Cadherin-Mediated Adhesion Is Required for Normal Growth Regulation of Human Gingival Epithelial Cells

The cadherins are a family of cell membrane proteins that mediate calcium-dependent cell-cell adhesion. E-cadherin is required for the formation, differentiation, polarization and stratification of epithelia; P-cadherin is also expressed on many epithelia. We report here the first study of cadherin expression in immortalized human gingival epithelial cells (IHGK) and examine the role of cadherins in growth regulation of these cells. We found that the IHGK cells are similar to normal gingival epithelial cells in their cadherin expression and density-dependent inhibition of growth.

The IHGK cells proliferate more rapidly at low calcium concentration (0.15 mM) than at physiological concentrations of calcium (1.8 mM) and magnesium (0.65 mM; Ca/Mg medium) suggesting that calcium is required for density-dependent regulation of proliferation. To evaluate the possibility that cadherin function is required for contact inhibition in these cells, we grew them in Ca/Mg medium in the presence of adhesion-blocking anti-cadherin monoclonal antibodies. At anti-E-cadherin concentrations sufficient to disrupt cell-cell adhesion, the proliferation of the IHGK cells was similar to that observed in medium containing 0.2 mM EDTA. Anti-P-cadherin had a much weaker effect on cell proliferation than anti-E-cadherin, and cells grown in medium containing both antibodies grew at intermediate rates. The increased proliferation of the IHGK cells in either low calcium medium or Ca/Mg medium containing adhesion-blocking anti-cadherin antibodies suggests that cadherin-medi-ated adhesion is required for density-dependent regulation of growth of these cells.     

Calcium-dependent cell-cell adhesion molecules (cadherins): subclass specificities and possible involvement of actin bundles

Cadherins are a family of cell-cell adhesion molecules and are divided into subclasses with distinct adhesive specificities and tissue distribution. Here we examined the distribution of cadherins at contact sites between cells expressing the same or different cadherin subclasses. Each cadherin was concentrated at the boundary between cells expressing an identical cadherin subclass, irrespective of the cell types connected. However, such localization decreased or disappeared at the boundary between cells containing different cadherin subclasses. We also found that the localization of cadherins precisely coincided with that of actin bundles; both were detected at the apical region of cell sheets. This co-localization was retained even after cells were either treated with cytochalasin D or extracted with the detergent NP40. These results suggest that each cadherin subclass preferentially interacts with its own molecular type at intercellular boundaries, and that cadherin molecules may be associated with actin- based cytoskeletal elements.     

Modulation of E-cadherin monomer folding by cooperative binding of calcium ions

Classical cadherins are transmembrane glycoproteins involved in calcium-dependent cell-cell adhesion. Calcium ions are coordinated at the interface between successive modules of the cadherin ectodomain and are thought to regulate the adhesive interactions of cadherins when present at millimolar concentrations. It is widely accepted that calcium plays a critical role in cadherin-mediated cell-cell adhesion, but the nature of cadherin-calcium binding remains a matter of debate. We investigated the parameters of noncovalent cadherin-calcium binding, using the two N-terminal modules of E-cadherin (E/EC12) with a native N-terminal end and nondenaturing electrospray ionization mass spectrometry. By directly visualizing the molecular complexes, we demonstrated that E/EC12 binds three calcium ions, with an average KD of 20 +/- 0.7 microM. These calcium ions bound cooperatively to E/EC12 in its monomeric state, and these properties were not modified by an N-terminal extension consisting of a single methionine residue. This binding induced specific structural changes, as shown by assessments of protease sensitivity, circular dichroism, and mass spectrometry. Furthermore, the D103A mutation (a residue involved in E-cadherin adhesive function) modified calcium binding and led to a loss of cooperativity and the absence of structural changes, despite calcium binding. As the amino acids involved in calcium binding are found within the cadherin consensus motif, our findings may be relevant to other members of the cadherin family.     

Glycosyl phosphatidylinositol--anchored T-cadherin mediates calcium-dependent, homophilic cell adhesion.

Cadherins are a family of cell adhesion molecules that exhibit calcium-dependent, homophilic binding. Their function depends on both an HisAlaVal sequence in the first extracellular domain, EC1, and the interaction of a conserved cytoplasmic region with intracellular proteins. T-cadherin is an unusual member of the cadherin family that lacks the HisAlaVal motif and is anchored to the membrane through a glycosyl phosphatidylinositol moiety (Ranscht, B., and M. T. Dours-Zimmermann. 1991. Neuron. 7:391-402). To assay the function of T-cadherin in cell adhesion, we have transfected T-cadherin cDNA into CHO cells. Two proteins, mature T-cadherin and the uncleaved T-cadherin precursor, were produced from T-cadherin cDNA. The T-cadherin proteins differed from classical cadherins in several aspects. First, the uncleaved T-cadherin precursor was expressed, together with mature T-cadherin, on the surface of the transfected cells. Second, in the absence of calcium, T-cadherin was more resistant to proteolytic cleavage than other cadherins. Lastly, in contrast to classical cadherins, T-cadherin was not concentrated into cell-cell contacts between transfected cells in monolayer cultures. In cellular aggregation assays, T-cadherin induced calcium-dependent, homophilic adhesion which was abolished by treatment of T-cadherin-transfected cells with phosphatidylinositol-specific phospholipase C. These results demonstrate that T-cadherin is a functional cadherin that differs in several properties from classical cadherins. The function of T-cadherin in homophilic cell recognition implies that the mechanism of T-cadherin-induced adhesion is distinct from that of classical cadherins.     

Advanced glycation endproducts interefere with integrin-mediated osteoblastic attachment to a type-I collagen matrix

The adhesion of osteoblasts to bone extracellular matrix, of which type-I collagen constitutes >85%, can modulate diverse aspects of their physiology such as growth, differentiation and mineralisation. In this study we examined the adhesion of UMR106 rat osteoblast-like cells either to a control (Col) or advanced-glycation-endproduct-modified (AGEs-Col) type I collagen matrix. We investigated the possible role of different integrin receptors in osteoblastic adhesion, by co-incubating these cells either with beta-peptide (conserved sequence 113-125 of the beta subunit of integrins) or with two other peptides, RGD (Arg-Gly-Asp) and DGEA (Asp-Gly-Glu-Ala), which are recognition sequences for the alpha-subunits of alpha(1,5)beta(1) and alpha(2)beta(1) integrins. Collagen glycation inhibited the adhesion of UMR106 osteoblasts to the matrix (40% reduction versus Col, P > 0.001). beta-Peptide showed a dose- and glycation-dependent inhibitory effect on adhesion, and at a concentration of 100 microM decreased the attachment of UMR106 cells to both matrices (42% to Col, P<0.001and 25% to AGEs-Col, P<0.01). The synthetic peptides RGD (1mM) and DGEA (5mM) inhibited the attachment of UMR106 cells to Col (30 and 20%, P > 0.01 and P< 0.001, respectively), but not to AGEs-Col. beta-Peptide induced an increase in UMR106 cell clumping and a decrease in cellular spreading, while DGEA increased spreading with cellular extensions in multiple directions. These results indicate that both alpha and beta integrin subunits participate in osteoblastic attachment to type-I collagen, probably through the alpha(1,5)beta(1) and alpha(2)beta(1) integrins. AGEs-modification of type-I collagen impairs the integrin-mediated adhesion of osteoblastic cells to the matrix, and could thus contribute to the pathogenesis of diabetic osteopenia.     

Tyrosine phosphorylation and cadherin/catenin function

Cadherin-mediated cell-cell adhesion is perturbed in protein tyrosine kinase (PTK)-transformed cells. While cadherins themselves appear to be poor PTK substrates, their cytoplasmic binding partners, the Arm catenins, are excellent PTK substrates and therefore good candidates for mediating PTK-induced changes in cadherin behavior. These proteins, p120^ctn, β-catenin and plakoglobin, bind to the cytoplasmic region of classical cadherins and function to modulate adhesion and/or bridge cadherins to the actin cytoskeleton. In addition, as demonstrated recently for β-catenin, these proteins also have crucial signaling roles that may or may not be related to their effects on cell-cell adhesion. Tyrosine phosphorylation of cadherin complexes is well documented and widely believed to modulate cell adhesiveness. The data to date, however, is largely correlative and the mechanism of action remains unresolved. In this review, we discuss the current literature and suggest models whereby tyrosine phosphorylation of Arm catenins contribute to regulation or perturbation of cadherin function.     

EndoCAM: a novel endothelial cell-cell adhesion molecule

Cell-cell adhesion is controlled by many molecules found on the cell surface. In addition to the constituents of well-defined junctional structures, there are the molecules that are thought to play a role in the initial interactions of cells and that appear at precise times during development. These include the cadherins and cell adhesion molecules (CAMs). Representatives of these families of adhesion molecules have been isolated from most of the major tissues. The notable exception is the vascular endothelium. Here we report the identification of a cell surface molecule designated "endoCAM" (endothelial Cell Adhesion Molecule), which may function as an endothelial cell-cell adhesion molecule. EndoCAM is a 130-kD glycoprotein expressed on the surface of endothelial cells both in culture and in situ. It is localized to the borders of contiguous endothelial cells. It is also present on platelets and white blood cells. Antibodies against endoCAM prevent the initial formation of endothelial cell-cell contacts. Despite similarities in size and intercellular location, endoCAM does not appear to be a member of the cadherin family of adhesion receptors. The serologic and protease susceptibility characteristics of endoCAM are different from those of the known cadherins, including an endogenous endothelial cadherin. Although the precise biologic function of endoCAM has not been determined, it appears to be one of the molecules responsible for regulating endothelial cell-cell adhesion processes and may be involved in platelet and white blood cell interactions with the endothelium.     

Regulation of collagenase-3 gene expression in osteoblastic and non-osteoblastic cell lines

Collagenase-3 expression in osteoblastic (UMR 106-01, ROS 17/2.8) and non-osteoblastic cell lines (BC1, NIH3T3) was examined. We observed that parathyroid hormone (PTH) induces collagenase-3 expression only in UMR cells but not in BC1 (which express collagenase-3 constitutively) or ROS and NIH3T3 cells. Since we know from UMR cells that the AP-1 factors and Cbfa1 are required for collagenase-3 expression, we analyzed the expression and PTH regulation of these factors by gel shift and Northern blot analysis in all cell lines. Gel mobility shift with a [(32)P]-labeled collagenase-3 AP-1 site probe indicated the induction of c-Fos in osteoblastic cells upon PTH treatment. While c-fos was induced in UMR cells, both c-fos and jun B were induced in ROS cells. Since Jun B is inhibitory of Fos and Jun in the regulation of the rat collagenase-3 gene in UMR cells, it is likely that high levels of Jun B prevent PTH stimulation of collagenase-3 in ROS cells. When we carried out gel shift analysis with a [(32)P]-labeled collagenase-3 RD (runt domain) site probe and Northern blot analysis with a Cbfa1 specific probe, we have observed the presence of Cbfa1 in both osteoblastic and non-osteoblastic cell lines, but there was no change in the levels of Cbfa1 RNA or protein in these cells under either control conditions or PTH treatment. From our studies above, it is evident that the expression of collagenase-3 and its regulation by PTH in osteoblastic and non-osteoblastic cells may be influenced by differential temporal stimulation of the AP-1 family members, especially c-Fos and Jun B along with the potential for posttranslational modification(s) of Cbfa1.     

Nonchordate classic cadherins have a structurally and functionally unique domain that is absent from chordate classic cadherins

Classic cadherins, which are adhesion molecules in cell-cell adherens junctions, have a large contribution to the construction of the animal body. Their molecular structures show clear differences between chordate and nonchordate metazoans. Although nonchordate classic cadherins have cadherin superfamily-specific extracellular repeats (CRs) and a highly conserved cytoplasmic domain (CP), these cadherins have a unique extracellular domain that is absent from vertebrate and ascidian classic cadherins. We called this the primitive classic cadherin domain (PCCD). To understand the roles of the PCCD, we constructed and characterized a series of mutant forms of the Drosophila classic cadherin DE-cadherin. Biochemical analyses indicated that the last two CRs and PCCD form a special structure with proteolytic cleavage. Mutations in the PCCD did not eliminate the cell-cell-binding function of DE-cadherin in cultured cells, but prevented the cadherin from efficiently translocating to the plasma membrane in epithelial cells of the developing embryo. In addition, genetic rescue assays suggested that although CP-mediated control plays a central role in tracheal fusion, the role of the PCCD in efficient recruitment of DE-cadherin to apical areas of the plasma membranes is also important for dynamic epithelial morphogenesis. We propose that there is a fundamental difference in the mode of classic cadherin-mediated cell-cell adhesion between chordate and nonchordate metazoans.     

Should I stay or should I go?: Shedding of RPTPs in cancer cells switches signals from stabilizing cell-cell adhesion to driving cell migration

Dissolution of cell-cell adhesive contacts and increased cell-extracellular matrix adhesion are hallmarks of the migratory and invasive phenotype of cancer cells. These changes are facilitated by growth factor binding to receptor protein tyrosine kinases (RTKs). In normal cells, cell-cell adhesion molecules (CAMs), including some receptor protein tyrosine phosphatases (RPTPs), antagonize RTK signaling by promoting adhesion over migration. In cancer, RTK signaling is constitutive due to mutated or amplified RTKs, which leads to growth factor independence or autonomy. An alternative route for a tumor cell to achieve autonomy is to inactivate cell-cell CAMs such as RPTPs. RPTPs directly mediate cell adhesion and regulate both cadherin-dependent adhesion and signaling. In addition, RPTPs antagonize RTK signaling by dephosphorylating molecules activated following ligand binding. Both RPTPs and cadherins are downregulated in tumor cells by cleavage at the cell surface. This results in shedding of the extracellular, adhesive segment and displacement of the intracellular segment, altering its subcellular localization and access to substrates or binding partners. In this commentary we discuss the signals that are altered following RPTP and cadherin cleavage to promote cell migration. Tumor cells both step on the gas (RTKs) and disconnect the brakes (RPTPs and cadherins) during their invasive and metastatic journey.Key words: receptor protein tyrosine kinase, receptor-like protein tyrosine phosphatase, cadherins, cell adhesion, signal transduction, phospholipase C gamma, protein kinase C, catenins, IQGAP1 protein, regulated intramembrane proteolysis     

Molecular nature of the calcium-dependent cell-cell adhesion system in mouse teratocarcinoma and embryonic cells studied with a monoclonal antibody

The molecular nature of the Ca2+-dependent cell-cell adhesion system in mouse teratocarcinoma (t-CDS) was studied using a monoclonal antibody recognizing t-CDS. We isolated a hybridoma clone producing a monoclonal antibody (ECCD-1) able to disrupt cell-cell adhesion when added to monolayer cultures of teratocarcinoma cells. This antibody bound to the cells with intact t-CDS, resulting in an inhibition of their aggregation, but did not bind to cells from which t-CDS was removed by trypsin treatment in the absence of Ca2+. The binding of ECCD-1 to cell surfaces required Ca2+ but not other ions. Western blot analysis showed that ECCD-1 recognizes multiple cell surface proteins, the major one of which is a component with a molecular weight of 124,000. The binding of ECCD-1 to these antigens was Ca2+-dependent even in cell-free systems, suggesting that the molecules involved in t-CDS undergo conformational changes by binding with Ca2+, leading to conversion of their molecular structure into an active form. ECCD-1 also reacted with 8-cell stage mouse embryos and with certain types of epithelial cells (excluding fibroblastic cells) in various differentiated tissues collected from mouse fetuses, again affecting their cell-cell adhesion. We also showed that a monoclonal antibody (DE1) raised against gp84 (F. Hyafil et al., 1981, Cell 26, 447-454) recognizes the same antigens as ECCD-1.     

Regulation of Rho family GTPases by cell-cell and cell-matrix adhesion

Integrins and cadherins are transmembrane adhesion receptors that are necessary for cells to interact with the extracellular matrix or adjacent cells, respectively. Integrins and cadherins initiate signaling pathways that modulate the activity of Rho family GTPases. The Rho proteins Cdc42, Rac1, and RhoA regulate the actin cytoskeleton. Cdc42 and Rac1 are primarily involved in the formation of protrusive structures, while RhoA generates myosin-based contractility. Here we examine the differential regulation of RhoA, Cdc42, and Rac1 by integrin and cadherin signaling. Integrin and cadherin signaling leads to a decrease in RhoA activity and activation of Cdc42 and Rac1. When the normal RhoA suppression is antagonized or RhoA signaling is increased, cells exhibited impaired spreading on the matrix protein fibronectin and decreased cell-cell adhesion. Spreading on fibronectin and the formation of cell-cell adhesions is decreased in cells expressing dominant negative forms of Cdc42 or Rac1. These data demonstrate that integrins and cadherins regulate Rho proteins in a comparable manner and lead us to speculate that these changes in Rho protein activity participate in a feedback mechanism that promotes further cell-matrix or cell-cell interaction, respectively.     

Parathyroid hormone stimulation and PKA signaling of latent transforming growth factor-beta binding protein-1 (LTBP-1) mRNA expression in osteoblastic cells

Parathyroid hormone (PTH) regulates bone remodeling and calcium homeostasis by acting on osteoblasts. Recently, the gene expression profile changes in the rat PTH (1-34, 10(-8)M)-treated rat osteoblastic osteosarcoma cell line, UMR 106-01, using DNA microarray analysis showed that mRNA for LTBP-1, a latent transforming growth factor (TGF-beta)-binding protein is stimulated by PTH. Latent TGF-beta binding proteins (LTBPs) are required for the proper folding and secretion of TGF-beta, thus modifying the activity of TGF-beta, which is a local factor necessary for bone remodeling. We show here by real time RT-PCR that PTH-stimulated LTBP-1 mRNA expression in rat and mouse preosteoblastic cells. PTH also stimulated LTBP-1 mRNA expression in all stages of rat primary osteoblastic cells but extended expression was found in differentiating osteoblasts. PTH also stimulated TGF-beta1 mRNA expression in rat primary osteoblastic cells, indicating a link between systemic and local factors for intracellular signaling in osteoblasts. An additive effect on LTBP-1 mRNA expression was found when UMR 106-01 cells were treated with PTH and TGF-beta1 together. We further examined the signaling pathways responsible for PTH-stimulated LTBP-1 and TGF-beta1 mRNA expression in UMR 106-01 cells. The PTH stimulation of LTBP-1 and TGF-beta1 mRNA expression was dependent on the PKA and the MAPK (MEK and p38 MAPK) pathways, respectively in these cells, suggesting that PTH mediates its effects on osteoblasts by several intracellular signaling pathways. Overall, we demonstrate here that PTH stimulates LTBP-1 mRNA expression in osteoblastic cells and this is PKA-dependent. This event may be important for PTH action via TGF-beta in bone remodeling.     

Differential Purinergic Receptor Signalling in Osteoclasts and Osteoblastic Cells

There are differences between osteoclasts and osteoblastic cells in their cytosolic calcium responses to purinergic receptor activation. Application of 50 or 100 μM extracellular ATP inhibits the calcium response to a second application of ATP in osteoblastic rat osteosarcoma UMR 106 cells, but not in rabbit osteoclasts. This shows that there is adaptation to the extracellular ATP in osteoclasts, but not in the UMR 106 cells. Extracellular washing of the UMR 106 cells restores the calcium response to ATP partially but not completely, indicating that there is a purinergic receptor activation-induced desensitisation of the receptor or its linked signalling pathways. In contrast to these results, if extracellular UTP is applied first, application of ATP produces no calcium response in osteoclasts, with or without washing, while in the UMR 106 cells there is some response to the ATP, which is greatly enhanced by washing. This indicates that UTP induces a complete desensitisation of the purinergic receptor/calcium signalling system in osteoclasts, but not in the osteoblastic cells, in which there is simply competition between UTP and ATP for the same receptors. Taken together, these results demonstrate that ATP and UTP could differentially regulate osteoblasts and osteoclasts.     

Detection of the Initial Step of Mesenchymal Differentiation of Teratocarcinoma Cells Using the Monoclonal Antibody Eccd-11

The monoclonal antibody ECCD-1 recognizes the Ca²⁺-dependent cell-cell adhesion molecule of teratocarcinoma stem cells (EC cells) and of a certain class of differentiated epithelial cells. It actively disrupts cell-cell adhesion when added to monolayer cultures of these cells, but does not affect adhesion of mesenchymal or neuronal cells. When ECCD-1 was added to clonal cultures of EC cells (PCC3/A/1 line), all the cells were initially sensitive to the antibody, but after 5 to 6 days of culture a fraction of the cells in certain colonies no longer reacted with the antibody although they expressed alkaline phosphatase activity, which is a marker of undifferentiated EC cells. We isolated these ECCD-1-resistant cells by recloning and examined their differentiation by clonal culture. Most of them differentiated into fibroblastic cells and a few into skeletal muscle-like cells, but none differentiated into any other cell types. From these observations, we suppose that the ECCD-1-resistant population of EC cells are committed to mesenchymal differentiation. The use of ECCD-1, thus, permitted us to detect EC cells at the initial stage of a particular differentiation pathway.     

Osteoclastogenic activity and RANKL expression are inhibited in osteoblastic cells expressing constitutively active Gα12 or constitutively active RhoA

Gα₁₂–RhoA signaling is a parathyroid hormone (PTH)‐stimulated pathway that mediates effects in bone and may influence genetic susceptibility to osteoporosis. To further elucidate effects of the pathway in osteoblasts, UMR‐106 osteoblastic cells were stably transfected with constitutively active (ca) Gα₁₂ or caRhoA or dominant negative (dn) RhoA and co‐cultured with RAW 264.7 cells to determine effects on hormone‐stimulated osteoclastogenesis. Whereas PTH and calcitriol‐stimulated osteoclastogenesis in co‐cultures with UMR‐106 cells expressing pcDNA or dominant negative RhoA, the osteoclastogenic effects of PTH and calcitriol were significantly attenuated when the UMR‐106 cells expressed either caRhoA or caGα₁₂. These inhibitory effects were partially reversed by the Rho kinase inhibitor Y27632. None of the constructs affected osteoclastogenesis in untreated co‐cultures, and the constructs did not inhibit the osteoclastogenic responses to receptor activator of NFκB ligand (RANKL). To investigate the mechanism of the inhibitory effects of caGα₁₂ and caRhoA, expression of RANKL, osteoprotegerin (OPG), osteopontin (OPN), and intercellular adhesion molecule‐1 (ICAM) in response to PTH or calcitriol was examined in the UMR‐106 cells. In the cells expressing pcDNA or dnRhoA, PTH and calcitriol increased RANKL mRNA and decreased OPG mRNA, whereas these effects were absent in the cells expressing caGα₁₂ or caRhoA. Basal expression of RANKL and OPG was unaffected by the constructs. The results suggest that Gα₁₂–RhoA signaling can inhibit hormone‐stimulated osteoclastogenesis by effects on expression of RANKL and OPG. Since PTH can stimulate the Gα₁₂–RhoA pathway, the current findings could represent a homeostatic mechanism for regulating osteoclastogenic action. J. Cell. Biochem. 111: 1531–1536, 2010. © 2010 Wiley‐Liss, Inc.     

Functional cis-heterodimers of N- and R-cadherins

Classical cadherins form parallel cis-dimers that emanate from a single cell surface. It is thought that the cis-dimeric form is active in cell-cell adhesion, whereas cadherin monomers are likely to be inactive. Currently, cis-dimers have been shown to exist only between cadherins of the same type. Here, we show the specific formation of cis-heterodimers between N- and R-cadherins. E-cadherin cannot participate in these complexes. Cells coexpressing N- and R-cadherins show homophilic adhesion in which these proteins coassociate at cell-cell interfaces. We performed site- directed mutagenesis studies, the results of which support the strand dimer model for cis-dimerization. Furthermore, we show that when N- and R-cadherins are coexpressed in neurons in vitro, the two cadherins colocalize at certain neural synapses, implying biological relevance for these complexes. The present study provides a novel paradigm for cadherin interaction whereby selective cis-heterodimer formation may generate new functional units to mediate cell-cell adhesion.     

The cadherins: cell-cell adhesion molecules controlling animal morphogenesis

Cadherins are a family of glycoproteins involved in the Ca2+-dependent cell-cell adhesion mechanism which is detected in most kinds of tissues. Inhibition of the cadherin activity with antibodies induces dissociation of cell layers, indicating a fundamental importance of these molecules in maintaining the multicellular structure. Cadherins are divided into subclasses, including E-, N- and P-cadherins. While all subclasses are similar in molecular weight, Ca2+- and protease-sensitivity, each subclass is characterized by a unique tissue distribution pattern and immunological specificity. Analysis of amino acid sequences deduced from cDNA encoding these molecules showed that they are integral membrane proteins of 723-748 amino acids long and share common sequences; similarity in the sequences between subclasses is in a range of 50-60% when compared within a single animal species. L cells, with very little endogenous cadherin activity, transfected with the cadherin cDNA acquired high cadherin-mediated aggregating activity. Their colony morphology was altered by the ectopic expression of cadherins from the dispersed type to the compact type, providing direct evidence for a key role of cadherins in cell-cell adhesion. It has been suggested that cadherins bind cells by their homophilic interactions at the extracellular domain and are associated with actin bundles at the cytoplasmic domain. It appears that each cadherin subclass has binding specificity and this molecular family is involved in selective cell-cell adhesion. In development, the expression of each cadherin subclass is spatiotemporally regulated and associated with a variety of morphogenetic events; e.g. the termination or initiation of expression of a cadherin subclass in a given cell collective is correlated with its segregation from or connection with other cell collectives. Antibodies to cadherins were shown to perturb the morphogenesis of some embryonic organs in vitro. These observations suggest that cadherins play a crucial role in construction of tissues and the whole animal body.