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

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

Transmembrane proteins of tight junctions

Tight junctions contribute to the paracellular barrier, the fence dividing plasma membranes, and signal transduction, acting as a multifunctional complex in vertebrate epithelial and endothelial cells. The identification and characterization of the transmembrane proteins of tight junctions, claudins, junctional adhesion molecules (JAMs), occludin and tricellulin, have led to insights into the molecular nature of tight junctions. We provide an overview of recent progress in studies on these proteins and highlight their roles and regulation, as well as their functional significance in human diseases.     

Functional analysis of tight junctions

Epithelial and endothelial cells are joined to each other via a set of intercellular junctions that differ in their morphological appearance, composition, and function. The tight junction or zonula occludens is the intercellular junction that regulates diffusion between cells and therefore allows endothelia and epithelia to form cellular barriers that separate compartments of different composition. This intercellular gate formed by tight junctions is not only highly regulated but is size- and ion-selective and, hence, represents a semipermeable diffusion barrier. In epithelia, tight junctions form a morphological and functional border between the apical and basolateral cell surface domains. They directly contribute to the maintenance of cell surface polarity by forming a fence that prevents apical/basolateral diffusion of lipids in the outer leaflet of the plasma membrane. Here we describe a set of assays that allow the analysis of tight junctions to determine their integrity and functional state.     

Transmembrane proteins of tight junctions

Tight junctions from a morphological and functional boundary between the apical and basolateral cell surface domains of epithelia and endothelia, and regulate selective diffusion along the paracellular space. Two types of four-span transmembrane proteins, occludin and claudins, as well as the single-span protein JAM are associated with tight junctions. The functional analysis of these proteins starts to reveal how they are involved in the functions of tight junctions, which of their domains are important for these functions, and how they interact with each other to form the junctional diffusion barriers.     

Cytokine regulation of tight junctions

Epithelial and endothelial tight junctions act as a rate-limiting barrier between an organism and its environment. Continuing studies have highlighted the regulation of the tight junction barrier by cytokines. Elucidation of this interplay is vital for both the understanding of physiological tight junction regulation and the etiology of pathological conditions. This review will focus on recent advances in our understanding of the molecular mechanisms of tight junctions modulation by cytokines.     

Transmembrane proteins of tight junctions

Tight junctions contribute to the paracellular barrier, the fence dividing plasma membranes, and signal transduction, acting as a multifunctional complex in vertebrate epithelial and endothelial cells. The identification and characterization of the transmembrane proteins of tight junctions, claudins, junctional adhesion molecules (JAMs), occludin and tricellulin, have led to insights into the molecular nature of tight junctions. We provide an overview of recent progress in studies on these proteins and highlight their roles and regulation, as well as their functional significance in human diseases.     

Vertebrate-like tight junctions in the insect eye

Unequivocal vertebrate-like anastomosing tight junctions have been observed for the first time in insect tissues. In freeze-fractured replicas of dipteran compound eyes, the intercellular junctions between certain glial cells in regions distal to the optic neuropile display an extensive network of continuous intramembranous P face (PF) ridges. The intramembranous E face (EF) possesses a reticulum of grooves which occur in the depths of troughs and thereby produce a ‘quilted’ appearance. At PF/EF membrane face transitions, there is an obliteration of the intercellular space at points of membrane fusion; here the PF ridges and EF grooves appear in register and are therefore complementary. Although the septate junctions found here are patent, these tight junctions are occluding to lanthanum and appear to represent the blood-retinal barrier previously demonstrated electrophysiologically in insects. The existence and vertebrate-like structural complexity of these junctions in arthropods supports the concept of the universality of the membrane specializations that mediate cell-to-cell interactions.     

Structural integrity of hepatocyte tight junctions

The significance of discontinuities frequently found in freeze-fracture replicas of the tight junction was evaluated using complementary replicas of hepatocyte junctions from control and bile duct-ligated rats. An extensive analysis of complementary replicas using rotary platinum shadowing indicates that discontinuities in the protoplasmic (P) fracture face do not represent structural breaks in the tight- junctional network. In no case did P-face discontinuities correspond with interruptions in the groove network on the complementary extracellular (E) face. Quantitative analysis of replicas shows that P- face discontinuities result in part from "transfer" of material to the complementary E face (approximately 7% of the junctional length). However, many P-face discontinuities (7-30% of the junctional length) are matched only by a groove on the complementary E face. This finding demonstrates that a significant amount of material can be lost during freeze-fracture. An analysis of junctions from bile duct-ligated rats, which are known to have an increased paracellular permeability, shows comparable transfer and loss of material. However, the number of junctional elements and the tight-junction network density was significantly reduced by bile duct ligation. These observations indicate that discontinuities in tight-junctional elements result during the preparation of freeze-fracture replicas and are not physiologically important features of the junctional barrier. Variation in the number of elements provides the best explanation for observed differences in tight-junction permeability.     

Structural organization of the tight junctions

Tight junctions are the most apical organelle of the apical junctional complex and are primarily involved in the regulation of paracellular permeability and membrane polarity. Extensive research in the past two decades has identified not only the individual molecules of the tight junctions but also their mutual interactions, which are the focus of the present review article. While a complete map of the interactions among the tight junction molecules is probably far from being complete, the available evidence already allows outlining the general molecular architecture of the tight junctions. Here, with the aim of gaining deeper mechanistic understanding of tight junction assembly, regulation and function, we have subdivided the known molecular interactions into four major clusters that are centered on cell surface, polarity, cytoskeletal and signaling molecules.     

Signalling to and from tight junctions

Tight junctions have long been regarded as simple barriers that separate compartments of different compositions, but recent research indicates that different types of signalling proteins and transduction pathways are associated with these junctions. They receive and convert signals from the cell interior to regulate junction assembly and function, and transmit signals to the cell interior to modulate gene expression and cell behaviour.     

Structural organization of the tight junctions

Tight junctions are the most apical organelle of the apical junctional complex and are primarily involved in the regulation of paracellular permeability and membrane polarity. Extensive research in the past two decades has identified not only the individual molecules of the tight junctions but also their mutual interactions, which are the focus of the present review article. While a complete map of the interactions among the tight junction molecules is probably far from being complete, the available evidence already allows outlining the general molecular architecture of the tight junctions. Here, with the aim of gaining deeper mechanistic understanding of tight junction assembly, regulation and function, we have subdivided the known molecular interactions into four major clusters that are centered on cell surface, polarity, cytoskeletal and signaling molecules.     

Molecular physiology and pathophysiology of tight junctions. I. Biogenesis of tight junctions and epithelial polarity

The tight junction (TJ) was first noticed through its ability to control permeation across the paracellular route, but the homologies of its molecular components with peptides that participate in tumor suppression, nuclear addressing, and cell proliferation indicate that it may be involved in many other fundamental functions. TJs are formed by a dozen molecular species that assemble through PDZ and other protein-protein clustering promoting sequences, in response to the activation of E-cadherin. The TJ occupies a highly specific position between the apical and the basolateral domains. Its first molecular components seem to be delivered to such a position by addressing signals in their molecule and, once anchored, serve as a clustering nucleus for further TJ-associated molecules. Although in mature epithelial cells TJs and E-cadherin do not colocalize, a complex chain of reactions goes from one to the other that involves alpha-, beta-, and gamma-catenins, two different G proteins, phospholipase C, protein kinase C, calmodulin, mitogen-activated protein kinase, and molecules pertaining to the cytoskeleton, which keep the TJ sensitive to physiological requirements and local conditions (notably to Ca(2+)-dependent cell-cell contacts) throughout the life of the epithelium.     

Maturation of tight junctions in guinea-pig cecal epithelium

Summary By means of the freeze-fracture technique and in tracer studies it is demonstrated that the structure of tight junctions and the permeability to lanthanum of the guinea-pig cecal epithelium change during maturation of cells. Height and strand number of tight junctions in the apical-basal direction increase as crypt cells migrate to the surface of the epithelium. Likewise, the interlacing of continuous strands was greater in surface than in crypt junctions. The numerous free-ends, isolated individual freestrands and maculae occludentes found in crypt cells were absent in surface epithelial cells. Goblet cells, located at the bottom of crypts, displayed tight junctions similar in characteristics to those of cells located in the middle region of crypts. Cells at the surface and in middle regions of crypts possess tight junctions impermeable to lanthanum, whereas junctions between cells located at the bottom of crypts often were permeable to the tracer, indicating that permeability decreases as the epithelial cells mature. Genesis and maturation mechanisms related to structural configuration of tight junctions are discussed.