Rotavirus-Induced Structural and Functional Alterations in Tight Junctions of Polarized Intestinal Caco-2 Cell Monolayers

doi:10.1128/JVI.74.10.4645-4651.2000

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Journal of Virology, May 2000, p. 4645-4651, Vol. 74, No. 10
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Rotavirus-Induced Structural and Functional Alterations in Tight Junctions of Polarized Intestinal Caco-2 Cell Monolayers

Guillaume Obert, Isabelle Peiffer, and Alain L. Servin^*

Unité 510, Pathogènes et Fonctions des Cellules Epithéliales Polarisées, Institut National de la Santé et de la Recherche Médicale, Faculté de Pharmacie, Université Paris XI, 92296 Châtenay-Malabry, France

Received 12 November 1999/Accepted 24 February 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

We provide here new insights into rotavirus (RRV) pathogenicity by showing that RRV infection promotes structural and functionalinjuries localized at the tight junctions (TJ) in the cell-celljunctional complex of cultured polarized human intestinal Caco-2cells forming monolayers. RRV infection resulted in a progressiveincrease in the paracellular permeability to [³H]mannitol as a function of the time postinfection. We observeda disorganization of the TJ-associated protein occludin as a functionof the time postinfection, whereas distribution of the zonulaadherens associated E-cadherin was not affected. These structuraland functional RRV-induced TJ injuries were not accompanied byalteration in cell and monolayer integrity, as assessed by thelack of change in transepithelial membrane resistance and lactatedehydrogenase release. Finally, using the stabilizer of actinfilaments Jasplakinolide, we demonstrated that the RRV-inducedstructural and functional alterations in TJ are independent ofthe RRV-induced apical F-actinrearrangements.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Rotaviruses (RRV), nonenveloped double-stranded RNA viruses, are recognized as the most important worldwide cause of viralgastroenteritis in infants (for reviews see references 7 and16). There is increasing information on their replication andmaturation processes. Currently, the pathophysiological mechanismsby which RRV induce diarrhea remain unclear. RRV diarrhea mightbe due to enterocyte destruction from the top of intestinal villi.In agreement with this, extensive studies of animal models havereported the presence of histopathologic changes and functionalabnormalities in infected intestinal mucosae that varied frommild to severe depending on the RRV strain virulence. However,this mechanism cannot explain situations in which mild histopathologicchanges without enterocyte destruction are associated with lowdisaccharidase level. Indeed, whatever the severity of histopathologicchanges, the activity of functional intestinal proteins is frequentlydecreased by RRV infection. Recently, we have gained consistentdata which lead us to propose a alternate RRV pathophysiologicalmodel in which alteration of enterocytic functions depends onperturbation in protein trafficking and the cytoskeleton (3,13).

In the present study we have investigated the mechanisms by which RRV impair the structural and functional organization ofthe intestinal epithelial cell monolayers. In epithelia, the permeabilitybarrier between different environments results from the assemblyand maintenance of different junctional domains in the polarizedcells; that the regulation of the paracellular pathway by itswell-defined structures is a complex process is now apparent (forreviews see references 1, 4, and 18). In order to approachin vitro the situation in vivo and to gain further insights intothe pathophysiological mechanisms of RRV infection, we have usedthe human polarized intestinal epithelial Caco-2 cells (23).These cells, established from a human colon adenocarcinoma, spontaneouslydifferentiate after confluency and display many of the morphologicaland biochemical properties of mature enterocytes (32). Interestingly,the human polarized intestinal Caco-2 cells which form monolayersmimicking an epithelial barrier are known to allow the transcellularpassage of water (11). In relation to our previous observationthat RRV infection in Caco-2 cells is accompanied by brush border-associatedcytoskeletal rearrangements (3, 13), we decided to examinewhether or not RRV infection produces structural and functionalchanges in the junctional domains of polarized Caco-2 cells. Weprovide here new insights into the pathophysiological events followingRRV infection consisting of structural and functional injurieslocalized at the tight junctions (TJ) in the cell-cell junctionalcomplexes of polarized intestinal cell monolayers mimickingepithelia.

	MATERIALS AND METHODS

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Reagents. [2-³H]mannitol (15 to 30 Ci/mM) was from Amersham (Les Ulis, France). [1,2-³H]polyethylene glycol (PEG) 900 and 4000 (2 Ci/mM) were from NEN(Paris, France). Fluorescein-5 and -6 sulfonic acid (FS) and Jasplakinolide(JAS) were from Molecular Probes (Eugene, Oreg.).

Cell lines and culture. The cultured human colonic adenocarcinoma Caco-2 cells (23) were routinely grown in Dulbecco modified Eagle's minimal essentialmedium (DMEM) (25 mM glucose) (Eurobio, Paris, France), supplementedwith 20% fetal calf serum (Boehringer, Mannheim, Germany) and1% nonessential amino acids as previously described (13-15). Formaintenance purposes, cells were passaged weekly using 0.25% trypsinin Ca²⁺- and Mg²⁺-free phosphate-buffered saline (PBS) containing 3 mM EDTA. Maintenanceof the cells and all experiments were carried out at 37°C in a10% CO₂-90% airatmosphere.

All experiments were carried out at late confluency, i.e., after 15 days in culture (fully differentiated cells) (3, 13-15).For paracellular flux studies, the cells were seeded at a densityof 10,000 cells per cm² on tissue culture-treated polycarbonate Transwell filters containingpores 0.4 mm in diameter. Apical and/or basal media were replacedat 2-day intervals from day 2. In other experiments, cells wereseeded in 24-well tissue culture plates (Corning Glass Works,Corning, N.Y.) at a concentration of 2.5 × 10⁴ cells perwell.

MA104 cells were cultured in MEM supplemented with 10% fetal bovine serum FBS, 1% glutamine, antibiotics (20 U of penicillinand 40 U of streptomycin/ml), and 1% nonessential amino acids(100×) in a 5% CO₂ incubator. Cells (10⁵/cm²) were seeded in 150-cm² tissue culture flasks (Falcon; Becton Dickinson, Le Pont-de-Claix,France) and were used for virus stock production after 48 h ofculture.

Cell infection. The method used for Caco-2 cell infection has been described elsewhere (13-15). Briefly, the virus inoculum was activated for30 min by treatment with 0.5 mg of trypsin/ml. Caco-2 cells (culturedwithout FBS for 24 h) were apically infected with an inoculumof activated RRV at a multiplicity of infection of 1 or 10 PFUfor 1 h at room temperature. The inoculum was then removed, andfresh medium containing 0.5 mg of trypsin/ml was added. Infectedcells were incubated at 37°C in a 10% CO₂-90% air atmosphere andwere processed for experiments at various times postinfection.Each assay was conducted in triplicate with three successive passagesof Caco-2cells.

Antibodies. The monoclonal antibody (MAb) against E-cadherin was from Biogenesis (Interchim, Montluçon, France). The MAb directed againstoccludin was obtained from Zymed Laboratories (ICN, San Francisco,Calif.). The ascites fluid containing antibody HBB 2/614/88 againsthuman sucrase-isomaltase (SI) was a gift from H. P. Hauri (Biocenterof the University of Basel, Basel, Switzerland). The polyclonalanti-group A RRV antibody 8148 was a gift from J. Cohen (InstitutNational de la Recherche Agronomique, Jouy-en-Josas, France).Fluorescein isothiocyanate-phalloidin was from Molecular ProbesInc. Fluorescein-coupled goat anti-mouse immunoglobulins werefrom Institut Pasteur Productions (Paris,France).

Immunofluorescence. Monolayers of Caco-2 cells were prepared on glass coverslips, which were placed in 24-well tissue culture plates (CorningGlass Works). Control and RRV-infected cell monolayers were fixedfor 15 min at room temperature in 3.5% paraformaldehyde in PBS,washed three times, and then treated with 50 mM NH₄Cl for 10 min.When occludin and E-cadherin were to be visualized, the cellsgrown on coverslips were permeabilized by incubation with 0.2%Triton X-100 in PBS for 4 min, and the coverslips were then rewashedthree times with PBS. Permeabilized cell monolayers were incubatedwith a specific primary antibody (diluted 1:20 to 1:100 in PBSin 0.2% bovine serum albumin [BSA]-PBS) for 45 min at room temperature,washed, and then incubated with their respective secondary fluorescein-conjugatedantibodies (Institut Pasteur Productions) (diluted 1:50 in 0.2%BSA-PBS).

SI was revealed by indirect immunofluorescence labeling on unpermeabilized cell monolayers as previously described (13).Preparations were fixed for 10 min at room temperature in 3.5%paraformaldehyde in PBS. Cell monolayers were incubated with MAbanti-SI (diluted 1:100 in 2% BSA-PBS) for 30 min at room temperature,washed, and then incubated with the respective secondary fluorescein-conjugatedantibodies. Appropriate secondary antibodies were used at a dilutionof 1:20 to 1:100 in 0.2% BSA-PBS. No fluorescence staining wasobserved when nonimmune serum was used or when the primary antibodywasomitted.

RRV proteins were revealed by indirect immunofluorescence in cells fixed postinfection with 3% paraformaldehyde, permeabilizedwith 0.1% Triton X-100, and labeled with polyclonal anti-groupA RRV antibody 8148 (diluted 1:100 in PBS in 0.2% BSA-PBS) andfluorescein isothiocyanate-labeled anti-rabbit immunoglobulinG antibody (Institut Pasteur Productions) (diluted 1:50 in 0.2%BSA-PBS), as previously described (13-15). No fluorescence stainingwas observed when nonimmune serum was used or when the primaryantibody wasomitted.

When F-actin was to be visualized, cells grown on coverslips were permeabilized by incubation with 0.2% Triton X-100 in PBSfor 4 min at room temperature before incubation with fluorescein-phalloidinfor 45 min at 22°C. The coverslips were then rewashed three timeswithPBS.

Specimens were examined using a Leitz Aristoplan microscope with epifluorescence coupled to a Visiolab 1000 image analyzer(Biocom, Les Ulis, France). More than 200 individual cells wereexamined for each assay, and assays were conducted in triplicatewith three successive passages of Caco-2 cells. All photographswere taken on T-MAX 400 black-and-white film (Eastman Kodak Co.,Rochester, N.Y.).

LDH release. Cell integrity was determined by measuring the release of lactate dehydrogenase (LDH) into the culture medium postinfectionusing a commercially available kit (Enzyline LDH; Biomérieux,Dardilly, France). The results are expressed as the units perliter of LDHreleased.

TER measurements. Monolayers of Caco-2 cells were grown in filters mounted in culture chambers (Costar culture plate inserts; 0.4-µm pore size;4.7 cm²; 3 × 10⁴ cells per cm²), an arrangement which delineates an apical (luminal) and a basolateral(serosal) reservoir. After RRV infection, the integrity of theconfluent polarized monolayers was checked by measuring transepithelialmembrane resistance (TER) with a volt-ohmmeter (Millicel ERS;Millipore, Saint Quentin, France). TER (in units of ohms timescentimeters squared) was calculated as the measured electricalresistance times the surface area of a filter. The backgroundreading of a free control filter wassubtracted.

Permeability measurements. The permeability of Caco-2 cell monolayers was determined by measuring the paracellular passage of water-soluble radioactiveor fluorescent compounds, having various sizes, from the apicalto the basolateral compartments of the culture chamber (Costarculture plate inserts; 0.4-µm pore size; 4.7 cm²; 3 × 10⁴ cells perfilter).

[³H]mannitol, [³H]PEG, or FS was dissolved in the culture medium. To measure the flux in the apical-to-basolateral direction,the tracer solution (2.5 µCi/ml for radioactive compounds and20 µg/ml for FS) was loaded into the apical side of the monolayerand the cells were incubated for 1 h at 37°C. After the incubationperiod, the tracer concentrations in the apical and basolateralcompartments were assayed. The concentrations of [³H]mannitol and [³H]PEG were determined by measurement in a $beta$ -scintillation counter.The values were corrected for the background radioactivity ofthe media or PBS, as appropriate. The fluorescence due to FS wasdetermined using a Jobin-Yvon JY3C spectrofluorimeter at an excitationwavelength of 410 nm (slit width, 2 nm) and an emission wavelengthof 530 nm (slit width, 10nm).

JAS treatment. JAS (1 µM) was added to the culture medium 30 min before RRV infection, and this concentration was maintained during the infectiontime course. In a preliminary experiment, an examination of LDHrelease and TER in uninfected cells treated with JAS showed nomodification in the cell and monolayerintegrities.

Statistics. Data are expressed as means ± standard errors of the means of several experiments, with at least three monolayers from threesuccessive passages of cells per experiment. The statistical significancewas assessed by Student's ttest.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

RRV infection induces an increase in paracellular permeability. The effect of RRV infection on paracellular permeability in Caco-2 intestinal monolayers was examined using [³H]mannitol (182 Da) (Fig. 1A). The rate of unidirectional fluxof [³H]mannitol was negligibly low in control monolayers. RRV infectionresulted in a progressive increase in the paracellular permeabilityto [³H]mannitol as a function of the time postinfection. We investigatedmonolayer integrity and cell viability at 12, 18, and 24 h postinfection(Table 1). As assessed by TER measurement, there was no significantchange in monolayer integrity within the first 24 h postinfection.In contrast, a significant increase in LDH release and a decreasein TER were observed at 36 h postinfection, revealing that RRV-inducedcell lysis had commenced. Altogether, these results demonstratedthat the RRV-induced increase in paracellular permeability developsbefore the RRV-induced cell lysis.

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FIG. 1. RRV infection promotes an increase in paracellular fluxes of Caco-2 cell monolayers. Markers were loaded into the apical side of the Caco-2 cell monolayer (1 h at 37°C), and the tracer concentration in the basolateral compartment was assayed. (A) Paracellular permeability to [³H]mannitol as a function of the time postinfection. (B) Levels of RRV-induced paracellular permeability determined using defined paracellular markers having different sizes: [³H]mannitol (182 Da), FS (478 Da), [³H]PEG 900 (900 Da), and [³H]PEG 4000 (4,000 Da).

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TABLE 1. LDH release and TER in uninfected control and RRV-infected Caco-2 cells^a

The extent of the RRV-induced paracellular permeability was determined using defined paracellular markers having differentsizes: FS (478 Da), [³H]PEG 900 (900 Da), and [³H]PEG 4000 (4,000 Da) (Fig. 1B). The mucosal-to-serosal flux rateof markers across the filter-grown Caco-2 cell monolayers wasdetermined at 18 h postinfection. The rate of unidirectional fluxof markers was negligibly low in control monolayers. RRV infectionresulted in a highly significant increase in the paracellularpermeability to FS, which was lower than that to [³H]mannitol. In contrast, the paracellular permeability to PEG900 and PEG 4000 in RRV-infected monolayers did not change comparedwith that in controlmonolayers.

RRV infection induces selective alterations in the distribution of proteins associated with the TJ. The above results showing an RRV-induced increase in the paracellular permeability to [³H]mannitol and FS suggest a mechanism involving an alterationin the distribution of functional junctional complex-associatedproteins. For polarized epithelial cells forming monolayers, theintercellular junctional complexes include well-defined structuresincluding TJ or zonula occludens, zonula adherens (ZA), and desmosomes(for reviews see references 1and 4). The most apical structureof the junctional complex is the TJ, in which functional proteinssuch as occludin (2, 9, 20) have been identified. Justnext to the TJ lies the ZA, also named adherens junction, in whichthe classical cadherins (e.g., E-, N-, and P-cadherins) act asadhesion receptors (10).

We examined whether or not the distribution of the TJ-associated occludin and ZA-associated E-cadherin was modified in Caco-2cells upon RRV infection. Figure 2A shows that occludin stainingwas localized to sites of cell-cell boundaries in control uninfectedcells. Occludin distribution was characterized by a brightly stained,continuous band with a sharp honeycomb-like organization. In RRV-infectedcells (Fig. 2B to D), the occludin distribution appeared disorganizedas a function of the time postinfection. Indeed, at 12 h postinfectionrandomly distributed cells showed that alteration of the occludindistribution had begun (Fig. 2B). At 18 and 24 h postinfection(Fig. 2C and D, respectively), occludin distribution appeareddramatically altered and was characterized by the formation oflarge gaps and the appearance of a fluffy disorganized pattern.As disclosed in Fig. 2E the E-cadherin distribution in uninfectedcontrol cells results in a continuous large band with a honeycomb-likeorganization. In contrast, with occludin, no obvious change inE-cadherin distribution in RRV-infected Caco-2 cells was found(Fig. 2F).

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FIG. 2. Alteration in the distribution of junction-associated proteins upon RRV infection in Caco-2 cells. (A) Occludin in control cells. (B to D) Occludin in RRV-infected cells at 12, 18, and 24 h postinfection, respectively. (E and F) E-cadherin in control cells and RRV-infected cells, respectively, at 24 h postinfection. Magnification, ×100.

Altogether, these results demonstrated that infection by RRV in polarized epithelial intestinal cells forming monolayers isfollowed by the opening of the cell barrier localized just inthe upper part of the junctional domain, involving redistributionof the TJ-associated occludin, whereas the ZA domain appearedunmodified.

RRV-induced structural and functional alterations in TJ are independent of apical cytoskeletal rearrangements. We have previously reported that RRV infection in Caco-2 cells is followed by apical cytoskeleton rearrangements (3, 13).Moreover, alteration in the junctional domain could result fromcentrifugal traction of the TJ membrane in polarized epithelialcells in which alteration of the apical cytoskeleton develops.In order to assess whether RRV-induced structural and functionalalterations in TJ are dependent or not on the RRV-induced apicalF-actin rearrangements, we used JAS, a monocyclic peptide isolatedfrom the sea sponge Jaspis johnstoni, known to be a stabilizerof actin filaments (30). As a control, we verified that JASat the concentration (1 µM) used had no effect on RRV infection(Fig. 3D and H). As disclosed in Fig. 3, JAS treatment of theRRV-infected Caco-2 cells resulted in inhibition of the RRV-inducedapical F-actin disassembly (Fig. 3A to C), whereas the RRV-induceddecrease in SI expression was partially inhibited (Fig. 3E toG). In contrast, JAS treatment of RRV-infected Caco-2 cells didnot modify the increase in the paracellular permeability to [³H]mannitol (Fig. 4A). In parallel, immunolabeling of occludinin RRV-infected cells treated with JAS shows that the TJ-associatedprotein remains redistributed (Fig. 4C) compared with what isfound for untreated RRV-infected cells (Fig. 2C, respectively).Taken together, these results demonstrate that the RRV-inducedfunctional alteration in the TJ of the Caco-2 cell monolayersdoes not result from the RRV-induced apical cytoskeleton rearrangements.The fact that JAS does not inhibit the RRV-induced increase inmannitol fluxes could be the consequence of occludin not beingdirectly linked to the cytoskeleton. Indeed, occludin is directlylinked to the zonula occludens protein ZO-1, which is directlylinked to the F-actin cytoskeleton (for a review see reference4). Results showing that the occludin distribution remainsmodified in RRV-infected cells treated with JAS support the hypothesisthat JAS could reassemble F-actin and ZO-1 together but does notreassemble ZO-1 with occludin, leading to the persistence of theincrease in mannitol fluxes.

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FIG. 3. Effect of JAS treatment on RRV-induced apical F-actin and SI rearrangements. (A and E) Uninfected cells. (B, D, F, G, and H) RRV-infected cells at 18 h postinfection. (C, G, and H) Cells treated with JAS. (A to C) F-actin labeling. Control cells show the fine and homogeneous labeling centrally, representing microvillus-associated F-actin (A). RRV-infected cells show the disassembly of F-actin characterized by the disappearance of the fine and homogeneous labeling centrally in the cells and the appearance of clumped F-actin (B). RRV-infected cells treated with JAS (1 µM) show the protection of the apical F-actin characterized by the reappearance of the fine and homogeneous labeling centrally in the cells (C). (E to G) SI labeling. Control cells show the characteristic high expression of SI in a mosaic pattern (E). RRV-infected cells show the disappearance of the SI mosaic pattern and the appearance of clumped SI (F). RRV-infected cells treated with JAS show the incomplete reappearance of the SI mosaic pattern (G). (D and H) RRV protein labeling in infected cells without and with JAS treatment, respectively. Note that JAS treatment does not modify the level of RRV-infected cells.

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FIG. 4. Effect of JAS treatment on the RRV-induced increase in paracellular fluxes and occludin distribution. (A) Paracellular fluxes of [³H]mannitol and FS measured in the mucosal-to-serosal direction (1 h at 37°C) without or with RRV infection (18 h postinfection). (B) Occludin in control cells treated with JAS (1 µM). (C) Occludin in RRV-infected cells treated with JAS (1 µM) (18 h postinfection).

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

We have recently revisited the pathophysiological mechanisms by which RRV infection promotes cell injuries in polarized humanintestinal cells. In particular, we have investigated the mechanismby which RRV impairs some intestinal functional proteins withoutapparent cell destruction. Data demonstrated that RRV infectioninduced the blockade of the direct transport of SI from the trans-Golginetwork to the brush border (13). In parallel, RRV infectioninduces an important alteration of the brush border-associatedcytoskeleton that correlates with decreased SI apical surfaceexpression. Finally, we have demonstrated the ability of one orseveral intracellular or released viral proteins from RRV-infectedhuman intestinal epithelial cells to induce an alteration in themicrovillar cytoskeleton by a Ca²⁺-dependent mechanism (3).

It is well established that several gastrointestinal epithelial functions are influenced by the establishment and the maintenanceof the polarized organization of the epithelial intestinal cells.Organization of polarized epithelial cells in monolayers providesa permeability barrier between different environments (for reviewssee references 1, 4, and 18). The junctional domains inpolarized epithelial cells function as a "fence" separating apicaland basolateral domains, thereby segregating cell surface proteinsand lipids into each domain. They also function as a "gate" toprovide a permeability barrier between the mucosal and serosalenvironments. Several diarrheagenic bacteria alter the junctionalcomplexes in polarized epithelial cells to develop pathogenicity(for reviews see references 8 and 25). For example, infectionof the polarized epithelial cell monolayers with Salmonella entericaserovar Typhimurium, Helicobacter pylori, or enteropathogenicand enterohemorrhagic Escherichia coli results in alteration inthe junctionalcomplexes.

Reports have described the activity of viruses in TJ of the human polarized epithelial cells. The herpes simplex virus (HSV)interacts through its glycoprotein complex gE-gI with the adherentjunction, but not the TJ, to mediate the spread of viruses betweenadjacent cells (5). This interaction occurs without HSV-mediatedchange of either ZO-1 or $beta$ -catenin and without alteration in TJfunctions. Wild-type retinal cytomegalovirus strain AD169 infectingthe retinal pigment epithelium promotes epithelial permeabilizationand ZO-1 disassembly, whereas deletion mutants RV35, RV80, andAD169 do not (21). The results presented here show that thealterations observed in the junctional domain upon RRV infectiondiffered from the alterations induced by the nonenveloped poliovirusin monolayers of Caco-2 cells (27). Indeed, poliovirus infectionresults in a decrease in TER accompanied by an increase in paracellularpermeability to inulin prior to visible cytopathic effect. Theresults presented here show that RRV infection results in an increasein paracellular permeability to low-molecular-weight markers accompaniedby rearrangement in TJ-associated occludin without an associateddecrease in TER of monolayers. Dissociation of paracellular permeabilityfrom electrical resistance upon RRV infection is surprising sincethese two parameters have generally been considered to evolvein parallel. The only other example of identically paradoxicalresults was the result of a recently reported examination of therole of occludin in TJ functionality (2). Indeed, in MDCK IIcells transfection with C-terminally truncated occludin increasedthe paracellular flux without affecting the TER of monolayers.In parallel, the distribution of the mutant occludin exhibiteda discontinuous junctional staining pattern accompanied by a disruptionof the continuous junctional ring formed by the endogenous TJ-associatedproteinoccludin.

The observation that the RRV-induced selective opening of the TJ allowing passage of low-molecular-weight molecules resultsfrom a redistribution of functional TJ-associated proteins independentfrom the RRV-induced apical cytoskeleton disassembly is of interest.Indeed, the observed RRV-induced alterations in the TJ domaincould be related to the alteration in the apical expression ofthe brush border-associated hydrolase SI previously reported byus (13). This phenomenon results from the blockade of SI transportto the brush border without affecting SI biosynthesis, maturation,or stability. Several cytoskeleton-associated proteins and junction-associatedproteins play a pivotal role in the architectural organizationof the polarized cells (for reviews see references 12, 17,and 22). Moreover, it is well established that intracellulartrafficking of functional intestinal proteins is influenced bythe establishment and maintenance of the polarized organizationof the epithelial intestinal cells (19). Several intriguingperipheral membrane proteins are concentrated at the TJ and arethought to be involved not only in cross-linking TJ strands withunderlying actin-based cytoskeletons but also in vesicle targetingfor cellular polarization. For example, rab3B (29) and rab13(31), belonging to the family of rab GTPases involved in vesiculartransport, have been localized at the apical pole near the junctionalcomplexes. A current opinion is that, in association with thesubapical compartment in polarized intestinal cells (24, 28),the junctional domain may function as a novel sorting center forthe docking and fusion of some apical vesicles transporting brushborder-associated functional molecules. In consequence, alterationsin TJ induced by RRV infection could explain the previously reportedmodification of the vectorial delivery of functional componentsto the apical domain (13).

	ACKNOWLEDGMENTS

We thank J. Cohen (INRA, Jouy-en-Josas, France) for kindly providing anti-RRV serum and the RRV strain. We thank J. Cotte-Laffittefor helpfuladvice.

This work was supported by a grant from the French Ministère de l'Education Nationale, de la Recherche et de la Technologie(MENRT-PRFMMIP [Réseau de Recherche sur les Gastro-entéritesà Rotavirus: épidémiologie, structure et interaction avec l'hôte]).

	FOOTNOTES

^* Corresponding author. Mailing address: INSERM U-510, Faculté de Pharmacie, 5 rue J. B. Clément, 92296 Châtenay-Malabrycedex, France. Phone and fax: 33-1 46 83 56 61. E-mail: alain.servin{at}cep.u-psud.fr.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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14. Jourdan, N., J. Cotte-Laffitte, F. Forestier, A. L. Servin, and A. M. Quero. 1995. Infection of cultured human intestinal cells by monkey RRV and human Wa rotavirus as a function of intestinal epithelial cell differentiation. Res. Virol. 146:325-331[CrossRef][Medline].

15. Jourdan, N., M. Maurice, D. Delautier, A. M. Quero, A. L. Servin, and G. Trugnan. 1997. Rotavirus is released from the apical surface of cultured human intestinal cells through nonconventional vesicular transport that bypasses the Golgi apparatus. J. Virol. 71:8268-8278[Abstract].

16. Kapikian, A. Z., and R. M. Shanock. 1996. Rotaviruses, p. 1657-1708. In B. N. Fields, D. M. Knipe, and P. M. Howley (ed.), Fields virology, 3rd ed. Lippincott-Raven Publishers, Philadelphia, Pa.

17. Louvard, D., M. Kedinger, and H. P. Hauri. 1992. The differentiating intestinal epithelial cell: establishment and maintenance of functions through interactions between cellular structures. Annu. Rev. Cell Biol. 8:157-195[CrossRef].

18. Madara, J. L. 1988. Tight junction dynamics: is paracellular transport regulated? Cell 53:497-498[CrossRef][Medline].

19. Matter, K., and H. P. Hauri. 1991. Intracellular transport and conformational maturation of intestinal brush border hydrolases. Biochemistry 30:1916-1923[CrossRef][Medline].

20. McCarthy, K. M., I. B. Skare, M. C. Stankewich, M. Furuse, S. Tsukita, R. A. Rogers, R. D. Lynch, and E. E. Schneeberger. 1996. Occludin is a functional component of the tight junction. J. Cell Sci. 109:2287-2298[Abstract].

21. Pereira, L., E. Maidji, S. Tugisov, and T. Jones. 1995. Deletion mutants in human cytomegalovirus glycoprotein US9 are impaired in cell-cell transmission and in altering tight junctions of polarized human retinal pigment epithelial cells. Scand. J. Infect. Dis. 99:82-87.

22. Peterson, M. D., and M. S. Mooseker. 1993. An in vitro model for the analysis of intestinal brush border assembly. I. Ultrastructural analysis of cell contact-induced brush border assembly in Caco-2_BBe cells. J. Cell Sci. 105:445-460[Abstract].

23. Pinto, M., S. Robine-Leon, M. D. Appay, M. Kedinger, N. Triadou, E. Dussaulx, B. Lacroix, P. Simon-Aussman, K. Haffen, J. Fogh, and A. Zweibaum. 1983. Enterocyte-like differentiation and polarization of the human colon carcinoma cell line Caco-2 in culture. Biol. Cell. 47:323-330.

24. Salas, P. J. I., M. L. Rodriguez, A. L. Viciana, D. E. Vegas-Salas, and H. P. Hauri. 1997. The apical submembrane cytoskeleton participates in the organization of the apical pole in epithelial cells. J. Cell Biol. 137:359-375[Abstract/Free Full Text].

25. Sears, C. L., and J. B. Kaper. 1996. Enteric bacterial toxins: mechanisms of action and linkage to intestinal secretion. Microbiol. Rev. 60:167-215[Free Full Text].

26. Tian, P., M. K. Estes, Y. Hu, J. M. Ball, C. Q. Y. Zeng, and W. P. Schilling. 1995. The rotavirus nonstructural glycoprotein NSP4 mobilizes Ca²⁺ from the endoplasmic reticulum. J. Virol. 69:5763-5772[Abstract].

27. Tucker, S. P., C. L. Thornton, E. Wimmer, and R. W. Compans. 1993. Bidirectional entry of poliovirus into polarized epithelial cells. J. Virol. 67:29-38[Abstract/Free Full Text].

28. van Ijzendoorn, S. C. D., and D. Hoekstra. 1999. The subapical compartment: A novel sorting centre? Trends Cell Biol. 9:144-149[CrossRef][Medline].

29. Weber, E., G. Berta, A. Tousson, P. St. John, M. W. Green, U. Gopalokrishnan, T. Jilling, E. J. Sorscher, T. S. Elton, D. R. Abrahamson, and K. L. Kirk. 1994. Expression and polarized targeting of Rab3 isoform in epithelial cells. J. Cell Biol. 125:583-594[Abstract/Free Full Text].

30. Zabriskie, T. M., J. A. Klocke, C. M. Ireland, A. H. Marcus, T. F. Molinski, D. J. Faulkner, C. Xu, and J. C. Clardy. 1986. Jaspamide, a modified peptide from Jaspis sponge, with insecticidal and antifungal activity. J. Am. Chem. Soc. 108:3123-3124[CrossRef].

31. Zahraoui, A., G. Joberty, M. Arpin, J. J. Fontaine, R. Hellio, A. Tavitian, and D. Louvard. 1994. A small rab GTPase is distributed in cytoplasmic vesicles in non polarized cells but colocalizes with the tight junction marker ZO-1 in polarized epithelial cells. J. Cell Biol. 124:101-115[Abstract/Free Full Text].

32. Zweibaum, A., M. Laburthe, E. Grasset, and D. Louvard. 1991. Use of cultured cell lines in studies of intestinal cell differentiation and function, p. 223-255. In S. J. Schultz, M. Field, and R. A. Frizell (ed.), Handbook of physiology. The gastrointestinal system, vol. 4. American Physiological Society, Bethesda, Md.

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Clin. Vaccine Immunol.	ALL ASM JOURNALS

1.	Anderson, J. M., and C. M. van Itallie. 1995. Tight junctions and the molecular basis for regulation of paracellular pathway. Am. J. Physiol. 269:G467-G475[Abstract/Free Full Text].
2.	Balda, M. S., J. A. Whitney, C. Flores, S. Gonzales, M. Cereijido, and K. Matter. 1996. Functional dissociation of paracellular permeability and transepithelial electrical resistance and disruption of the apical-basolateral intramembrane diffusion barrier by expression of mutant tight junction membrane protein. J. Cell Biol. 134:1031-1049[Abstract/Free Full Text].
3.	Brunet, J.-P., J. Cotte-Laffitte, C. Linxe, A.-M. Quero, M. Géniteau-Legendre, and A. Servin. 2000. Rotavirus infection induces intracellular calcium concentration increase in human intestinal epithelial cells: role in microvillar actin alteration. J. Virol. 74:2323-2332[Abstract/Free Full Text].
4.	Denker, B. M., and S. K. Nigam. 1998. Molecular structure and assembly of the tight junction. Am. J. Physiol. 274:F1-F9.
5.	Dingwell, K. S., and D. C. Johnson. 1998. The herpes simplex virus gE-gI complex facilitates cell-to-cell spread and binds to components of cell junctions. J. Virol. 72:8933-8942[Abstract/Free Full Text].
6.	Dong, Y., C. Q. Y. Zeng, J. M. Ball, M. K. Estes, and A. P. Morris. 1997. The rotavirus enterotoxin NSP4 mobilizes intracellular calcium in human intestinal cells by stimulating phospholipase C-mediated inositol 1,4,5-trisphosphate production. Proc. Natl. Acad. Sci. USA 94:3960-3965[Abstract/Free Full Text].
7.	Estes, M. K. 1996. Rotaviruses and their replication, p. 1329-1352. In B. N. Fields, D. M. Knipe, and P. M. Howley (ed.), Fields virology, 3rd ed. Lippincott-Raven Publishers, Philadelphia, Pa.
8.	Finlay, B. B., and S. Falkow. 1997. Common themes in microbial pathogenicity revisited. Microb. Mol. Biol. Rev. 61:136-169[Abstract].
9.	Furuse, M., T. Hirase, M. Itoh, A. Nagafuchi, S. Yonemura, S. Tsukita, and S. Tsukita. 1993. Occludin: a novel integral membrane protein localizing at tight junctions. J. Cell Biol. 123:1777-1788[Abstract/Free Full Text].
10.	Geiger, B., and O. Ayalon. 1992. Cadherins. Annu. Rev. Cell Biol. 8:307-332[CrossRef].
11.	Grasset, E., M. Pinto, E. Dussaulx, A. Zweibaum, and J.-F. Desjeux. 1984. Epithelial properties of the human colonic carcinoma cell line Caco-2: electrical parameters. Am. J. Physiol. 247:C260-C267[Abstract/Free Full Text].
12.	Heintzelman, M. B., and M. S. Mooseker. 1992. Assembly of the intestinal brush border cytoskeleton. Curr. Top. Dev. Biol. 26:93-122[Medline].
13.	Jourdan, N., J.-P. Brunet, C. Sapin, A. Blais, J. Cotte-Laffitte, F. Forestier, A.-M. Quero, G. Trugnan, and A. Servin. 1998. Rotavirus infection reduces sucrase-isomaltase expression in human intestinal epithelial cells by perturbing protein targeting and organization of microvillar cytoskeleton. J. Virol. 72:7228-7236[Abstract/Free Full Text].
14.	Jourdan, N., J. Cotte-Laffitte, F. Forestier, A. L. Servin, and A. M. Quero. 1995. Infection of cultured human intestinal cells by monkey RRV and human Wa rotavirus as a function of intestinal epithelial cell differentiation. Res. Virol. 146:325-331[CrossRef][Medline].
15.	Jourdan, N., M. Maurice, D. Delautier, A. M. Quero, A. L. Servin, and G. Trugnan. 1997. Rotavirus is released from the apical surface of cultured human intestinal cells through nonconventional vesicular transport that bypasses the Golgi apparatus. J. Virol. 71:8268-8278[Abstract].
16.	Kapikian, A. Z., and R. M. Shanock. 1996. Rotaviruses, p. 1657-1708. In B. N. Fields, D. M. Knipe, and P. M. Howley (ed.), Fields virology, 3rd ed. Lippincott-Raven Publishers, Philadelphia, Pa.
17.	Louvard, D., M. Kedinger, and H. P. Hauri. 1992. The differentiating intestinal epithelial cell: establishment and maintenance of functions through interactions between cellular structures. Annu. Rev. Cell Biol. 8:157-195[CrossRef].
18.	Madara, J. L. 1988. Tight junction dynamics: is paracellular transport regulated? Cell 53:497-498[CrossRef][Medline].
19.	Matter, K., and H. P. Hauri. 1991. Intracellular transport and conformational maturation of intestinal brush border hydrolases. Biochemistry 30:1916-1923[CrossRef][Medline].
20.	McCarthy, K. M., I. B. Skare, M. C. Stankewich, M. Furuse, S. Tsukita, R. A. Rogers, R. D. Lynch, and E. E. Schneeberger. 1996. Occludin is a functional component of the tight junction. J. Cell Sci. 109:2287-2298[Abstract].
21.	Pereira, L., E. Maidji, S. Tugisov, and T. Jones. 1995. Deletion mutants in human cytomegalovirus glycoprotein US9 are impaired in cell-cell transmission and in altering tight junctions of polarized human retinal pigment epithelial cells. Scand. J. Infect. Dis. 99:82-87.
22.	Peterson, M. D., and M. S. Mooseker. 1993. An in vitro model for the analysis of intestinal brush border assembly. I. Ultrastructural analysis of cell contact-induced brush border assembly in Caco-2_BBe cells. J. Cell Sci. 105:445-460[Abstract].
23.	Pinto, M., S. Robine-Leon, M. D. Appay, M. Kedinger, N. Triadou, E. Dussaulx, B. Lacroix, P. Simon-Aussman, K. Haffen, J. Fogh, and A. Zweibaum. 1983. Enterocyte-like differentiation and polarization of the human colon carcinoma cell line Caco-2 in culture. Biol. Cell. 47:323-330.
24.	Salas, P. J. I., M. L. Rodriguez, A. L. Viciana, D. E. Vegas-Salas, and H. P. Hauri. 1997. The apical submembrane cytoskeleton participates in the organization of the apical pole in epithelial cells. J. Cell Biol. 137:359-375[Abstract/Free Full Text].
25.	Sears, C. L., and J. B. Kaper. 1996. Enteric bacterial toxins: mechanisms of action and linkage to intestinal secretion. Microbiol. Rev. 60:167-215[Free Full Text].
26.	Tian, P., M. K. Estes, Y. Hu, J. M. Ball, C. Q. Y. Zeng, and W. P. Schilling. 1995. The rotavirus nonstructural glycoprotein NSP4 mobilizes Ca²⁺ from the endoplasmic reticulum. J. Virol. 69:5763-5772[Abstract].
27.	Tucker, S. P., C. L. Thornton, E. Wimmer, and R. W. Compans. 1993. Bidirectional entry of poliovirus into polarized epithelial cells. J. Virol. 67:29-38[Abstract/Free Full Text].
28.	van Ijzendoorn, S. C. D., and D. Hoekstra. 1999. The subapical compartment: A novel sorting centre? Trends Cell Biol. 9:144-149[CrossRef][Medline].
29.	Weber, E., G. Berta, A. Tousson, P. St. John, M. W. Green, U. Gopalokrishnan, T. Jilling, E. J. Sorscher, T. S. Elton, D. R. Abrahamson, and K. L. Kirk. 1994. Expression and polarized targeting of Rab3 isoform in epithelial cells. J. Cell Biol. 125:583-594[Abstract/Free Full Text].
30.	Zabriskie, T. M., J. A. Klocke, C. M. Ireland, A. H. Marcus, T. F. Molinski, D. J. Faulkner, C. Xu, and J. C. Clardy. 1986. Jaspamide, a modified peptide from Jaspis sponge, with insecticidal and antifungal activity. J. Am. Chem. Soc. 108:3123-3124[CrossRef].
31.	Zahraoui, A., G. Joberty, M. Arpin, J. J. Fontaine, R. Hellio, A. Tavitian, and D. Louvard. 1994. A small rab GTPase is distributed in cytoplasmic vesicles in non polarized cells but colocalizes with the tight junction marker ZO-1 in polarized epithelial cells. J. Cell Biol. 124:101-115[Abstract/Free Full Text].
32.	Zweibaum, A., M. Laburthe, E. Grasset, and D. Louvard. 1991. Use of cultured cell lines in studies of intestinal cell differentiation and function, p. 223-255. In S. J. Schultz, M. Field, and R. A. Frizell (ed.), Handbook of physiology. The gastrointestinal system, vol. 4. American Physiological Society, Bethesda, Md.