elucidate the binding partners and the signaling pathways activated by these ZO-1 truncation mutants.
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