Claudin-8 interacts with multi-PDZ domain protein 1 (MUPP1) and reduces paracellular conductance in epithelial cells.

The claudin family is a set of integral membrane proteins found at cell-cell interactions in tight junctions. To identify proteins that interact with claudin-8, we used the yeast two-hybrid system to search for binding partners. Using the C-terminal 37 amino acids of claudin-8 as bait, we screened a human kidney cDNA library and identified multi-PDZ domain protein 1 (MUPP1) as a claudin-8 binding protein. MUPP1 contains 13 PDZ domains and binds to claudin-8 though its PDZ9 domain. When MDCK cells were transfected with epitope-tagged claudin-8 or MUPP1, both molecules were concentrated at cell-cell junctions. The interaction of claudin-8 and MUPP1 in vivo was confirmed by co-immunolocalization and co-immunoprecipitation in MDCK cells. Expression of claudin-8-myc increased transepithelial electrical resistance (TER) and reduced paracellular flux using FITC-dextran as a tracer. Over-expression of FLAG-MUPP1 in MDCK cells also reduced the epithelial paracelhular conductance. Our results indicate that claudin-8 and MUPP1 interact in tight junctions of epithelial cells and are involved in the tight junction barrier function.

Prenatal lens development in connexin43 and connexin50 double knockout mice.

PURPOSE: To determine the roles of intercellular communication in embryonic eye growth and development, mice with a targeted deletion of the Cx43 gene were examined, and mice without both Cx43 and Cx50 were generated and analyzed. METHODS: Embryonic eyes and lenses from wild-type mice, or mice deficient in Cx43, Cx50, or both Cx43 and Cx50 were collected and analyzed structurally by light and electron microscopy, immunohistochemically using connexin-specific antibodies, biochemically by Western blot analysis, and physiologically by measuring patterns of junctional communication revealed by iontophoretic injection of junction-permeable reporter molecules. RESULTS: Cx50 expression was limited to the ocular lens and was not detected in either the cornea or the retina. Cx43(-/-) embryos showed development of structurally normal lenses and eyes when examined by light and electron microscopy through embryonic day (E)18.5. In addition, Cx43(-/-) lenses synthesized four different markers of lens differentiation: MIP26, alphaA-crystallin, alphaB-crystallin, and gamma-crystallin. Double-knockout lenses were also histologically normal through E18.5 and synthesized the four lens differentiation markers. When assayed by intracellular injection with Lucifer yellow (Molecular Probes, Eugene, OR) and neurobiotin at E15.5, Cx43(-/-)/Cx50(-/-) lenses retained gap junction-mediated dye transfer between fiber cells. In contrast, dye transfer in double-knockout lenses was dramatically reduced between epithelial cells and was eliminated between epithelial cells and fibers. CONCLUSIONS: These data indicate that the unique functional properties of both Cx43 and Cx50 are not required for prenatal lens development and that connexin diversity is required for regulation of postnatal growth and homeostasis.

Molecular cloning, expression analysis, and functional characterization of connexin44.1: a zebrafish lens gap junction protein.

The connexin family of genes codes for proteins that oligomerize into a connexon of six subunits to form one half of the gap junction channel. Gap junctions are plasma membrane structures that mediate intercellular communication by joining the cytoplasm of two cells, allowing the passage of small molecules and metabolites, and contributing significantly to the maintenance of tissue homeostasis. The signaling mediated by these junctions appears to be necessary for the correct timing of key developmental events. This communication is especially important in the avascular lens where the intercellular passage of metabolites, second messengers, and ions is necessary to maintain the correct ionic balance in the lens fibre cells, and prevent cataract formation. To characterize the role that the connexin genes play in development, a novel connexin was cloned from zebrafish. A genomic clone was isolated that contained a 1,173 base open reading frame. The nucleotide sequence in this open reading frame shows extensive sequence similarity to mouse connexin50 (Cx50), chicken Cx45.6, sheep Cx49, and human Cx50. The protein encoded by this open reading frame contains 391 amino acids, with a predicted molecular weight of 44.1 kDa and a typical connexin transmembrane topology. By using the LN54 radiation hybrid panel, the Cx44.1 gene was mapped to linkage group 1. Whole-mount in situ hybridization and Northern blot analyses were performed on zebrafish embryos at various developmental stages to characterize the developmental expression of the Cx44.1 message. The ocular lens was the only tissue in which Cx44.1 transcripts were detected. The transcripts were first detected in the lens around 24 hr post fertilization and remained detectable until 120 hr post fertilization. Electrophysiological analysis of Cx44.1 channels revealed gating properties that were virtually identical to the mouse and chicken orthologues of Cx44.1.

Oocyte-granulosa cell heterologous gap junctions are required for the coordination of nuclear and cytoplasmic meiotic competence.

Homologous gap junctions are generally recognized as a means of coordinating cellular behavior under developmental and homeostatic conditions. In the mammalian ovary, heterologous gap junctions between the oocyte and the granulosa cells have been widely implicated in the regulation of meiotic maturation late in oogenesis. However, the role of oocyte-granulosa cell gap junctions at earlier stages of oogenesis is poorly understood. Stage-specific defects in both oocyte and follicle development have been identified in juvenile mice deficient in heterologous oocyte-granulosa cell gap junctions due to targeted deletion of Gja4, the gene encoding connexin-37. Follicle development arrests at the type 4 preantral stage and although oocytes commence growth, oocyte growth ceases at a diameter of 52 microm (74.3% of control size). Analysis of cell cycle and cytoskeletal markers indicates that oocytes arrest in a G(2) state based on uniform decondensed GV chromatin, interphase microtubule arrays, and nonphosphorylated cytoplasmic centrosomes. Functional assays of meiotic competence confirm that oocytes from connexin-37-deficient mice are unable to enter M phase (initiate meiotic maturation) unless treated with the phosphatase inhibitor okadaic acid (OA). Unlike growing oocytes from heterozygous control animals, OA-treated oocytes from connexin-37-deficient mice respond acutely and progress rapidly to the circular bivalent stage of meiosis I and upon removal from OA rapidly revert to an interphase state. In contrast, OA-treated control incompetent oocytes are slow to respond, exhibit a lower proportion of chromosomal bivalent stage oocytes, but remain in and progress into meiotic M phase upon removal from OA. This study demonstrates that heterologous gap-junctional communication is required for the completion of oocyte growth and the acquisition of cytoplasmic meiotic competence.

Gap junctional communication in the early Xenopus embryo.

In the Xenopus embryo, blastomeres are joined by gap junctions that allow the movement of small molecules between neighboring cells. Previous studies using Lucifer yellow (LY) have reported asymmetries in the patterns of junctional communication suggesting involvement in dorso-ventral patterning. To explore that relationship, we systematically compared the transfer of LY and neurobiotin in embryos containing 16-128 cells. In all cases, the junction-permeable tracer was coinjected with a fluorescent dextran that cannot pass through gap junctions. Surprisingly, while LY appeared to transfer in whole-mount embryos, in no case did we observe junctional transfer of LY in fixed and sectioned embryos. The lack of correspondence between data obtained from whole-mounts and from sections results from two synergistic effects. First, uninjected blastomeres in whole-mounts reflect and scatter light originating from the intensely fluorescent injected cell, creating a diffuse background interpretable as dye transfer. Second, the heavier pigmentation in ventral blastomeres masks this scattered signal, giving the impression of an asymmetry in communication. Thus, inspection of whole-mount embryos is an unreliable method for the assessment of dye transfer between embryonic blastomeres. A rigorous and unambiguous demonstration of gap junctional intercellular communication demands both the coinjection of permeant and impermeant tracers followed by the examination of sectioned specimens. Whereas LY transfer was never observed, neurobiotin was consistently transferred in both ventral and dorsal aspects of the embryo, with no apparent asymmetry. Ventralization of embryos by UV irradiation and dorsalization by Xwnt-8 did not alter the patterns of communication. Thus, our results are not compatible with current models for a role of gap junctional communication in dorso-ventral patterning.

Truncation mutants of the tight junction protein ZO-1 disrupt corneal epithelial cell morphology.

The tight junction is the most apical intercellular junction of epithelial cells and regulates transepithelial permeability through the paracellular pathway. To examine possible functions for the tight junction-associated protein ZO-1, C-terminally truncated mutants and a deletion mutant of ZO-1 were epitope tagged and stably expressed in corneal epithelial cell lines. Only full-length ZO-1 and one N-terminal truncation mutant targeted to cell borders; other mutants showed variable cytoplasmic distributions. None of the mutants initially disrupted the localization of endogenous ZO-1. However, long-term stable expression of two of the N-terminal mutants resulted in a dramatic change in cell shape and patterns of gene expression. An elongated fibroblast-like shape replaced characteristic epithelial cobblestone morphology. In addition, vimentin and smooth muscle actin expression were up-regulated, although variable cytokeratin expression remained, suggesting a partial transformation to a mesenchymal cell type. Concomitant with the morphological change, the expression of the integral membrane tight junction protein occludin was significantly down-regulated. The localizations of endogenous ZO-1 and another family member, ZO-2, were disrupted. These findings suggest that ZO-1 may participate in regulation of cellular differentiation.

Restoration of tight junction structure and barrier function by down-regulation of the mitogen-activated protein kinase pathway in ras-transformed Madin-Darby canine kidney cells.

In the Madin-Darby canine kidney epithelial cell line, the proteins occludin and ZO-1 are structural components of the tight junctions that seal the paracellular spaces between the cells and contribute to the epithelial barrier function. In Ras-transformed Madin-Darby canine kidney cells, occludin, claudin-1, and ZO-1 were absent from cell-cell contacts but were present in the cytoplasm, and the adherens junction protein E-cadherin was weakly expressed. After treatment of the Ras-transformed cells with the mitogen-activated protein kinase kinase (MEK1) inhibitor PD98059, which blocks the activation of mitogen-activated protein kinase (MAPK), occludin, claudin-1, and ZO-1 were recruited to the cell membrane, tight junctions were assembled, and E-cadherin protein expression was induced. Although it is generally believed that E-cadherin-mediated cell-cell adhesion is required for tight junction assembly, the recruitment of occludin to the cell-cell contact area and the restoration of epithelial cell morphology preceded the appearance of E-cadherin at cell-cell contacts. Both electron microscopy and a fourfold increase in the transepithelial electrical resistance indicated the formation of functional tight junctions after MEK1 inhibition. Moreover, inhibition of MAPK activity stabilized occludin and ZO-1 by differentially increasing their half-lives. We also found that during the process of tight junction assembly after MEK1 inhibition, tyrosine phosphorylation of occludin and ZO-1, but not claudin-1, increased significantly. Our study demonstrates that down-regulation of the MAPK signaling pathway causes the restoration of epithelial cell morphology and the assembly of tight junctions in Ras-transformed epithelial cells and that tyrosine phosphorylation of occludin and ZO-1 may play a role in some aspects of tight junction formation.

Occludin 1B, a variant of the tight junction protein occludin.

Occludin and claudin are the major integral membrane components of the mammalian tight junction. Although more than 11 distinct claudins have been identified, only 1 occludin transcript has been reported thus far. Therefore, we searched by reverse transcription-PCR for occludin-related sequences in Madin-Darby canine kidney (MDCK) mRNA and identified a transcript encoding an alternatively spliced form of occludin, designated occludin 1B. The occludin 1B transcript contained a 193-base pair insertion encoding a longer form of occludin with a unique N-terminal sequence of 56 amino acids. Analysis of the MDCK occludin gene revealed an exon containing the 193-base pair sequence between the exons encoding the original N terminus and the distal sequence, suggesting that occludin and occludin 1B arise from alternative splicing of one transcript. To assess the expression and distribution of occludin 1B, an antibody was raised against its unique N-terminal domain. Immunolabeling of occludin 1B in MDCK cells revealed a distribution indistinguishable from that of occludin. Furthermore, occludin 1B staining at cell-to-cell contacts was also found in cultured T84 human colon carcinoma cells and in frozen sections of mouse intestine. Immunoblots of various mouse tissues revealed broad coexpression of occludin 1B with occludin. The wide epithelial distribution and the conservation across species suggests a potentially important role for occludin 1B in the structure and function of the tight junction.

Isoform specific expression of the neuronal F-actin binding protein, drebrin, in specialized cells of stomach and kidney epithelia.

To further understand the functional role that the F-actin binding protein, drebrin (developmentally regulated brain protein), plays in the regulation of F-actin, we characterized its expression in non-neuronal cells. Using nanoelectrospray mass spectrometry methods, we initially identified drebrin in non-neuronal cultured cells. Using a drebrin-specific monoclonal antibody, we were able to detect drebrin protein in several different cell lines derived from fibroblasts, astrocytomas, and simple epithelia, but not in cell lines derived from stratified epithelia. Double-label immunofluorescence experiments of cultured cell monolayers revealed the localization of drebrin at the apical plasma membrane together with a pool of submembranous F-actin. Immunoblot analysis of mouse organs revealed that, in addition to its high levels of expression in brain, drebrin was present in stomach and to a lesser degree in kidney, colon, and urinary bladder. Drebrin protein detected in the non-brain organs migrated faster through SDS-PAGE gels, indicating that the lower molecular weight embryonic brain isoform (E2) may be the prominent isoform in these organs. RT-PCR experiments confirmed the specific expression of the E2 isoform in adult stomach, kidney, and cultured cells. In situ immunofluorescence experiments revealed a cell-type specific pattern in both stomach and kidney. In stomach, drebrin was specifically expressed in the acid-secreting parietal cells of the fundic glands, where it accumulated at the extended apical membrane of the canaliculi. In kidney, drebrin was expressed in acid-secreting type A intercalated cells, where it localized specifically to the apical plasma membrane. Drebrin was expressed as well in the distal tubule epithelial cells where the protein was concentrated at the luminal surface and present at the interdigitations of the basolateral membranes.

Innexin-3 forms connexin-like intercellular channels.

Innexins comprise a large family of genes that are believed to encode invertebrate gap junction channel-forming proteins. However, only two Drosophila innexins have been directly tested for the ability to form intercellular channels and only one of those was active. Here we tested the ability of Caenorhabditis elegans family members INX-3 and EAT-5 to form intercellular channels between paired Xenopus oocytes. We show that expression of INX-3 but not EAT-5, induces electrical coupling between the oocyte pairs. In addition, analysis of INX-3 voltage and pH gating reveals a striking degree of conservation in the functional properties of connexin and innnexin channels. These data strongly support the idea that innexin genes encode intercellular channels.

Functional characteristics of skate connexin35, a member of the gamma subfamily of connexins expressed in the vertebrate retina.

Retinal neurons are coupled by electrical synapses that have been studied extensively in situ and in isolated cell pairs. Although many unique gating properties have been identified, the connexin composition of retinal gap junctions is not well defined. We have functionally characterized connexin35 (Cx35), a recently cloned connexin belonging to the gamma subgroup expressed in the skate retina, and compared its biophysical properties with those obtained from electrically coupled retinal cells. Injection of Cx35 RNA into pairs of Xenopus oocytes induced intercellular conductances that were voltage-gated at transjunctional potentials >/= 60 mV, and that were also closed by intracellular acidification. In contrast, Cx35 was unable to functionally interact with rodent connexins from the alpha or beta subfamilies. Voltage-activated hemichannel currents were also observed in single oocytes expressing Cx35, and superfusing these oocytes with medium containing 100 microm quinine resulted in a 1.8-fold increase in the magnitude of the outward currents, but did not change the threshold of voltage activation (membrane potential = +20 mV). Cx35 intercellular channels between paired oocytes were insensitive to quinine treatment. Both hemichannel activity and its modulation by quinine were seen previously in recordings from isolated skate horizontal cells. Voltage-activated currents of Cx46 hemichannels were also enhanced 1. 6-fold following quinine treatment, whereas Cx43-injected oocytes showed no hemichannel activity in the presence, or absence, of quinine. Although the cellular localization of Cx35 is unknown, the functional characteristics of Cx35 in Xenopus oocytes are consistent with the hemichannel and intercellular channel properties of skate horizontal cells.

Gap junctional intercellular communication in the mouse ovarian follicle.

A targeted disruption of the gene encoding the gap junction protein connexin37 (Cx37; alpha 4) results in female infertility. Mutant follicles are not observed to develop beyond early antral stages, and there is a lack of both observable mature Graafian follicles and ovulation. The oocytes are unable to acquire meiotic competence. Following oocyte failure, the residual follicular cells do not undergo atresia but rather transdifferentiate into luteal cells, resulting in a mutant ovary populated with numerous, inappropriate corpora lutea. These results indicate that the Cx37-containing gap junctions formed between oocyte and follicular cells permit bidirectional signalling between the two cell types. These junctions are required for oocyte growth and development during preantral stages of the follicle, and for the inhibition of follicle cell luteinization. An additional role for these junctions may be to permit transfer of cytoplasmic signals required to hold oocytes in meiotic arrest. Since the mutant follicles never acquire meiotic competence, this latter role for gap junctional communication cannot be tested in this model.

Diverse functions of vertebrate gap junctions.

Gap junctions are clusters of intercellular channels between adjacent cells. The channels are formed by the direct apposition of oligomeric transmembrane proteins, permitting the direct exchange of ions and small molecules (< 1 kDa) between cells without involvement of the extracellular space. Vertebrate gap junction channels are composed of oligomers of connexins, an enlarging family of proteins consisting of perhaps > 20 members. This article reviews recent advances in understanding the structure of intercellular channels and describes the diverse functions attributable to gap junctions as a result of insights gained from targeted gene disruptions in mice and genetic disease in humans.

Targeted ablation of connexin50 in mice results in microphthalmia and zonular pulverulent cataracts.

In the ocular lens, gap junctional communication is a key component of homeostatic mechanisms preventing cataract formation. Gap junctions in rodent lens fibers contain two known intercellular channel-forming proteins, connexin50 (Cx50) and Cx46. Since targeted ablation of Cx46 has been shown to cause senile-type nuclear opacities, it appears that Cx50 alone cannot meet homeostatic requirements. To determine if lens pathology arises from a reduction in levels of communication or the loss of a connexin-specific function, we have generated mice with a targeted deletion of the Cx50 gene. Cx50-null mice exhibited microphthalmia and nuclear cataracts. At postnatal day 14 (P14), Cx50-knockout eyes weighed 32% less than controls, whereas lens mass was reduced by 46%. Cx50-knockout lenses also developed zonular pulverulent cataracts, and lens abnormalities were detected by P7. Deletion of Cx50 did not alter the amounts or distributions of Cx46 or Cx43, a component of lens epithelial junctions. In addition, intercellular passage of tracers revealed the persistence of communication between all cell types in the Cx50-knockout lens. These results demonstrate that Cx50 is required not only for maintenance of lens transparency but also for normal eye growth. Furthermore, these data indicate that unique functional properties of both Cx46 and Cx50 are required for proper lens development.

Problem based teaching and learning as a bridge from basic anatomy to clinical clerkships.

This article describes a Clinical Anatomy course designed to bridge basic anatomy with clinical clerkships. It is given in the second year, after the traditional dissecting anatomy course. Students revisit anatomy during small group discussions of clinical cases. An example of a case is described together with a summary of a typical group process stimulated by the case. The group process enables students to develop clinical thinking and problem solving skills fundamental to clinical practice. They learn to search for medical knowledge resources, and to work in teams. The tutor evaluates the students' progress based on their knowledge building, problem solving and development of their interpersonal skills. Problem based learning in this interdisciplinary anatomy course allows students and faculty both horizontal and vertical integration within the curriculum.

Phosphorylation of lens-fiber connexins in lens organ cultures.

Lens gap junction proteins, connexins [1], are known to be phosphorylated in vivo. Phosphorylated states of connexins were examined in lens cultures to define in vitro models for the study of the functions of lens connexin phosphorylation in lens biology. In organ and differentiated cell primary cultures, chick lens-fiber connexins, connexin45.6 and connexin56, were labeled with [32P]orthophosphate. Pulse-chase experiments of lens organ cultures with [35S]methionine demonstrated that connexin45.6 and connexin56 were properly processed into the phosphorylated forms observed in vivo. However, in lens cell primary cultures, both connexins had short half-lives, and connexin56 was degraded before it was phosphorylated into the form which showed the largest mobility shift. The data suggested that the phosphorylation patterns of connexins in lens organ cultures were similar to in vivo connexin phosphorylation, while primary cultures revealed abnormal rates of protein turnover and incomplete phosphorylation. Treatment of lens organ cultures with protein kinase inhibitors indicated that protein kinase C was involved in the phosphorylation of connexin45.6 and connexin56. Comparison of the phosphopeptide patterns by two-dimensional mapping suggested that protein kinase C was involved in the phosphorylation of connexin45.6 and that it phosphorylated the C-terminus of connexin45.6 in vitro.

Formation of the gap junction intercellular channel requires a 30 degree rotation for interdigitating two apposing connexons.

Intercellular communication via gap junction membrane channels cannot occur until two apposing hemichannels (connexons) meet and dock to form a sealed cell-cell conduit. In particular, an important question is how does the structure at the extracellular surface influence the molecular recognition of the two connexons. In this study, cryoelectron microscopy and computer modeling provide evidence that the formation of the gap junction intercellular channel requires a 30 degree rotation between hemichannels for proper docking. With this amount of rotation, the peaks (protrusions) on one connexon fit into the valleys of the apposed connexon in the 3-D model, which would make for an ionically tight interface necessary for a functional cell-cell channel. Docking appears to be governed by a "lock and key" mechanism via a simple interdigitation of the six protrusions from each connexon. This interdigitation increases significantly the contact surface area and potential number of hydrogen bonds or hydrophobic interactions and/or other attractive interactions. Having a larger surface area than if the surfaces were flat would explain the biochemical requirements for conditions characterized previously for splitting of channels into hemichannels. The docked connexons were computationally fitted into two gap junction structures, which further confirmed the interdigitated manner of docking.

Mice lacking connexin40 have cardiac conduction abnormalities characteristic of atrioventricular block and bundle branch block.

Activation of cardiac muscle is mediated by the His-Purkinje system, a discrete pathway containing fast-conducting cells (Purkinje fibers) which coordinate the spread of excitation from the atrioventricular node (AV node) to ventricular myocardium [1]. Although pathologies of this specialized conduction system are common in humans, especially among the elderly [2], their molecular bases have not been defined. Gap junctions are present at appositions between Purkinje fibers and could provide a mechanism for propagating impulses between these cells [3]. Studies of the expression of connexins - the family of proteins from which gap junctions are formed - reveal that connexin40 (Cx40) is prominent in the conduction system [4]. In order to study the role of gap junction communication in cardiac conduction, we generated mice that lack Cx40. Using electrocardiographic analysis, we show that Cx40 null mice have cardiac conduction abnormalities characteristic of first-degree atrioventricular block with associated bundle branch block. Thus, gap junctions are essential for the rapid conduction of impulses in the His-Purkinje system.