p120 serine and threonine phosphorylation is controlled by multiple ligand-receptor pathways but not cadherin ligation

p120-catenin (p120) regulates cadherin turnover and is required for cadherin stability. Extensive and dynamic phosphorylation on tyrosine, serine and threonine residues in the N-terminal regulatory domain has been postulated to regulate p120 function, possibly through modulation of the efficiency of p120/cadherin interaction. Here we have utilized novel phospho-specific monoclonal antibodies to four major p120 serine and threonine phosphorylation sites to monitor individual phosphorylation events and their consequences. Surprisingly, membrane-localization and not cadherin interaction is the main determinant in p120 serine and threonine phosphorylation and dephosphorylation. Furthermore, the phospho-status of these four residues had no obvious effect on p120's role in cadherin complex stabilization or cell-cell adhesion. Interestingly, dephosphorylation was dramatically induced by PKC activation, but PKC-independent pathways were also evident. The data suggest that p120 dephosphorylation at these sites is modulated by multiple cell surface receptors primarily through PKC-dependent pathways, but these changes do not seem to reduce p120/cadherin affinity.     

Proteins reacting with cadherin and catenin antibodies are present in maize showing tissue-, domain-, and development-specific associations with endoplasmic-reticulum membranes and actin microfilaments in root cells

Summary With heterologous antibodies raised against animal N-cadherin, -catenin, and -catenin, we have visualized their reactive proteins within cells of maize root apices. Embedding using Steedman's wax allowed us to accomplish tissue-specific analysis which revealed that cells of epidermis, endodermis/pericycle, and outer stele tissues, all of which are tightly associated to each other, are especially enriched with presumed plant homologues of N-cadherin and both catenins. In the root epidermis, trichoblasts initiating root hairs showed prominent accumulations of cadherin-like antigens at outgrowing domains where they co-localize with actin. Close associations of cadherin-like proteins with F-actin were detected in parenchymatic cells of the stele, also at the immunogold electron microscopy level. A possible role of these interesting proteins in membrane-membrane interactions is indicated by their prominent accumulations at endoplasmic-reticulum-enriched pit-field-based plant cell adhesion domains in plasmolyzing cells of maize root apices exposed to mannitol. Intriguingly, these unique adhesion domains of plasmolyzing cells are enriched with endoplasmic-reticulum-resident calreticulin. Cadherin-like, but not catenin-like, proteins were abundant also within the nucleoplasm.Abbreviations AGPs arabinogalactan proteins - EM electron microscopy - ER endoplasmic reticulum - MFs microfilaments - SB stabilizing buffer     

E-Cadherin negatively modulates delta-catenin-induced morphological changes and RhoA activity reduction by competing with p190RhoGEF for delta-catenin

δ-Catenin is a member of the p120-catenin subfamily of armadillo proteins. Here, we describe distinctive features of δ-catenin localization and its association with E-cadherin in HEK293 epithelial cells. In HEK293 cells maintained in low cell densities, approximately 15% of cells overexpressing δ-catenin showed dendrite-like process formation, but there was no detectable change in RhoA activity. In addition, δ-catenin was localized mainly in the cytoplasm and was associated with p190RhoGEF. However, at high cell densities, δ-catenin localization was shifted to the plasma membrane. The association of δ-catenin with E-cadherin was strengthened, whereas its interaction with p190RhoGEF was weakened. In mouse embryonic fibroblast cell, ectopic expression of E-cadherin decreased the effect of δ-catenin on the reduction of RhoA activity as well as on dendrite-like process formation. These results suggest that δ-catenin is more dominantly bound to E-cadherin than to p190RhoGEF, and that δ-catenin’s function is dependent on its cellular binding partner.     

The N-cadherin/catenin complex in colon fibroblasts and myofibroblasts.

Fibroblasts and myofibroblasts were isolated respectively from normal colon mucosa and from colon cancers. Immunostaining with an antibody against alpha-smooth muscle actin (alpha-SMA) of the tissues of origin and of early passage cultures showed equal proportions of alpha-SMA positive myofibroblasts in vivo as in vitro. Immunocytochemistry, immunoprecipitation of metabolically labelled cells followed by Western blotting and RT-PCR of RNA isolates demonstrated the presence of a N-cadherin/catenin complex in both fibroblasts and myofibroblasts. This complex was found preferentially at the cell cell boundaries. Immunocytochemistry and, to a lesser extent, co-immunoprecipitation indicated partial colocalisation of catenins and alpha-SMA. Transforming growth factor beta1 (TGF-beta1) greatly enhanced the expression of alpha-SMA, but left the N-cadherin/catenin complex unaltered. We speculate that the N-cadherin/catenin complex may have different functions in myofibroblasts than in fibroblasts because of its interaction with alpha-SMA.     

N-cadherin mediates cortical organization in the mouse brain

The cerebral cortex is a complex laminated structure generated by the sequential migration of developing neurons from the ventricular zone. One of the molecules that may play a role in cortical morphogenesis is N-cadherin since its blocking causes disruption of the ordered arrangement of cells in other neural tissues, such as the neural retina. Here, we show that when the N-cadherin gene had been conditionally deleted in the mouse cerebral cortex, the intra-cortical structures were nearly completely randomized; e.g., mitotic cells and postmitotic cells were scattered throughout the cortex without any order. These defects seemed to mainly originate from the disruption of the adherens junctions (AJs) localized in the apical end of neuroepithelial cells, where N-cadherin is normally most highly concentrated. In the absence of N-cadherin, neuroepithelial or radial glial cells could not expand their bodies or processes to span the distance between the ventricular and pial surfaces and therefore terminated them in the middle zone of the cortex. These results demonstrate that N-cadherin is essential for maintaining the normal architecture of neuroepithelial or radial glial cells and that their disruption randomizes the internal structures of the cortex.     

Roles and modes of action of nectins in cell–cell adhesion

Nectins are Ca²⁺-independent immunoglobulin (Ig)-like cell–cell adhesion molecules (CAMs), which comprise a family consisting of four members. Each nectin homophilically and heterophilically trans-interacts and causes cell–cell adhesion. Biochemical, cell biological, and knockout mice studies have revealed that nectins play important roles in formation of many types of cell–cell junctions and cell–cell contacts, including cadherin-based adherens junctions (AJs) and synapses. Mode of action of nectins in the formation of AJs has extensively been investigated. Nectins form initial cell–cell adhesion and recruit E-cadherin to the nectin-based cell–cell adhesion sites. In addition, nectins induce activation of Cdc42 and Rac small G proteins, which eventually enhances the formation of cadherin-based AJs through the reorganization of the actin cytoskeleton. Nectins furthermore heterophilically trans-interact with nectin-like molecules (Necls), other Ig-like CAMs, and assist or modify their various functions, such as cell adhesion, migration, and proliferation. We describe here the roles and modes of action of nectins as CAMs.     

Identification of a novel intermediate filament-linked N-cadherin/gamma-catenin complex involved in the establishment of the cytoarchitecture of differentiated lens fiber cells

Tissue morphogenesis and maintenance of complex tissue architecture requires a variety of cell-cell junctions. Typically, cells adhere to one another through cadherin junctions, both adherens and desmosomal junctions, strengthened by association with cytoskeletal networks during development. Both β- and γ-catenins are reported to link classical cadherins to the actin cytoskeleton, but only γ-catenin binds to the desmosomal cadherins, which links them to intermediate filaments through its association with desmoplakin. Here we provide the first biochemical evidence that, in vivo, γ-catenin also mediates interactions between classical cadherins and the intermediate filament cytoskeleton, linked through desmoplakin. In the developing lens, which has no desmosomes, we discovered that vimentin became linked to N-cadherin complexes in a differentiation-state specific manner. This newly identified junctional complex was tissue specific but not unique to the lens. To determine whether in this junction N-cadherin was linked to vimentin through γ-catenin or β-catenin we developed an innovative “double” immunoprecipitation technique. This approach made possible, for the first time, the separation of N-cadherin/γ-catenin from N-cadherin/β-catenin complexes and the identification of multiple members of each of these isolated protein complexes. The study revealed that vimentin was associated exclusively with N-cadherin/γ-catenin junctions. Assembly of this novel class of cadherin junctions was coincident with establishment of the unique cytoarchitecture of lens fiber cells. In addition, γ-catenin had a distinctive localization to the vertices of these hexagonally shaped differentiating lens fiber cells, a region devoid of actin; while β-catenin co-localized with actin at lateral cell interfaces. We believe this novel vimentin-linked N-cadherin/γ-catenin junction provides the tensile strength necessary to establish and maintain structural integrity in tissues that lack desmosomes.     

Analysis of the distribution and phosphorylation state of ZO-1 in MDCK and nonepithelial cells

We have examined the distribution and extent of phosphorylation of the tight junction-associated protein ZO-1 in the epithelial MDCK cell line, and in three cell types that do not form tight junctions: S180 (sarcoma) cells, S180 cells transfected with E-cadherin (S180L), and primary cultures of astrocytes. In shortterm calcium chelation experiments on MDCK cells, removal of extracellular calcium caused cells to pull apart. However, ZO-1 remained concentrated at the plasma membrane and no change in ZO-1 phosphorylation was observed. Maintenance of MDCK cells in low calcium medium, conditions where no tight junctions are found, resulted in altered ZO-1 distribution and lower total phosphorylation of the protein. In S180 cells, ZO-1 was diffusely distributed along the entire cell surface, with concentration of the antigen in motile regions of the cell. Cell-cell contact was not a prerequisite for ZO-1 localization at the plasma membrane in this cell type, and the phosphate content of ZO-1 was found to be lower in S180 cells relative to MDCK cells. Expression of Ecadherin in S180L cells did not alter either the distribution or phosphorylation of ZO-1. In contrast to S180 cells, ZO-1 in primary cultures of astrocytes was concentrated at sites of cell-cell contact, and the phosphorylation state was the same as that in control MDCK cells. Comparison of one-dimensional proteolytic digests of ³²P-labeled ZO-1 revealed the phosphorylation of two peptides in control MDCK cells that was absent in both MDCK cells grown in low calcium and in S180 cells.We would like to thank Cheryl Richards for her help with the cell culture and immunohistochemistry; David Begg, Gary Firestone, Vik Maraj, Manijeh Pasdar and Colin Rasmussen for helpful discussions; Jaclyn Peebles and Greg Morrison for help with graphics and photography; and Grace Martin and Bob Campenot for rat tail collagen. We are grateful to all the members of our laboratories for their friendship, advice and support. This work was supported by an Establishment Award to B.R.S. from the Alberta Heritage Foundation for Medical Research and grants to B.R.S. from the Kidney Foundation of Canada and the Medical Research Council of Canada. A.H. is funded by a Studentship from the AHFMR. K.L.S. was supported by a grant from the National Institutes of Health (DK-42799) to Gary L. Firestone. B.R.S. is a Medical Research Council of Canada and AHFMR Scholar.     

Ectodomain shedding of nectin-1alpha by SF/HGF and TPA in MDCK cells

Nectin is a Ca(2+)-independent immunoglobulin-like cell-cell adhesion molecule implicated in the organization of the junctional complex comprised of E-cadherin-based adherens junctions and claudin-based tight junctions in epithelial cells. Scatter factor (SF)/hepatocyte growth factor (HGF) and 12-O-tetradecanoylphorbol-13-acetate (TPA), a tumor-promoting phorbol ester, induce cell spreading, followed by cell-cell dissociation and cell scattering, in Madin-Darby canine kidney (MDCK) cells. We found here that SF/HGF and TPA induced proteolytic cleavage of nectin-1alpha in the ectodomain, resulting in generation of the 80-kDa extracellular fragment and the 33-kDa fragment composed of the transmembrane and cytoplasmic domains, in MDCK cells. This shedding of nectin-1alpha was inhibited by metalloprotease inhibitors. These results indicate that SF/HGF and TPA induce the ectodomain shedding of nectin-1alpha presumably by a metalloprotease, and have raised the possibility that this shedding is involved in the SF/HGF- and TPA-induced cell-cell dissociation.     

Protective role of p120-catenin in maintaining the integrity of adherens and tight junctions in ventilator-induced lung injury

Background

Ventilator-induced lung injury (VILI) is one of the most common complications for patients with acute lung injury (ALI) or acute respiratory distress syndrome (ARDS). Although p120 is an important protein in the regulation of cell junctions, further mechanisms should be explored for prevention and treatment of VILI.

Methods

Mouse lung epithelial cells (MLE-12), which were transfected with p120 small interfering (si)RNA, p120 cDNA, wild-type E-cadherin juxtamembrane domain or a K83R mutant juxtamembrane domain (K83R-JMD), were subjected to 20 % cyclic stretches for 2 or 4 h. Furthermore, MLE-12 cells and mice, which were pretreated with the c-Src inhibitor PP₂ or RhoA inhibitor Y27632, underwent 20 % cyclic stretches or mechanical stretching, respectively. Moreover, wild-type C57BL/6 mice were transfected with p120 siRNA-liposome complexes before mechanical ventilation. Cell lysates and lung tissues were then analyzed to detect lung injury.

Results

cyclic stretches of 20 % actived c-Src, which induced degradation of E-cadherin, p120 and occludin. However, loss of p120 increased the degradation and endocytosis of E-cadherin. Immunoprecipitation and Immunofluorescence results showed a decrease in the association between p120 and E-cadherin, while gap formation increased in p120 siRNA and K83R-JMD groups after 20 % cyclic stretches. Loss of p120 also reduced the occludin level and decreased the association of occludin and ZO-1 by enhancing RhoA activity. However, the altered levels of occludin and E-cadherin were reversed by PP₂ or Y27632 treatments compared with the cyclic stretch group. Consistently, the expression, redistribution and disassociation of junction proteins were all restored in the p120 overexpression group after 20 % cyclic stretches. Moreover, the role of p120 in VILI was confirmed by increased wet/dry weigh ratio and enhanced production of cytokines (tumor necrosis factor-α and interleukin-six) in p120-depleted mice under mechanical ventilation.

Conclusions

p120 protected against VILI by regulating both adherens and tight junctions. p120 inhibited E-cadherin endocytosis by increasing the association between p120 and juxtamembrane domain of E-cadherin. Furthermore, p120 reduced the degradation of occludin by inhibiting RhoA activity. These findings illustrated further mechanisms of p120 in the prevention of VILI, especially for patients with ALI or ARDS.     

Regulation by nectin of the velocity of the formation of adherens junctions and tight junctions

Cadherins are key Ca(2+)-dependent cell-cell adhesion molecules at adherens junctions (AJs) in fibroblasts and epithelial cells, whereas claudins are key Ca(2+)-independent cell-cell adhesion molecules at tight junctions (TJs) in epithelial cells. The formation and maintenance of TJs are dependent on the formation and maintenance of AJs. Nectins are Ca(2+)-independent immunoglobulin-like cell-cell adhesion molecules which comprise a family of four members, nectin-1, -2, -3, and -4, and are involved in the formation of AJs in cooperation with cadherins, and the subsequent formation of TJs. We show here that the velocity of the formation of the E-cadherin-based AJs is increased by overexpression of nectin-1 and is reduced by addition of the nectin-1 inhibitors to the medium in L cells stably expressing E-cadherin and Madin-Darby canine kidney cells. Moreover, the velocity of the formation of the claudin-based TJs is increased by overexpression of nectin-1 and is reduced by addition of the nectin-1 inhibitors to the medium in Madin-Darby canine kidney cells. These results indicate that nectins regulate the velocity of the formation of the E-cadherin-based AJs and the subsequent formation of the claudin-based TJs.     

Interaction of p190RhoGAP with C-terminal Domain of p120-catenin Modulates Endothelial Cytoskeleton and Permeability

p120-catenin is a multidomain intracellular protein, which mediates a number of cellular functions, including stabilization of cell-cell transmembrane cadherin complexes as well as regulation of actin dynamics associated with barrier function, lamellipodia formation, and cell migration via modulation of the activities of small GTPAses. One mechanism involves p120 catenin interaction with Rho GTPase activating protein (p190RhoGAP), leading to p190RhoGAP recruitment to cell periphery and local inhibition of Rho activity. In this study, we have identified a stretch of 23 amino acids within the C-terminal domain of p120 catenin as the minimal sequence responsible for the recruitment of p190RhoGAP (herein referred to as CRAD; catenin-RhoGAP association domain). Expression of the p120-catenin truncated mutant lacking the CRAD in endothelial cells attenuated effects of barrier protective oxidized phospholipid, OxPAPC. This effect was accompanied by inhibition of membrane translocation of p190RhoGAP, increased Rho signaling, as well as suppressed activation of Rac1 and its cytoskeletal effectors PAK1 (p21-activated kinase 1) and cortactin. Expression of p120 catenin-truncated mutant lacking CRAD also delayed the recovery process after thrombin-induced endothelial barrier disruption. Concomitantly, RhoA activation and downstream signaling were sustained for a longer period of time, whereas Rac signaling was inhibited. These data demonstrate a critical role for p120-catenin (amino acids 820–843) domain in the p120-catenin·p190RhoGAP signaling complex assembly, membrane targeting, and stimulation of p190RhoGAP activity toward inhibition of the Rho pathway and reciprocal up-regulation of Rac signaling critical for endothelial barrier regulation.     

Endothelial adherens and tight junctions in vascular homeostasis, inflammation and angiogenesis

Endothelial cells lining the vessel wall are connected by adherens, tight and gap junctions. These junctional complexes are related to those found at epithelial junctions but with notable changes in terms of specific molecules and organization. Endothelial junctional proteins play important roles in tissue integrity but also in vascular permeability, leukocyte extravasation and angiogenesis. In this review, we will focus on specific mechanisms of endothelial tight and adherens junctions.     

Coxsackie and adenovirus receptor (CAR) is a product of Sertoli and germ cells in rat testes which is localized at the Sertoli-Sertoli and Sertoli-germ cell interface

The coxsackie and adenovirus receptor (CAR), a putative cell-cell adhesion molecule, has attracted wide interest due to its importance in viral pathogenesis and in mediating adenoviral gene delivery. However, the distribution pattern and physiological function of CAR in the testis is still not clear. Here, we identified CAR in Sertoli cells and germ cells of rats. In vivo studies have shown that CAR resides at the blood-testis barrier as well as at the ectoplasmic specialization. The persistent expression of CAR in rat testes from neonatal period throughout adulthood implicates its role in spermatogenesis. Using primary Sertoli cell cultures, we observed a significant induction of CAR during the formation of Sertoli cell epithelium. Furthermore, CAR was seen to be concentrated at inter-Sertoli cell junctions, co-localizing with tight junction protein marker ZO-1 and adherens junction protein N-cadherin. CAR was also found to be associated with proteins of Src kinase family and its protein level declined after TNFα treatment in Sertoli cell cultures. Immunofluorescent staining of isolated germ cells has revealed the presence of CAR on spermatogonia, spermatocytes, round spermatids and elongate spermatids. Taken together, we propose that CAR functions as an adhesion molecule in maintaining the inter-Sertoli cell junctions at the basal compartment of the seminiferous epithelium. In addition, CAR may confer adhesion between Sertoli and germ cells at the Sertoli-germ cell interface. It is possible that the receptor utilized by viral pathogens to breakthrough the epithelial barrier was also employed by developing germ cells to migrate through the inter-Sertoli cell junctions.     

Inversin forms a complex with catenins and N-cadherin in polarized epithelial cells

Nephrogenesis starts with the reciprocal induction of two embryonically distinct analages, metanephric mesenchyme and ureteric bud. This complex process requires the refined and coordinated expression of numerous developmental genes, such as inv. Mice that are homozygous for a mutation in the inv gene (inv/inv) develop renal cysts resembling autosomal-recessive polycystic kidney disease. The gene locus containing inv has been proposed to serve as a common modifier for some human and rodent polycystic kidney disease phenotypes. We generated polyclonal antibodies to inversin to study its subcellular distribution, potential binding partners, and functional aspects in cultured murine proximal tubule cells. A 125-kDa inversin protein isoform was found at cell-cell junctions. Two inversin isoforms, 140- and 90-kDa, were identified in the nuclear and perinuclear compartments. Plasma membrane allocation of inversin is dependent upon cell-cell contacts and was redistributed when cell adhesion was disrupted after incubation of the cell monolayer with low-calcium/EGTA medium. We further show that the membrane-associated 125-kDa inversin forms a complex with N-cadherin and the catenins. The 90-kDa nuclear inversin complexes with beta-catenin. These findings indicate that the inv gene product functions in several cellular compartments, including the nucleus and cell-cell adhesion sites.     

Multifaceted role of Rho, Rac, Cdc42 and Ras in intercellular junctions, lessons from toxins

Tight junctions (TJs) and adherens junctions (AJs) are dynamic structures linked to the actin cytoskeleton, which control the paracellular permeability of epithelial and endothelial barriers. TJs and AJs are strictly regulated in a spatio-temporal manner by a complex signaling network, including Rho/Ras-GTPases, which have a pivotal role. Rho preferentially regulates TJs by controlling the contraction of apical acto-myosin filaments, whereas Rac/Cdc42 mainly coordinate the assembly-disassembly of AJ components. However, a subtle balance of Rho/Ras-GTPase activity and interplay between these molecules is required to maintain an optimal organization and function of TJs and AJs. Conversely, integrity of intercellular junctions generates signals through Rho-GTPases, which are involved in the regulation of multiple cellular processes. Rho/Ras-GTPases and the control of intercellular junctions are the target of various bacterial toxins responsible for severe diseases in man and animals, and are part of their mechanism of action. This review focuses on the regulation of TJs and AJs by Rho/Ras-GTPases through molecular approaches and bacterial toxins.     

Distribution of adherens junction mediated by VE-cadherin complex in rat spleen sinus endothelial cells

The splenic sinus endothelium regulates the passage of blood cells through the splenic cord. The goal of the present study was to assess the localization of vascular endothelial (VE)-cadherin, β-catenin, and p120-catenin in the sinus endothelial cells of rat spleen and to characterize the presence and distribution of adherens junction formation mediated by the cadherin-catenin complex. Immunofluorescent microscopy of tissue cryosections demonstrated that VE-cadherin, β-catenin, and p120-catenin were localized in the junctional regions of adjacent endothelial cells. Double-staining immunofluorescent microscopy for VE-cadherin and β-catenin revealed colocalization at junctional regions. Transmission electron microscopy of thin sections of sinus endothelial cells treated with Triton X-100 clearly showed adherens junctions within the plasma membrane. Adherens junctions were located at various levels in the lateral membranes of adjacent endothelial cells regardless of the presence or absence of underlying ring fibers. Immunogold electron microscopy revealed VE-cadherin, β-catenin, and p120-catenin in the juxtaposed junctional membranes of adjacent sinus endothelial cells. Double-staining immunogold microscopy for VE-cadherin and β-catenin and for VE-cadherin and p120-catenin demonstrated colocalization to the junctional membranes of adjacent endothelial cells. Immunolabeling was evident at various levels in the lateral junctional membranes and was intermittently observed in the sinus endothelium. These data suggest that adherens junctions, whose formation appears to be mediated by VE-cadherin-catenin complexes, probably regulate the passage of blood cells through the spleen. This work was supported by a Grant-in-Aid for Scientific Research (C), Japan     

Involvement of afadin in the formation and remodeling of synapses in the hippocampus

In the hippocampus, synapses are formed between mossy fiber terminals and CA3 pyramidal cell dendrites and comprise highly developed synaptic junctions (SJs) and puncta adherentia junctions (PAJs). Dynamic remodeling of synapses in the hippocampus is implicated in learning and memory. Components of both the nectin-afadin and cadherin-catenin cell adhesion systems exclusively accumulate at PAJs. We investigated the role of afadin at synapses in mice in which the afadin gene was conditionally inactivated in hippocampal neurons. In these mutant mice, the signals for not only nectins, but also N-cadherin and β-catenin, were hardly detected in the CA3 area, in addition to loss of the signal for afadin, resulting in disruption of PAJs. Ultrastructural analysis revealed an increase in the number of perforated synapses, suggesting the instability of SJs. These results indicate that afadin is involved not only in the assembly of nectins and cadherins at synapses, but also in synaptic remodeling.     

Loss and recovery of the blood–nerve barrier in the rat sciatic nerve after crush injury are associated with expression of intercellular junctional proteins

The blood–nerve barrier in peripheral nerves is important for maintaining the environment for axons. Breakdown of the barrier by nerve injury causes various pathologies. We hypothesized that the breakdown and recovery of the blood–nerve barrier after injury are associated with the changes in the expression of intercellular junctional proteins. To test this hypothesis, we induced crush injuries in the rat sciatic nerve by ligation and analyzed spatiotemporal changes of claudin-1, claudin-5, occludin, VE-cadherin, and connexin43 by immunoconfocal microscopy and morphometry and compared them with changes in the permeability of the blood–nerve barrier by intravenous and local administration of Evans blue–albumin (EBA). On day 1 after removal of the ligature EBA leaked into the connective tissue in the endoneurium and then the leakage gradually decreased and disappeared on day 7. On day 1 claudin-1, claudin-5, occludin, VE-cadherin, and connexin43 had totally disappeared from the perineurium and endoneurium. Thereafter, claudin-1, claudin-5, occludin, and VE-cadherin recovered from day 2, whereas connexin43 was redetected on day 5. These results indicate that the breakdown and following recovery of the blood–nerve barrier are closely associated with changes in the expression of claudins, occludin, VE-cadherin, and connexin43 and that the recovery time course is similar but nonidentical.