The tight junction protein complex undergoes rapid and continuous molecular remodeling at steady state

doi:10.1083/jcb.200711165

Published online May 12, 2008
doi:10.1083/jcb.200711165
The Journal of Cell Biology, Vol. 181, No. 4, 683-695
The Rockefeller University Press, 0021-9525 $30.00
© 2008 Shen et al.

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The tight junction protein complex undergoes rapid and continuous molecular remodeling at steady state

Le Shen, Christopher R. Weber, and Jerrold R. Turner

Department of Pathology, The University of Chicago, Chicago, IL 60637

Correspondence to Jerrold R. Turner: jturner{at}bsd.uchicago.edu

The tight junction defines epithelial organization. Structurally,the tight junction is comprised of transmembrane and membrane-associatedproteins that are thought to assemble into stable complexesto determine function. In this study, we measure tight junctionprotein dynamics in live confluent Madin–Darby caninekidney monolayers using fluorescence recovery after photobleachingand related methods. Mathematical modeling shows that the majorityof claudin-1 (76 ± 5%) is stably localized at the tightjunction. In contrast, the majority of occludin (71 ±3%) diffuses rapidly within the tight junction with a diffusionconstant of 0.011 µm²s^–1. Zonula occludens-1 moleculesare also highly dynamic in this region, but, rather than diffusingwithin the plane of the membrane, 69 ± 5% exchange betweenmembrane and intracellular pools in an energy-dependent manner.These data demonstrate that the tight junction undergoes constantremodeling and suggest that this dynamic behavior may contributeto tight junction assembly and regulation.

Abbreviations used in this paper: FLIP, fluorescent loss inphotobleaching; MBCD, methyl-β-cyclodextrin; PA, photoactivable;TER. transepithelial resistance; ZO, zonula occludens.

© 2008 Shen et al. This article is distributed under theterms of an Attribution–Noncommercial–Share Alike–NoMirror Sites license for the first six months after the publicationdate (see http://www.jcb.org/misc/terms.shtml). After six monthsit is available under a Creative Commons License (Attribution–Noncommercial–ShareAlike 3.0 Unported license, as described at http://creativecommons.org/licenses/by-nc-sa/3.0/).

Introduction

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Abstract
Introduction
Results
Discussion
Materials and methods
References

The epithelial tight junction, or zonula occludens (ZO), separatesapical and basolateral plasma membrane domains and serves asa selectively permeable barrier to regulate paracellular diffusion(Farquhar and Palade, 1963; Claude and Goodenough, 1973). Morethan 30 integral and peripheral membrane proteins targeted tothe tight junction have been identified (Stevenson et al., 1986;Citi et al., 1988; Furuse et al., 1993, 1998; Itoh et al., 1993;Jesaitis and Goodenough, 1994; Zahraoui et al., 1994; Dodane and Kachar, 1996;Haskins et al., 1998; Izumi et al., 1998; Martin-Padura et al., 1998;Chen and Lu, 2003; Hurd et al., 2003; Kohler et al., 2004; Ohnishi et al., 2004;Tomson et al., 2004; Ikenouchi et al., 2005). ZO-1, the firsttight junction protein identified (Stevenson et al., 1986),includes three tandem PDZ protein interaction domains that mediatebinding to other plaque and transmembrane tight junction proteins(Beatch et al., 1996; Haskins et al., 1998; Itoh et al., 1999;Ebnet et al., 2000; Bezprozvanny and Maximov, 2001; Hamazaki et al., 2002;Fanning et al., 2007). In addition, ZO-1 and the structurallyrelated proteins ZO-2 and -3 interact with perijunctional filamentousactin both directly and indirectly through other proteins suchas ${alpha}$ -catenin and cingulin, thereby anchoring the tight junctionto the cytoskeleton (Rajasekaran et al., 1996; Itoh et al., 1997;Fanning et al., 1998; Cordenonsi et al., 1999; Wittchen et al., 1999;Bazzoni et al., 2000; Fanning et al., 2002). Claudins bind ZO-1,-2, and -3 via a C-terminal PDZ-binding motif (Itoh et al., 1999).The importance of this interaction is demonstrated by the associationof a ZO-2 mutation that reduces claudin binding with familialhypercholanemia (Carlton et al., 2003) as well as a study ofcells lacking ZO-1 and -2, which fail to recruit claudins anddo not develop barrier function (Umeda et al., 2006).

Together with the functional importance of claudin–ZO-1/-2interactions, the multitude of interactions among tight junctionproteins demonstrated by in vitro binding assays and coimmunoprecipitationstudies (Balda et al., 1996; Fanning et al., 1998; Mitic and Anderson, 1998;Cordenonsi et al., 1999; Bazzoni et al., 2000; Kale et al., 2003;Van Itallie and Anderson, 2004; Li et al., 2005) has led tothe hypothesis that the steady-state tight junction is a largecomplex maintained by abundant protein cross-links. By analogy,this model is supported by a recent study of the adherens junctionthat demonstrates that epithelial cadherin, ${alpha}$ -catenin, and β-cateninform a stable complex with one another (Yamada et al., 2005).However, only one study has directly assessed the dynamic behaviorof tight junction proteins in the absence of external stimuli.That work concluded that fluorescent-tagged claudin-1 expressedin fibroblasts is not mobile within the tight junction–likestrands that develop in these cells (Sasaki et al., 2003). Thus,the tight junction is widely viewed as a static structure understeady-state conditions.

Our study of fluorescent tight junction fusion proteins expressedin epithelial monolayers raised the possibility of occludinflow within the tight junction (Shen and Turner, 2005). Althoughthis observation could represent the flow of tight junctionprotein complexes, as occurs for cadherin–catenin complexesat the adherens junction, it could also suggest that bindinginteractions at the tight junction are far more dynamic thanpreviously thought. Therefore, we directly assessed proteindynamics within the tight junction and now show that tight junctionproteins are highly dynamic in resting steady-state epithelialmonolayers. Each protein studied displays distinct dynamic behavior,reflecting different mechanisms of protein movement. These datademand that our current model of tight junction molecular structurebe revised and may provide a basis for understanding the mechanismsthat allow rapid tight junction remodeling in response to extracellularstimuli.

Results

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Abstract
Introduction
Results
Discussion
Materials and methods
References

The multiprotein complex within the tight junction is dynamic at steady state
We recently reported the generation and validation of ZO-1,occludin, and claudin-1 fluorescent fusion proteins using EGFPand monomeric RFP1 (Shen and Turner, 2005). Each of these fusionproteins is accurately targeted to the tight junction and localizeswith the corresponding endogenous protein, as assessed biochemicallyand morphologically at steady state and in response to stimuli(Shen and Turner, 2005). Moreover, expression of these fusionproteins does not disrupt normal function either in vitro (Shen and Turner, 2005)or in vivo (unpublished data). Therefore, we conclude that thesefluorescent fusion proteins are suitable tools for analysisof tight junction protein dynamics in live cells.

Time-lapse imaging of confluent MDCK epithelial cell monolayersexpressing fluorescent-tagged occludin frequently demonstratedsmall fluctuations in fluorescent intensity despite stable barrierfunction (Shen and Turner, 2005). Although such fluctuationswere not seen in fixed monolayers, they could potentially representimaging artifacts as a result of slight movements of live cellswithin the z plane. To distinguish between artifact and actualmovement of occludin within the tight junction, occludin dynamicswere assessed by monitoring FRAP in confluent monolayers withestablished intercellular junctions. These experiments showthat the majority of tight junction–associated occludinis available for exchange; the mobile fraction is 71 ±3% (Fig. 1, A–C). This observation was unexpected becauseoccludin interacts with many proteins at the tight junction,and the generally accepted model of steady-state tight junctionstructure is of a highly stable multiprotein complex (Chen et al., 1997;Gonzalez-Mariscal et al., 2000; Tsukita et al., 2001; Peng et al., 2003;Seth et al., 2007).

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Figure 1. Individual tight junction proteins display distinct FRAP behaviors in polarized epithelia. (A) EGFP-occludin, –claudin-1, –ZO-1, and –β-actin were studied by FRAP. High magnification images of tight junction segments before and at the indicated time points after photobleaching are shown in the left panels. Corresponding kymographs are shown at the right. (B) Quantitative analysis of FRAP from experiments similar to those shown in B (n = 7, 6, 8, and 6 for occludin, claudin-1, ZO-1, and β-actin, respectively). (C) The mobile fraction and t_1/2 of recovery for each protein were calculated from the recovery curves in B. Error bars represent SEM. Bars, 2 µm.

Because occludin exchange occurs relatively slowly with a t_1/2of 194 ± 19 s, the observed FRAP could represent diffusionof an occludin-containing protein complex within the tight junction.To determine whether tight junction proteins remain bound toone another during exchange, the mobility of ZO-1, which bindsdirectly to occludin, was assessed (Furuse et al., 1994; Fanning et al., 1998;Schmidt et al., 2001; Li et al., 2005). Similar to occludin,69 ± 5% of tight junction–associated ZO-1 is availablefor exchange (Fig. 1, A–C). However, unlike occludin,ZO-1 exchanges more rapidly, with a t_1/2 of only 119 ±21 s. Thus, despite well-characterized binding interactionsbetween ZO-1 and occludin, these data suggest that there isa continuous and rapid dissociation of the majority of eachof these proteins from one another within fully assembled steady-statetight junctions.

The unexpected differences in FRAP kinetics between ZO-1 andoccludin prompted investigation of the exchange kinetics ofclaudin-1 and tight junction–associated β-actin.Claudin-1 has a small mobile fraction of 24 ± 5% (Fig. 1, A–C).Thus, in contrast to occludin and ZO-1, only a minority of tightjunction–associated claudin-1 undergoes exchange at thetight junction. Consistent with reports that actin is highlydynamic at cell–cell contact sites (Yamada et al., 2005),the majority of junction-associated β-actin exchanges rapidlywith a mobile fraction of 98 ± 6% and a t_1/2 of 106 ±18 s. Remarkably, the combination of mobile fraction and t_1/2of fluorescent recovery is unique for each of these four representativeproteins (Fig. 1 C).

Recent work suggests that interactions between claudin proteinsand ZO-1 or -2 are necessary for tight junction assembly (Umeda et al., 2006)and that the stability of steady-state tight junction functionincreases with the duration of postconfluent monolayer culture(Tang and Goodenough, 2003). Therefore, it is possible thatthe aforementioned distinct FRAP behaviors may differ if studiedshortly or at prolonged intervals after confluence. To assessthis, FRAP behaviors of occludin, claudin-1, ZO-1, and β-actinwere measured in monolayers 1, 3, and 10 d after confluence,representing steady-state kinetics present in newly formed (1d), assembled (3 d), and older, stable (10 d) MDCK monolayers(Table I). At 1 d after confluence, the increased ZO-1 mobilefraction and decreased β-actin t_1/2, both relative to valuesat 3 d, suggest that the assembling tight junction is highlydynamic. Although the tight junction is far more stable at 3d after confluence, there is an increase in dynamic behavior10 d after confluence that is manifested as reduced t_1/2 forboth occludin and tight junction–associated β-actin(Table I). Although the significance of this late increase inexchange rates is not clear, it is possible that the structureof the fully mature tight junction is specially modified toallow rapid regulation and fine-tuning of function. In any case,these data demonstrate that in stark disagreement with prevailingmodels of the tight junction, the multiprotein complex withinthe tight junction is highly dynamic at steady state.

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Table I. The dynamic behavior of tight junction proteins changes after confluence

Occludin and ZO-1 exchange are differentially dependent on membrane properties and metabolic energy
To begin to dissect processes that mediate tight junction proteinexchange, monolayers were subjected to treatments that broadlyaffect cellular functions. Initially, the temperature dependenceof occludin and ZO-1 FRAP behavior was assessed (Fig. 2 A). The t_1/2 of occludin and ZO-1 increased in a nearly linear manneras monolayers were chilled from 37 to 14°C (Fig. 2 B). Interestingly,this paralleled transepithelial resistance (TER) increases (Fig. 2 B).In contrast, the occludin mobile fraction decreased only slightlybetween 37 and 17°C but was then sharply reduced at 14°C(Fig. 2 C), suggesting that membrane fluidity might be importantto occludin FRAP behavior. The ZO-1 mobile fraction did notchange significantly as monolayers were cooled from 37 to 14°C(Fig. 2 C).

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Figure 2. Occludin and ZO-1 FRAP are differentially dependent on membrane composition and metabolic energy. (A) FRAP experiments were performed on monolayers of EGFP-occludin– and EGFP–ZO-1–expressing cells incubated at 37 (control), 18, or 14°C, with MBCD, or after ATP depletion. Representative kymographs are shown. (B and C) The t_1/2 and mobile fraction were calculated from FRAP experiments (n $≥$ 5 at each temperature). TER was measured in parallel. (D–F) TER and mobile fraction were determined in monolayers incubated with MBCD or after ATP depletion. n $≥$ 5 for each treatment. Error bars represent SEM. Bar, 2 µm.

Tight junction membranes are enriched in cholesterol, and cholesteroldepletion is known to disrupt barrier function (Lynch et al., 1993;Francis et al., 1999). Thus, it is plausible that the observeddecrease in occludin mobile fraction at 14°C is caused bythe stabilization of cholesterol-rich tight junction membranedomains. To assess the effect of cholesterol depletion on occludinexchange, monolayers were treated with methyl-β-cyclodextrin(MBCD). This reduced TER by 45 ± 1% (Fig. 2 D) and alsosharply reduced the occludin mobile fraction from 73 ±4 to 18 ± 2% (P < 0.01; Fig. 2 E). In contrast, cholesteroldepletion had no effect on ZO-1 FRAP behavior (Fig. 2 F). BecauseMBCD treatment affects both membrane fluidity and vesiculartraffic, these data suggest that occludin may recover by mechanismsthat require these processes.

To further characterize the general mechanisms of occludin andZO-1 exchange, FRAP behavior was assessed in metabolically depletedmonolayers. Reduction of cellular ATP levels by 65 ±5% had no effect on occludin FRAP dynamics, although TER decreasedby 56 ± 2% (Fig. 2 D). In contrast, ATP depletion reducedthe ZO-1 mobile fraction to 36 ± 6% (Fig. 2 F) and theβ-actin mobile fraction to 19 ± 4% (not depicted).These findings show that occludin and ZO-1 dynamics requiredistinct factors. Furthermore, the differential regulation ofoccludin and ZO-1 dynamics by these treatments supports theconclusion that occludin and ZO-1 do not form stable complexesat the tight junction.

The primary mechanism of occludin exchange is diffusion within the plasma membrane
Although fractions of the occludin and ZO-1 available for exchangeare similar, the differences in t_1/2 and sensitivity to perturbationsthat alter membrane function or metabolic energy content suggestthat distinct mechanisms are involved in the observed FRAP behaviorsof these proteins. To preliminarily determine the mechanismof occludin recovery at the tight junction, an $~$ 10-µm segmentof the tight junction was bleached, and recovery was monitoredin the center and edges of this region. Fluorescent recoverybegan at the edges; the center of the bleached region recoveredonly after a lag of $~$ 500 s (Fig. 3 A). Because total occludincontent within the tight junction is constant at steady stateand fluorescent recovery represents the recruitment of unbleachedoccludin molecules into the bleached region, this suggests thatoccludin moves by diffusion within the membrane. Two separateapproaches were used to directly assess occludin movement atsteady state. First, the fluorescent loss in photobleaching(FLIP) technique was used to continuously bleach a small regionof the tight junction. Consistent with occludin diffusion withinthe membrane, loss of fluorescence occurred most rapidly inareas directly adjacent to the bleached region, whereas fluorescenceloss occurred more slowly at greater distances from the bleachedregion (Fig. 3 B). A complementary experiment made use of anoccludin construct containing photoactivatable (PA) GFP (Patterson and Lippincott-Schwartz, 2002).As shown in Fig. 3 C, occludin fluorescence was activated attwo tight junction regions. Although total tight junction fluorescenceremained constant after activation, occludin fluorescence decreasedprogressively in areas of activation and increased in adjacentregions of the tight junction, demonstrating occludin exchangebetween these areas (Fig. 3 C). These data confirm that a principalmode of occludin exchange is diffusion within the membrane.

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Figure 3. Occludin diffuses within tight junction. (A) EGFP-occludin–expressing cells within confluent monolayers were studied by FRAP after photobleaching elongated tight junction regions. Representative images before and at the indicated time points after photobleaching and the corresponding kymograph are shown. (B) The effect of continuous photobleaching of EGFP-occludin within a region of the tight junction is shown in representative images at the indicated times and in the corresponding kymograph. (A and B) Quantitative analysis of the individual sites indicated by the colored arrows is shown at the right. (C) Fluorescence of PA-GFP was activated in the white areas shown in the image collected during activation. Images collected at subsequent times show diffusion of activated PA-GFP–occludin to adjacent regions. The corresponding kymograph and quantitative analysis of the indicated activation region and adjacent region are shown. (D) The effect of continuous intracellular photobleaching of an EGFP-occludin–expressing cell within a confluent monolayer is shown. The kymographs and quantitative analyses show FLIP analysis of tight junction–associated EGFP-occludin within the indicated regions of photobleached and adjacent control cells. Bars: (A and B) 5 µm; (C and D) 10 µm.

The aforementioned experiments do not exclude a contributionof vesicular traffic to the observed occludin FRAP. This iscritical, as occludin has frequently been reported in cytoplasmicvesicles, and endocytic removal of occludin from the tight junctioncorrelates with barrier loss in response to a variety of stimuli(Furuse et al., 1996; Lapierre et al., 1999; Ye et al., 1999;Clayburgh et al., 2005; Shen and Turner, 2005; Schwarz et al., 2007).Intracellular occludin-containing vesicles are readily seenwithin transfected monolayers (Shen and Turner, 2005). However,fluorescent intracellular vesicles were not apparent after activationof tight junction–associated PA-GFP–occludin (Fig. 3 C),suggesting that at steady state, large quantities of occludindo not routinely leave the tight junction to be concentratedin cytoplasmic vesicles. In addition, FLIP analysis showed thatcontinuous photobleaching of the entire intracellular region,sparing the tight junction, only slightly diminished tight junction–associatedoccludin fluorescence (Fig. 3 D). Thus, the recognized intracellularpool of occludin does not exchange rapidly with tight junction–associatedoccludin at steady state. As an additional test of this conclusion,the guanine exchange factor inhibitor brefeldin A, which blocksmultiple exocytic and endocytic processes, was applied to monolayers.Brefeldin A did not inhibit occludin FRAP at the tight junction(unpublished data), confirming that intracellular pools of occludinare not transported to the tight junction at rates sufficientto explain the observed occludin FRAP. However, brefeldin Atreatment decreased epithelial barrier function progressivelyover 2 h, suggesting that membrane traffic may be importantto the maintenance of tight junction integrity. Collectively,these data show that the observed occludin FRAP behavior occursprimarily by diffusion within the membrane and that deliveryof occludin from an intracellular pool participates either toa minor extent or not at all.

Tight junction–associated ZO-1 exchanges with an intracellular ZO-1 pool
As demonstrated in Fig. 1, although ZO-1 and occludin displaysimilar mobile fractions at the tight junction, ZO-1 fluorescencerecovers more rapidly than does occludin. Thus, experimentssimilar to those used to assess the mechanisms of occludin recoverywere used to determine the mechanisms of ZO-1 recovery at thetight junction. In contrast to the results obtained with occludin,similar rates and extents of fluorescent recovery were seenat the center and edges after bleaching an extended $~$ 10-µmregion of the tight junction (Fig. 4 A). In addition, FLIPanalysis showed that continuous bleaching of a small regionof the tight junction resulted in only limited fluorescenceloss in adjacent and distant regions of the tight junction (Fig. 4 B).These data suggest that ZO-1 does not recover by diffusion withinthe membrane but by exchange with a separate pool. This wasunexpected, as it is difficult to detect intracellular ZO-1pools immunohistochemically. Although some nuclear EGFP–ZO-1is present in subconfluent monolayers, which is consistent witha study of nuclear ZO-1 in undifferentiated epithelia (Gottardi et al., 1996),only faint intracellular fluorescence is detectable in cellsexpressing EGFP–ZO-1. FLIP analysis with continuous intracellularbleaching was used to evaluate the presence or absence of intracellularZO-1 pools. This maneuver resulted in progressive decreasesin tight junction–associated ZO-1 fluorescence (Fig. 4 C).As these experiments were performed only on confluent monolayerswhere no nuclear ZO-1 is detected, the intracellular pool ofZO-1 is likely cytoplasmic. Tight junction–associatedZO-1 fluorescent loss measured by FLIP occurs with a t_1/2 of89 ± 17 s, similar to the t_1/2 of 119 ± 21 s forexchange measured by FRAP. Therefore, these data demonstratethat a large fraction of tight junction–associated ZO-1exchanges continuously with an intracellular pool. These studiesalso show that a small nonexchangeable pool of ZO-1 exists atthe tight junction. The interactions that anchor this subsetof ZO-1 at the tight junction are not defined, but this nonexchangeablepool increases between 1 and 3 d after confluence (Table I),suggesting that anchoring is related to the process of tightjunction maturation.

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Figure 4. Tight junction–associated ZO-1 exchanges with an intracellular pool. (A) EGFP–ZO-1–expressing cells within confluent monolayers were studied by FRAP after photobleaching elongated tight junction regions. Representative images before and at the indicated times after photobleaching and the corresponding kymograph are shown. (B) The effect of continuous photobleaching of EGFP–ZO-1 within a region of the tight junction is shown in representative images at the indicated times and in the corresponding kymograph. (A and B) Quantitative analysis of the individual sites indicated by the colored arrows is shown at the right. (C) The effect of continuous intracellular photobleaching of an EGFP–ZO-1–expressing cell within a confluent monolayer is shown. The kymograph and quantitative analysis show tight junction–associated EGFP–ZO-1 fluorescence within the indicated tight junction region of a photobleached cell. Bars: (A and B) 5 µm; (C) 10 µm.

Claudin-1 exchange occurs by limited diffusion within the tight junction
In contrast to occludin and ZO-1, claudin-1 exhibits littlefluorescent recovery. To assess the mechanisms of claudin-1exchange, FLIP experiments similar to those described for occludinand ZO-1 were performed. Continuous bleaching of a small regionof the tight junction showed rapid loss of claudin-1 fluorescencein the immediately adjacent area but not at more distant regions(Fig. 5 A). This is consistent with the limited mobile fractionobserved in the initial claudin-1 FRAP experiments and suggeststhat claudin-1 also exchanges by diffusion within the tightjunction. Continuous intracellular photobleaching had no significanteffect on tight junction–associated claudin-1 fluorescence(Fig. 5 B), suggesting that exchange between the tight junctionand intracellular claudin-1 pools is minimal during the intervalof these experiments.

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Figure 5. Limited claudin-1 exchange occurs by diffusion within the tight junction. (A) EGFP–claudin-1–expressing cells within confluent monolayers were studied by continuous photobleaching of a region of the tight junction. Representative images at indicated times and the corresponding kymograph show the effect on tight junction fluorescence. Quantitative analysis of the individual sites indicated by the colored arrows is shown at the right. (B) The effect of continuous intracellular photobleaching of an EGFP–claudin-1–expressing cell within a confluent monolayer is shown. The kymograph and quantitative analysis shows tight junction–associated EGFP–claudin-1 fluorescence within the indicated region of a photobleached cell before and at intervals after photobleaching. (C) High magnification images and corresponding kymograph of EGFP–claudin-1^YV are shown. The mobile fraction and t_1/2 of wild-type EGFP–claudin-1 and EGFP–claudin-1^YV are shown in the graph at the right. Bars: (A) 5 µm; (B) 10 µm; (C) 2 µm.

The aforementioned data demonstrate that the majority of claudin-1is immobile at the tight junction. Although the majority ofZO-1 at the tight junction is exchangeable, the mobile fractionis $~$ 70% in monolayers with fully assembled tight junctions (Table I),suggesting that a small but significant fraction of tight junction–associatedZO-1 is nonexchangeable. Therefore, it is possible that theimmobile pool of tight junction–associated claudin-1 isanchored by binding to nonexchangeable ZO-1 molecules. To explorethis possibility, an EGFP–claudin-1 mutant lacking theC-terminal YV motif necessary for PDZ binding was expressedin MDCK cells. Although trafficking of EGFP–claudin-1^YVto the tight junction is defective, localization to cell contactsites does occur in some cells. Remarkably, tight junction–associatedEGFP–claudin-1^YV displayed a mobile fraction of 13 ±2%, which is significantly lower than that of wild-type EGFP–claudin-1(P < 0.05). The t_1/2 of EGFP–claudin-1^YV was similarto that of wild-type EGFP–claudin-1 (Fig. 5 C). Thus,although it is clear that the PDZ-binding motif of claudin-1is important for initial delivery, these data suggest that interactionsrequiring the C-terminus YV are not necessary for anchoringthe majority of claudin-1 at the tight junction.

Quantitative modeling of tight junction protein exchange processes
To test the qualitative conclusions developed above and mathematicallymodel tight junction protein exchange, MDCK cells were simulatedas cylinders. Based on their observed distributions, occludin,claudin-1, and ZO-1 were distributed among the lateral membrane,tight junction, and intracellular compartments (Table II). The mobility of each protein was defined based on the physicaldata shown in Figs. 1–4 . Small area FRAP, large area FRAP,tight junction FLIP, and intracellular FLIP were performed byvarying location, duration, and intensity of the virtual laserpulse without altering mobility parameters for each protein(Fig. 6).

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Table II. Parameters that define tight junction protein dynamic behavior in computer simulations

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Figure 6. In silico simulations accurately model tight junction protein dynamic behavior. Computer models were established to predict tight junction protein dynamics (pink and cyan lines in A–L) and were compared with experimental data (red and blue symbols in A–L) for occludin (A–D), claudin-1 (E–H), and ZO-1 (I–L). Small area FRAP (A, E, and I), large area FRAP (B, F, and J), tight junction FLIP (C, G, and K), and intracellular FLIP experiments (D, H, and L) are compared. The models at the left show the assumptions required for the simulation to fit the experimental data. Specific values are given in Table II.

To test whether simple diffusion within the tight junction issufficient to account for the observed occludin behavior inFRAP and FLIP experiments, a model was developed with occludinlocalized only at the tight junction (unpublished data). Insmall area FRAP experiments ( $~$ 3 µm), 89% of observed occludinrecovery at 600 s could be explained using simple diffusionwithin the tight junction and a diffusion constant of 0.011µm²s^–1 (Table II). However, this simulation didnot accurately model larger area FRAP and tight junction–bleachingFLIP experiments. To improve the simulation, a lateral membranepool of occludin was included. This pool was modeled to represent20% of total cellular occludin and was allowed to exchange withtight junction–associated occludin according to the followingequation: Formula

Using the determined rate constants (Table II), this simulation accurately modeledrecovery within large and small photobleached areas (Fig. 6, A and B).Including lateral membrane occludin in the model also allowedaccurate simulation of FLIP experiments in which a region ofthe tight junction was bleached continuously (Fig. 6 C). Althoughit is clear from imaging experiments that an intracellular poolof occludin is frequently present, it was not necessary to includethis component in the models, which is consistent with the conclusionthat intracellular occludin pools do not contribute significantlyto the observed FRAP and FLIP behaviors. This is confirmed byFLIP with continuous intracellular bleaching (Fig. 6 D). Incontrast, the exchange of lateral membrane– and tightjunction–associated occludin is necessary for the simulationsto accurately model the physical observations, suggesting thatthis exchange does contribute to FRAP and FLIP behaviors andthat lateral membrane occludin may diffuse more rapidly thantight junction occludin. An immobile fraction is not necessaryfor the accurate modeling of occludin dynamic behavior, suggestingthat the observed immobile fraction may reflect technical limitationsrather than physical retention.

The t_1/2 of claudin-1 recovery in small area FRAP experimentswas similar to that of occludin (Fig. 1). Thus, claudin-1 exchangewas modeled with a diffusion constant of 0.011 µm²s^–1,which is identical to that used for occludin. An immobile fractionrepresenting 60% of total claudin-1 was included to model thelarge immobile fraction observed experimentally. This modelaccurately simulates small (Fig. 6 E) and large (Fig. 6 F) areaFRAP experiments. As an alternative to a large claudin-1 immobilefraction, models in which the diffusion constant for claudin-1was reduced were developed. These were able to display recoveryat 600 s but did not accurately represent the experimentallydetermined t_1/2 of claudin-1 recovery. Moreover, the model includinga large claudin-1 immobile fraction accurately simulated FLIPexperiments bleaching tight junction (Fig. 6 G) and intracellularregions (Fig. 6 H). Thus, the simulation suggests that tightjunction–associated claudin-1 and occludin recover bydiffusion within the membrane at similar rates. However, incontrast to occludin, claudin-1 has a prominent immobile fraction.

As suggested by the physical data, ZO-1 could not be modeledby simple diffusion within membrane compartments. The physicalobservations that prevented such modeling were that (1) recoverywithin different parts of photobleached areas occurred uniformly;(2) overall recovery rates after bleaching large and small areaswere identical; and (3) tight junction–associated ZO-1fluorescence decreased after continuous intracellular photobleaching.To model the dynamic behavior of ZO-1, the exchange betweentight junction and intracellular pools was allowed to occuras described by the following equation: Formula This required 60% of ZO-1 to be cytosolic, withthe remaining 40% localized to the tight junction and dividedinto exchangeable and nonexchangeable pools (Table II). Thismodel accurately simulated small (Fig. 6 I) and large (Fig. 6 J)area FRAP experiments. The model also predicts the observedsmall 9% decay in regions adjacent to the photobleached regionin FLIP experiments (Fig. 6 K) as well as the large decreasesin tight junction fluorescence seen in intracellular FLIP experiments(Fig. 6 L). Therefore, this model accurately simulates all observedZO-1 behavior on the basis of exchange between tight junctionand intracellular pools without any diffusion within the tightjunction. Notably, a nonexchangeable pool at the tight junctionis required to accurately model ZO-1 behavior.

Discussion

Top
Abstract
Introduction
Results
Discussion
Materials and methods
References

The explosion in recognized tight junction–associatedproteins and identification of interactions between these proteinshas led to the widespread agreement that the tight junctionis a complex of multiple cross-linked proteins (Tsukita et al., 2001;Peng et al., 2003; Anderson et al., 2004). This has led to thedevelopment of a model in which assembled tight junctions inintact steady-state epithelia are static and is consistent withobservations of stable structure and barrier function over time.

However, relatively little direct evidence supports this view.For example, behavior of fluorescent-tagged claudin proteinshas been studied to only a limited degree in epithelial cellsand fibroblasts. In the latter, which do not form tight junctions,claudin proteins assemble into long fibrils within the plasmamembrane (Sasaki et al., 2003). Although these strands interactwith one another and frequently move within the plasma membrane,FRAP analysis showed that claudin-1 within these strands isimmobile (Sasaki et al., 2003). This observation lent supportto the belief that proteins within the tight junction are immobileor static.

The data presented here directly contradict the static modelof tight junction structure. One piece of evidence supportingthis conclusion is that each of the tight junction–associatedproteins studied displays distinct dynamic behaviors and mechanismsof exchange. Approximately 70% of tight junction–associatedZO-1 and occludin are each present within the mobile fraction.This might imply that they traffic as a complex. However, subsequentinvestigation demonstrated that the rates and mechanisms ofexchange differ for these proteins. Therefore, they do not exchangein complex with one another. Although only 24% of claudin-1is in the mobile fraction, a number far greater than that suggestedby experiments in fibroblasts, it should be noted that thisalso indicates that the majority of tight junction–associatedclaudin-1 resides within an immobile pool. The interactionsthat anchor claudin-1 at the tight junction remain to be determined,but the experiments using claudin-1^YV suggest that stable bindingbetween claudin-1 and PDZ domains of ZO-1, -2, and other tightjunction proteins are not required. In fact, interaction betweenthe claudin-1 C terminus and PDZ domains may promote claudin-1exchange within the tight junction, as claudin-1^YV has a smallermobile fraction than wild-type claudin-1. Consistent with theconclusion that interactions with endogenous full-length claudinor other proteins stabilizes EGFP–claudin-1^YV at the tightjunction, a previous study has shown that claudin-1–EGFP,in which EGFP placement at the C terminus obstructs interactionswith ZO-1, displays limited exchange within the tight junction–likestrands that develop in fibroblasts (Sasaki et al., 2003). Nonetheless,interactions between the claudin-1 C terminus and PDZ domainsare important in directing claudin-1 to localize at the tightjunction, as claudin-1^YV protein trafficking to cell contactsites was clearly defective.

The data clearly demonstrate that the majority of tight junction–associatedZO-1, occludin, claudin-1, and β-actin do not remain boundto one another at steady state. How can a model of tight junctionstructure be developed to accommodate these new data? One pointthat must be considered is that 31% of tight junction–associatedZO-1 does not exchange over the course of these FRAP and FLIPexperiments. Together with the mathematical modeling of ZO-1behavior, which required the inclusion of a nonexchangeablepool to accurately simulate the physical data, these data suggestthat a stable pool of ZO-1 exists at the tight junction. Althoughthe functional differences between exchangeable and nonexchangeableZO-1 and the relevance of these pools to tight junction functionremain to be determined, the studies of general perturbations,including temperature modulation, cholesterol chelation, andATP depletion, make it clear that any relationships betweenFRAP behavior and barrier function must be complex and dependenton many factors. Similar questions may be asked about occludindiffusion within the tight junction membrane, although controversyremains regarding the function of this protein (Furuse et al., 1993;Chen et al., 1997; Sakakibara et al., 1997; Van Itallie and Anderson, 1997;Wong and Gumbiner, 1997; Li and Mrsny, 2000; Saitou et al., 2000;Kuwabara et al., 2001; Schulzke et al., 2005; Yu et al., 2005).It is also likely that the constant movement of proteins withinthe tight junction and the observed exchange of these proteinswith extra-tight junction pools are important to the rapid structuraland functional responses to stimuli. In the absence of suchplasticity, it is perhaps hard to understand how barrier functioncan be modified in minutes.

In conclusion, the data presented here show that each of theproteins studied is surprisingly dynamic at the tight junctionand that these dynamics are kinetically distinct as a resultof different mechanisms of exchange. These results demand thatthe prevailing model of tight junction structure be revisedto incorporate the idea that interactions between tight junctionproteins are transient and characterized by continuous engagementand release. Future characterization of the structural domainsand elements that control the dynamic behaviors of tight junctionproteins promises to finally provide molecular characterizationof tight junction regulation.

Materials and methods

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Abstract
Introduction
Results
Discussion
Materials and methods
References

Plasmids
EGFP–β-actin and EGFP–claudin-1 constructswere generated as reported previously (Shen and Turner, 2005).EGFP–claudin-1^YV was created by site-directed mutagenesisto create a premature stop codon (Stratagene). EGFP- and PA-GFP–taggedoccludin were generated by PCR amplification and cloning ofthe coding region of human occludin (a gift from R.J. Mrsny,Cardiff University, Cardiff, UK) into KpnI–XbaI sitesof pEGFP-C1 (Clontech Laboratories, Inc.) and PA-GFP (a giftfrom J. Lippincott-Schwartz, National Institute of Child Healthand Human Development, National Institutes of Health, Bethesda,MD) vectors in frame with EGFP or PA-GFP. EGFP–ZO-1 wasgenerated by first inserting KpnI sites flanking the codingregion of human ZO-1 (a gift from J. Anderson and A. Fanning,University of North Carolina at Chapel Hill, Chapel Hill, NC)and then cloning the coding region into the KpnI site of pEGFP-C1in frame with EGFP. The integrity of all plasmids was verifiedby restriction digestion and direct sequencing.

FRAP and FLIP
MDCK cells were transfected and maintained as described previously(Shen and Turner, 2005) and were studied 3 d after confluence,except where otherwise indicated. Monolayers were transferredto bicarbonate-free HBSS supplemented with 15 mM Hepes, pH 7.4,at 37°C and mounted on a custom-designed temperature-controlledstage (Brook Industries) at 37°C for 30 min to allow equilibration.Confocal scanning light microscopy was performed by using amicroscope system (TCS SP2 AOBS; Leica) with a 63x NA 1.40 oilimmersion objective and a pinhole between 1 and 2 AU. EGFP fusionproteins were excited using the argon 488-nm laser line andemission gated between 490 and 530 nm. FRAP experiments wereperformed using the FRAP module of confocal software (Leica).A region of interest to be bleached was defined, and maximumlaser power at the appropriate wavelength for an empiricallydetermined number of iterations was used to bleach signals.Bleaching time was usually <10 s, resulting in bleachingthroughout the full thickness of the tight junction. After bleaching,images were taken within the same focal plane at regular intervals(between 2 and 30 s) to monitor fluorescence recovery.

To test the continuity of different cellular pools of tightjunction proteins, FLIP experiments were performed using theFLIP module of the confocal software. Observation and photobleachingwere performed in the same scan for different regions of thescanning field. Continuous scanning was performed with no delaybetween scans for 5–15 min. For tight junction bleaching,a small area at the tight junction was continuously bleachedat full laser power. For intracellular bleaching, a large areathat encompasses $~$ 80% of the intracellular area at the tightjunction level was continuously bleached at full laser power.In either case, the remainder of the field was observed usingthe laser at $~$ 10% power.

For inhibitor experiments, monolayers were treated with appropriatedrugs in HBSS for 1 h before use. ATP depletion experimentswere performed using glucose-free HBSS containing 2 mM 2-D-deoxy-glucose,1 mM 2,4-dinitrophenol, and 10 mM NaN₃ to inhibit ATP generation.MBCD was used at 5 mM.

Fluorescence quantification and data analysis
Time series of image files were opened and converted to multipageimage files using Image J (National Institutes of Health). Imageanalyses were performed by using MetaMorph 7 (MDS AnalyticalTechnologies). Regions of interest were drawn, and the meanfluorescence intensity of each region was logged for each timepoint. For small area FRAP experiments, regions of interestwere drawn at the center of the bleach region, which occupiesa fraction of the whole bleaching area.

For all FRAP experiments, mean fluorescence in bleached areaswas corrected for observation bleaching using a distant areaof the tight junction for reference. The corrected data werefit to the equation below, which assumes that recovery involvesa single coefficient (Yguerabide et al., 1982):

Formula
Preliminary analyses showed that higher order equationsdid not improve the quality of fit. Using experimental data,the value for t_1/2 was calculated with nonlinear regressionwithout any constraints using Sigma Plot (SPSS, Inc.). Mobilefraction was determined as

Formula

Computer simulation
A three-dimensional computer simulation was created to modelthe results of FRAP and FLIP experiments using the Virtual Cellbiological modeling framework (www.vcell.org). Cells were modeledas cylinders with a diameter of 30 µm and a height of10 µm to approximate the measured physical dimensionsof MDCK cells in confluent monolayers. The tight junction wasmodeled as a 1-µm thick band. The model includes separatetight junction and extra tight junction membrane domains andan intracellular pool. A spatially defined laser was used torapidly bleach 90% of fluorescent molecules within 1 s, andmolecules diffused according to defined rate constants and spatialconstraints. Simulations used 10-ms time steps with a spatialsimulation mesh of 1 µm in the z axis and 0.6 µmin the xy axis. Fluorescent intensities were normalized to initialconditions. After assignment of different constants and restraints,only the location, duration, and intensity of the laser pulsewere altered to simulate the various FRAP and FLIP experimentsfor each protein. The models used and data obtained can be accessedat http://vcell.org/applications/published%20_models.html.

TER measurements
MDCK cells were plated at confluent density on semipermeablesupports (Corning). TER was measured after 3 d using electrodeswith a voltohmeter (EVOM; World Precision Instruments).

Statistical analysis
All data are presented as mean ± SEM and represent atleast three independent experiments. P-value was determinedby two-tailed t test and was considered to be significant ifP $≤$ 0.05.

Acknowledgments

We are indebted to Drs. James Anderson, Vytas Bindokas, AlanFanning, Christine Labno, Jennifer Lippincott-Schwartz, StephenMeredith, and Randall Mrsny for generously sharing advice andessential reagents.

This work was supported by National Institutes of Health grantsR01DK061931 and R01DK068271 and by The University of ChicagoCancer Center grant P30 CA14599. Virtual Cell software is supportedby the National Resource for Cell Analysis and Modeling.

Submitted: 30 November 2007

Accepted: 11 April 2008

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Results
Discussion
Materials and methods
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