Deficiency of Angulin-2/ILDR1, a Tricellular Tight Junction-Associated Membrane Protein,Causes Deafness with Cochlear Hair Cell Degeneration in Mice

Tricellular tight junctions seal the extracellular spaces of tricellular contacts, where the vertices of three epithelial cells meet, and are required for the establishment of a strong barrier function of the epithelial cellular sheet. Angulins and tricellulin are known as specific protein components of tricellular tight junctions, where angulins recruit tricellulin. Mutations in the genes encoding angulin-2/ILDR1 and tricellulin have been reported to cause human hereditary deafness DFNB42 and DFNB49, respectively. To investigate the pathogenesis of DFNB42, we analyzed mice with a targeted disruption of Ildr1, which encodes angulin-2/ILDR1. Ildr1 null mice exhibited profound deafness. Hair cells in the cochlea of Ildr1 null mice develop normally, but begin to degenerate by two weeks after birth. Tricellulin localization at tricellular contacts of the organ of Corti in the cochlea was retained in Ildr1 null mice, but its distribution along the depth of tricellular contacts was affected. Interestingly, compensatory tricellular contact localization of angulin-1/LSR was observed in the organ of Corti in Ildr1 null mice although it was hardly detected in the organ of Corti in wild-type mice. The onset of hair cell degeneration in Ildr1 null mice was earlier than that in the reported Tric mutant mice, which mimic one of the tricellulin mutations in DFNB49 deafness. These results indicate that the angulin-2/ILDR1 deficiency causes the postnatal degenerative loss of hair cells in the cochlea, leading to human deafness DFNB42. Our data also suggest that angulin family proteins have distinct functions in addition to their common roles of tricellulin recruitment and that the function of angulin-2/ILDR1 for hearing cannot be substituted by angulin-1/LSR.     

Loss of occludin affects tricellular localization of tricellulin

The tricellular tight junction (tTJ) forms at the convergence of bicellular tight junctions (bTJs) where three epithelial cells meet in polarized epithelia, and it is required for the maintenance of the transepithelial barrier. Tricellulin is a four transmembrane domain protein recently identified as the first marker of tTJ, but little is known about how tricellulin is localized at tTJs. As for the molecular mechanism of association of tricellulin with tight junctions (TJs), we found that tricellulin was incorporated into claudin-based TJs independently of binding to zona occludens-1. Unexpectedly, exogenous expression of tricellulin increased cross-links of TJ strands in the plasma membrane. As for the molecular mechanisms for localization of tricellulin at tricellular junctions, we found that knockdown of occludin caused mislocalization of tricellulin to bTJs, implying that occludin supports tricellular localization of tricellulin by excluding tricellulin from bTJs.     

Tricellulin constitutes a novel barrier at tricellular contacts of epithelial cells

For epithelia to function as barriers, the intercellular space must be sealed. Sealing two adjacent cells at bicellular tight junctions (bTJs) is well described with the discovery of the claudins. Yet, there are still barrier weak points at tricellular contacts, where three cells join together. In this study, we identify tricellulin, the first integral membrane protein that is concentrated at the vertically oriented TJ strands of tricellular contacts. When tricellulin expression was suppressed with RNA interference, the epithelial barrier was compromised, and tricellular contacts and bTJs were disorganized. These findings indicate the critical function of tricellulin for formation of the epithelial barrier.     

Angulin-1 seals tricellular contacts independently of tricellulin and claudins

Tricellular tight junctions (tTJs) are specialized tight junctions (TJs) that seal the intercellular space at tricellular contacts (TCs), where the vertices of three epithelial cells meet. Tricellulin and angulin family membrane proteins are known constituents of tTJs, but the molecular mechanism of tTJ formation remains elusive. Here, we investigated the roles of angulin-1 and tricellulin in tTJ formation in MDCK II cells by genome editing. Angulin-1–deficient cells lost the plasma membrane contact at TCs with impaired epithelial barrier function. The C terminus of angulin-1 bound to the TJ scaffold protein ZO-1, and disruption of their interaction influenced the localization of claudins at TCs, but not the tricellular sealing. Strikingly, the plasma membrane contact at TCs was formed in tricellulin- or claudin-deficient cells. These findings demonstrate that angulin-1 is responsible for the plasma membrane seal at TCs independently of tricellulin and claudins.     

Tricellulin Forms a Barrier to Macromolecules in Tricellular Tight Junctions without Affecting Ion Permeability

Tricellulin is a tight junction protein localized in tricellular tight junctions (tTJs), the meeting points of three cells, but also in bicellular tight junctions (bTJs). To investigate its specific barrier functions in bTJs and tTJs, TRIC-a was expressed in low-level tricellulin–expressing cells, and MDCK II, either in all TJs or only in tTJs. When expressed in all TJs, tricellulin increased paracellular electrical resistance and decreased permeability to ions and larger solutes, which are associated with enhanced ultrastructural integrity of bTJs toward enhanced strand linearity. In tTJs in contrast, ultrastructure was unchanged and tricellulin minimized permeability to macromolecules but not to ions. This paradox is explained by properties of the tTJ central tube which is wide enough for passage of macromolecules, but too rare to contribute significantly to ion permeability. In conclusion, at low tricellulin expression the tTJ central tube forms a pathway for macromolecules. At higher expression, tricellulin forms a barrier in tTJs effective only for macromolecules and in bTJs for solutes of all sizes.     

Pulses of Cell Ca<Superscript>2+</Superscript> and the Dynamics of Tight Junction Opening and Closing

A mathematical modeling of tight junction (TJ) dynamics was elaborated in a previous study (Kassab, F., Marques, R.P., Lacaz-Vieira, F. 2002. Modeling tight junction dynamics and oscillations. J. Gen. Physiol. 120:237–247) to better understand the dynamics of TJ opening and closing, as well as oscillations of TJ permeability that are observed in response to changes of extracellular Ca²⁺ levels. In this model, TJs were assumed to be specifically controlled by the Ca²⁺ concentration levels at the extracellular Ca²⁺ binding sites of zonula adhaerens. Despite the fact that the model predicts all aspects of TJ dynamics, we cannot rule out the likelihood that changes of intracellular Ca²⁺ concentration (Ca²⁺ _cell), which might result from changes \ of extracellular Ca²⁺ concentration (Ca²⁺ _extl), contribute to the observed results. In order to address this aspect of TJ regulation, fast Ca²⁺-switch experiments were performed in which changes of Ca²⁺ _cell were induced using the Ca²⁺ ionophore A23187 or thapsigargin, a specific inhibitor of the sarco-endoplasmic reticulum Ca²⁺-ATPase. The results indicate that the ionophore or thapsigargin per se do not affect basal tissue electrical conductance (G), showing that the sealing of TJs is not affected by a rise in Ca²⁺ _cell. When TJs were kept in a dynamic state, as partially open structures or in oscillation, conditions in which the junctions are very sensitive to disturbances that affect their regulation, a rise of Ca²⁺ _cell never led to a decline of G, indicating that a rise of Ca²⁺ _cell does not trigger per se TJ closure. On the contrary, always the first response to a rise of Ca²⁺ _cell is an increase of G that, in most cases, is a transient response. Despite these observations we cannot assure that a rise of Ca²⁺ _cell is without effect on the TJs, since an increase of Ca²⁺ _cell not only causes a transient increase of G but, in addition, during oscillations a rise of Ca²⁺ _cell induced by the Ca²⁺ ionophore transiently halted the oscillatory pattern of TJs. The main conclusion of this study is that TJ closure that is observed when basolateral Ca²⁺ concentration (Ca²⁺ _bl) is increased after TJs were opened by Ca²⁺ _bl removal cannot be ascribed to a rise of Ca²⁺ _cell and might be a consequence of Ca²⁺ binding to extracellular Ca²⁺ sites.     

Tricellulin is a tight-junction protein necessary for hearing

The inner ear has fluid-filled compartments of different ionic compositions, including the endolymphatic and perilymphatic spaces of the organ of Corti; the separation from one another by epithelial barriers is required for normal hearing. TRIC encodes tricellulin, a recently discovered tight-junction (TJ) protein that contributes to the structure and function of tricellular contacts of neighboring cells in many epithelial tissues. We show that, in humans, four different recessive mutations of TRIC cause nonsyndromic deafness (DFNB49), a surprisingly limited phenotype, given the widespread tissue distribution of tricellulin in epithelial cells. In the inner ear, tricellulin is concentrated at the tricellular TJs in cochlear and vestibular epithelia, including the structurally complex and extensive junctions between supporting and hair cells. We also demonstrate that there are multiple alternatively spliced isoforms of TRIC in various tissues and that mutations of TRIC associated with hearing loss remove all or most of a conserved region in the cytosolic domain that binds to the cytosolic scaffolding protein ZO-1. A wild-type isoform of tricellulin, which lacks this conserved region, is unaffected by the mutant alleles and is hypothesized to be sufficient for structural and functional integrity of epithelial barriers outside the inner ear.     

Calcium Site Specificity : Early Ca2+-related Tight Junction Events

The molecular mechanisms by which Ca²⁺ and metal ions interact with the binding sites that modulate the tight junctions (TJs) have not been fully described. Metal ions were used as probes of these sites in the frog urinary bladder. Basolateral Ca²⁺ withdrawal induces the opening of the TJs, a process that is abruptly terminated when Ca²⁺ is readmitted, and is followed by a complete recovery of the TJ seal. Mg²⁺ and Ba²⁺ were incapable of keeping the TJ sealed or of inducing TJ recovery. In addition, Mg²⁺ causes a reversible concentration-dependent inhibition of the Ca²⁺-induced TJ recovery. The effects of extracellular Ca²⁺ manipulation on the TJs apparently is not mediated by changes of cytosolic Ca²⁺ concentration. The transition elements, Mn²⁺ and Cd²⁺, act as Ca²⁺ agonists. In the absence of Ca²⁺, they prevent TJ opening and almost immediately halt the process of TJ opening caused by Ca²⁺ withdrawal. In addition, Mn²⁺ promotes an almost complete recovery of the TJ seal. Cd²⁺, in spite of stabilizing the TJs in the closed state and halting TJ opening, does not promote TJ recovery, an effect that apparently results from a superimposed toxic effect that is markedly attenuated by the presence of Ca²⁺. The interruption of TJ opening caused by Ca²⁺, Cd²⁺, or Mn²⁺, and the stability they confer to the closed TJs, might result from the interaction of these ions with E-cadherin. Addition of La³⁺ (2 μM) to the basolateral Ca²⁺-containing solution causes an increase of TJ permeability that fully reverses when La³⁺ is removed. This effect of La³⁺, observed in the presence of Ca²⁺ (1 mM), indicates a high La³⁺ affinity for the Ca²⁺-binding sites. This ability of La³⁺ to open TJs in the presence of Ca²⁺ is a relevant aspect that must be considered when using La³⁺ in the evaluation of TJ permeability of epithelial and endothelial membranes, particularly when used during in vivo perfusion or in the absence of fixatives.     

Evidence of tricellulin expression by immune cells, particularly microglia

Tight junctions (TJs) are elaborate structures located on the apical region of epithelial cells that limit paracellular permeability. Tricellulin is a recently discovered TJ protein, which is concentrated at the structurally specialized tricellular TJs but also present at bicellular contacts between epithelial cells, namely in the stomach. Interestingly, several TJ proteins have been found in other than epithelial cells, as astrocytes, and tricellulin mRNA expression was reported in mature dendritic cells. These findings prompted us to look for tricellulin expression in both epithelial and immune cells in the stomach, as well as in microglia, the brain resident immunocompetent cells. Immunohistochemical analysis of human stomach tissue sections revealed peroxidase staining at three-corner contact sites, as well as at the contact between two adjacent epithelial cells, thus evidencing the expression of tricellulin not only at tricellullar but at bicellular junctions as well. Such analysis, further revealed tricellulin immunostaining in cells of the monocyte/macrophage lineage, scattered throughout the lamina propria. Cultured rat microglia exhibited a notorious tricellulin staining, consistent with an extensive expression of the protein along the cell, which was not absolutely coincident with the lysosomal marker CD68. Detection of mRNA expression by real-time PCR provided supportive evidence for the expression of the TJ protein in microglia. These data demonstrate for the first time that microglia express a TJ protein. Moreover, the expression of tricellulin both in microglia and in the stomach immune cells point to a possible role of this new TJ protein in the immune system.     

Occludin and tricellulin facilitate formation of anastomosing tight-junction strand network to improve barrier function

Tight junctions (TJs) are composed of a claudin-based anastomosing network of TJ strands at which plasma membranes of adjacent epithelial cells are closely attached to regulate the paracellular permeability. Although the TJ proteins occludin and tricellulin have been known to be incorporated in the TJ strand network, their molecular functions remain unknown. Here, we established tricellulin/occludin-double knockout (dKO) MDCK II cells using a genome editing technique and evaluated the structure and barrier function of these cells. In freeze-fracture replica electron microscopy, the TJ strands of tricellulin/occludin-dKO cells had fewer branches and were less anastomosed compared with the controls. The paracellular permeability of ions and small tracers was increased in the dKO cells. A single KO of tricellulin or occludin had limited effects on the morphology and permeability of TJs. Mathematical simulation using a simplified TJ strand network model predicted that reduced cross-links in TJ strands lead to increased permeability of ions and small macromolecules. Furthermore, overexpression of occludin increased the complexity of TJ strand network and strengthened barrier function. Taken together, our data suggest that tricellulin and occludin mediate the formation and/or stabilization of TJ-strand branching points and contribute to the maintenance of epithelial barrier integrity.     

Redistribution and Phosphorylation of Occludin During Opening and Resealing of Tight Junctions in Cultured Epithelial Cells

We studied the expression, distribution, and phosphorylation of the tight junction (TJ) protein occludin in confluent MDCK cell monolayers following three procedures for opening and resealing of TJs. When Ca²⁺ is transiently removed from the culture medium, the TJs open and the cells separate from each other, but the occludin band around each cell is retained. When Ca²⁺ is reintroduced, the TJs reseal. When the monolayers are exposed to prolonged Ca²⁺ starvation the cells maintain contact, but occludin disappears from the cell borders and can be detected only in a cytoplasmic compartment. When Ca²⁺ is reintroduced, new TJs are assembled and the transepithelial electrical resistance (TER) is reestablished in about 20 hr. Monolayers treated with the phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA) show a different pattern of TJ opening: the cell-cell contact is maintained but the TJ strand network, as seen in freeze-fracture replicas, becomes discontinuous. Occludin is still localized at the cell periphery, but in a pattern of distribution that matches the discontinuous TJ. These TJs do not reseal even 24 hr after removal of the TPA. Western blot analysis showed that the 62–65 kD double band of occludin did not change with these treatments. However, in vivo phosphorylation analysis showed that the TPA treatment reduced the phosphorylation levels of occludin, while the prolonged Ca²⁺ starvation completely dephosphorylated the two occludin bands. In addition, a highly phosphorylated 71 kD band that immunoprecipitates with occludin is not present when TJ is opened by the Ca²⁺ removal. Phosphoaminoacid analysis showed that the 62–65 kD occludin bands are phosphorylated on serine and threonine, while the 71 kD band was phosphorylated exclusively on serine. Our results provide further evidence that phosphorylation of occludin is an important step in regulating TJ formation and permeability. Received: 28 December 1998/Revised: 8 April 1999     

Downsloping High-Frequency Hearing Loss Due to Inner Ear Tricellular Tight Junction Disruption by a Novel ILDR1 Mutation in the Ig-Like Domain

The immunoglobulin (Ig)-like domain containing receptor 1 (ILDR1) gene encodes angulin-2/ILDR1, a recently discovered tight junction protein, which forms tricellular tight junction (tTJ) structures with tricellulin and lipolysis-stimulated lipoprotein receptor (LSR) at tricellular contacts (TCs) in the inner ear. Previously reported recessive mutations within ILDR1 have been shown to cause severe to profound nonsyndromic sensorineural hearing loss (SNHL), DFNB42. Whole-exome sequencing of a Korean multiplex family segregating partial deafness identified a novel homozygous ILDR1 variant (p.P69H) within the Ig-like domain. To address the pathogenicity of p.P69H, the angulin-2/ILDR1 p.P69H variant protein, along with the previously reported pathogenic ILDR1 mutations, was expressed in angulin-1/LSR knockdown epithelial cells. Interestingly, partial mislocalization of the p.P69H variant protein and tricellulin at TCs was observed, in contrast to a severe mislocalization and complete failure of tricellulin recruitment of the other reported ILDR1 mutations. Additionally, three-dimensional protein modeling revealed that angulin-2/ILDR1 contributed to tTJ by forming a homo-trimer structure through its Ig-like domain, and the p.P69H variant was predicted to disturb homo-trimer formation. In this study, we propose a possible role of angulin-2/ILDR1 in tTJ formation in the inner ear and a wider audiologic phenotypic spectrum of DFNB42 caused by mutations within ILDR1.     

STIM1-Regulated Ca2+ Influx across the Apical and the Basolateral Membrane in Colonic Epithelium

In nonexcitable cells, store-operated Ca²⁺ entry is the most important pathway for influx of extracellular Ca²⁺ serving as a second messenger in the cytoplasm. The present study investigated the expression, localization and polar distribution of two key components of store-operated Ca²⁺ entry identified, e.g., in lymphocytes or epithelial cell lines—STIM1 (stromal interacting molecule 1), working as a Ca²⁺ sensor in the endoplasmic reticulum, and Orai1, working as the (or part of the) store-operated Ca²⁺ channel in the plasma membrane—in a native intestinal epithelium, i.e., rat colon. Immunohistochemical investigations revealed expression of STIM1 and Orai1 in the rat colonic epithelium. Ca²⁺ store depletion led to a translocation of STIM1 both to the basolateral as well as to the apical cell pole as observed by confocal microscopy. A Ca²⁺ depletion/repletion protocol was used in Ussing chamber experiments to investigate the contribution of basolateral and apical store-operated Ca²⁺ entry to the induction of anion secretion. These experiments revealed that Ca²⁺-dependent anion secretion was induced not only by basolateral Ca²⁺ repletion but also, to a lesser extent, by apical Ca²⁺ repletion. Both responses were suppressed by La³⁺. The effect of basolateral Ca²⁺ repletion was significantly inhibited by brefeldin A, a blocker of vesicular transport from the endoplasmic reticulum to the Golgi apparatus. In a final series of experiments, fura-2-loaded HT29/B6 cells were used. A carbachol-induced increase in the cytosolic Ca²⁺ concentration was significantly reduced when cells were pretreated with siRNA against STIM1. In conclusion, these results demonstrate that STIM1 as a key component of intracellular Ca²⁺ signaling is expressed by rat colonic epithelium and is involved in the regulation not only of basolateral but also of apical Ca²⁺ influx.     

A look at tricellulin and its role in tight junction formation and maintenance

Tight junctions are elaborate networks of transmembrane and cytosolic proteins that regulate epithelial permeability. Tricellulin was the first tight junction protein found at tricellular tight junctions, the specialized structures occurring where three cells meet together. Here, we summarize the current knowledge about tricellulin (marvelD2), a MARVEL domain protein. We address tricellulin location at tricellular junctions, and establish the comparison with the other members of the MARVEL family, occludin (marvelD1) and marvelD3. The structure of tricellulin and its membrane folding, as well as the proposed molecular interactions of tricellulin with other tight junction proteins, together with the interplay between those proteins are also discussed. In addition, we address the role of tricellulin in barrier properties, discriminating the involvement of the protein in paracellular permeability at bicellular and at tricellular tight junctions. Moreover, the key importance of the protein for hearing is highlighted based on the fact that mutations in TRIC, the human tricellulin gene, lead to deafness. Furthermore, this review points to some of the aspects that still deserve clarification for a better understanding of the biology of tight junctions in general and of tricellulin in particular.     

Alkalinization Stimulates Ca2+-Dependent Spreading During the Activation of Resting Lens Epithelial Cells In Primary Culture

Lens epithelium, when attached to its natural substratum, the lens capsule, can be maintained in culture for more than 2 weeks in a simple HEPES- and EDTA-buffered salt solution (HBS). In HBS, the epithelium shows the same characteristic phenomena of locomotion, initial retraction and respreading which in MEM plus serum precedes the inception of DNA synthesis. These phenomena have been shown to be dependent on extracellular Ca²⁺. 0·05 mM Ca²⁺ is necessary for maintaining cell-to-cell contacts of the in vivo epithelium. Higher concentrations of Ca²⁺ cause the epithelium to retract initially. In contrast, Mg²⁺ greatly favours cell-substratum interactions leading to the formation of lamellopodia and an initial spreading of the epithelium. After some hours in culture the epithelium changes markedly in response to extracellular Ca²⁺ and Mg²⁺; it respreads and flattens in the presence of Ca²⁺, while Mg²⁺ becomes less effective in maintaining cell-to-substratum contacts. Mg²⁺-dependent initial spreading is promoted at pH values near 7·0 but the Ca²⁺-dependent respreading requires an alkalinization of the salt solution.     

Tight Junction Dynamics in the Frog Urinary Bladder

In a previous study in frog skin (Castro et al., J. Memb. Biol. 134:15–29, 1993), it was shown that TJs experimentally disrupted by a selective deposition of BaSO₄ could be re-sealed upon addition of Ca²⁺to the apical solution; in the absence of apical Ca²⁺, the normal Ca²⁺ activity of the Na₂SO₄-Ringer's bathing the basolateral side was not able to induce TJ resealing. We now show that apical Ca²⁺also activates the TJ sealing mechanism in frog urinary bladders. Three known procedures were utilized to increase TJ permeability, all in the absence of apical Ca²⁺: (i) exposure to high positive transepithelial clamping potentials; (ii) exposure of the apical surface to hypertonic solutions; and (iii) selective deposition of BaSO₄ in the TJs. The resealing of the TJs was promoted by raising the concentration of Ca²⁺ in the apical solution. This effect of Ca²⁺ is not impaired by the presence of Ca²⁺ channel blockers (nifedipine, verapamil, Mn²⁺ or Cd²⁺) in the apical solution, indicating that junction resealing does not depend on Ca²⁺ entering the cells through the apical membrane. TJ resealing that occurs in response to raised apical Ca²⁺ most likely results from a direct effect of Ca²⁺, entering the disrupted TJs from the apical solution and reaching the zonula adhaerens Ca²⁺ receptors (E-cadherins). Protein kinase C (PKC) must play a significant role in the control of TJ assembly in this tight epithelia since the PKC inhibitor (H7) and the activator (diC8) markedly affect TJ recovery after disruption by apical hypertonicity. H7 treated tissues show marked recuperation of conductance even in the absence of apical Ca²⁺. In contrast, diC8 prevents tissue recuperation which normally occurs after addition of Ca²⁺ to the apical solution.     

Cytosolic Ca2+ concentration during Ca2+ depletion of isolated rat hearts

Reperfusion of isolated mammalian hearts with a Ca²⁺-containing solution after a short Ca²⁺-free period at 37°:C results in massive influx of Ca²⁺ into the cells and irreversible cell damage: the Ca²⁺paradox. Information about the free intracellular, cytosolic [Ca²⁺] ([Ca²⁺]_i) during Ca²⁺ depletion is essential to assess the possibility of Ca²⁺ influx through reversed Na⁺/Ca²⁺ exchange upon Ca²⁺ repletion. Furthermore, the increase in end-diastolic pressure often seen during Ca²⁺-free perfusion of intact hearts may be similar to that seen during ischemia and caused by liberation of Ca²⁺ from intracellular stores. Therefore, in this study, we measured [Ca²⁺]i during Ca²⁺- free perfusion of isolated rat hearts. To this end, the fluorescent indicator Indo-1 was loaded into isolated Langendorff-perfused hearts and Ca²⁺-transients were recorded. Ca²⁺-transients disappeared within 1 min of Ca²⁺ depletion. Systolic [Ca²⁺]i during control perfusion was 268±54 nM. Diastolic [Ca²⁺]i during control perfusion was 114±34 nM and decreased to 53±19 nM after 10 min of Ca²⁺ depletion. Left ventricular end-diastolic pressure (LVEDP) significantly increased from 13±4 mmHg during control perfusion after Indo-1 AM loading to 31±5 mmHg after 10 min Ca²⁺ depletion. Left ventricular developed pressure did not recover during Ca²⁺ repletion, indicating a full Ca²⁺ paradox. These results show that LVEDP increased during Ca²⁺ depletion despite a decrease in [Ca²⁺]i, and is therefore not comparable to the contracture seen during ischemia. Furthermore, calculation of the driving force for the Na⁺/Ca²⁺ exchanger showed that reversed Na⁺/Ca²⁺ exchange during Ca²⁺ repletion is not able to increase [Ca²⁺]i to cytotoxic levels.     

Tricellulin expression in brain endothelial and neural cells

Tricellulin is a tight junction (TJ) protein, which is not only concentrated at tricellular contacts but also present at bicellular contacts between epithelial tissues. We scrutinized the brain for tricellulin expression in endothelial and neural cells by using real-time polymerase chain reaction, Western blot and immunohistochemical and immunocytochemical analysis of cultured brain cells and paraffin sections of brain. Tricellulin mRNA was detected in primary cultures and in a cell line of human brain microvascular endothelial cells. Protein expression was confirmed by Western blot and immunofluorescence analysis, which further highlighted the localization of tricellulin in the cell membrane at tricellular and along bicellular contacts, and in the nucleus and perinuclear region. Compared with the well-studied TJ protein, zonula occludens-1, tricellulin expression was less marked at the cell membrane but more evident in the nuclear and perinuclear regions. The presence of tricellulin in cultured endothelial cells was corroborated by immunohistochemical and immunofluorescence staining in brain blood vessels, where it was colocalized with another TJ protein, claudin-5. Tricellulin mRNA was detected in neurons and astrocytes, whereas protein expression was observed in astrocytes but not in neurons, as shown by immunofluorescence analysis. This study reveals the presence and subcellular distribution of tricellulin in brain endothelial cells, both in vitro and in situ and its colocalization with other relevant TJ proteins. Moreover, it demonstrates the expression of the protein in astrocytes opening new avenues for future research to establish the biological significance of tricellulin expression in glial cells.     

Different Roles for Contracture and Calpain in Calcium Paradox-Induced Heart Injury

The Ca²⁺ paradox represents a good model to study Ca²⁺ overload injury in ischemic heart diseases. We and others have demonstrated that contracture and calpain are involved in the Ca²⁺ paradox-induced injury. This study aimed to elucidate their roles in this model. The Ca²⁺ paradox was elicited by perfusing isolated rat hearts with Ca²⁺-free KH media for 3 min or 5 min followed by 30 min of Ca²⁺ repletion. The LVDP was measured to reflect contractile function, and the LVEDP was measured to indicate contracture. TTC staining and the quantification of LDH release were used to define cell death. Calpain activity and troponin I release were measured after Ca²⁺ repletion. Ca²⁺ repletion of the once 3-min Ca²⁺ depleted hearts resulted in almost no viable tissues and the disappearance of contractile function. Compared to the effects of the calpain inhibitor MDL28170, KB-R7943, an inhibitor of the Na⁺/Ca²⁺ exchanger, reduced the LVEDP level to a greater extent, which was well correlated with improved contractile function recovery and tissue survival. The depletion of Ca²⁺ for 5 min had the same effects on injury as the 3-min Ca²⁺ depletion, except that the LVEDP in the 5-min Ca²⁺ depletion group was lower than the level in the 3-min Ca²⁺ depletion group. KB-R7943 failed to reduce the level of LVEDP, with no improvement in the LVDP recovery in the hearts subjected to the 5-min Ca²⁺ depletion treatment; however, KB-R7943 preserved its protective effects in surviving tissue. Both KB-R7943 and MDL28170 attenuated the Ca²⁺ repletion-induced increase in calpain activity in 3 min or 5 min Ca²⁺ depleted hearts. However, only KB-R7943 reduced the release of troponin I from the Ca²⁺ paradoxic heart. These results provide evidence suggesting that contracture is the main cause for contractile dysfunction, while activation of calpain mediates cell death in the Ca²⁺ paradox.     

Effect of Ca2+ on programmed death of guard and epidermal cells of pea leaves

The effect of Ca²⁺ on programmed death of guard cells (GC) and epidermal cells (EC) determined from destruction of the cell nucleus was investigated in epidermis of pea leaves. Ca²⁺ at concentrations of 1–100 μM increased and at a concentration of 1 mM prevented the CN—induced destruction of the nucleus in GC, disrupting the permeability barrier of GC plasma membrane for propidium iodide (PI). Ca²⁺ at concentrations of 0.1–1 mM enhanced drastically the number of EC nuclei stained by PI in epidermis treated with chitosan, an inducer of programmed cell death. The internucleosomal DNA fragmentation caused by CN^? was suppressed by 2 mM Ca²⁺ on 6 h incubation, but fragmentation was stimulated on more prolonged treatment (16 h). Presumably, the disruption of the permeability barrier of plasma membrane for PI is not a sign of necrosis in plant cells. Quinacrine and diphenylene iodonium at 50 μM concentration prevented GC death induced by CN^? or CN^? + 0.1 mM Ca²⁺ but had no influence on respiration and photosynthetic O₂ evolution in pea leaf slices. The generation of reactive oxygen species determined from 2′,7′-dichlorofluorescein fluorescence was promoted by Ca²⁺ in epidermal peels from pea leaves.