Manner of interaction of heterogeneous claudin species within and between tight junction strands

In tight junctions (TJs), TJ strands are associated laterally with those of adjacent cells to form paired strands to eliminate the extracellular space. Claudin-1 and -2, integral membrane proteins of TJs, reconstitute paired TJ strands when transfected into L fibroblasts. Claudins comprise a multigene family and more than two distinct claudins are coexpressed in single cells, raising the questions of whether heterogeneous claudins form heteromeric TJ strands and whether claudins interact between each of the paired strands in a heterophilic manner. To answer these questions, we cotransfected two of claudin-1, -2, and -3 into L cells, and detected their coconcentration at cell-cell borders as elaborate networks. Immunoreplica EM confirmed that distinct claudins were coincorporated into individual TJ strands. Next, two L transfectants singly expressing claudin-1, -2, or -3 were cocultured and we found that claudin-3 strands laterally associated with claudin-1 and -2 strands to form paired strands, whereas claudin-1 strands did not interact with claudin-2 strands. We concluded that distinct species of claudins can interact within and between TJ strands, except in some combinations. This mode of assembly of claudins could increase the diversity of the structure and functions of TJ strands.     

Clostridium perfringens enterotoxin fragment removes specific claudins from tight junction strands: Evidence for direct involvement of claudins in tight junction barrier.

Claudins, comprising a multigene family, constitute tight junction (TJ) strands. Clostridium perfringens enterotoxin (CPE), a single approximately 35-kD polypeptide, was reported to specifically bind to claudin-3/RVP1 and claudin-4/CPE-R at its COOH-terminal half. We examined the effects of the COOH-terminal half fragment of CPE (C-CPE) on TJs in L transfectants expressing claudin-1 to -4 (C1L to C4L, respectively), and in MDCK I cells expressing claudin-1 and -4. C-CPE bound to claudin-3 and -4 with high affinity, but not to claudin-1 or -2. In the presence of C-CPE, reconstituted TJ strands in C3L cells gradually disintegrated and disappeared from their cell surface. In MDCK I cells incubated with C-CPE, claudin-4 was selectively removed from TJs with its concomitant degradation. At 4 h after incubation with C-CPE, TJ strands were disintegrated, and the number of TJ strands and the complexity of their network were markedly decreased. In good agreement with the time course of these morphological changes, the TJ barrier (TER and paracellular flux) of MDCK I cells was downregulated by C-CPE in a dose-dependent manner. These findings provided evidence for the direct involvement of claudins in the barrier functions of TJs.     

Occludin and tricellulin facilitate formation of anastomosing tight-junction strand network to improve barrier function

Tight junctions (TJs) are composed of a claudin-based anastomosing network of TJ strands at which plasma membranes of adjacent epithelial cells are closely attached to regulate the paracellular permeability. Although the TJ proteins occludin and tricellulin have been known to be incorporated in the TJ strand network, their molecular functions remain unknown. Here, we established tricellulin/occludin-double knockout (dKO) MDCK II cells using a genome editing technique and evaluated the structure and barrier function of these cells. In freeze-fracture replica electron microscopy, the TJ strands of tricellulin/occludin-dKO cells had fewer branches and were less anastomosed compared with the controls. The paracellular permeability of ions and small tracers was increased in the dKO cells. A single KO of tricellulin or occludin had limited effects on the morphology and permeability of TJs. Mathematical simulation using a simplified TJ strand network model predicted that reduced cross-links in TJ strands lead to increased permeability of ions and small macromolecules. Furthermore, overexpression of occludin increased the complexity of TJ strand network and strengthened barrier function. Taken together, our data suggest that tricellulin and occludin mediate the formation and/or stabilization of TJ-strand branching points and contribute to the maintenance of epithelial barrier integrity.     

The role of epithelial tight junctions involved in pathogen infections

Tight junctions (TJs) are sealing complexes between adjacent epithelial cells, functioning by controlling paracellular passage and maintaining cell polarity. These functions of TJs are primarily based on structural integrity as well as dynamic regulatory balance, indicating plasticity of TJ in response to external stimuli. An indispensable role of TJs involved in pathogen infection has been widely demonstrated since disruption of TJs leads to a distinct increase in paracellular permeability and polarity defects which facilitate viral or bacterial entry and spread. In addition to pathological changes in TJ integrity, TJ proteins such as occludin and claudins can either function as receptors for pathogen entry or interact with viral/bacterial effector molecules as an essential step for characterizing an infective stage. This suggests a more complicated role for TJ itself and especially specific TJ components. Thus, this review surveys the role of the epithelial TJs involved in various pathogen infections, and extends TJ targeted therapeutic and pharmacological application prospects.     

Molecular Basis of the Core Structure of Tight Junctions

The morphological feature of tight junctions (TJs) fits well with their functions. The core of TJs is a fibril-like proteinaceous structure within the lipid bilayer, the so-called TJ strands. TJ strands in apposing plasma membranes associate with each other to eliminate the intercellular space. A network of paired TJ strands generates a continuous belt that circumscribes each cell to establish the diffusion barrier to the solutes in the paracellular pathway throughout the cellular sheet. Identification and characterization of TJ-associated proteins during the last two decades has unveiled the nature of TJ strands and how they are spatially organized. The interplay between integral membrane proteins, claudins, and cytoplasmic plaque proteins, ZO-1/ZO-2, is critical for TJ formation and function.Tight junctions (TJs) are fascinating structures in terms of their function and morphology. In 1963, using ultrathin-section electron microscopy, Farquhar and Palade described the fine structure of TJs together with adherens junctions (AJs) and desmosomes at the most luminal side of the lateral membrane (Farquhar and Palade 1963). In addition, they demonstrated insightfully that TJs function as permeability seals for mass tracers. Indeed, the structure of TJs observed in electron microscopy indicates that TJs could physically restrict the leak of solutes through the intercellular space. However, physiological studies at the same time revealed that solute transport occurred via the intercellular space in a variety of epithelial cells. A resolution of these different views of TJ function comprises the current concept that the TJ regulates the diffusion of solutes with size and charge selectivity and that it is functionally different in physiologically diverse epithelial cell types (Powell 1981; Anderson and Cereijido 2001). To understand the molecular mechanism controlling TJ structure and function, it is important to determine their molecular composition and organization.Although purification of TJs is difficult, Stevenson and Goodenough developed an isolation method for a TJ-enriched plasma membrane fraction from rodent liver. They discovered the first TJ-associated protein, ZO-1, in 1986 by generating monoclonal antibodies against this fraction (Stevenson et al. 1986). Since then, many molecular components of TJs have been identified using immunological approaches or searches for binding proteins with known molecules, which have enabled detailed molecular cell biological analyses of TJs. Among the TJ-associated proteins, the claudin family of membrane proteins identified in 1998 by the Tsukita group are key molecules in the architecture and barrier function of TJs (Furuse et al. 1998a). Functional analyses of claudins have allowed remarkable progress in the development of a comprehensive understanding of the molecular basis of the ultrastructure and physiological characteristics of TJs (Van Itallie and Anderson 2006; Furuse and Tsukita 2006; Angelow et al. 2008). In addition, the cytoplasmic plaque proteins associated with TJs are important in regulating TJ architecture (Guillemot et al. 2008).In this article, we present the molecular basis for the core structure of TJs based on recent progress in functional analyses of TJ-associated proteins. The current molecular basis of TJ physiology is covered in detail in Anderson and Van Itallie (2009).     

Junctional adhesion molecule (JAM) binds to PAR-3: a possible mechanism for the recruitment of PAR-3 to tight junctions

At tight junctions (TJs), claudins with four transmembrane domains are incorporated into TJ strands. Junctional adhesion molecule (JAM), which belongs to the immunoglobulin superfamily, is also localized at TJs, but it remains unclear how JAM is integrated into TJs. Immunoreplica electron microscopy revealed that JAM showed an intimate spatial relationship with TJ strands in epithelial cells. In L fibroblasts expressing exogenous JAM, JAM was concentrated at cell-cell adhesion sites, where there were no strand-like structures, but rather characteristic membrane domains free of intramembranous particles were detected. These domains were specifically labeled with anti-JAM polyclonal antibody, suggesting that JAM forms planar aggregates through their lateral self-association. Immunofluorescence microscopy and in vitro binding assays revealed that ZO-1 directly binds to the COOH termini of claudins and JAM at its PDZ1 and PDZ3 domains, respectively. Furthermore, another PDZ-containing polarity-related protein, PAR-3, was directly bound to the COOH terminus of JAM, but not to that of claudins. These findings led to a molecular architectural model for TJs: small aggregates of JAM are tethered to claudin-based strands through ZO-1, and these JAM aggregates recruit PAR-3 to TJs. We also discuss the importance of this model from the perspective of the general molecular mechanisms behind the recruitment of PAR proteins to plasma membranes.     

Endothelial claudin: claudin-5/TMVCF constitutes tight junction strands in endothelial cells.

Tight junctions (TJs) in endothelial cells are thought to determine vascular permeability. Recently, claudin-1 to -15 were identified as major components of TJ strands. Among these, claudin-5 (also called transmembrane protein deleted in velo-cardio-facial syndrome [TMVCF]) was expressed ubiquitously, even in organs lacking epithelial tissues, suggesting the possible involvement of this claudin species in endothelial TJs. We then obtained a claudin-6-specific polyclonal antibody and a polyclonal antibody that recognized both claudin-5/TMVCF and claudin-6. In the brain and lung, immunofluorescence microscopy with these polyclonal antibodies showed that claudin-5/TMVCF was exclusively concentrated at cell-cell borders of endothelial cells of all segments of blood vessels, but not at those of epithelial cells. Immunoreplica electron microscopy revealed that claudin-5/TMVCF was a component of TJ strands. In contrast, in the kidney, the claudin-5/TMVCF signal was restricted to endothelial cells of arteries, but was undetectable in those of veins and capillaries. In addition, in all other tissues we examined, claudin-5/TMVCF was specifically detected in endothelial cells of some segments of blood vessels, but not in epithelial cells. Furthermore, when claudin-5/TMVCF cDNA was introduced into mouse L fibroblasts, TJ strands were reconstituted that resembled those in endothelial cells in vivo, i.e., the extracellular face-associated TJs. These findings indicated that claudin-5/TMVCF is an endothelial cell-specific component of TJ strands.     

The C-terminal cytoplasmic tail of claudins 1 and 5 but not its PDZ-binding motif is required for apical localization at epithelial and endothelial tight junctions

Claudins are a family of tetraspan transmembrane proteins that represent the major constituents of epithelial and endothelial tight junctions (TJs). They form TJ strands representing the major barrier regulating paracellular transport of solutes and water. Intracellularly, claudins are connected via a C-terminal PDZ-binding motif with several TJ-associated proteins containing PDZ domains. Although these interactions can provide a link to the actin cytoskeleton, they appear to be dispensable for the TJ localization of claudins. To identify TJ-targeting elements in the C-terminal cytoplasmic domains of the claudins 1 and 5, we generated a series of C-terminal deletion mutants and analyzed their distribution in polarized epithelial (MDCK) and endothelial (HMEC-1) cells. TJ localization was revealed by establishing an in vivo cross-linking approach that stabilized claudin-TJ interactions. We show that residues located C-terminal to the last transmembrane domain are required for the proper targeting to apical TJ.s. While claudin derivatives lacking only the very C-terminal PDZ-binding motif continue to localize to TJs, mutants lacking the entire C-terminal juxtamembrane sequence do not associate with TJs and accumulate in intracellular structures. This indicates that crucial determinants for stable TJ incorporation of claudins reside in a cytoplasmic C-terminal sequence which up to now has not been implicated in specific protein-protein interactions.     

Formation of tight junction strands by expression of claudin-1 mutants in their ZO-1 binding site in MDCK cells

To investigate the formation mechanism of tight junctions (TJs), we constructed three claudin-1 mutants which varied in their COOH-termini and expressed them in MDCK cells under the control of doxycycline. The differences between these constructs are that a putative ZO-1 binding sequence (KDYV) at the COOH-terminus of claudin-1 was deleted (DeltaCmyc) or present (1CLmyc and DeltaCmycYV), or that a myc-epitope was added at the COOH-terminus (1CLmyc and DeltaCmyc) or inserted just before the KDYV sequence (DeltaCmycYV). All three constructs caused the formation of aberrant TJ strands along the lateral plasma membranes. However, when their expression levels were reduced by adding 0.2 ng/ml doxycycline, they were located at apical TJs and colocalized with ZO-1, even in the KDYV-deleted construct. These results suggest that, although the addition of the myc-epitope at or near the COOH-terminus of claudin-1 interfered with the binding to ZO-1 and induced aberrant TJ strand formation, endogenous claudins which could bind to ZO-1 might recruit these deformed claudin-1s expressed at a low level to apical TJs. A calcium switch assay revealed that claudin-1 was transported to cadherin-based cell-cell contacts where ZO-1 had already accumulated, and was then concentrated at apical TJs together with ZO-1. Crosslinking between claudin-1 and the perijunctional actin ring through ZO-1 may be necessary for TJ strands to be localized or retained at apical TJs.     

Multi-PDZ domain protein 1 (MUPP1) is concentrated at tight junctions through its possible interaction with claudin-1 and junctional adhesion molecule.

Claudins, most of which end in valine at their COOH termini, constitute tight junction (TJ) strands, suggesting that TJ strands strongly attract PDZ-containing proteins. Indeed, ZO-1, -2, and -3, each of which contains three PDZ domains, were shown to directly bind to claudins. Using the yeast two-hybrid system, we identified ZO-1 and MUPP1 (multi-PDZ domain protein 1) as binding partners for the COOH terminus of claudin-1. MUPP1 has been identified as a protein that contains 13 PDZ domains, but it has not been well characterized. In vitro binding assays with recombinant MUPP1 confirmed the interaction between MUPP1 and claudin-1 and identified PDZ10 as the responsible domain for this interaction. A polyclonal antibody specific for MUPP1 was then generated. Immunofluorescence confocal microscopy as well as immunoelectron microscopy with this antibody revealed that in polarized epithelial cells MUPP1 was exclusively concentrated at TJs. Furthermore, in vitro binding and transfection experiments showed that junctional adhesion molecule, another TJ adhesion molecule, also bound to the PDZ9 domain of MUPP1. These findings suggested that MUPP1 is concentrated at TJs in epithelial cells through its binding to claudin and junctional adhesion molecule and that it may function as a multivalent scaffold protein that recruits various proteins to TJs.     

Enteropathogenic Escherichia coli infection leads to appearance of aberrant tight junctions strands in the lateral membrane of intestinal epithelial cells

Infection of intestinal epithelial cells with enteropathogenic Escherichia coli (EPEC) disrupts tight junction (TJ) architecture and barrier function. The aim of this study was to determine the impact of EPEC on TJ protein interactions and localization. Human intestinal epithelial cells (T84) were infected for 1, 3 or 6 h with EPEC. To probe the TJ protein-protein interactions, co-immunoprecipitations were performed. The associations between ZO-1, occludin and claudin-1 progressively decreased after infection. Corresponding morphological changes were analysed by immunofluorescence confocal microscopy. Tight junction proteins progressively lost their apically restricted localization. Freeze-fracture electron microscopy revealed the appearance of aberrant strands throughout the lateral membrane that contained claudin-1 and occludin as determined by immunogold labelling. These structural alterations were accompanied by a loss of barrier function. Mutation of the gene encoding EspF, important in the disruption of TJs by EPEC, prevented the disruption of TJs. Tight junction structure normalized following eradication of EPEC with gentamicin and overnight recovery. This is the first demonstration that a microbial pathogen can cause aberrant TJ strands in the lateral membrane of host cells. We speculate that the disruption of integral and cytoplasmic TJ protein interactions following EPEC infection allows TJ strands to form or diffuse into the lateral plasma membrane.     

Occludin-deficient Embryonic Stem Cells Can Differentiate into Polarized Epithelial Cells Bearing Tight Junctions

Occludin is the only known integral membrane protein of tight junctions (TJs), and is now believed to be directly involved in the barrier and fence functions of TJs. Occludin-deficient embryonic stem (ES) cells were generated by targeted disruption of both alleles of the occludin gene. When these cells were subjected to suspension culture, they aggregated to form simple, and then cystic embryoid bodies (EBs) with the same time course as EB formation from wild-type ES cells. Immunofluorescence microscopy and ultrathin section electron microscopy revealed that polarized epithelial (visceral endoderm-like) cells were differentiated to delineate EBs not only from wild-type but also from occludin-deficient ES cells. Freeze fracture analyses indicated no significant differences in number or morphology of TJ strands between wild-type and occludin-deficient epithelial cells. Furthermore, zonula occludens (ZO)-1, a TJ-associated peripheral membrane protein, was still exclusively concentrated at TJ in occludin-deficient epithelial cells. In good agreement with these morphological observations, TJ in occludin-deficient epithelial cells functioned as a primary barrier to the diffusion of a low molecular mass tracer through the paracellular pathway. These findings indicate that there are as yet unidentified TJ integral membrane protein(s) which can form strand structures, recruit ZO-1, and function as a barrier without occludin.     

Role of claudin species-specific dynamics in reconstitution and remodeling of the zonula occludens

Tight-junction strands, which are organized into the beltlike cell-cell adhesive structure called the zonula occludens (TJ), create the paracellular permselective barrier in epithelial cells. The TJ is constructed on the basis of the zonula adherens (AJ) by polymerized claudins in a process mediated by ZO-1/2, but whether the 24 individual claudin family members play different roles at the TJ is unclear. Here we established a cell system for examining the polymerization of individual claudins in the presence of ZO-1/2 using an epithelial-like cell line, SF7, which lacked endogenous TJs and expressed no claudin but claudin-12 in immunofluorescence and real-time PCR assays. In stable SF7-derived lines, exogenous claudin-7, -14, or -19, but no other claudins, individually reconstituted TJs, each with a distinct TJ-strand pattern, as revealed by freeze-fracture analyses. Fluorescence recovery after photobleaching (FRAP) analyses of the claudin dynamics in these and other epithelial cells suggested that slow FRAP-recovery dynamics of claudins play a critical role in regulating their polymerization around AJs, which are loosely coupled with ZO-1/2, to form TJs. Furthermore, the distinct claudin stabilities in different cell types may help to understand how TJs regulate paracellular permeability by altering the paracellular flux and the paracellular ion permeability.     

RalA and RalB differentially regulate development of epithelial tight junctions

Tight junctions (TJs) are structures indispensable to epithelial cells and are responsible for regulation of paracellular diffusion and maintenance of cellular polarity. Although many interactions between TJ constituents have been identified, questions remain concerning how specific functions of TJs are established and regulated. Here we investigated the roles of Ral GTPases and their common effector exocyst complex in the formation of nascent TJs. Unexpectedly, RNA interference-mediated suppression of RalA or RalB caused opposing changes in TJ development. RalA reduction increased paracellular permeability and decreased incorporation of components into TJs, whereas RalB reduction decreased paracellular permeability and increased incorporation of components into TJs. Activities of both Ral GTPases were mediated through the exocyst. Finally, we show that TJ-mediated separation of apical-basal membrane domains is established prior to equilibration of barrier function and that it is unaffected by Ral knockdown or specific composition of TJs.     

Conversion of zonulae occludentes from tight to leaky strand type by introducing claudin-2 into Madin-Darby canine kidney I cells

There are two strains of MDCK cells, MDCK I and II. MDCK I cells show much higher transepithelial electric resistance (TER) than MDCK II cells, although they bear similar numbers of tight junction (TJ) strands. We examined the expression pattern of claudins, the major components of TJ strands, in these cells: claudin-1 and -4 were expressed both in MDCK I and II cells, whereas the expression of claudin-2 was restricted to MDCK II cells. The dog claudin-2 cDNA was then introduced into MDCK I cells to mimic the claudin expression pattern of MDCK II cells. Interestingly, the TER values of MDCK I clones stably expressing claudin-2 (dCL2-MDCK I) fell to the levels of MDCK II cells (>20-fold decrease). In contrast, when dog claudin-3 was introduced into MDCK I cells, no change was detected in their TER. Similar results were obtained in mouse epithelial cells, Eph4. Morphometric analyses identified no significant differences in the density of TJs or in the number of TJ strands between dCL2-MDCK I and control MDCK I cells. These findings indicated that the addition of claudin-2 markedly decreased the tightness of individual claudin-1/4-based TJ strands, leading to the speculation that the combination and mixing ratios of claudin species determine the barrier properties of individual TJ strands.     

Polarity reversal of inside-out thyroid follicles cultured within collagen gel: structure of the junctions assessed by freeze-fracture and lanthanum permeability

The organization of tight junctional complexes (TJs) was studied in cultured porcine thyroid cells during the inversion of polarity induced by collagen-embedding of inside-out follicles, using freeze-fracture replicas and lanthanum penetration. During the early steps of polarity reversal, freeze-fractures showed that TJs generally persisted. They increased in width and progressively branched out into the basolateral surfaces, towards the basal pole. Later, the number of TJ strands decreased and gap junctions inserted within TJ networks were found between cells in reversed follicles, in the same manner as in typically polarized follicles, embedded in collagen or in suspension. The de novo formation of TJ complexes was rarely found in the reversing structures. Despite the heterogeneity of TJs assessed by freeze-fracture, impermeability to lanthanum tracer was noted in inside-out structures. During the reversal process, some TJs remained unstained, whereas others displayed permeability to lanthanum. This heterogeneity might be due to the "opening" of a small number of junctions (perhaps only one by aggregate). When the process was achieved after 48 hr in collagen, the tightness of the junctions was complete, confirmed by the absence of lanthanum in luminal cavities of newly formed follicles.     

Disruption of epithelial tight junctions is prevented by cyclic nucleotide-dependent protein kinase inhibitors

Tight junctions (TJs), the most apical of the intercellular junctions, prevent the passage of ions and molecules through the paracellular pathway. Intracellular signalling molecules are likely to be involved in the regulation of TJ integrity. In order to specifically investigate the role of protein kinase A (PKA) in the maintenance of epithelial TJ integrity, calcium-switch experiments were performed, in which calcium was removed from EpH4 and MDCK culture medium, in the absence or presence of the PKA inhibitors H-89 or HA-1004. Removal of calcium from the culture media of the epithelial cells resulted in disruption of the TJs, characterised by a loss of membrane association of the TJ-associated proteins occludin, ZO-1 and ZO-2, by a loss of TJ strands, by a marked decrease in the transepithelial electrical resistance and by a dramatic increase in the transepithelial permeability to tracers. The association of occludin, ZO-1 and ZO-2 with the actin cytoskeleton is not affected. In contrast, when the removal of calcium was performed in the presence of either the PKA inhibitor H-89 or HA-1004, all barrier characteristics were preserved. Our data indicate that following the removal of calcium from the culture medium of epithelial cells in vitro, PKA is activated and subsequently is involved in the disruption of TJs.     

Methyl-beta-cyclodextrin increases permeability of Caco-2 cell monolayers by displacing specific claudins from cholesterol rich domains associated with tight junctions.

In a previous study we demonstrated that depletion of Caco-2 cell cholesterol results in the loss of tight junction (TJ) integrity through the movement of claudins 3 and 4 and occludin, but not claudin 1, out of the TJs [1]. The aims of this study were to determine whether the major tight junction (TJ) proteins in Caco-2 cells are associated with cholesterol rich, membrane raft-like domains and if the loss of TJ integrity produced by the extraction of cholesterol reflects the dissolution of these domains resulting in the loss of TJ organisation. We have demonstrated that in Caco-2 cells claudins 1, 3, 4 and 7, JAM-A and occludin, are associated with cholesterol rich membrane domains that are insoluble in Lubrol WX. Co-immunoprecipitation studies demonstrated that there is no apparent restriction on the combination of claudins present in the rafts and that interaction between the proteins is dependent on cholesterol. JAM-A was not co-immunoprecipitated with the other TJ proteins indicating that it is resident within in a distinct population of rafts and therefore is likely not directly associated with the claudins/occludin present in the TJ complexes. Depletion of Caco-2 cell cholesterol with methyl-beta-cyclodextrin resulted in the displacement of claudins 3, 4 and 7, JAM-A and occludin, but not claudin 1, out of the cholesterol rich domains. Our data indicate that depletion of cholesterol does not result in the loss of the TJ-associated membrane rafts. However, the sterol is required to maintain the association of key proteins with the TJ associated membrane rafts and therefore the TJs. Furthermore, the data suggest that cholesterol may actually directly stabilise the multi-protein complexes that form the TJ strands.     

NaCl flux between apical and basolateral side recruits claudin-1 to tight junction strands and regulates paracellular transport

In multicellular organisms, epithelia separate and divide the internal environment maintaining appropriate conditions in each compartment. To maintain homeostasis in these compartments, claudins, major cell adhesion molecules in tight junctions (TJs), regulate movements of several substances through the paracellular pathway (barrier function). In this study, we investigated effects of the flux of several substances between apical and basolateral side on paracellular transport and TJ protein localization. NaCl flux from apical to basolateral side increased paracellular conductance (Gp) and recruited claudin-1 from lateral cell membrane to the apical end with the colocalization with occludin, one of the TJ proteins concentrated at TJ strands. Oppositely-directed flux of sucrose against NaCl flux inhibited these reactions and same directional flux of sucrose with NaCl enhanced the increase of Gp, whereas 10-kDa dextran inhibited these reactions regardless of the side of administration. Our present findings indicated that TJ protein localization and barrier function are regulated depending on the environmental differences between apical and basolateral side.