Stability studies of extracellular domain two of neural-cadherin

Neural- (NCAD) and epithelial- (ECAD) cadherin are calcium-dependent cell-adhesive molecules, and are localized at excitatory and inhibitory synapses respectively. They play an important role in synaptogenesis, synapse maintenance and plasticity. The extracellular region plays a critical role in cadherin-mediated cell adhesion, and has five tandemly repeated ectodomains (EC1-EC5). Calcium binding is required for dimer formation between first two N-terminal domains (EC1-EC2). Despite similarity in the primary structure, the extracellular domains of NCAD and ECAD have different intrinsic stability, dimerization affinity and kinetics of disassembly. To investigate the origin of these differences, we are characterizing the modular domains individually. Here, we report studies of NCAD2, EC2 of NCAD. This domain is important for calcium binding and is the physical linkage between the dimerization interface in EC1 and the membrane proximal modular domains. Thermal-denaturation studies show that NCAD2 is less stable than ECAD2 and less influenced by the adjoining 7-residue, N- and C-terminal linker segments. In addition the NCAD2 constructs are less influenced by added salt. This difference is likely due to variation in the overall number and distribution of charges on these anionic proteins. Our studies indicate that despite their sequence similarity and apparently passive role in adhesive dimer formation, EC2 of E- and N-cadherins are distinctly different and may contribute to the differences in energetics and kinetics of dimerization.     

μ2‐Dependent endocytosis of N‐cadherin is regulated by β‐catenin to facilitate neurite outgrowth

Circuit formation in the brain requires neurite outgrowth throughout development to establish synaptic contacts with target cells. Active endocytosis of several adhesion molecules facilitates the dynamic exchange of these molecules at the surface and promotes neurite outgrowth in developing neurons. The endocytosis of N‐cadherin, a calcium‐dependent adhesion molecule, has been implicated in the regulation of neurite outgrowth, but the mechanism remains unclear. Here, we identified that a fraction of N‐cadherin internalizes through clathrin‐mediated endocytosis (CME). Two tyrosine‐based motifs in the cytoplasmic domain of N‐cadherin recognized by the μ2 subunit of the AP‐2 adaptor complex are responsible for CME of N‐cadherin. Moreover, β‐catenin, a core component of the N‐cadherin adhesion complex, inhibits N‐cadherin endocytosis by masking the 2 tyrosine‐based motifs. Removal of β‐catenin facilitates μ2 binding to N‐cadherin, thereby increasing clathrin‐mediated N‐cadherin endocytosis and neurite outgrowth without affecting the steady‐state level of surface N‐cadherin. These results identify and characterize the mechanism controlling N‐cadherin endocytosis through β‐catenin‐regulated μ2 binding to modulate neurite outgrowth.      

N‐cadherin is dispensable for pancreas development but required for β‐cell granule turnover

The cadherin family of cell adhesion molecules mediates adhesive interactions that are required for the formation and maintenance of tissues. Previously, we demonstrated that N‐cadherin, which is required for numerous morphogenetic processes, is expressed in the pancreatic epithelium at E9.5, but later becomes restricted to endocrine aggregates in mice. To study the role of N‐cadherin during pancreas formation and function we generated a tissue‐specific knockout of N‐cadherin in the early pancreatic epithelium by inter‐crossing N‐cadherin‐floxed mice with Pdx1Cre mice. Analysis of pancreas‐specific ablation of N‐cadherin demonstrates that N‐cadherin is dispensable for pancreatic development, but required for β‐cell granule turnover. The number of insulin secretory granules is significantly reduced in N‐cadherin‐deficient β‐cells, and as a consequence insulin secretion is decreased. genesis 48:374–381, 2010. © 2010 Wiley‐Liss, Inc.     

Evidence that tyrosine phosphorylation regulates N-cadherin turnover during retinal development

N-cadherin, a member of the cadherin family of calcium-dependent cell adhesion molecules, mediates adhesive and signaling interactions between cells during development. N-Cadherin undergoes dynamic spatiotemporal changes in expression which correlate with morphogenetic movements of cells during organogenesis and histogenesis. We have previously shown that N-cadherin expression during development is regulated by several mechanisms, including mRNA expression, cytokine modulation, and proteolytically mediated turnover, yielding the NCAD90 protein. The present study was directed at determining the extent to which N-cadherin in primary embryonic cells is the target of endogenous kinases and phosphatases, as well as the effects of modulation of these enzymes on NCAD90 expression. The results of phosphoamino acid analyses, peptide mapping, and measurements of N-cadherin and NCAD90 expression in embryonic tissues indicate that N-cadherin is indeed the target of endogenous kinase and phosphatase action, and that modulation of different classes of these enzymes can result in either stimulation or inhibition of NCAD90 production. These results provide a mechanistic explanation for observations that cadherin function is downregulated following expression of exogenously introduced viral tyrosine kinases and provide a function for the tyrosine phosphatases recently found in association with cadherins. The results indicate that N-cadherin expression during retinal development is possibly regulated in part by modulation of its phosphorylation state, the balance of which may determine whether N-cadherin remains stably expressed or is targeted for proteolytically mediated turnover to produce NCAD90. Dev. Genet. 20:224–234, 1997. © 1997 Wiley-Liss, Inc.     

神经钙粘着蛋白在P19神经元分化中的作用

利用ＲＴ－ＰＣＲ技术,我们检测Ｐ１９细胞体外神经元分化过程中神经钙粘着蛋白（Ｎ－ｃａｄｈｅｒｉｎ）的表达模式。结果显示,该基因在上述过程中存在上调和下调过程,与体内中枢神经系统发育过程的表达模式十分相近。在此基础上,我们将神经钙粘着蛋白基因ｃＤＮＡ全长转入Ｐ１９细胞,通过药物筛选,得到稳定表达钙粘着蛋白的细胞株。     

RhoA/ROCK and Cdc42 regulate cell‐cell contact and N‐cadherin protein level during neurodetermination of P19 embryonal stem cells

RhoGTPases regulate actin‐based signaling cascades and cellular contacts. In neurogenesis, their action modulates cell migration, neuritogenesis, and synaptogenesis. Murine P19 embryonal stem cells differentiate to neurons upon aggregation in the presence of retinoic acid, and we previously showed that RhoA and Cdc42 RhoGTPases are sequentially up‐regulated during neuroinduction, suggesting a role at this very early developmental stage. In this work, incubation of differentiating P19 cells with C3 toxin resulted in decreased aggregate cohesion and cadherin protein level. In contrast, C3 effects were not observed in cells overexpressing recombinant dominant active RhoA. On the other hand, C3 did not affect cadherin in uninduced cells and their postmitotic neuronal derivatives, respectively expressing E‐ and N‐cadherin. RhoA is thus influential on cell aggregation and cadherin expression during a sensitive time window that corresponds to the switch of E‐ to N‐cadherin. Cell treatment with Y27632 inhibitor of Rho‐associated‐kinase ROCK, or advanced overexpression of Cdc42 by gene transfer of a constitutively active form of the protein reproduced C3 effects. RhoA‐antisense RNA also reduced cadherin level and the size of cell aggregates, and increased the generation of fibroblast‐like cells relative to neurons following neuroinduction. Colchicin, a microtubule disrupter, but not cytochalasin B actin poison, importantly decreased cadherin in neurodifferentiating cells. Overall, our results indicate that the RhoA/ROCK pathway regulates cadherin protein level and cell‐cell interactions during neurodetermination, with an impact on the efficiency of the process. The effect on cadherin seems to involve microtubules. The importance of correct timing of RhoA and Cdc42 functional expression in neurogenesis is also raised. © 2004 Wiley Periodicals, Inc. J Neurobiol 60: 289–307, 2004     

miR379–410 cluster miRNAs regulate neurogenesis and neuronal migration by fine‐tuning N‐cadherin

N‐cadherin‐mediated adhesion is essential for maintaining the tissue architecture and stem cell niche in the developing neocortex. N‐cadherin expression level is precisely and dynamically controlled throughout development; however, the underlying regulatory mechanisms remain largely unknown. MicroRNAs (miRNAs) play an important role in the regulation of protein expression and subcellular localisation. In this study, we show that three miRNAs belonging to the miR379–410 cluster regulate N‐cadherin expression levels in neural stem cells and migrating neurons. The overexpression of these three miRNAs in radial glial cells repressed N‐cadherin expression and increased neural stem cell differentiation and neuronal migration. This phenotype was rescued when N‐cadherin was expressed from a miRNA‐insensitive construct. Transient abrogation of the miRNAs reduced stem cell differentiation and increased cell proliferation. The overexpression of these miRNAs specifically in newborn neurons delayed migration into the cortical plate, whereas the knockdown increased migration. Collectively, our results indicate a novel role for miRNAs of the miR379–410 cluster in the fine‐tuning of N‐cadherin expression level and in the regulation of neurogenesis and neuronal migration in the developing neocortex.     

A Common Clathrin‐Mediated Machinery Co‐ordinates Cell–Cell Adhesion and Bacterial Internalization

Invasive bacterial pathogens often target cellular proteins involved in adhesion as a first event during infection. For example, Listeria monocytogenes uses the bacterial protein InlA to interact with E‐cadherin, hijack the host adherens junction (AJ) machinery and invade non‐phagocytic cells by a clathrin‐dependent mechanism. Here, we investigate a potential role for clathrin in cell–cell adhesion. We observed that the initial steps of AJ formation trigger the phosphorylation of clathrin, and its transient localization at forming cell–cell contacts. Furthermore, we show that clathrin serves as a hub for the recruitment of proteins that are necessary for the actin rearrangements that accompany the maturation of AJs. Using an InlA/E‐cadherin chimera, we show that adherent cells expressing the chimera form AJs with cells expressing E‐cadherin. We demonstrate that non‐adherent cells expressing the InlA chimera, as bacteria, can be internalized by E‐cadherin‐expressing adherent cells. Together these results reveal that a common clathrin‐mediated machinery may regulate internalization and cell adhesion and that the relative mobility of one of the interacting partners plays an important role in the commitment to either one of these processes.     

Zebrafish lines expressing UAS‐driven red probes for monitoring cytoskeletal dynamics

Actin filaments and microtubules are principal components of the cytoskeleton that regulate the basic cellular phenomena underlying many fundamental cellular processes. Therefore, analyzing their dynamics in living cells is important for understanding cellular events more precisely. In this article, we report two novel transgenic zebrafish lines expressing red fluorescent proteins tagged with Lifeact or EB1 that interact with actin filaments and microtubule plus ends, respectively, under the control of the GAL4‐UAS system. Using these transgenic lines, we could detect F‐actin and microtubule plus end dynamics in specific tissues of living zebrafish embryos by crossing with GAL4 driver lines. In addition, we could achieve multi‐color imaging using these transgenic lines with GFP‐expressing transgenic lines. Therefore, our transgenic lines that carry UAS‐driven red fluorescent cytoskeletal probes are useful tools for analyzing spatiotemporal changes of the cytoskeletal elements using multicolor live imaging.     

Synapse‐dependent and independent mechanisms of thalamocortical axon branching are regulated by neuronal activity

Axon branching and synapse formation are critical processes for establishing precise circuit connectivity. These processes are tightly regulated by neural activity, but the relationship between them remains largely unclear. We use organotypic coculture preparations to examine the role of synapse formation in the activity‐dependent axon branching of thalamocortical (TC) projections. To visualize TC axons and their presynaptic sites, two plasmids encoding DsRed and EGFP‐tagged synaptophysin (SYP‐EGFP) were cotransfected into a small number of thalamic neurons. Time‐lapse imaging of individual TC axons showed that most branches emerged from SYP‐EGFP puncta, indicating that synapse formation precedes emergences of axonal branches. We also investigated the effects of neuronal activity on axon branching and synapse formation by manipulating spontaneous firing activity of thalamic cells. An inward rectifying potassium channel, Kir2.1, and a bacterial voltage‐gated sodium channel, NaChBac, were used to suppress and promote firing activity, respectively. We found suppressing neural activity reduced both axon branching and synapse formation. In contrast, increasing neural activity promoted only axonal branch formation. Time‐lapse imaging of NaChBac‐expressing cells further revealed that new branches frequently appeared from the locations other than SYP‐EGFP puncta, indicating that enhancing activity promotes axonal branch formation due to an increase of branch emergence at nonsynaptic sites. These results suggest that presynaptic locations are hotspots for branch emergence, and that frequent firing activity can shift branch emergence to a synapse‐independent process. © 2015 Wiley Periodicals, Inc. Develop Neurobiol 76: 323–336, 2016     

Rac1 and RhoA GTPases have antagonistic functions during N-cadherin-dependent cell-cell contact formation in C2C12 myoblasts

Background information. N‐cadherin, a member of the Ca²⁺‐dependent cell—cell adhesion molecule family, plays an essential role in the induction of the skeletal muscle differentiation programme. However, the molecular mechanisms which govern the formation of N‐cadherin‐dependent cell—cell contacts in myoblasts remain unexplored. Results. In the present study, we show that N‐cadherin‐dependent cell contact formation in myoblasts is defined by two stages. In the first phase, N‐cadherin is highly mobile in the lamellipodia extensions between the contacting cells. The second stage corresponds to the formation of mature N‐cadherin‐dependent cell contacts, characterized by the immobilization of a pool of N‐cadherin which appears to be clustered in the interdigitated membrane structures that are also membrane attachment sites for F‐actin filaments. We also demonstrated that the formation of N‐cadherin‐dependent cell—cell contacts requires a co‐ordinated and sequential activity of Rac1 and RhoA. Rac1 is involved in the first stage and facilitates N‐cadherin‐dependent cell—cell contact formation, but it is not absolutely required. Conversely, RhoA is necessary for N‐cadherin‐dependent cell contact formation, since, via ROCK (Rho‐associated kinase) signalling and myosin 2 activation, it allows the stabilization of N‐cadherin at the cell—cell contact sites. Conclusions. We have shown that Rac1 and RhoA have opposite effects on N‐cadherin‐dependent cell—cell contact formation in C2C12 myoblasts and act sequentially to allow its formation.     

Cancer‐upregulated gene 2 (CUG2) overexpression induces apoptosis in SKOV‐3 cells

Cancer‐upregulated gene 2 (CUG2) was originally identified as a potential oncogene commonly up‐regulated in various human cancers. Recently, CUG2 was also identified as a new member of a centromere protein complex, important in the formation of a functional kinetochore complex. Presently, we report the pro‐apoptotic effect of CUG2 when this gene was overexpressed in the SKOV‐3 human ovarian cancer cell line. Apoptotic cell death mediated by CUG2 overexpression was independently demonstrated using cell viability determination, flow cytometry analysis, chromosome fragmentation assay, and the cleavage of the death substrate poly(ADP‐ribose) polymerase. Moreover, activation of caspase‐3 and ‐8 and the cytoplasmic translocation of mitochondrial cytochrome c were evident upon CUG2 expression. Apoptotic cell death was also observed during early development of zebrafish when CUG2 was overexpressed in zebrafish embryo. We propose that high expression of CUG2 induces apoptotic cell death. Copyright © 2010 John Wiley & Sons, Ltd.     

Protocadherin‐17 function in Zebrafish retinal development

Cadherin cell adhesion molecules play crucial roles in vertebrate development including the development of the retina. Most studies have focused on examining functions of classic cadherins (e.g. N‐cadherin) in retinal development. There is little information on the function of protocadherins in the development of the vertebrate visual system. We previously showed that protocadherin‐17 mRNA was expressed in developing zebrafish retina during critical stages of the retinal development. To gain insight into protocadherin‐17 function in the formation of the retina, we analyzed eye development and differentiation of retinal cells in zebrafish embryos injected with protocadherin‐17 specific antisense morpholino oligonucleotides (MOs). Protocadherin‐17 knockdown embryos (pcdh17 morphants) had significantly reduced eyes due mainly to decreased cell proliferation. Differentiation of several retinal cell types (e.g. retinal ganglion cells) was also disrupted in the pcdh17 morphants. Phenotypic rescue was achieved by injection of protocadherin‐17 mRNA. Injection of a vivo‐protocadherin‐17 MO into one eye of embryonic zebrafish resulted in similar eye defects. Our results suggest that protocadherin‐17 plays an important role in the normal formation of the zebrafish retina. © 2012 Wiley Periodicals, Inc. Develop Neurobiol, 2013     

The prodomain of the Bordetella two‐partner secretion pathway protein FhaB remains intracellular yet affects the conformation of the mature C‐terminal domain

Two‐partner secretion (TPS) systems use β‐barrel proteins of the Omp85‐TpsB superfamily to transport large exoproteins across the outer membranes of Gram‐negative bacteria. The Bordetella FHA/FhaC proteins are prototypical of TPS systems in which the exoprotein contains a large C‐terminal prodomain that is removed during translocation. Although it is known that the FhaB prodomain is required for FHA function in vivo, its role in FHA maturation has remained mysterious. We show here that the FhaB prodomain is required for the extracellularly located mature C‐terminal domain (MCD) of FHA to achieve its proper conformation. We show that the C‐terminus of the prodomain is retained intracellularly and that sequences within the N‐terminus of the prodomain are required for this intracellular localization. We also identify sequences at the C‐terminus of the MCD that are required for release of mature FHA from the cell surface. Our data support a model in which the intracellularly located prodomain affects the final conformation of the extracellularly located MCD. We hypothesize that maturation triggers cleavage and degradation of the prodomain.     

Alterations in the temporal expression and function of cadherin‐7 inhibit cell migration and condensation during chondrogenesis of chick limb mesenchymal cells in vitro

Endochondral bone formation requires a complex interplay among immature mesenchymal progenitor cells to form the cartilaginous anlagen, which involves migration, aggregation and condensation. Even though condensation of chondrogenic progenitors is an essential step in this process, its mechanism(s) has not been well studied. Here, we show that cadherin‐7 plays a central role in cellular condensation by modulating cell motility and migration. In this study, many mesenchymal cells failed to migrate, and precartilage condensation was inhibited, after knockdown of endogenous cadherin‐7 levels. Exposure of mesenchymal cells to SB203580 (a specific inhibitor of p38MAPK), LiCl (an inhibitor of GSK‐3β) or overexpression of β‐catenin resulted in inhibition of cadherin‐7 levels and, subsequently, suppression of cell migration. Collectively, our results suggest that cadherin‐7 controls cell migration in chick limb bud mesenchymal cells, and that p38MAPK and GSK signals are responsible for regulating cadherin‐7‐mediated cell migration. J. Cell. Physiol. 221: 161–170, 2009. © 2009 Wiley‐Liss, Inc     

Classic cadherins regulate tangential migration of precerebellar neurons in the caudal hindbrain

Classic cadherins are calcium dependent homophilic cell adhesion molecules that play a key role in developmental processes such as morphogenesis, compartmentalization and maintenance of a tissue. They also play important roles in development and function of the nervous system. Although classic cadherins have been shown to be involved in the migration of non-neuronal cells, little is known about their role in neuronal migration. Here, we show that classic cadherins are essential for the migration of precerebellar neurons. In situ hybridization analysis shows that at least four classic cadherins, cadherin 6 (Cad6), cadherin 8 (Cad8), cadherin11 (Cad11) and N-cadherin (Ncad), are expressed in the migratory streams of lateral reticular nucleus and external cuneate nucleus (LRN/ECN) neurons. Functional analysis performed by electroporation of cadherin constructs into the hindbrain indicates requirement for cadherins in the migration of LRN/ECN neurons both in vitro and in vivo. While overexpression of full-length classic cadherins, NCAD and CAD11, has no effect on LRN/ECN neuron migration, overexpression of two dominant negative (DN) constructs, membrane-bound form and cytoplasmic form, slows it down. Introduction of a DN construct does not alter some characteristics of LRN/ECN cells as indicated by a molecular marker, TAG1, and their responsiveness to chemotropic activity of the floor plate (FP). These results suggest that classic cadherins contribute to contact-dependent mechanisms of precerebellar neuron migration probably via their adhesive property.     

Nucleation and growth of cadherin adhesions

Cell-cell contact formation relies on the recruitment of cadherin molecules and their anchoring to actin. However, the precise chronology of events from initial cadherin trans-interactions to adhesion strengthening is unclear, in part due to the lack of access to the distribution of cadherins within adhesion zones. Using N-cadherin expressing cells interacting with N-cadherin coated surfaces, we characterized the formation of cadherin adhesions at the ventral cell surface. TIRF and RIC microscopies revealed streak-like accumulations of cadherin along actin fibers. FRAP analysis indicated that engaged cadherins display a slow turnover at equilibrium, compatible with a continuous addition and removal of cadherin molecules within the adhesive contact. Association of cadherin cytoplasmic tail to actin as well as actin cables and myosin II activity are required for the formation and maintenance of cadherin adhesions. Using time lapse microscopy we deciphered how cadherin adhesions form and grow. As lamellipodia protrude, cadherin foci stochastically formed a few microns away from the cell margin. Neo-formed foci coalesced aligned and coalesced with preformed foci either by rearward sliding or gap filling to form cadherin adhesions. Foci experienced collapse at the rear of cadherin adhesions. Based on these results, we present a model for the nucleation, directional growth and shrinkage of cadherin adhesions.     

Cell junctions during morphogenesis of feathers: general ultrastructure with emphasis on adherens junctions

Alibardi, L. 2011. Cell junctions during morphogenesis of feathers: general ultrastructure with emphasis on adherens junctions. —Acta Zoologica (Stockholm) 92 : 89–100. The present ultrastructural and immunocytochemical study analyzes the cell junctions joining barb/barbule cells versus cell junctions connecting supportive cells in forming feathers. Differently from the epidermis or the sheath, desmosomes are not the prevalent junctions among feather cells. Numerous adherens junctions, some gap junctions and fewer tight junctions are present among differentiating barb/barbule cells during early stages of their differentiation. Adherens junctions are frequent also among differentiating supportive cells and show weak immunolabeling for both N‐cadherin and neural‐cell adhesion molecule (N‐CAM). Differentiating barb and barbule cells do not show labeled junctions for N‐cadherin and N‐CAM. The labeling occurs at patches in the cytoplasm of supportive cells but is more frequently seen in the external cytoplasm and along the extra‐cellular space (glycocalix) covering the plasma membrane of supportive cells. Labeling for N‐cadherin is also found in medium‐dense 0.1‐ to 0.3‐μm granules present in supportive cells and sometimes is associated with coarse filaments or periderm granules. The study indicates that adherens junctions form most of the transitional connections among supportive cells before their degeneration. Keratinizing barb and barbule cells loose the labeling for adherens junctions (N‐CAM and N‐chaderin) while their adhesion is strengthened by the incorporation of cell junctions in the corneous mass forming the barbules.     

Pou‐V factor Oct25 regulates early morphogenesis in Xenopus laevis

POU‐V class proteins like Oct4 are crucial for keeping cells in an undifferentiated state. An Oct4 homologue in Xenopus laevis, Oct25, peaks in expression during early gastrulation, when many cells are still uncommitted. Nevertheless, extensive morphogenesis is taking place in all germ layers at that time. Phenotypical analysis of embryos with Oct25 overexpression revealed morphogenesis defects, beginning during early gastrulation and resulting in spina‐bifida‐like axial defects. Analysis of marker genes and different morphogenesis assays show inhibitory effects on convergence and extension and on mesoderm internalization. On a cellular level, cell–cell adhesion is reduced. On a molecular level, Oct25 overexpression activates expression of PAPC, a functional inhibitor of the cell adhesion molecule EP/C‐cadherin. Intriguingly, Oct25 effects on cell–cell adhesion can be restored by overexpression of EP/C‐cadherin or by inhibition of the PAPC function. Thus, Oct25 affects morphogenesis via activation of PAPC expression and subsequent functional inhibition of EP/C‐cadherin.