Calcium-dependent Cell Adhesion Molecules Research Articles

The cadherin-binding specificities of B-cadherin and LCAM.

The cadherin family of calcium-dependent cell adhesion molecules plays an important part in the organization of cell adhesion and tissue segregation during development. The expression pattern and the binding specificity of each cadherin are of principal importance for its role in morphogenesis. B-Cadherin and LCAM, two chicken cadherins, have similar, but not identical, spatial and temporal patterns of expression. To examine the possibility that they might bind to one another in a heterophilic manner, we generated, by cDNA transfection, L-cell lines that express LCAM or B-cadherin. We then examined the abilities of these cells to coaggregate with each other and with other cadherin-expressing cells in short-term aggregation assays. The B-cadherin- and the LCAM-expressing cell lines segregate from P-, N-, or R-cadherin-expressing cells. B-cadherin- and LCAM-expressing cell lines, however, appear to be completely miscible, forming large mixed aggregates. Chick B-cadherin and murine E-cadherin also form mixed aggregates, indistinguishable from homophilic aggregates. Murine E-cadherin and chick LCAM coaggregate less completely, suggesting that the heterophilic interactions of these two cell lines are weak relative to homophilic interactions. These data suggest that heterophilic interactions between B-cadherin and LCAM are important during avian morphogenesis and help identify the amino acids in the binding domain that determine cadherin specificity.

The role of cadherin in the generation of multinucleated osteoclasts from mononuclear precursors in murine marrow.

A critical step in bone resorption is the fusion of mononuclear osteoclast precursors to form multinucleated osteoclasts. However, little is known of the molecular mechanisms that are responsible for this important process. Since the expression of proteins in the cadherin family of homophilic calcium-dependent cell adhesion molecules is involved in the fusion process for certain other cells, we examined their role in osteoclast formation. Immunohistochemical examination of human and mouse bone using monoclonal antibodies to human and mouse E-cadherin clearly demonstrated positive staining in osteoclasts. N- and P-cadherin were not detected. In cultures of murine marrow mononuclear cells in which osteoclasts form by cell fusion, E-cadherin expression determined by Western blotting reached the highest levels as fusion was taking place. Expression of E-cadherin gene fragment was also detected in the marrow cultures by polymerase chain reaction. To study the functional role of E-cadherin expression in osteoclastic differentiation, neutralizing monoclonal antibodies were examined for their effects on osteoclast formation. The antibodies decreased the number of tartrate-resistant acid phosphatase (a marker of murine osteoclast)-positive multinucleated cell (TRAP-positive MNC) by inhibiting the fusion of mononuclear osteoclast precursors, but not proliferation of these cells or their attachment to plastic dish surfaces. This inhibitory effect was reversible. Furthermore, synthetic peptides containing the cell adhesion recognition sequence of cadherins also decreased TRAP-positive MNC formation. The antibodies and peptides inhibited not only osteoclast formation but also bone resorption. Antibodies to other types of cadherins and control rat IgG had no effects in these culture systems. Our findings suggest that E-cadherin expression may be involved in fusion (differentiation) of hemopoietic osteoclast precursors into mature multinucleated osteoclasts.

Cloning and Expression Analysis of a Novel Mesodermally Expressed Cadherin

Cadherins are calcium-dependent cell adhesion molecules which show developmental and tissue-specific expression. Here we report the cloning of a mouse cadherin which is predominantly expressed in tissues of mesodermal origin. In contrast to other cadherins, cadherin-11 expression is largely restricted to mesenchymal tissues surrounding various organs but is not found in epithelia. Sequence analysis suggests that this cadherin is the mouse homologue of the previously reported human cadherin-11 and is a member of a cadherin subfamily, which is evolutionarily distinct from other cadherin subfamilies identified so far.

Cadherins, steroids and cancer

The cadherins are a family of calcium-dependent cell adhesion molecules which are thought to be key regulators of morphogenesis. This review contains a discussion of the structure, function and regulation of these cell adhesion molecules. In particular, we discuss recent studies that demonstrate the ability of steroids to modulate cadherin levelsin vivo. We speculate that steroids and estrogenic organochlorines exert their diverse morphoregulatory actions on tissues by altering cadherin levels.

Solution structure of the epithelial cadherin domain responsible for selective cell adhesion.

Cadherins are calcium-dependent cell adhesion molecules containing extracellular repeats of approximately 110 amino acids. The three-dimensional structure of the amino-terminal repeat of mouse epithelial cadherin was determined by multidimensional heteronuclear magnetic resonance spectroscopy. The calcium ion was bound by a short alpha helix and by loops at one end of the seven-stranded beta-barrel structure. An exposed concave face is in a position to provide homophilic binding specificity and was also sensitive to calcium ligation. Unexpected structural similarities with the immunoglobulin fold suggest an evolutionary relation between calcium-dependent and calcium-independent cell adhesion molecules.

Cadmium-Induced Rat Embryotoxicity in Vitro Is Associated with an Increased Abundance of E-Cadherin Protein in the Yolk-Sac

Cadmium, a cytotoxic heavy metal, is embryotoxic. Cadmium interferes with the functions of other cations such as zinc and calcium. Cadherins, calcium-dependent cell adhesion molecules, are expressed and spatiotemporally regulated in embryos and their yolk sacs during organogenesis. Cadmium has been shown to disrupt calcium-dependent cell-cell interactions and to alter the distribution of epithelial or E-cadherin in cultured cells. The purpose of this study was to determine whether the embryotoxicity of cadmium is mediated through an effect on E-cadherin. Day 10 rat embryos were cultured for 1 hr without cadmium and then cultured for another 2, 6, or 20 hr in the presence or absence of 2.5 μM CdCl2. Embryos and yolk sacs were collected and analyzed separately. The growth of embryos and yolk sacs after exposure to cadmium for 2 or 6 hr was not different from that of controls. After 20 hr exposure to cadmium, embryos were growth retarded, with morphological scores 10-15% lower than those of controls; more dramatically, their yolk sacs were thickened and decreased in diameter to only half of that of control yolk sacs. Northern blot analysis revealed no significant differences in the relative amounts of E-cadherin mRNA between control and cadmium-treated embryos or their yolk sacs. There was also no alteration in the abundance of E-cadherin protein in cadmium-treated embryos at any of the times examined. There was a gradual decline in the relative amount of E-cadherin protein in control yolk sacs with time in culture; interestingly, cadmium treatment appeared to prevent this decline, resulting in significantly higher concentrations of E-cadherin protein in the cadmium-exposed yolk sacs after 6 hr (1.7-fold) or 20 hr (2.3-fold) of culture. The relative abundance of other structural proteins such as α- or β-tubulin and actin was unchanged. Exposure of embryos for 20 hr to concentrations of cadmium varying from nonembryotoxic to embryotoxic resulted in concentration-dependent increases in E-cadherin protein in the yolk sac; E-cadherin was only increased in the yolk sac of growth-retarded embryos. Thus, an increase in yolk sac E-cadherin protein is associated with the induction of embryotoxicity by cadmium. To determine the ability of cadmium to interact directly with the cadherins, the binding of radioactive 109Cd to embryo and yolk sac proteins was assessed. 109Cd bound to an unidentified 87-kDa protein; binding to this protein was attenuated by 1 mM zinc, but not by 1 mM calcium. No 109Cd binding was detected in the similar to 120-kDa region, indicating that cadmium did not interact directly with the cadherin molecules. Furthermore, when both 2 mM CaCl2 and 2.5 μM CdCl2 were added to the embryo culture medium, calcium did not prevent the teratogenic effects of cadmium. These data suggest that during the induction of embryo malformations by cadmium, the regulation of E-cadherin protein in the yolk sac is altered. However, cadmium does not appear to directly interact with E-cadherin.

The Genes for the Calcium-Dependent Cell Adhesion Molecules P- and E-Cadherin Are Tandemly Arranged in the Human Genome

Cadherins constitute a gene family of Ca2+-dependent cell-cell adhesion molecules involved in the morphogenesis and maintenance of tissue integrity. E- and P-cadherin are members of the cadherin family that are both expressed in epithelial tissues. Here we present the localization of the human P-cadherin gene at 32 kb upstream of the human E-cadherin gene, mapping it to chromosome 16q22.1. Tandem arrangement of two cell-cell adhesion molecules from the cadherin family has also been reported in chicken. This is the first evidence for the direct linkage of two cadherins in mammals. The evolutionary conservation of the tandem arrangement of two genes encoding cell adhesion molecules suggests that the close proximity of the genes may be important for the regulation of the genes.

Estradiol regulates E-cadherin mRNA levels in the surface epithelium of the mouse ovary

E-cadherin is a calcium-dependent cell adhesion molecule which is present in the surface epithelium of the mouse ovary. This cell adhesion molecule has been implicated as a suppressor of tumorigenesis. The regulators of E-cadherin mRNA levels in the ovary have not been identified. We have examined the ability of steroids to influence ovarian E-cadherin mRNA levels in vivo. Immature mice were injected with either progesterone, testosterone, dihydrotestosterone, 17-beta estradiol or 17-alpha estradiol. Only 17-beta estradiol caused a rapid and significant increase in the ovarian E-cadherin mRNA levels. We speculate that this steroid is a key regulator of E-cadherin-mediated epithelial cell interactions in vivo. We also discuss the possibility that the carcinogenic effects of estrogens on the ovary may be related to their ability to regulate E-cadherin levels in this tissue.

The Expression of B-Cadherin during Embryonic Chick Development

Cadherins compose a family of calcium-dependent cell adhesion molecules that are involved in the segregation of differentiating tissues during development. Each cadherin has a unique spatial and temporal pattern of expression. As has been observed for other cadherins, B-cadherin, when expressed in mouse L929 fibroblasts, confers upon them a calcium-dependent cell aggregation activity. A monoclonal antibody to B-cadherin was isolated and used to determine the pattern of expression of B-cadherin in the developing chick embryo. Antibody staining and in situ hybridization reveal that B-cadherin protein and mRNA are found in diverse epithelia derived from each of the three primary germ layers, where their expression is strikingly regulated during differentiation. In some instances, the regional distribution of B-cadherin within a tissue reflects the distinct functional regions of the tissue. Patterns of staining are similar to, but distinct from, those seen with anti-LCAM antibodies. Although there are many examples where B-cadherin and LCAM are coexpressed, there are also distinctive regional differences.

Identification of the promoter and a transcriptional enhancer of the gene encoding L-CAM, a calcium-dependent cell adhesion molecule.

L-CAM is a calcium-dependent cell adhesion molecule that is expressed in a characteristic place-dependent pattern during development. Previous studies of ectopic expression of the chicken L-CAM gene under the control of heterologous promoters in transgenic mice suggested that cis-acting sequences controlling the spatiotemporal expression patterns of L-CAM were present within the gene itself. We have now examined the L-CAM gene for sequences that control its expression and have found an enhancer within the second intron of the gene. A 2.5-kb Kpn I-EcoRI fragment from the intron acted as an enhancer of a simian virus 40 minimal promoter driving a chloramphenicol acetyltransferase (CAT) reporter gene and produced 14.0-fold induction of CAT activity in MDCK cells. To narrow down the region responsible for enhancer activity and to determine whether the enhancer could function in a cell type-specific manner, a number of smaller restriction fragments from the intron were tested for activity in two chicken cell lines, the LMH hepatoma line, which produces high levels of L-CAM, and the SL-29 fibroblast line, which produces little, if any, L-CAM. Four L-CAM enhancer plasmids containing shorter segments derived from the intron showed enhanced CAT activity levels (between 9.4- and 16.5-fold) in extracts from transfected LMH cells but not from SL-29 cells. DNA sequence analysis of the L-CAM enhancer region revealed putative binding sites for the transcription factors SP1, E2A, and AP-2. In addition, LE-9, the smallest L-CAM enhancer segment (310 bp), contained a consensus binding site for the liver-enriched POU-homeodomain transcription factor, HNF-1. Tests of upstream sequences showed that a 630-bp fragment, corresponding to nearly the entire intergenic region between L-CAM and its neighboring CAM gene, K-CAM, could function as a promoter. In combination with the L-CAM enhancer, this fragment directed cell type-specific expression of the CAT reporter gene in LMH cells at a level comparable to that observed with enhancer constructs using the simian virus 40 minimal promoter. These combined observations define a promoter and an enhancer for the chicken L-CAM gene. They raise the possibility that these cis-acting regulatory sequences may be instrumental in directing specific place-dependent expression of the L-CAM gene in the chicken.

Extracellular matrix 5: adhesive interactions in early mammalian embryogenesis, implantation, and placentation.

Normal morphogenesis and differentiation depend heavily on the coordination of cell-cell and cell-extracellular matrix interactions. During early mammalian development, the first cell lineages to be established are extraembryonic (trophoblast and extraembryonic endoderm), which are essential for satisfying the nutritional requirements of the developing embryo. This review emphasizes the importance of the cadherin family of cell-cell adhesion molecules and the integrin family of extracellular matrix receptors in mediating interactions between cells and their environment during early development. The review first discusses the critical role of cell-cell interactions in fertilization and early lineage decisions that occur during pre- and peri-implantation development in the mouse, using the calcium-dependent cell adhesion molecule E-cadherin as the primary example. The remainder of the review discusses the importance of cell-ECM interactions in the further morphogenesis and differentiation of the newly segregated lineages. The critical roles of integrins in differentiation, migration, and invasion of trophoblast in both mouse and human are emphasized.

The structural and functional analysis of cadherin calcium-dependent cell adhesion molecules

During the past year considerable progress has been made in our understanding of cadherin structure and function. Recent research has concentrated on several aspects of the cell and molecular biology of cadherins, including genomic organization, cytoskeletal interactions, regulation of expression and function by post-translational modifications, differential expression during embryonic development, and the emerging role of cadherin misexpression and malfunction in pathogenesis.

Purification and characterization of NCAD90, a Soluble endogenous form of N‐cadherin, which is generated by proteolysis during retinal development and retains adhesive and neurite‐promoting function

The cadherins are calcium-dependent cell adhesion molecules which regulate cell-cell interactions during morphogenesis. During development, cadherin expression is subject to dynamic patterns of regulation. We have previously demonstrated that expression of N-cadherin, the predominant cadherin of neural tissues, is sharply down-regulated during development of the retina and brain during later stages of histogenesis (Lagunowich and Grunwald, Dev Biol 135:158-171, 1989; Lagunowich et al., J Neurosci Res 32:202-208, 1992), and that this down-regulation is due to multiple factors, including decreased mRNA levels and turnover apparently mediated by endogenous metalloproteolytic activity (Roark et al., Development 114:973-984, 1992). In the present study, we describe metabolic studies which provide direct biochemical evidence for turnover of 130-kDa N-cadherin in embryonic retina tissues, yielding a soluble 90-kDa N-terminal fragment. We demonstrate that this form of N-cadherin, which we refer to as NCAD90, accumulates in vivo during development. We further demonstrate that purified NCAD90, obtained from embryonic vitreous humor, retains biological function and promotes cell adhesion and neurite growth in a dose-dependent fashion among chick embryo neural retina cells when present in a substrate-bound form. The morphology of retinal cells and neurites grown on a substrate of NCAD90 differs strikingly from that seen on a laminin substrate, in a manner similar to that described for intact 130-kDa N-cadherin. We conclude that proteolysis of N-cadherin at the cell surface during embryonic retinal histogenesis is an endogenous mechanism for regulating N-cadherin expression which generates a novel and functional form of the protein. The results further indicate that an intact cytoplasmic domain is not essential for all cadherin functions.

An immortalized cystic fibrosis tracheal epithelial cell line homozygous for the delta F508 CFTR mutation.

The development of transformed human airway epithelial cell lines has been important in advancing the understanding of the biochemical and genetic mechanisms underlying the cystic fibrosis (CF) defect. Since the most common mutation associated with CF is a phenylalanine deletion at position 508 (delta F508) in the CF transmembrane conductance regulator (CFTR) gene, a transformed airway epithelial cell line homozygous for this mutation will be important for determining the biologic significance of this mutation in the airways. We report the genotypic and phenotypic characterization of a delta F508 homozygote cell line derived from luminal epithelium in the trachea. The cells were transformed with a plasmid containing an origin of replication defective SV40 genome and have progressed through crisis. Immunocytochemical characterization of the cells shows that they express keratin, indicating epithelial cell origin, and that a calcium-dependent cell adhesion molecule, cellCAM 120/80, is present at plasma membrane junctions between cells. Electrophysiologically, the cells show no cAMP-dependent Cl transport. However, after treatment with the calcium ionophore, ionomycin, cells secrete Cl, albeit at a lower level than that observed in normal cells. Genetically, the cells express CFTR mRNA as determined by polymerase chain reaction amplification and CFTR protein as determined by Western hybridization analysis. Karyotypic analysis shows that 70% of the cells contain two copies of chromosome 7.

Subclass Reactivity of Pemphigus Foliaceus Autoantibodies with Recombinant Human Desmoglein

Pemphigus foliaceus (PF) and its endemic form, Fogo Selvagem (FS), are autoimmune disorders characterized by subcorneal vesicles and IgG4 subclass autoantibodies that recognize a surface antigen of normal epidermal cells. FS and PF autoantibodies have been shown to bind desmoglein (DGI), a desmosomal glycoprotein classified as a member of the cadherin family of calcium-dependent cell adhesion molecules. In the present study we report the isolation of three overlapping cDNA clones representing greater than 90% of the extracellular domain of human DGI. Recombinant proteins encoded by these clones, designated DGI-1, DGI-2, and DGI-3, were produced in bacteria and analyzed for immunoblot (IB) reactivity with a panel of FS, PF, and control sera. FS and PF autoantibodies possessing reactivity with each of the three recombinant fusion proteins (FPs) were identified. FP DGI-3 (containing 123 amino acids of the membrane proximal region of the DGI ectodomain) showed reactivity with the largest number of patient sera--seven FS and one PF. IB reactivity with the DGI-1 FP (encoding 205 amino acids of the N-terminal region of DGI) could be eliminated by truncation of the C-terminal portion of this protein, indicating that autoantibodies were not binding the R-A-L motif. Autoantibodies reactive with two of the three FPs were predominantly restricted to IgG4, the subclass shown to be pathogenic in the passive transfer mouse model. The findings of this study demonstrate that the extracellular domain of DGI contains at least three antigenic sites recognized by FS and PF autoantibodies. The region near the membrane-spanning domain of DGI appears to contain an immunodominant site. This study is the first to document immunoblot reactivity of FS and PF autoantibodies with recombinant forms of DGI. The use of such molecular tools should facilitate the identification and characterization of relevant antigen/antibody systems in FS and PF.

Structural and functional aspects of the thyroid follicular epithelium

The thyroid epithelium is morphologically and functionally polarized, with an apical surface facing the follicular lumen containing colloid and a basolateral surface facing the interstitium. Iodination and thyroid hormone synthesis occur in the colloid at the apical plasma membrane. The introduction by Mauchamp et al. of primary cultures of porcine thyroid cells grown as a polarized, confluent monolayer on a filter in a bicameral chamber system has now made it possible to study in more detail the barrier function and vectorial ion transport in the thyroid epithelium. The follicular cells form a very tight monolayer (transepithelial resistance > 6000 ohm cm 2) and establish a transepithelial potential difference (apical medium negative) of about 20 mV. These parameters are rapidly influenced by TSH, mainly by an action on apical sodium channels, and by EGF. The integrity of the barrier is, as in other epithelia, dependent on extracellular calcium. A calcium-dependent cell adhesion molecule, uvomorulin, is expressed at the lateral plasma membrane surface. EGF induces cell proliferation as well as migration of some of the epithelial cells to a position below the monolayer, which however maintains its polarity and barrier function. In contrast, during TPA-induced proliferation the barrier function is disrupted. Iodide is vectorially transported in basoapical direction while the epithelial layer is virtually impermeable for iodide transfer in the opposite direction. Iodide is concentrated in the cell by the basolateral “iodide-pump” and its efflux across the apical plasma membrane is rapidly and selectively increased by TSH via cAMP. EGF inhibits vectorial basoapical iodide transport mainly by reducing the iodide permeability of the apical plasma membrane. Together, these recent observations indicate that the ion content of the follicular lumen is strictly controlled by the thyroid epithelium.

Expression of cell adhesion molecule E-cadherin in human arachnoid villi.

Calcium-dependent epithelial cell adhesion molecules designated as E-cadherin (also known as uvomorulin or L-CAM) were identified in human arachnoid villi by immunoblotting and immunocytochemical analyses using a monoclonal antibody HECD-1 raised against human mammary carcinoma MCF-7 cells. Immunoblot analysis showed that HECD-1 recognizes E-cadherin with a molecular weight of 124 kD. In all arachnoid cells of an arachnoid villus, E-cadherin was detected by immunolight microscopy within the cytoplasm rather than the cellular boundaries as seen in the control group. Furthermore, the extent of expression by immunolight microscopy varied from portion to portion. The expression was usually weak in the syncytial cluster which was ultrastructurally composed of tightly juxtaposed cells characterized by few extracellular cisterns and numerous cell junctions, while it was intense in the reticular cluster and the surface layer which were ultrastructurally characterized by abundant extracellular cisterns and smaller numbers of cell junctions. The cells of the reticular cluster and the surface layer contained more free ribosomes than those of the syncytial cluster. Immunoelectron microscopy showed that E-cadherin was localized not only to the opposing plasma membranes and the cytoplasm around the free ribosomes or the rough endoplasmic reticulum but also to the extracellular cisterns. As the expression of E-cadherin was closely related to the arachnoid cells adjacent to the cerebrospinal fluid pathway, it is suggested that, instead of the cell junctions, E-cadherin may play an important role in the flexible adhesion of arachnoid cells even in the presence of the cerebrospinal fluid.

Genes for two calcium-dependent cell adhesion molecules have similar structures and are arranged in tandem in the chicken genome.

Genomic sequences immediately upstream of the translational start site for the chicken liver cell adhesion molecule (L-CAM) gene contain a second closely related gene, which, because of its location, we have designated the K-CAM gene. Less than 700 base pairs separate the presumed poly(A) site in the K-CAM gene from the translation initiation site for L-CAM. The sizes of exons 4-15 of the K-CAM gene are almost identical to those in the L-CAM gene and the exon/intron junctions occur at exactly equivalent positions in both genes. Exon 16, which includes the 3' untranslated region, is much shorter in the K-CAM gene and intron sizes and sequences are not generally conserved between the two genes. Probes from the K-CAM gene hybridized to a 3-kilobase mRNA that was present at high levels in embryonic skin, at lower levels in kidney, heart, and gizzard, and at still lower levels in brain and liver, as determined by Northern blotting. The sequence of the predicted gene product was nearly identical to that of the chicken B-cadherin cDNA, although the distribution of the K-CAM gene transcript differed from that reported for the cadherin. The proximity and identical overall structure of the K-CAM and L-CAM genes strongly suggest that they arose by gene duplication and raise the possibility that genes for other calcium-dependent CAMs may be located in clusters. Moreover, the tandem arrangement of the genes may have important implications for the regulation of their expression.

Regulation of connexin 43-mediated gap junctional intercellular communication by Ca2+ in mouse epidermal cells is controlled by E-cadherin.

Gap junctional intercellular communication (GJIC) of cultured mouse epidermal cells is mediated by a gap junction protein, connexin 43, and is dependent on the calcium concentration in the medium, with higher GJIC in a high-calcium (1.2 mM) medium. In several mouse epidermal cell lines, we found a good correlation between the level of GJIC and that of immunohistochemical staining of E-cadherin, a calcium-dependent cell adhesion molecule, at cell-cell contact areas. The variant cell line P3/22 showed both low GJIC and E-cadherin protein expression in low- and high-Ca2+ media. P3/22 cells showed very low E-cadherin mRNA expression. To test directly whether E-cadherin is involved in the Ca(2+)-dependent regulation of GJIC, we transfected the E-cadherin expression vector into P3/22 cells and obtained several stable clones which expressed high levels of E-cadherin mRNA. All transfectants expressed E-cadherin molecules at cell-cell contact areas in a calcium-dependent manner. GJIC was also observed in these transfectants and was calcium dependent. These results suggest that Ca(2+)-dependent regulation of GJIC in mouse epidermal cells is directly controlled by a calcium-dependent cell adhesion molecule, E-cadherin. Furthermore, several lines of evidence suggest that GJIC control by E-cadherin involves posttranslational regulation (assembly and/or function) of the gap junction protein connexin 43.

Desmocollins form a distinct subset of the cadherin family of cell adhesion molecules.

The desmosomal adhesive core is formed by four major components: desmoglein (Mr, 165,000), desmocollins I and II (Mr, 120,000 and 110,000, respectively), and a Mr 22,000 protein. Here, we report the cloning and sequencing of cDNAs encoding a bovine desmocollin. The open reading frame found in the longest cDNA, 5 kilobases, contains a region encoding a protein of 839 amino acids. The features of the deduced amino acid sequence imply that the mature 707-amino acid desmocollin is a type I transmembrane protein that is produced by proteolytic cleavage of an 810-amino acid precursor. The ectodomain of desmocollin contains repeats that show extensive sequence similarity to members of the cadherin family of calcium-dependent cell adhesion molecules. A comparison of the amino acid sequences of desmocollin, desmoglein, and the cadherins shows that although these intercellular junctional adhesion molecules share a consensus sequence in their adhesive domains that defines them as a family, several features, including the divergence in the sequence of their cytoplasmic tails, divide them into three distinct subtypes.