Specific substrates composed of collagen and fibronectin support the formation of epithelial cell sheets by MDCK cells lacking α-catenin or classical cadherins.

The effect of the extracellular matrix substrates on the formation of epithelial cell sheets was studied using MDCK cells in which the α-catenin gene was disrupted. Although the mutant cells did not form an epithelial cell sheet in conventional cell culture, the cells formed an epithelial cell sheet when they were cultured on or in a collagen gel; the same results were not observed when cells were cultured on collagen-coated cover glasses or culture dishes. Moreover, the cells cultured on the cell culture inserts coated with fibronectin, Matrigel, or vitronectin formed epithelial cell sheets, whereas the cells cultured on cover glasses coated with these proteins did not form the structure, implying that the physical and chemical features of the substrates exert a profound effect on the formation of epithelial cell sheets. MDCK cells lacking the expression of E- and K-cadherins displayed similar properties. When the mutant MDCK cells were cultured in the presence of blebbistatin, they formed epithelial cell sheets, suggesting that myosin II was involved in the formation of these sheets. These cell sheets showed intimate cell-cell adhesion, and electron microscopy confirmed the formation of cell junctions. We propose that specific ECM substrates organize the formation of basic epithelial cell sheets, whereas classical cadherins stabilize cell-cell contacts and promote the formation of structures.

Desmoglein 2 regulates the intestinal epithelial barrier via p38 mitogen-activated protein kinase.

Intestinal epithelial barrier properties are maintained by a junctional complex consisting of tight junctions (TJ), adherens junctions (AJ) and desmosomes. Desmoglein 2 (Dsg2), an adhesion molecule of desmosomes and the only Dsg isoform expressed in enterocytes, is required for epithelial barrier properties and may contribute to barrier defects in Crohn's disease. Here, we identified extradesmosomal Dsg2 on the surface of polarized enterocytes by Triton extraction, confocal microscopy, SIM and STED. Atomic force microscopy (AFM) revealed Dsg2-specific binding events along the cell border on the surface of enterocytes with a mean unbinding force of around 30pN. Binding events were blocked by an inhibitory antibody targeting Dsg2 which under same conditions activated p38MAPK but did not reduce cell cohesion. In enterocytes deficient for Dsg2, p38MAPK activity was reduced and both barrier integrity and reformation were impaired. Dsc2 rescue did not restore p38MAPK activity indicating that Dsg2 is required. Accordingly, direct activation of p38MAPK in Dsg2-deficient cells enhanced barrier reformation demonstrating that Dsg2-mediated activation of p38MAPK is crucial for barrier function. Collectively, our data show that Dsg2, beside its adhesion function, regulates intestinal barrier function via p38MAPK signalling. This is in contrast to keratinocytes and points towards tissue-specific signalling functions of desmosomal cadherins.

Epithelial DLD-1 Cells with Disrupted E-cadherin Gene Retain the Ability to Form Cell Junctions and Apico-basal Polarity.

Gene editing methods were applied to the study of E-cadherin function in epithelial cells. The E-cadherin gene in epithelial DLD-1 cells was ablated using TALEN. The resultant cells showed round fibroblast-like morphology and had almost no Ca(2+)-dependent cell aggregation activity. E-cadherin re-expression in the knockout cells restored epithelial cell morphology and strong Ca(2+)-dependent cell-cell adhesion activity, indicating that the knockout cells retained the ability to support cadherin function. The knockout cells showed partial localization of desmoplakin and ZO-1 at intercellular contact sites. The transfectants expressing mutant E-cadherin lacking the cytoplasmic domain showed clear localization of desmoplakin and ZO-1 at cell-cell contact sites, although the cells had only weak Ca(2+)-dependent cell adhesion activity. Electron microscopy revealed the formation of intercellular junctions and apico-basal polarity in these cells. A portion of these cells occasionally formed an epithelial-like structure after prolonged culture. When the cells were treated with blebbistatin, the localization was enhanced. However, the localization was incomplete and contained defects. Double-knockout MDCK cells for the E-cadherin and cadherin-6 genes showed similar results, suggesting that the above properties were general. The present results showed that an epithelial-like structure could be formed without E-cadherin, but that the construction of mature epithelia requires E-cadherin.

Desmocollin-2 alone forms functional desmosomal plaques, with the plaque formation requiring the juxtamembrane region and plakophilins.

The role of the juxtamembrane region of the desmocollin-2 cytoplasmic domain in desmosome formation was investigated by using gene knockout and reconstitution experiments. When a deletion construct of the desmocollin-2 juxtamembrane region was expressed in HaCaT cells, the mutant protein became localized linearly at the cell-cell boundary, suggesting the involvement of this region in desmosomal plaque formation. Then, desmocollin-2 and desmoglein-2 genes of epithelial DLD-1 cells were ablated by using the CRISPR/Cas9 system. The resultant knockout cells did not form desmosomes, but re-expression of desmocollin-2 in the cells formed desmosomal plaques in the absence of desmoglein-2 and the transfectants showed significant cell adhesion activity. Intriguingly, expression of desmocollin-2 lacking its juxtamembrane region did not form the plaques. The results of an immunoprecipitation and GST-fusion protein pull-down assay suggested the binding of plakophilin-2 and -3 to the region. Ablation of plakophilin-2 and -3 genes resulted in disruption of the plaque-like accumulation and linear localization of desmocollin-2 at intercellular contact sites. These results suggest that the juxtamembrane region of desmocollin-2 and plakophilins are involved in the desmosomal plaque formation, possibly through the interaction between this region and plakophilins.

Protocadherin-9 involvement in retinal development in Xenopus laevis.

Biological roles of most protocadherins (Pcdhs) are a largely unsolved problem. Therefore, we cloned cDNA for Xenopus laevis protocadherin-9 and characterized its properties to elucidate the role. The deduced amino acid sequence was highly homologous to those of mammalian protocadherin-9 s. X. laevis protocadherin-9 expressed from the cDNA in L cells showed basic properties similar to those of mammalian Pcdhs. Expression of X. laevis protocadherin-9 was first detected in stage-31 embryos and increased as the development proceeded. In the later stage embryos and the adults, the retina strongly expressed protocadherin-9, which was mainly localized at the plexiform layers. Injection of morpholino anti-sense oligonucleotide against protocadherin-9 into the fertilized eggs inhibited eye development; and eye growth and formation of the retinal laminar structure were hindered. Moreover, affected retina showed abnormal extension of neurites into the ganglion cell layer. Co-injection of protocadherin-9 mRNA with the morpholino anti-sense oligonucleotide rescued the embryos from the defects. These results suggest that X. laevis protocadherin-9 was involved in the development of retina structure possibly through survival of neurons, formation of the lamina structure and neurite localization.

p120-Catenin is essential for N-cadherin-mediated formation of proper junctional structure, thereby establishing cell polarity in epithelial cells.

The role of p120-catenin in the function of classical cadherins is still enigmatic despite various studies. To elucidate its role, we examined the effect of p120-catenin on the N-cadherin-mediated localization of junctional proteins in epithelial cells in this study. Cadherin-deficient MIA PaCa-2 epithelial cells did not show linear localization of tight junction proteins ZO-1 and occludin. When N-cadherin was expressed in these cells, however, the resultant transfectant cells revealed strong cell adhesion activity and linear localization of ZO-1, occludin, and N-cadherin in the lateral membrane. When the p120-catenin-binding site of N-cadherin was disrupted, the linear localization of ZO-1 and occludin disappeared, and the mutant N-cadherin became localized more diffusely in the transfectant, although the cell adhesion activity did not change much. Knockdown of p120-catenin also resulted in the very weak localization of ZO-1 and occludin. A similar effect of p120-catenin on the localization of junctional proteins was obtained under more dynamic conditions in a wound healing assay. Moreover, p120-catenin was essential for the regulation of centrosome orientation in this healing assay. Taken together, the present data indicate that p120-catenin is essential for N-cadherin-mediated formation of proper junctional structures and thereby the establishment of the cell polarity. Similar results were obtained when E-cadherin mutants comparable to those of N-cadherin were used, suggesting that p120-catenin plays the same role in the function of other classical cadherins.

Adhesion properties and retinofugal expression of chicken protocadherin-19.

Protocadherin-19 has been implicated in some neurological diseases, but even the basic properties of this protocadherin have not yet been characterized well. Hence, various basic properties of chicken protocadherin-19 were examined to elucidate its biological role. The protocadherin-19 expressed in L cells was localized at the intercellular contact sites and showed Ca(2+)-dependent homophilic cell aggregation activity that was relatively weak but showed stringent specificity. The results of a pull-down assay using fusion proteins of the cytoplasmic domain and glutathione S-transferase yielded specifically bound proteins. In the bound fractions, liquid chromatography-mass spectrometry identified Nck-associated protein 1 and cytoplasmic FMP1 interacting protein 2, which have been reported to bind to glutathione S-transferase fused with the cytoplasmic domain of OL-protocadherin, suggesting that these proteins generally have affinity for delta protocadherins. Protocadherin-19 was mainly expressed in the central nervous system. In the chicken retina, protocadherin-19 was expressed as early as embryonic day 5 and was localized in the ganglion cell layer, inner plexiform layer, and optic nerve layer. Chicken protocadherin-19 was co-localized with syntaxin 1 in inner plexiform layer and was also expressed in the optic nerve and in specific layers of optic tectum. These results suggest that protocadherin-19 plays a role as an adhesion protein in optic nerve fiber bundling, optic nerve targeting, and/or synapse formation.

The extracellular domains of E- and N-cadherin determine the scattered punctate localization in epithelial cells and the cytoplasmic domains modulate the localization.

The accumulation of classical cadherins is essential for their function, but the mechanism is poorly understood. Hence, we investigated the accumulation of E- and N-cadherin and the formation of cell junctions in epithelial cells. Immunostaining revealed a scattered dot-like accumulation of E- and N-cadherin throughout the lateral membrane in MDCK II and other epithelial cells. Mutant E-cadherin lacking the beta-catenin binding site accumulated granularly at cell-cell contact sites and showed weak cell aggregation activity in cadherin-deficient epithelial cells, MIA PaCa2 cells. Mutant E-cadherin lacking the p120-catenin binding site exhibited scattered punctate accumulation and strong cell adhesion activity in MIA PaCa2 cells. Electron microscopy demonstrated that MIA PaCa2 transfectants of E-cadherin containing beta-catenin binding site formed adherens junction, whereas E-cadherin lacking the binding site did not. Mutant N-cadherins showed accumulation properties similar to those of corresponding mutant E-cadherins. Moreover, wild type and mutant N-cadherin lacking the p120-catenin binding site showed subapical accumulation in polarized DLD-1 cells, whereas mutant N-cadherin lacking beta-catenin binding site did not. These results indicate that the extracellular domains of E- and N-cadherin determines the basic localization pattern, whereas the cytoplasmic domains modulate it thereby affects the cell adhesion activity, subapical accumulation, and the formation of adherens junction.

OL-Protocadherin is essential for growth of striatal axons and thalamocortical projections.

The ventral telencephalon in the embryonic brain is thought to provide guidance cues for navigation of thalamocortical axons, but the mechanisms involved remain largely elusive. OL-protocadherin (OL-pc), a member of the cadherin superfamily, is highly expressed by striatal neurons in the developing ventral telencephalon. Here we show that OL-pc-deficient (Pcdh10(-/-)) mice have defects in axon pathways through the ventral telencephalon; for example, thalamocortical and corticothalamic projections cannot cross the ventral telencephalon. In the ventral telencephalon, striatal axons fail to grow out, and, concomitantly, the caudal portion of the globus pallidus and the associated 'corridor' thought to be important for thalamocortical fiber navigation do not form. The inability of the striatum to extend axons is also observed in vitro. These results show that OL-pc is essential for both elongation of striatal axons and patterning of the putative guidance cues for thalamocortical projections.

Distribution of OL-protocadherin in axon fibers in the developing chick nervous system.

OL-protocadherin (OL-pc) is a homophilic cell adhesion molecule that belongs to the cadherin gene superfamily. We cloned and characterized the chicken homologue of OL-pc and examined its expression pattern in chick embryos mainly from embryonic day (E) 3.5 to E6.5. The structure of chick OL-pc was found to be essentially the same as that of mammalian OL-pc's except for some small deletions and insertions in the amino acid sequence. OL-pc protein was detected prominently along developing axonal fibers in the brain and also in the peripheral nervous system. In addition, it was detected in some mesenchymal cells and in the embryonic ectoderm of the mandible and limb bud. In the spinal cord, OL-pc was specifically expressed in motor neurons, and the protein was distributed along motor nerves. Motor nerves merged gradually with sensory nerves showing negative/faint OL-pc expression, but their fibers remained separated as small bundles in the nerves. Interestingly, OL-pc-positive motor nerves such as those to the sternocoracoideus became segregated from OL-pc-faint/weak motor nerves at the plexus region. Moreover, OL-pc was distributed along the path of the branchial nerves. These results suggest that OL-pc might play some roles in axon navigation such as in axon elongation, selective fasciculation, and pathfinding in the early stage of neural development.

The cadherin superfamily in neural development: diversity, function and interaction with other molecules.

Cell-cell interactions are crucial steps for the development of the highly complex nervous system. A variety of cell-cell adhesion molecules of the cadherin superfamily have been found to be expressed in the developing nervous system. Recently it was proposed classic cadherins are involved in various aspects of neural development such as regionalization, brain nucleus formation, neurite outgrowth, target recognition and synaptogenesis. Classic cadherins preferentially bind to the same cadherin subtype ("homophilic adhesion"), and this binding specificity can provide an "adhesive code" that can account for various aspects of neural morphogenesis. In addition, novel members of the cadherin superfamily are also involved in various steps of neural development. The function of these cadherins molecules is orchestrated in the cellular context by a complex network of signaling pathways such as the small GTPase pathway. Here, we will review the molecular properties of the cadherin superfamily and their coordinated roles in the formation of the nervous system along with the accumulated knowledge in non-neuronal systems.

Patch/matrix patterns of gray matter differentiation in the telencephalon of chicken and mouse.

The mammalian striatum, a subpallial area, consists of two compartments (patches/striosomes and matrix) that differ in their neuronal birth dates, connectivity, neurochemistry, and molecular make-up. For example, members of the cadherin family of adhesion molecules (cadherin-8 and OL-protocadherin) are differentially expressed by the striosomes and the striatal matrix. A patch/matrix type of organization also has recently been found in the ventral hyperstriatum and the neostriatum of the chicken pallium, where cell clusters of similar birthdates ("isochronic" clusters) are surrounded by a matrix of cells that are born at a different time. Immunostaining with antibodies against cadherins reveals a similar arrangement of cell clusters. In the avian neostriatum, cadherin-7-positive cell clusters ("islands") are surrounded by a matrix of cells that express R-cadherin. The islands coincide, at least in part, with the isochronic cell clusters, as shown by pulse-labeling with bromodeoxyuridine. Likewise, isochronic clusters of the hyperstriatum ventrale relate to patchy heterogeneities in the cadherin-7 immunoreactivity pattern. Cadherins are known to mediate the aggregation and sorting of cells during development in many organs. Their differential expression by isochronic cell populations in the mammal subpallium and avian pallium suggests a common morphogenetic mechanism that regulates the formation of the patch/matrix patterns in these regions.

Restricted expression of protocadherin 2A in the developing mouse brain.

Protocadherins are cell-cell adhesion molecules that are thought to be involved in neural development. Here, we report the expression pattern of protocadherin 2A (Pc2A) in the developing mouse brain as determined by the in situ hybridization technique. In the postnatal day 2 brain, various regions expressed Pc2A including the cerebellar cortex, ventral posterior thalamic nucleus, dorsal lateral geniculate nucleus, hippocampus and cerebellum (Purkinje cells). In particular, some ependymal cells that form the lining of the lateral ventricle and the third ventricle and floor plate cells lining the fourth ventricle showed prominent expression. In the adult brain, strong expression was restricted to the Purkinje cells. Expression in other areas of the adult brain was down-regulated to a faint level, and only a weak signal was detected in regions such as the retina, olfactory bulb, dentate gyrus of the hippocampus, and in some parts of the medial eminence. These observations suggest that Pc2A is expressed in various regions of the brain in a developmentally regulated manner.