|
|
|
|
|
|
|
||
© The Rockefeller University Press,
0021-9525/2000//31 $5.00
The Journal of Cell Biology, Volume 151, Number 5,
, 2000 31-36
Mini-Review |
Tight Junction, a Platform for Trafficking and Signaling Protein Complexes
© 2000 The Rockefeller University Press
Epithelial cells are associated laterally in a sheet, with the apical surface facing the lumina, often covered by microvilli, and the basolateral side underlying connective tissue. Development and maintenance of epithelial polarity require cell–substrate and cell–cell adhesions that promote localized assembly of submembranous cytoskeleton networks and specialized membrane intracellular transport pathways. The assembly of tight junctions (TJs) plays a key role in the formation of structurally and functionally distinct basolateral and apical plasma membrane (PM) domains. How are the PM proteins delivered to specialized and polarized cell surface domains? Even though the involvement of v- and t-soluble N-ethylmaleimide–sensitive factor attachment protein receptors (SNAREs) in apical and basolateral PM delivery is now well established, are these proteins sufficient to specify vesicle docking and fusion at sites in the appropriate membrane domains? Recent data highlight TJs as major sites for localization of proteins involved in vesicle docking/targeting and signaling. This review will focus on how TJ constituents contribute to these processes.
 |
Molecular Architecture of TJ, Plasma Membrane Barriers |
|---|
 Top Molecular Architecture of TJ,... Polarized Membrane Traffic in...Two PM Domains—Two SNARE...TJ, a Spatial Landmark...TJ, a Signal Transduction...References |
|---|
Occludin was the first integral membrane protein found concentrated within TJ fibrils. Several pieces of evidence suggest that occludin is involved in the barrier and fence functions of TJs (Tsukita and Furuse 1999). Overexpression of the chicken occludin in MDCK cells increases transepithelial electrical resistance, whereas COOH-terminal truncated occludin increases paracellular flux of small tracers and induces leakage of N-(4,4-difluoro-5,7-dimethyl-4-bora-3a,4a-diaza-S-indacene-3-pentanoyl) sphingosyl phosphocholine (BODIPY)–sphingomyelin from the apical domain (Balda et al. 1996). Introduction of a peptide containing the second extracellular loop of occludin into Xenopus A6 epithelial cells causes a drop in transepithelial electrical resistance and mislocalization of occludin at TJs (Wong and Gumbiner 1997). However, data from several experiments indicate that occludin is not sufficient to generate bona fide TJ strands. For example, differentiated embryonic bodies that were isolated from embryonic stem cells in which the occludin gene was knocked out still developed a normal network of TJ fibrils between adjacent epithelial cells (Saitou et al. 1998). In fact, establishment of TJ strands depends on claudins, which is another recently identified protein family that has at least 18 members. Claudins possess four transmembrane domains and are also localized at the site of close membrane–membrane apposition (kisses) within TJs. Expression of claudins1 and 2 into fibroblasts lacking TJs induces the formation of TJ strands that are morphologically similar to the epithelial TJ strands (Tsukita and Furuse 2000). Analysis of oligodendrocyte-specific protein (OSP/claudin11) KO mice reveals the absence of TJ strands in myelin sheets of oligodendrocytes and sertoli cells (Gow et al. 1999), and paracellin1/claudin16 KO mice show an abnormal paracellular passage of Mg2+ ions (Simon et al. 1999). This finding leads to the proposal that claudins and occludin generate a series of regulated channels within TJ membranes for the passage of ions and small molecules.
The cytoplasmic face of TJs is enriched in many peripheral membrane proteins (Table ). ZO-1, a 220-kD TJ phosphoprotein, is a member of the membrane-associated guanylate kinase domain (GUK) localized at cell–cell contacts (Mitic and Anderson 1998). It contains three PDZ (PSD95, Dlg, and ZO-1), an SH3 domain, and an inactive GUK. PDZ domains are protein–protein interaction modules that recognize motifs of three amino acids at the COOH terminus of transmembrane proteins. ZO-1 may act as a molecular scaffold bringing together many proteins of TJs. ZO-1 binds claudins, occludin, ZO-2, ZO-3, cingulin, and actin (Cordenonsi et al. 1999; Wittchen et al. 1999). It has three PDZ modules that could bind many different protein partners to control the dynamics of TJ assembly. Thus, it is tempting to speculate that the ZO-1/-2/-3 proteins are required for the clustering of claudins and occludin to generate TJ fibrils and, presumably, the pores within these fibrils.
|
|
Polarized Membrane Traffic in Epithelial Cells |
|---|
|
TopMolecular Architecture of TJ,...Polarized Membrane Traffic in...Two PM Domains—Two SNARE...TJ, a Spatial Landmark...TJ, a Signal Transduction...References |
|---|
|
|
Two PM Domains—Two SNARE Machineries? |
|---|
|
TopMolecular Architecture of TJ,...Polarized Membrane Traffic in...Two PM Domains—Two SNARE...TJ, a Spatial Landmark...TJ, a Signal Transduction...References |
|---|
Route A1 involves tetanus neurotoxin (TeNT) insensitive-(TI)VAMP (also called VAMP7). Indeed, TI-VAMP forms SNARE complexes with syntaxin 3, and antibodies against TI-VAMP inhibit delivery of HA to the apical PM (Galli et al. 1998; Lafont et al. 1999). The v-SNARE involved in route B1 has not yet been identified, but transport of VSV-G to the basolateral PM is partially inhibited by TeNT (Ikonen et al. 1995), so it is likely to involve cellubrevin, the only TeNT-sensitive brevin yet characterized in epithelial cells (Galli, T., unpublished observation). Epithelial cells could package together two different v-SNAREs to perform routes AB and BA, one binding to a basolateral syntaxin and one to an apical syntaxin distinct from syntaxin3. Alternatively, they could use one v-SNARE capable of binding both basolateral and apical syntaxins. In contrast to fibroblasts, cellubrevin does not colocalize with transferrin receptor in CaCo-2 cells (Galli et al. 1994, Galli et al. 1998), but it recycles with both the apical and basolateral PMs in MDCK cells (Steegmaier et al. 2000), and it colocalizes with transcytosed proteins, such as IgA in hepatocytes (Calvo et al. 2000). Therefore, cellubrevin is a good candidate for being the v-SNARE of routes BA and/or AB. Endobrevin/VAMP8 recycles with the apical PM in MDCK cells (Steegmaier et al. 2000) so it is expected to play a role in route A2 in these cells. In other epithelial cells, the v-SNARE of A2 is likely to be cellubrevin, because H+ secretion in collecting duct cells (Alexander et al. 1997) and recycling of the H+-ATPase with the apical PM in epididymis and vas deferens (Breton et al. 2000) are sensitive to TeNT. Whereas several of the above data suggest that v- and t-SNAREs function in polarized traffic, the complex case of cellubrevin, which is implicated in different routes, could imply that other factors define cognate docking and fusion sites. For instance, VAP-33, a protein localized in TJs that interacts with VAMP/synaptobrevins and with the cytoplasmic COOH-terminal of occludin (Lapierre et al. 1999), could participate in this process.
|
TJ, a Spatial Landmark for Vesicle Docking |
|---|
|
TopMolecular Architecture of TJ,...Polarized Membrane Traffic in...Two PM Domains—Two SNARE...TJ, a Spatial Landmark...TJ, a Signal Transduction...References |
|---|
A crucial question is what maintains the correct distribution of targeted proteins to one PM domain? A possible answer is suggested by recent studies on Scrib, Dlg, and Lgl, three Drosophila proteins localized to the epithelial septate junctions (the analogue of vertebrate TJs). Loss of function of any of these genes leads to the disruption of cell polarity. These genes show strong genetic interactions, suggesting they are involved in a common pathway to control both cell growth and polarity. Furthermore, Scrib, Dlg, and Lgl are mutually dependent for proper localization, raising the possibility that they physically interact (Bilder et al. 2000). In the Scrib mutants, adherens junction proteins, including armadillo (a β-catenin homologue), are mislocated and found around the cell periphery, and apical transmembrane proteins exhibit unrestricted distribution to both apical and basolateral domains (Bilder and Perrimon 2000). Thus, Scrib is required for maintaining apical membrane proteins at the apical domain, and it may play a role in polarized targeting of vesicles charged with apical proteins. In agreement with this hypothesis, the Lgl homologues in yeast (Sro7) and mammals (tomosyn) bind to PM t-SNAREs Sec9p and syntaxin 1, respectively, which directly promote fusion of transport vesicles with the PM (Fujita et al. 1998; Lehman et al. 1999). An attractive model for the function of Scrib, Dlg, and Lgl could be that the PDZ domains of Scrib and Dlg bind to transmembrane proteins and organize cell surface asymmetry, whereas Lgl locally promotes the assembly of SNARE complexes. The localized assembly of SNAREs at specific sites of the PM would restrict vesicle docking and fusion at these sites.
Scrib, like other leucine-rich repeats and PDZ domain (LAP) proteins, could also bind through its leucine-rich repeats to small GTPases of the Ras family known to play an important role in intracellular transport. Accordingly, PDZ-containing proteins may interact (directly or indirectly) with the Rab/exocyst and contribute to the specificity and accuracy of vesicle-targeting events. We speculate also that the interactions of Rab/exocyst/Lgl/Scrib/Dlg define a checkpoint site at TJs where misrouted proteins could be identified and rerouted to their correct destination.
|
TJ, a Signal Transduction Site |
|---|
|
TopMolecular Architecture of TJ,...Polarized Membrane Traffic in...Two PM Domains—Two SNARE...TJ, a Spatial Landmark...TJ, a Signal Transduction...References |
|---|
isoform. In the nematode Caenorhabditis elegans, Par-3 and Par-6 are implicated in asymmetric cell division. For example, Par-3 mutations cause mislocalization of several asymmetrically distributed proteins, disruption of mitotic spindle orientation and disruption of asymmetric cell division. In epithelial cells, Par3/ASIP localizes to TJs. Overexpression of either Par6, the NH2-terminal part of Par3, or the activated form of Cdc42 leads to mislocalization of ZO-1, indicating that the Cdc42/Par6/Par3/aPKC complex may be involved in maintaining cell–cell contact (Joberty et al. 2000; Lin et al. 2000). The specific binding of activated Cdc42/Rac1 to Par6 links Par6/Par3/aPKC complex to signaling pathways regulating actin cytoskeleton and vesicle targeting. Interestingly, microinjection of Cdc42T22N, a dominant-negative form of Cdc42, into MDCK cells leads to mislocalization of the basolateral membrane protein, gp58 (Kroschewski et al. 1999). Given the ability of Cdc42 to control actin cytoskeleton, it is possible that the Cdc42 mutation causes localized alterations in cortical actin filaments, leading to the loss of gp58's basolateral polarity. This result also suggests that the actin cytoskeleton may help to immobilize a Cdc42-interacting protein required to target basolateral membrane proteins. Control of the dynamics of F-actin rearrangement by the small GTPases Rho, Rac, and Cdc42 points to a role for these GTPases in TJ structure. Indeed, overexpression of activated forms RhoV14 and RacV12 induces the disorganization of TJ strands and a chaotic distribution of ZO-1 and occludin. ZO-1, as well as occludin staining, extends to the base of the cells expressing RhoV14 and RacV12 (Jou et al. 1998). One explanation is that RhoV14 and RacV12 cause dramatic changes in actin–myosin dynamics, leading to an alteration in TJ protein–protein interaction. Hence, the Rho-protein family, by regulating actin organization, could participate in targeting vesicles to the appropriate sites on the PM. Signal transduction at TJs could regulate membrane traffic by phosphorylation of Rab effectors, SNARE proteins, or their partners. For instance, these signaling pathways could play a major role in allowing exocytotic vesicles to reach the apical domain. Several membrane-associated GUKs are involved in organizing signal transduction at TJs. In Drosophila, the Dlg mutation interferes with proliferation control, apical–basal polarity, development of septate junctions, and the ability of cells to differentiate (Woods and Bryant 1991). In subconfluent epithelial cells, ZO-1, as well as symplekin, can be found in the nucleus, which raises the possibility that both proteins may have a role in regulating transcription (Gottardi et al. 1996; Keon et al. 1996). Recently, Balda and Matter 2000 have identified ZONAB, a protein homologous to Y-box transcription factors, which localizes to the nucleus and TJs. ZO-1 and ZONAB control endogenous ErbB-2 expression and regulate the paracellular permeability. These results indicate that ZO-1 is implicated in a signal transduction pathway that leads to the activation of specific gene expression. Expression of two NH2-terminal mutants of ZO-1 (ZO-11–422 and ZO-11–794) cause a dramatic change in cell morphology, reminiscent of an epithelium to mesenchyme transition (Ryeom et al. 2000), suggesting that ZO-1 is involved in regulating epithelial cell differentiation. In addition, it was recently reported that introduction of occludin into Raf-1–transformed Pa-4 epithelial cells results in reacquisition of epithelial phenotype, with formation of functionally intact TJs (Li and Mrsny 2000). These data also suggest that occludin is a key molecule in Raf-1–transformation signaling. Taken together, the results imply that the TJ is a site of signaling.
Based on the studies reviewed here, TJs emerge as a platform used to coordinate multiple cellular processes. TJs function at crossroads of the secretory and signaling routes. They may serve both as a docking domain and probably as a switch station for subsets of proteins and lipids destined to the basolateral and/or the apical PM. At least some of the basolateral and/or apical membrane proteins could be delivered to TJs via the Rab/exocyst/Scrib/Lgl complex. A major challenge for future TJ studies will be to investigate its potential role in organizing and orienting polarized membrane trafficking.
|
Acknowledgments |
|---|
This work was supported by grants from the Association pour la Recherche sur le Cancer (ARC 9923) to A. Zahraoui, and from the Ministère de la Recherche et des Technologies: ACI-Jeunes Chercheurs (no. 5254) to T. Galli.
Submitted: 27 July 2000
Revised: 29 September 2000
Accepted: 3 October 2000
T. Galli's present address is Group of Membrane Traffic and Neuronal Plasticity, INSERM U536, Institut du Fer-à-Moulin, 75005 Paris, France.
|
References |
|---|
|
TopMolecular Architecture of TJ,...Polarized Membrane Traffic in...Two PM Domains—Two SNARE...TJ, a Spatial Landmark...TJ, a Signal Transduction...References |
|---|
Alexander E.A., Shih T. & Schwartz J.H.. H+ secretion is inhibited by clostridial toxins in an inner medullary collecting duct cell line, Am. J. Physiol. Renal.Physiol., 42, 1997, F1054–F1057.
Balda M.S. & Matter K.. The tight junction protein ZO-1 and an interacting transcription factor regulate ErbB-2 expression, EMBO (Eur. Mol. Biol. Organ.) J., 19, 2000, 2024–2033.[Medline]
Balda M.S., Whitney J.A., Flores C., Gonzalez S., Cerejido M. & Matter K.. Functional dissociation of paracellular permeability and transepithelial electrical resistance and disruption of the apical–basolateral intramembrane diffusion barrier by expression of a mutant tight junction membrane protein, J. Cell Biol., 134, 1996, 1031–1049.
Bilder D. & Perrimon N.. Localization of apical epithelial determinants by the basolateral PDZ protein Scribble, Nature., 403, 2000, 676–680.[Medline]
Bilder D., Li M. & Perrimon N.. Cooperative regulation of cell polarity and growth by Drosophila tumor suppressors, Science, 289, 2000, 113–116.
Bock J.B. & Scheller R.H.. SNARE proteins mediate lipid bilayer fusion, Proc. Natl. Acad. Sci. USA., 96, 1999, 12227–12229.
Breton S., Nsumu N.N., Galli T., Sabolic I., Smith P.J. & Brown D.. Tetanus toxin-mediated cleavage of cellubrevin inhibits proton secretion in the male reproductive tract, Am. J. Physiol. Renal. Physiol, 278, 2000, F717–F725.
Calvo M., Pol A., Lu A., Ortega D., Pons M., Blasi J. & Enrich C.. Cellubrevin is present in the basolateral endocytic compartment of hepatocytes and follows the transcytotic pathway after IgA internalization, J. Biol. Chem., 275, 2000, 7910–7917.
Chavrier P. & Goud B.. The role of ARF and Rab GTPases in membrane transport, Curr. Opin. Cell Biol, 11, 1999, 466–475.[Medline]
Cordenonsi M., D'Atri F., Hammar E., Parry D.A., Kendrick-Jones J., Shore D. & Citi S.. Cingulin contains globular and coiled-coil domains and interacts with ZO-1, ZO-2, ZO-3, and myosin, J. Cell Biol, 147, 1999, 1569–1582.
Folsch H., Ohno H., Bonifacino J.S. & Mellman I.. A novel clathrin adaptor complex mediates basolateral targeting in polarized epithelial cells, Cell., 99, 1999, 189–198.[Medline]
Fujita Y., Shirataki H., Sakisaka T., Asakura T., Ohya T., Kotani H., Yokoyama S., Nishioka H., Matsuura Y., Mizoguchi A., Scheller R.H. & Takai Y.. Tomosyna syntaxin-1–binding protein that forms a novel complex in the neurotransmitter release process, Neuron, 20, 1998, 905–915.[Medline]
Galli T., Chilcote T., Mundigl O., Binz T., Niemann H. & De Camilli P.. Tetanus toxin–mediated cleavage of cellubrevin impairs exocytosis of transferrin receptor–containing vesicles in CHO cells, J.Cell Biol., 125, 1994, 1015–1024.
Galli T., Zahraoui A., Vaidyanathan V.V., Raposo G., Tian J.M., Karin M., Niemann H. & Louvard D.. A novel tetanus neurotoxin-insensitive vesicle-associated membrane protein in SNARE complexes of the apical plasma membrane of epithelial cells, Mol. Biol.Cell., 9, 1998, 1437–1448.
Gottardi C.J., Arpin M., Fanning A.S. & Louvard D.. The junction-associated protein, zonula occludens-1, localizes to the nucleus before the maturation and during the remodeling of cell–cell contacts, Proc. Natl. Acad. Sci. USA., 93, 1996, 10779–10784.
Gow A., Southwood C.M., Li J.S., Pariali M., Riordan G.P., Brodie S.E., Danias J., Bronstein J.M., Kachar B. & Lazzarini R.A.. CNS myelin and sertoli cell tight junction strands are absent in Osp/claudin-11 null mice, Cell, 99, 1999, 649–659.[Medline]
Grindstaff K.K., Yeaman C., Anandasabapathy N., Hsu S.C., Rodriguez-Boulan E., Scheller R.H. & Nelson W.J.. Sec6/8 complex is recruited to cell–cell contacts and specifies transport vesicle delivery to the basal-lateral membrane in epithelial cells, Cell, 93, 1998, 731–740.[Medline]
Guo W., Roth D., Walch-Solimena C. & Novick P.. The exocyst is an effector for Sec4p, targeting secretory vesicles to sites of exocytosis, EMBO (Eur. Mol. Biol. Organ.) J., 18, 1999, 1071–1080.[Medline]
Hazuka C.D., Foletti D.L., Hsu S.C., Kee Y., Hopf F.W. & Scheller R.H.. The sec6/8 complex is located at neurite outgrowth and axonal synapse-assembly domains, J. Neurol., 19, 1999, 1324–1334.
Huber L.A., Pimplikar S., Parton R.G., Virta H., Zerial M. & Simmons K.. Rab8, a small GTPase involved in vesicular traffic between the TGN and the basolateral plasma membrane, J. Cell Biol., 123, 1993, 35–45.
Ikonen E., Tagaya M., Ullrich O., Montecucco C. & Simons K.. Different requirements for NSF, SNAP, and rab proteins in apical and basolateral transport in MDCK cells, Cell., 81, 1995, 571–580.[Medline]
Itoh M, Furuse M., Morita K., Kubota K., Saoto M. & Tsukita S.. Direct binding of three tight junction-associated MAGUKs, ZO-1, ZO-2, and ZO-3, with the COOH termini of claudins, J. Cell Biol., 147, 1999, 1351–1363.
Izumi Y., Hirose T., Tamai Y., Hirai S., Nagashima Y., Fujimoto T., Tabuse Y., Kemphues K.J. & Ohno S.. An atypical PKC directly associates and colocalizes at the epithelial tight junction with ASIP, a mammalian homologue of Caenorhabditis elegans polarity protein PAR-3, J. Cell Biol, 143, 1998, 95–106.
Joberty G., Peterson C., Gao L. & Macara I.G.. The cell polarity protein Par6 links Par3 and an atypical protein kinase C to Cdc42, Nat. Cell Biol, 2, 2000, 531–539.[Medline]
Jou T.S., Schneeberger E.E. & Nelson W.J.. Structural and functional regulation of tight junctions by RhoA and Rac1 small GTPases, J. Cell Biol, 142, 1998, 101–115.
Keller P. & Simons K.. Post-Golgi biosynthetic trafficking, J. Cell Sci., 110, 1997, 3001–3009.[Abstract]
Keon B.H., Schafer S., Kuhn C., Grund C. & Franke W.W.. Symplekin, a novel type of tight junction plaque protein, J. Cell Biol., 134, 1996, 1003–1018.
Kroschewski R., Hall A. & Mellman I.. Cdc42 controls secretory and endocytic transport to the basolateral plasma membrane of MDCK cells, Nat. Cell Biol, 1, 1999, 8–13.[Medline]
Lafont F., Verkade P., Galli T., Wimmer C., Louvard D. & Simons K.. Raft association of SNAP receptors acting in apical trafficking in Madin-Darby canine kidney cells, Proc. Natl. Acad. Sci. USA., 96, 1999, 3734–3738.
Lapierre L.A., Tuma P.L., Navarre J., Goldenring J.R. & Anderson J.M.. VAP-33 localizes to both an intracellular vesicle population and with occludin at the tight junction, J. Cell Sci, 112, 1999, 3723–3732.[Abstract]
Lehman K.G., Rossi J.E., Adamo & Brenwald P.. Yeast homologues of Tomosyn and lethal giant larvae function in exocytosis and are associated with the plasma membrane SNARE, Sec9, J. Cell Biol., 146, 1999, 125–140.
Leung S.M., Chen D., DasGupta B.R., Whiteheart S.W. & Apodaca G.. SNAP-23 requirement for transferrin recycling in streptolysin-O-permeabilized Madin-Darby canine kidney cells, J. Biol. Chem., 273, 1998, 17732–17741.
Li D. & Mrsny R.J.. Oncogenic Raf-1 disrupts epithelial tight junctions via downregulation of occludin, J. Cell Biol, 148, 2000, 791–800.
Lin D., Edwards A.S., Fawcett J.P., Mbamalu G., Scott J.D. & Pawson T.. A mammalian PAR3–PAR6 complex implicated in Cdc42/Rac1 and aPKC signaling and cell polarity, Nat. Cell Biol, 2, 2000, 540–547.[Medline]
Louvard D.. Apical membrane aminopeptidase appears at site of cell–cell contact in cultured kidney epithelial cells, Proc. Natl. Acad. Sci.USA, 77, 1980, 4132–4136.
Low S.H., Chapin S.J., Weimbs T., Komuves L.G., Bennett M.K. & Mostov K.E.. Differential localization of syntaxin isoforms in polarized Madin-Darby canine kidney cells, Mol. Biol. Cell., 7, 1996, 2007–2018.[Abstract]
Low S.H., Roche P.A., Anderson H.A., vanIjzendoorn S.C., Zhang M., Mostov K.E. & Weimbs T.. Targeting of SNAP-23 and SNAP-25 in polarized epithelial cells, J. Biol. Chem, 273, 1998, 3422–3430.
Low S.H., Miura M., Roche P.A., Valdez A.C., Mostov K.E. & Weimbs T.. Intracellular redirection of plasma membrane trafficking after loss of epithelial cell polarity, Mol. Biol. Cell., 11, 2000, 3045–3060.
Madara J.L.. Regulation of the movement of solutes across tight junctions, Annu. Rev. Physiol, 60, 1998, 143–159.[Medline]
Martin-Padura I., Lostaglio S., Schneemann M., Williams L., Romano M., Fruscella P., Panzeri C., Stoppacciaro A., Ruco L., Villa A., Simmons D. & Dejana E.. Junctional adhesion molecule, a novel member of the immunoglobulin superfamily that distributes at intercellular junctions and modulates monocyte transmigration, J. Cell Biol, 142, 1998, 117–127.
Marzesco A.M., Galli T., Louvard D. & Zahraoui A.. The rod cGMP phosphodiesterase 
subunit dissociates the small GTPase Rab13 from membranes, J. Biol. Chem, 273, 1998, 22340–22345.
Mitic L.L. & Anderson J.M.. Molecular architecture of tight junctions, Annu. Rev. Physiol., 60, 1998, 121–142.[Medline]
Mostov K.E., Verges M. & Altschuler Y.. Membrane traffic in polarized epithelial cells, Curr. Opin. Cell Biol, 12, 2000, 483–490.[Medline]
Nusrat A., Parkos C.A., Verkade P., Foley C.S., Liang T.W., Innis-Whitehouse W., Eastburn K.K. & Madara J.L.. Tight junctions are membrane microdomains, J. Cell Sci, 113, 2000, 1771–1781.[Abstract]
Quiñones B., Riento K., Olkkonen V.M., Hardy S. & Bennett M.K.. Syntaxin 2 splice variants exhibit differential expression patterns, biochemical properties and subcellular localizations, J. Cell Sci, 112, 1999, 4291–4304.[Abstract]
Ren M., Zeng J., De L., Chiarandini C., Rosenfeld M., Adesnik M. & Sabatini D.D.. In its active form, the GTP-binding protein rab8 interacts with a stress-activated protein kinase, Proc. Natl. Acad. Sci. USA, 93, 1996, 5151–5155.
Riento K., Galli T., Jansson S., Ehnholm C., Lehtonen E. & Olkkonen V.M.. Interaction of munc-18-2 with syntaxin 3 controls the association of apical SNAREs in epithelial cells, J.Cell Sci, 111, 1998, 2681–2688.[Abstract]
Ryeom S.W., Paul D. & Goodenough D.A.. Truncation mutants of the tight junction protein ZO-1 disrupt corneal epithelial cell morphology, Mol. Biol. Cell, 11, 2000, 1687–1696.
Saitou M., Fujimoto K., Doi Y., Itoh M., Fujimoto T., Furuse M., Takano H., Noda T. & Tsukita S.. Occludin-deficient embryonic stem cells can differentiate into polarized epithelial cells bearing tight junctions, J. Cell Biol., 141, 1998, 397–408.
Schimmoller F., Simon I. & Pfeffer S.R.. Rab GTPases, directors of vesicle docking, J. Biol. Chem, 273, 1998, 22161–22164.
Simon D.B., Lu Y., Choate K.A., Velazquez H., Al-Sabban E., Praga M., Casari G., Bettinelli A., Colussi G., Rodriguez-Soriano J., McCredie D., Milford D., Sanjad S. & Lifton R.P.. Paracellin-1, a renal tight junction protein required for paracellular Mg2+ resorption, Science, 285, 1999, 103–106.
Steegmaier M., Lee K.C., Prekereis R. & Scheller R.H.. SNARE protein trafficking in polarized MDCK cells, Traffic, 1, 2000, 553–560.[Medline]
Tsukita S. & Furuse M.. Occludin and claudins in tight-junction strandsleading or supporting players?, Trends Cell Biol., 9, 1999, 268–273.[Medline]
Tsukita S. & Furuse M.. Pores in the wallclaudins constitute tight junction strands containing aqueous pores, J. Cell Biol., 149, 2000, 13–16.
Weber E., Berta G., Tousson A., St John P., Green M.W., Gopalokrishnan U., Jilling T., Sorscher E.J., Elton T.S., Abrahamson D.R. & Kirk K.L.. Expression and polarized targeting of a rab3 isoform in epithelial cells, J. Cell Biol, 125, 1994, 583–594.
Weber T., Zemelman B.V., McNew J.A., Westermann B., Gmachl M., Parlati F., Sollner T.H. & Rothman J.E.. SNAREpinsminimal machinery for membrane fusion, Cell., 92, 1998, 759–772.[Medline]
Wittchen E.S., Haskins J. & Stevenson B.R.. Protein interactions at the tight junction. Actin has multiple binding partners, and ZO-1 forms independent complexes with ZO-2 and ZO-3, J. Biol. Chem, 274, 1999, 35179–35185.
Wong V. & Gumbiner B.M.. A synthetic peptide corresponding to the extracellular domain of occludin perturbs the tight junction permeability barrier, J. Cell Biol, 136, 1997, 399–409.
Woods D.F. & Bryant P.J.. The discs-large tumor suppressor gene of Drosophila encodes a guanylate kinase homolog localized at septate junctions, Cell, 66, 1991, 451–464.[Medline]
Yamamoto T., Harada N., Kano K., Taya S., Canaani E., Matsuura Y., Mizoguchi A., Ide C. & Kaibuchi K.. The Ras target AF-6 interacts with ZO-1 and serves as a peripheral component of tight junctions in epithelial cells, J. Cell Biol, 139, 1997, 785–795.
Yeaman C., Grindstaff K.K. & Nelson W.J.. New perspectives on mechanisms involved in generating epithelial cell polarity, Physiol. Rev, 79, 1999, 73–98.
Zahraoui A., Joberty G., Arpin M., Fontaine J.J., Hellio R., Tavitian A. & Louvard D.. A small rab GTPase is distributed in cytoplasmic vesicles in nonpolarized cells but colocalizes with the tight junction marker ZO-1 in polarized epithelial cells, J. Cell Biol, 124, 1994, 101–115.
CiteULike 
Complore 
Connotea 
Del.icio.us 
Digg 
Facebook 
Reddit 
Technorati 
Twitter What's this?
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
|
|
