Chemical characterization of cell-CAM 105, a cell-adhesion molecule isolated from rat liver membranes

CEA-Related CAMs

The carcinoembryonic antigen (CEA) family comprises a large number of cellular surface molecules, the CEA-related cell adhesion molecules (CEACAMs), which belong to the Ig superfamily. CEACAMs exhibit a complex expression pattern in normal and malignant tissues. The majority of the CEACAMs are cellular adhesion molecules that are involved in a great variety of distinct cellular processes, for example in the integration of cellular responses through homo- and heterophilic adhesion and interaction with a broad selection of signal regulatory proteins, i.e., integrins or cytoskeletal components and tyrosine kinases. Moreover, expression of CEACAMs affects tumor growth, angiogenesis, cellular differentiation, immune responses, and they serve as receptors for commensal and pathogenic microbes. Recently, new insights into CEACAM structure and function became available, providing further elucidation of their kaleidoscopic functions.

hCEACAM1-4L downregulates hDAF-associated signalling after being recognized by the Dr adhesin of diffusely adhering Escherichia coli

Human decay accelerating factor (hDAF, CD55) and members of the carcinoembryonic-antigen-related cell-adhesion molecules (hCEACAMs) family are recognized as receptors by Gram-negative, diffusely adhering Escherichia coli (DAEC) strains expressing Afa/Dr adhesins. We report here that hCEACAM1-4L has a key function in downregulating the protein tyrosine Src kinase associated with hDAF signalling. After infecting HeLa epithelial cells stably transfected with hCEACAM1-4L cDNA with Dr adhesin-positive E. coli, the amount of the pTyr(416)-active form of the Src protein decreased, whereas that of the pTyr(527)-inactive form of Src protein did not increase. This downregulation of the Src protein implies that part of the hCEACAM1-4L protein had been translocated into lipid rafts, the protein was phosphorylated at Tyr residues in the cytoplasmic domain, and it was physically associated with the protein tyrosine phosphatase, SHP-2. Finally, we found that the hCEACAM1-4L-associated SHP-2 was not phosphorylated and lacked phosphatase activity, suggesting that the downregulation of Src protein associated with hDAF signalling results from the absence of dephosphorylation of the pTyr(527)-inactive form necessary for Src kinase activation.

Modulated expression of a nuclear-associated glycoprotein during normal rat liver development and in various hepatoma cells

Liver plays a major role in systemic detoxification and drug metabolism. NF-164, a protein of 164 kDa predominantly localized in hepatocyte nuclei, was found to be present in increasing amounts during liver maturation. In addition, fetal rat hepatocytes had ten times, and neonatal five times less of this protein than adult hepatocytes. It was also detected in an albumin producing hepatoma cell line, but not in three other lines that have lost several differentiated functions. These data suggest that NF-164 expression is development-dependent and that it may be a marker for both normal and malignant hepatocyte differentiation. NF-164 seems to be liver-specific, since it was not detected in rat brain, spleen, kidney, lung and bovine thymus. It was purified from adult rat hepatocyte nuclei. Its estimated pI is 6.8. Its total amino acid composition and partial amino acid sequence is also being reported. Despite major differences between their respective contents in amino acids, partial sequences showed homologies with carbamyl phosphate synthetase I (CPSI). These observations may suggest that NF-164 also shares some functional features with this enzyme.

Two Variable Regions in Carcinoembryonic Antigen-related Cell Adhesion Molecule1 N-terminal Domains Located in or Next to Monoclonal Antibody and Adhesion Epitopes Show Evidence of Recombination in Rat but Not in Human

In this paper, we have characterized the structure, evolutionary origin, and function of rat and human carcinoembryonic antigen-related cell adhesion molecule1 (CEACAM1) multifunctional Ig-like cell adhesion proteins that are expressed by many epithelial tissues. Restriction enzyme digestion reverse transcriptase-PCR analysis identified three cDNAs encoding novel CEACAM1 N-domains. Comparative sequence analysis showed that human and rat CEACAM1 N-domains segregated into two groups differing in similarity to rat CEACAM1(a)-4L and human CEACAM1. Sequence variability analysis indicated that both human and rat N-domains possessed two variable regions, and one contained a major adhesive epitope. Recombination analysis showed that the group of rat but not human N-domains with high sequence similarity was derived at least in part by recombination. Binding assays revealed that three monoclonal antibodies with strong reactivity for the CEACAM1(a)-4L N-domain showed no reactivity with CEACAM1(b)-4S, an allele with a different N-domain sequence. CEACAM1(b)-4S displayed adhesive activity efficiently blocked by a synthetic peptide corresponding to the adhesive epitope in CEACAM1(a)-4L. Blocking analysis also showed that the adhesive epitope for rat CEACAM1 was located downstream from the equivalent human and mouse epitopes. Glycosylation analysis demonstrated O-linked sugars on rat CEACAM1(b)-4S from COS-1 cells. However, this was not the alteration responsible for the lack of monoclonal antibody reactivity. When considered together with previous studies, our findings suggest an inverse relationship between functionality and amino acid sequence similarity to CEACAM1. Like IgG, the N-domain of CEACAM1 appears to tolerate 10-15% sequence diversification without loss of function but begins to show either altered specificity or diminished functionality at higher levels.

CEACAM1 isoforms with different cytoplasmic domains show different localization, organization and adhesive properties in polarized epithelial cells

CEACAM1 is a signaling cell adhesion molecule expressed in epithelia,vessel endothelia and leukocytes. It is expressed as two major isoforms with different cytoplasmic domains. CEACAM1 occurs both in cell-cell contact areas and on apical surfaces of polarized epithelial cells, but it is not known how the different isoforms are distributed in polarized cells or what the functions of CEACAM1 are in the apical surfaces. We investigated the localization and organization of the two CEACAM1 isoforms in transfected,polarized MDCK cells by confocal microscopy and differential surface labelling. CEACAM1-L was found on both the apical and the lateral surfaces,whereas CEACAM1-S appeared exclusively on the apical surfaces. Maintenance of the lateral localization of CEACAM1-L required homophilic binding between CEACAM1-L molecules on adjacent cells. Double-labelling with anti-CEACAM1 antibodies directed against different epitopes indicated that apical CEACAM1-L occurred either in a homophilic adhesive state or in a free non-adhesive state. CEACAM1-S appeared almost exclusively in the homophilic adhesive state. These findings suggest that CEACAM1 mediates adhesive bonds between adjacent microvilli on the apical surfaces.

The CEACAM1-L Ser503 residue is crucial for inhibition of colon cancer cell tumorigenicity

CEACAM1 (also known as biliary glycoprotein, C-CAM or CD66a) is a cell adhesion molecule of the immunoglobulin family behaving as a tumor inhibitory protein in colon, prostate, liver, endometrial and breast cancers. Inhibition of tumor development is dependent upon the presence of the long 71-73 amino acid cytoplasmic domain of the CEACAM1 protein (CEACAM1-L). We have recently defined a number of cis-acting motifs within the long cytoplasmic domain participating in tumor cell growth inhibition. These are Tyr488, corresponding to an Immunoreceptor Tyrosine-based Inhibition Motif, as well as the three terminal lysine residues of the protein. In this study, we provide evidence that treatment with phorbol esters leads to increased phosphorylation of in vivo (32)P-labeled CEACAM1-L in mouse CT51 carcinoma cells, in the mouse 1MEA 7R.1 liver carcinoma cells and in 293 human embryonic kidney cells transfected with the Ceacam1-L cDNA. Basal level Ser phosphorylation was abrogated by treatment with the staurosporine inhibitor, but not by the protein kinase C-specific inhibitor calphostin C or other inhibitors such as H7 or sphingosine. Specific inhibitors of protein kinase A or calmodulin kinase had only minimal effects on the levels of basal or PMA-induced Ser phosphorylation. Furthermore, PMA treatment of the CT51 cells induced cell spreading and cellular relocalization of the CEACAM1-L protein. Since Ser503 has been described as a PMA-induced phosphorylation site in other cell systems, we investigated whether Ser503 was involved in these responses in mouse intestinal cells. No differences were noticed in the basal or the PMA-induced phosphorylation levels, kinase inhibitor sensitivity or the PMA-induced relocalization of the protein between the wild-type and the Ser503Ala mutant CEACAM1-L. However, we provide evidence that Ser503 participates in CEACAM1-L-mediated tumor inhibition as its mutation to an Ala led to in vivo tumor development, contrary to the tumor inhibitory phenotype observed with the wild-type CEACAM1-L protein.

The CEACAM1-L glycoprotein associates with the actin cytoskeleton and localizes to cell-cell contact through activation of Rho-like GTPases

Associations between plasma membrane-linked proteins and the actin cytoskeleton play a crucial role in defining cell shape and determination, ensuring cell motility and facilitating cell-cell or cell-substratum adhesion. Here, we present evidence that CEACAM1-L, a cell adhesion molecule of the carcinoembryonic antigen family, is associated with the actin cytoskeleton. We have delineated the regions involved in actin cytoskeleton association to the distal end of the CEACAM1-L long cytoplasmic domain. We have demonstrated that CEACAM1-S, an isoform of CEACAM1 with a truncated cytoplasmic domain, does not interact with the actin cytoskeleton. In addition, a major difference in subcellular localization of the two CEACAM1 isoforms was observed. Furthermore, we have established that the localization of CEACAM1-L at cell-cell boundaries is regulated by the Rho family of GTPases. The retention of the protein at the sites of intercellular contacts critically depends on homophilic CEACAM1-CEACAM1 interactions and association with the actin cytoskeleton. Our results provide new evidence on how the Rho family of GTPases can control cell adhesion: by directing an adhesion molecule to its proper cellular destination. In addition, these results provide an insight into the mechanisms of why CEACAM1-L, but not CEACAM1-S, functions as a tumor cell growth inhibitor.

N-glycosylation of the carcinoembryonic antigen related cell adhesion molecule, C-CAM, from rat liver: detection of oversialylated bi- and triantennary structures

Rat C-CAM is a ubiquitous, transmembrane and carcinoembryonic antigen related cell adhesion molecule. The human counterpart is known as biliary glycoprotein (BGP) or CD66a. It is involved in different cellular functions ranging from intercellular adhesion, microbial receptor activity, signaling and tumor suppression. In the present study N-glycosylation of C-CAM immunopurified from rat liver was analyzed in detail. The primary sequence of rat C-CAM contains 15 potential N-glycosylation sites. The N-glycans were enzymatically released from glycopeptides, fluorescently labeled with 2-aminobenzamide, and separated by two-dimensional HPLC. Oligosaccharide structures were characterized by enzymatic sequencing and MALDI-TOF-MS. Mainly bi- and triantennary complex structures were identified. The presence of type I and type II chains in the antennae of these glycans results in heterogeneous glycosylation of C-CAM. Sialylation of the sugars was found to be unusual; bi- and triantennary glycans contained three and four sialic acid residues, respectively, and this linkage seemed to be restricted to the type I chain in the antennae. Approximately 20% of the detected sugars contain these unusual numbers of sialic acids. C-CAM is the first transmembrane protein found to be oversialylated.

C-CAM-mediated adhesion leads to an outside-in dephosphorylation signal

The rat cell-cell adhesion molecule C-CAM, a member of the carcinoembryonic antigen family, was shown to be expressed in various isoforms, differing in the length of the cytoplasmic domain. The long isoform C-CAML inhibits the growth of different malignant cells. Several studies suggest that it is involved in the mechanism of signal transduction. So far no direct correlation between C-CAM function and C-CAM phosphorylation has been reported. In the present study we addressed the question of whether C-CAM-mediated adhesion is accompanied by changes in phosphorylation of the cytoplasmic domain of C-CAM. It was demonstrated that C-CAML is constitutively phosphorylated in adherent growing cells as well as in cells growing in suspension. In contrast, C-CAML-mediated cell aggregation is accompanied by a 40% reduction in C-CAML phosphorylation compared with nonaggregated cells. The same dephosphorylation was achieved by antibody-induced clustering of C-CAML in the plasma membrane. Phosphorylation and dephosphorylation indicate a C-CAM-mediated outside-in signalling induced by cell-cell adhesion.

Carcinoembryonic antigen-related cell-cell adhesion molecule C-CAM is greatly increased in serum and urine of rats with liver diseases

C-CAM (rat cell CAM/human CD66a) is ubiquitous and multifunctional. It is involved in intercellular adhesion, signal transduction and cell growth inhibition. Structurally, it is related to the carcinoembryonic antigen. In the present study serum, bile and urine of rats with liver diseases were analyzed for the presence of cell CAM. After bile duct ligation and during galactosamine (GalN) hepatitis we found that large amounts of liver membrane-bound C-CAM are secreted or shed into blood. The serum level of another liver membrane-bound protein, LI-cadherin, is not increased. It was shown that C-CAM is also present in bile fluid, and for the first time that C-CAM is present in the urine of rats with liver diseases. A particularly high concentration was measured in the urine of rats suffering from GalN hepatitis.

Characterization of protein kinase C-mediated phosphorylation of the short cytoplasmic domain isoform of C-CAM

C-CAM is a ubiquitously expressed cell adhesion molecule belonging to the carcinoembryonic antigen family. Two co-expressed isoforms, C-CAM-L and C-CAM-S, are known, having different cytoplasmic domains both of which can be phosphorylated in vivo. Here we have characterized the PKC-mediated phosphorylation of the short cytoplasmic domain isoform, C-CAM-S. Phorbol myristyl acetate induced phosphorylation of C-CAM-S in transfected CHO cells. Using synthetic peptides and Edman degradation we identified Ser449 as the PKC-phosphorylated amino acid residue. Binding experiments with modified peptides indicated that this phosphorylation decreases the ability of the cytoplasmic domain of C-CAM-S to bind calmodulin.

Evidence for regulated dimerization of cell-cell adhesion molecule (C-CAM) in epithelial cells

C-CAM is a Ca(2+)-independent cell adhesion molecule (CAM) belonging to the immunoglobulin superfamily. Addition of chemical cross-linkers to isolated rat liver plasma membranes, intact epithelial cells and purified preparations of C-CAM stabilized one major C-CAM-containing product whose apparent molecular mass was approximately twice that of the C-CAM monomer. The failure to detect additional proteins after cleavage of the cross-linked species demonstrated that C-CAM exists as non-covalently linked dimers both in solution and on the cell surface. Dimerization occurred to the same extent in adherent monolayers and in single cell populations, indicating that dimer formation was the result of cis-interactions within the membranes of individual cells. Using isoform-specific anti-peptide antibodies, both C-CAM1 and C-CAM2 were found to be involved in dimerization, forming predominantly homo-dimeric species. Both calmodulin and Ca2+ ionophore modulated the level of dimer formation, suggesting a role for regulated self-association in the functional activity of C-CAM.

Calmodulin binds to specific sequences in the cytoplasmic domain of C-CAM and down-regulates C-CAM self-association

C-CAM is a cell adhesion molecule belonging to the immunoglobulin supergene family and is known to mediate calcium-independent homophilic cell-cell binding. Two major isoforms, C-CAM1 and C-CAM2, which differ in their cytoplasmic domains, have been identified. Previous investigations have demonstrated that both cytoplasmic domains can bind calmodulin in a calcium-dependent reaction. In this investigation, peptides corresponding to the cytoplasmic domains of C-CAM were synthesized on cellulose membranes and used to map the binding sites for 125I-labeled calmodulin. Both C-CAM1 and C-CAM2 had one strong calmodulin-binding site in the membrane-proximal region. Those binding regions were conserved in C-CAM from rat, mouse, and man. In addition, C-CAM1 from rat and mouse contained a weaker binding site in the distal region of the cytoplasmic domain. Biosensor experiments were performed to determine rate and equilibrium constants of the C-CAM/calmodulin interaction. An association rate constants of 3.3 x 10(5) M-1 s-1 and two dissociation rate constants of 2.2 x 10(-2) and 3.1 x 10(-5) s-1 were determined. These correspond to equilibrium dissociation constants of 6.7 x 10(-8) and 9.4 x 10(-11) M, respectively. In dot-blot binding experiments, it was found that binding of calmodulin causes a down-regulation of the homophilic self-association of C-CAM. This suggests that calmodulin can regulate the functional activity of C-CAM.

A short isoform of carcinoembryonic-antigen-related rat liver cell-cell adhesion molecule (C-CAM/gp110) mediates intercellular adhesion. Sequencing and recombinant functional analysis

Rat liver cell-cell adhesion molecule (C-CAM) is a type I transmembrane glycoprotein belonging to the immunoglobulin (Ig)-superfamily. Within this family it is related to the carcinoembryonic antigen (CEA) proteins. C-CAM, previously known as gp110, cell-CAM 105, HA4/pp120 or ecto-ATPase, is a highly glycosylated protein with an apparent M(r) or 100,000-115,000 and an isoelectric point of 3-3.5. It was analysed as a molecule that stimulates reaggregation of isolated hepatocytes. So far three different isoforms have been cloned. Only the isoform with a long intracellular tail (71 amino acids), C-CAM1, was shown to be involved in intercellular adhesion. C-CAM2, an isoform with only 10 cytoplasmic amino acids and a slightly different N-terminal Ig-like loop did not function as an adhesion molecule. In this study we show the existence of another short C-CAM isoform (C-CAM2a), which is an alternatively spliced product of the C-CAM1 gene. Like C-CAM2, it has a short cytoplasmic tail, but in the extracellular region it is identical to C-CAM1. To investigate whether C-CAM2a can function as an adhesion molecule, we stably expressed the corresponding cDNA in Chinese hamster ovary (CHO) cells. In these cells, we detected a specific increase of intercellular adhesion, indicating that, in contrast to the other short isoform, C-CAM2a can induce adhesion. This adhesion is homophilic and Ca2+ independent.

Cell adhesion activity of the short cytoplasmic domain isoform of C-CAM (C-CAM2) in CHO cells

C-CAM is a Ca(2+)-independent rat cell adhesion molecule belonging to the CEA gene family of the immunoglobulin superfamily. Two major isoforms that differ in the length of their cytoplasmic domains exist. In previous studies it has been reported that only the long isoform (C-CAM1) but not the short isoform (C-CAM2) can mediate adhesion. However, in the mouse, isoforms with both long and short cytoplasmic domains have been reported to have adhesive activity. In order to analyze this apparent conflict we transfected C-CAM1 or C-CAM2 into CHO Pro5 cells and examined their adhesive phenotype in an aggregation assay. We found that in this cellular system both C-CAM1 and C-CAM2 could mediate cell-cell adhesion in a Ca(2+)-independent and temperature-independent way. The results suggest that the cellular environment is important for the activity of C-CAM isoforms.

Liver-regulating protein (LRP) is a plasma membrane protein involved in cell contact-mediated regulation of Sertoli cell function by primary spermatocytes

We have identified a liver-regulating protein involved in cell contact-mediated regulation of Sertoli cell function by primary spermatocytes in rat testis. Liver-regulating protein was studied using monoclonal antibody L8 prepared from rat primitive biliary epithelial cells. This molecule was located in vivo at the interface of Sertoli cells and spermatocytes, and expressed in a stage-dependent manner (expression peaked on leptotene-zygotene spermatocytes). In vitro, the liver-regulating protein was found on Sertoli cell, spermatocyte and early spermatid membranes. Immunoaffinity procedures revealed two peptides of 85 and 73 kDa for Sertoli cells, while spermatocytes and spermatids displayed a single smaller peptide of 56 kDa. The involvement of the liver-regulating protein in cell interaction-mediated regulation of Sertoli cell was assessed in vitro by tracing Sertoli cell transferrin and inhibin secretion, as well as mRNA synthesis in spermatocyte-Sertoli cell cocultures and in rat liver biliary epithelial cell-Sertoli cell cocultures, performed in the presence or absence of monoclonal antibody L8. Inhibition of the spermatocyte- and liver biliary epithelial cell-stimulated secretion of transferrin and inhibin by Sertoli cells was observed in the presence of antibody, whereas spermatocyte adhesiveness was unchanged. Using northern blot analysis, the steady state levels of transferrin mRNA decreased when the anti-liver-regulating protein antibody was added to the Sertoli cell-spermatocyte cocultures or to the Sertoli cell-liver biliary epithelial cell cocultures. The data demonstrate the role of the liver-regulating protein in cell-cell contact-mediated regulation of Sertoli function by primary spermatocytes and the important implications of this cell contact-dependent control in testicular activity.

Ecto-ATPases: identities and functions

Ecto-ATPases are ubiquitous in eukaryotic cells. They hydrolyze extracellular nucleoside tri- and/or diphosphates, and, when isolated, they exhibit E-type ATPase activity, (that is, the activity is dependent on Ca2+ or Mg2+, and it is insensitive to specific inhibitors of P-type, F-type, and V-type ATPases; in addition, several nucleotide tri- and/or diphosphates are hydrolysed, but nucleoside monophosphates and nonnucleoside phosphates are not substrates). Ecto-ATPases are glycoproteins; they do not form a phosphorylated intermediate during the catalytic cycle; they seem to have an extremely high turnover number; and they present specific experimental problems during solubilization and purification. The T-tubule Mg2+-ATPase belongs to this group of enzymes, which may serve at least two major roles: they terminate ATP/ADP-induced signal transduction and participate in adenosine recycling. Several other functions have been discussed and identity to certain cell adhesion molecules and the bile acid transport protein was suggested on the basis of cDNA clone isolation and immunological work.

Differential regulation of C-CAM isoforms in epithelial cells

C-CAM is a Ca(2+)-independent cell adhesion molecule (CAM) that mediates intercellular adhesion of isolated rat hepatocytes. It is widely distributed in epithelia, where its presence both at lateral cell borders and on apical cell surfaces suggests that it may have diverse biological functions. Two major isoforms, C-CAM1 and C-CAM2, which differ in the lengths of their cytoplasmic domains, have been identified. The lack of suitable in vitro systems has so far prevented a detailed study of the physiological role of C-CAM in epithelia. We now report on the identification, biochemical characterization and functional analysis of C-CAM isoforms in the established epithelial cell line NBT II, derived from a chemically induced carcinoma of rat bladder. C-CAM in NBT II cells is a 110–115 kDa cell surface glycoprotein located predominantly at sites of cell-cell contact but also present on the apical cell surface. Northern blotting analysis revealed the presence of both C-CAM1 and C-CAM2, with the major transcripts for both isoforms present within the 4.0 kb size range. The dissociation of NBT II cell colonies by anti-C-CAM antibodies indicated that at least one function of C-CAM in these cells is to mediate intercellular adhesion. The maintenance of extensive cell-cell contacts and the expression of C-CAM at the contact sites in cells grown in low Ca2+ medium suggested that, like its counterpart in hepatocytes, C-CAM in NBT II cells may be a Ca(2+)-independent cell-cell adhesion molecule. The co-localization and coordinate reorganization of both C-CAM and actin by anti-C-CAM antibodies indicated that these two proteins were associated and suggested that interactions with the cytoskeleton may be important for the regulation of C-CAM function. The specific upregulation of C-CAM1 in cells induced to undergo epithelial to mesenchymal-like transitions (EMT) by the serum substitute Ultroser G suggested that C-CAM isoforms are important modulators of the adhesive properties of these cells.

C-CAM expression in the developing rat central nervous system

C-CAM, a transmembrane glycoprotein belonging to the immunoglobulin superfamily, can mediate intercellular adhesion by homophilic, Ca(2+)-independent binding. Immunohistochemical analysis of adult rat tissues has demonstrated that C-CAM is expressed in various epithelia, vessel endothelia, and hematopoietic cells. By molecular cloning and sequence analysis several isoforms differing both in the extracellular and the cytoplasmic domains have been found. Here we have analyzed the expression of C-CAM in the developing rat central nervous system. No neuronal expression was observed, but biochemical and immunohistochemical analyses demonstrated that C-CAM becomes expressed in the microvessels from embryonic day E-13; the intensity of the staining increased through day E-15 and then gradually decreased during the perinatal and early postnatal period. The expression of C-CAM in the walls of the microvessels was confirmed by in situ hybridization. Immunoelectron microscopy showed that C-CAM was localized both to the abluminal surface of the endothelial cells and to cellular processes of primordial pericytes where these two cell types are in contact with each other. No staining was found on the luminal endothelial cell surfaces or inter-endothelial cell contact areas. During the perinatal period C-CAM also became expressed on the opposite side of the pericytes and on other cells, possibly astrocytes, in contact with these areas of the pericytes. These observations suggest that C-CAM may be involved in heterotypic, homophilic adhesion between endothelial cells, pericytes and astrocytes, and in maturation of the vessel walls.

Evidence for calmodulin binding to the cytoplasmic domains of two C-CAM isoforms

C-CAM (cell-CAM 105) is a transmembrane cell adhesion molecule, belonging to the immunoglobulin superfamily. It is expressed in epithelia, vessel endothelia and leukocytes, and mediates intercellular adhesion in rat hepatocytes by homophilic binding. Two major isoforms (C-CAM1 and C-CAM2) that differ in their cytoplasmic domains occur. A previous study demonstrated that C-CAM can bind calmodulin in a Ca(2+)-dependent manner. In this study we have expressed the cytoplasmic domains of C-CAM1 and C-CAM2 in fusion proteins and measured calmodulin binding by a gel overlay assay, using 125I-labelled calmodulin. Our results indicate that the cytoplasmic domains of both C-CAM1 and C-CAM2 can bind calmodulin.

Characterisation of the ATP-dependent taurocholate-carrier protein (gp110) of the hepatocyte canalicular membrane

The canalicular domain-specific glycoprotein gp110, which recently has been shown to function as an ATP-dependent taurocholate transporter, has been purified 1800-fold from rat liver plasma membranes. gp110 has been characterised as an integral plasma membrane protein with M(r) of 100,000-115,000 and pI of 2.5-3.5 and possesses a highly glycosylated and negatively charged extra-cellular domain. The broad range of M(r) and pI values results from the existence of numerous glycoforms composed of sialylated N-glycans. After deglycosylation, the polypeptide has M(r) 48,000 and pI 5.0. In primary cultures of rat hepatocytes, gp110 is synthesised with M(r) 110,000, while in the presence of tunicamycin the non-glycosylated form has M(r) 48,000. In the presence of 1-deoxymannojirimycin, two forms of M(r) 83,000 and M(r) 91,000 were found, which were converted by endo-beta-N-acetylglucosaminidase H into a single 52,000-M(r) band, indicating the existence of two basic glycoforms at the oligomannosyl stage of biosynthesis. gp110 was phosphorylated at serine residues in primary cultures of hepatocytes. The sequences of ten internal peptides of gp110 were identical to the sequence of the high-M(r) form of ecto-ATPase, but ecto-ATPase activity from plasma-membrane extracts was not depleted by anti-(gp110) serum. In contrast, Fab fragments of these antibodies inhibit the aggregation of freshly isolated hepatocytes.

Different isoforms and stock-specific variants of the cell adhesion molecule C-CAM (cell-CAM 105) in rat liver

C-CAM is a cell adhesion molecule of the immunoglobulin superfamily with homophilic binding properties. Here we used the polymerase chain reaction to isolate clones of C-CAM from a rat liver cDNA library. Sequence analyses identified two major isoforms, C-CAM1 and C-CAM2, which differed in their 3' ends. C-CAM2 lacked a sequence of 53 nucleotides that was present in C-CAM1. This causes a frame shift and new stop codons, which gives rise to cytoplasmic domains of different sizes in the two isoforms (10 versus 71 amino-acid residues). In addition, all the clones had a different nucleotide and deduced amino-acid sequence (variant b) in the most N-terminal of the four immunoglobulin-like domains, compared to a previously published C-CAM sequence (variant a). Northern-blot analyses with specific oligonucleotide probes demonstrated that two different rat stocks expressed either variant a or variant b. Northern-blot analyses of rat liver and lung also showed that at least five different C-CAM transcripts are produced. Two major mRNA size classes of 4.0 kb and 6.0 kb, and one minor class of 3.0 kb were found. Both the 4.0-kb and 3.0-kb messenger classes reacted with two different probes that could distinguish between C-CAM1 and C-CAM2, while the 6.0-kb population only reacted with the probe selective for C-CAM1. Taken together these data demonstrate the existence of four different protein-coding sequences of rat liver C-CAM (C-CAM1 a and b, and C-CAM2 a and b). We suggest that both allelic variation and alternative splicing may contribute to the isoform-expression pattern of C-CAM in rats.

C-CAM (Cell-CAM 105) is a calmodulin binding protein

C-CAM (Cell-CAM 105) is a transmembrane cell adhesion molecule belonging to the immunoglobulin superfamily. It mediates intercellular adhesion of rat hepatocytes and occurs in various isoforms in several epithelia, vessel endothelia and leukocytes. We now report that purified liver C-CAM interacts specifically with calmodulin. Binding was observed both when 125I-labeled C-CAM was used in a dot-blot assay and when 125I-labeled calmodulin was used in a gel overlay assay. Experiments with protease-generated peptides indicated that calmodulin bound to the cytoplasmic domain of C-CAM. Analyses of whole liver membranes demonstrated that C-CAM is one of five major proteins that bind calmodulin in a calcium-dependent manner.

A Ca(2+)-ATPase from rat parotid gland plasma membranes has the characteristics of an ecto-ATPase

A Ca(2+)-ATPase with an apparent Km for free Ca2+ = 0.23 microM and Vmax = 44 nmol Pi/mg/min was detected in a rat parotid plasma membrane-enriched fraction. This Ca(2+)-ATPase could be stimulated without added Mg2+. However, the enzyme may require submicromolar concentrations of Mg2+ for its activation in the presence of Ca2+. On the other hand, Mg2+ could substitute for Ca2+. The lack of a requirement for added Mg2+ distinguished this Ca(2+)-ATPase from the Ca(2+)-transporter ATPase in the plasma membranes and the mitochondrial Ca(2+)-ATPase. The enzyme was not inhibited by several ATPase inhibitors and was not stimulated by calmodulin. An antibody which was raised against the rat liver plasma membrane ecto-ATPase, was able to deplete this Ca(2+)-ATPase activity from detergent solubilized rat parotid plasma membranes, in an antibody concentration-dependent manner. Immunoblotting analysis of the pellet with the ecto-ATPase antibody revealed the presence of a 100,000 molecular weight protein band, in agreement with the reported ecto-ATPase relative molecular mass. These data demonstrate the presence of a Ca(2+)-ATPase, with high affinity for Ca2+, in the rat parotid gland plasma membranes. It is distinct from the Ca(2+)-transporter, and immunologically indistinguishable from the plasma membrane ecto-ATPase.

A plasma membrane protein is involved in cell contact-mediated regulation of tissue-specific genes in adult hepatocytes

We have identified the liver-regulating protein (LRP), a cell surface protein involved in the maintenance of hepatocyte differentiation when cocultured with rat liver epithelial cells (RLEC). LRP was defined by immunoreactivity to a monoclonal antibody (mAb L8) prepared from RLEC. mAb L8 specifically detected two polypeptides of 85 and 73 kD in immunoprecipitation of both hepatocyte- and RLEC-iodinated plasma membranes. The involvement of these polypeptides, which are integral membrane proteins, in cell interaction-mediated regulation of hepatocytes was assessed by evaluating the perturbing effects of the antibody on cocultures with RLEC. Several parameters characteristic of differentiated hepatocytes were studied, such as liver-specific and house-keeping gene expression, cytoskeletal organization and deposition of extracellular matrix (ECM). An early cytoskeletal disturbance was evidenced and a marked alteration of hepatocyte functional capacity was observed in the presence of the antibody, together with a loss of ECM deposition. By contrast, cell-cell aggregation or cell adhesion to various extracellular matrix components were not affected. These findings suggest that LRP is distinct from an extracellular matrix receptor. The fact that early addition of mAb L8 during cell contact establishment was necessary to be effective may indicate that LRP is a novel plasma membrane protein that plays an early pivotal role in the coordinated metabolic changes which lead to the differentiated phenotype of mature hepatocytes.

Cell-cell contacts mediated by E-cadherin (uvomorulin) restrict invasive behavior of L-cells

L-cells were cotransfected with plasmids coding for mouse E-cadherin (uvomorulin) and the neophosphotransferase gene, and stable transfectants expressing E-cadherin at the cell surface were selected and cloned. Control transfection was done with the neophosphotransferase gene alone. The invasive migration of transfected and untransfected L-cells into three-dimensional collagen gels was then analyzed. L-cells not expressing E-cadherin migrated efficiently into the gels, whereas invasion of the E-cadherin-expressing L-cells was restricted in a cell density dependent manner. At sparse density, when the cells exhibited little cell-cell contacts, no difference was observed between the level of invasion of the cadherin-expressing cells and the control cells. However, with increasing cell density, decreasing amounts of the cadherin-expressing cells but increasing amounts of the control cells migrated into the gels. At confluent density hardly any cadherin-expressing cells were able to migrate into the gels. The inhibition of the invasion of the cadherin-expressing cells could be reverted if confluent cells were cultured in the presence of monoclonal antibodies against E-cadherin. Since the expression of E-cadherin did not influence the invasive mobility of single cells, these results indicate that E-cadherin-mediated cell-cell contacts inhibited invasive cellular migration. Time-lapse videoscopy and studies of cell migration from a monolayer into a cell-free area demonstrated that the restricted invasion could be explained by contact inhibition of cell movement of the cadherin-expressing cells.

C-CAM (cell-CAM 105)--a member of the growing immunoglobulin superfamily of cell adhesion proteins

Cell recognition and adhesion, being of prime importance for the formation and integrity of tissues, are mediated by cell adhesion molecules, which can be divided into several distinct protein superfamilies. The cell adhesion molecule C-CAM (cell-CAM 105) belongs to the immunoglobulin superfamily, and more specifically is a member of the carcinoembryonic antigen (CEA) gene family. C-CAM can mediate adhesion between hepatocytes in vitro in a homophilic, calcium-independent binding reaction. The molecule, which occurs in various isoforms, is expressed in liver, several epithelia, vessel endothelia, platelets and granulocytes and its expression is dynamically regulated under various physiological and pathological conditions. It is proposed that C-CAM in different cells and tissues plays different functional roles, where the common denominator is membrane-membrane binding.

Identification of a novel glycoprotein (AGp110) involved in interactions of rat liver parenchymal cells with fibronectin

We have identified an integral membrane glycoprotein in rat liver that mediates adhesion of cultured hepatocytes on fibronectin substrata. The protein was isolated by affinity chromatography of detergent extracts on wheat germ lectin-Agarose followed by chromatography of the WGA binding fraction on fibronectin-Sepharose. The glycoprotein (AGp110), eluted at high salt concentrations from the fibronectin column, has a molecular mass of 110 kD and a pI of 4.2. Binding of immobilized AGp110 to soluble rat plasma fibronectin required Ca2+ ions but was not inhibited by RGD peptides. Fab' fragments of immunoglobulins raised in rabbits against AGp110 reversed the spreading of primary hepatocytes attached onto fibronectin-coated substrata, but had no effect on cells spread on type IV collagen or laminin substrata. The effect of the antiserum on cell spreading was reversible. AGp110 was detected by immunofluorescence around the periphery of the ventral surface of substratum attached hepatocytes, and scattered on the dorsal surface. Immunohistochemical evidence and Western blotting of fractionated liver plasma membranes indicated a bile canalicular (apical) localization of AGp110 in the liver parenchyma. Expression of AGp110 is tissue specific: it was found mainly in liver, kidney, pancreas, and small intestine but was not detected in stomach, skeletal muscle, heart, and large intestine. AGp110 could be labeled by lactoperoxidase-catalyzed surface iodination of intact liver cells and, after phase partitioning of liver plasma membranes with the detergent Triton X-114, it was preferentially distributed in the hydrophobic phase. Treatment with glycosidases indicated extensive sialic acid substitution in at least 10 O-linked carbohydrate chains and 1-2 N-linked glycans. Immunological comparisons suggest that AGp110, the integrin fibronectin receptor and dipeptidyl peptidase IV, an enzyme involved in fibronectin-mediated adhesion of hepatocytes on collagen, are distinct proteins.

Bile duct ligation-induced redistribution of canalicular antigen in rat hepatocyte plasma membranes demonstrated by immunogold quantitation

Extrahepatic obstructive cholestasis has been demonstrated to induce a redistribution of domain specific membrane proteins in rat hepatocytes reflecting loss or even reversal of cell polarity. In order to further characterize the redistribution of canalicular antigens, we used the Lowicryl K4M immunogold technique for examination of the effects of bile duct ligation (50 h) on the distribution of antigen in rat hepatocytes at the ultrastructural level and quantitated immuno-gold density in the three domains of the plasma membrane. In normal hepatocytes, antigen was localized almost exclusively in the canalicular domain while the sinusoidal and lateral membranes showed only weak immunoreactivity. Other localizations included organelles compatible with known pathways of biosynthesis and degradation. Bile duct ligation markedly reduced immunolabel in the canalicular and increased it slightly in the sinusoidal domain. The number and staining intensity of immunoreactive subcanalicular lysosomes and vesicles probably representing endosomes was augmented. Number of immunogold particles per micron of plasma membrane were 7.86 vs 2.46 (P less than 0.005) in the canalicular, 1.16 vs 1.38 (n.s.) in the sinusoidal, and 1.23 vs 1.08 (n.s.) in the lateral domain resulting in a canalicular decrease by 68.7% and a sinusoidal increase of 19.0%. Overall decrease in total plasma membranes was by 29.7% (P less than 0.05). Thus, our data show that the sinusoidal and lateral domains behave differently. Furthermore, quantitative immunocytochemistry demonstrates a decrease in the canalicular antigen density and suggests a sinusoidal increase. The present data agree with the concept that bile duct ligation results in a loss or even reversal of cell polarity in hepatocytes.

The cell adhesion molecule Cell-CAM 105 is an ecto-ATPase and a member of the immunoglobulin superfamily

Cell-CAM 105 (C-CAM), a cell adhesion molecule in rat hepatocytes, was digested with trypsin, and peptides were isolated and sequenced by Edman degradation. The sequences of 4 peptides agreed with different regions of rat liver ecto-ATPase. Detailed biochemical analyses confirmed the identity between C-CAM and the ecto-ATPase. C-CAM/ecto-ATPase is a transmembrane protein having 4 immunoglobulin-like domains in the extracellular portion, demonstrating membership of the immunoglobulin superfamily. The ATPase activity suggests that ATP might influence cell adhesion, which would explain the inhibitory effect of exogenously added ATP on adhesion of several cell types.

Comparison and functional characterization of C-CAM, glycoprotein IIb/IIIa and integrin beta 1 in rat platelets

Three adhesion-related proteins in rat platelets were compared, namely C-CAM, gpIIb/IIIa, and integrin beta 1. These three proteins behaved as distinct components as judged by both biochemical and immunological analyses. GpIIb/IIIa bound to a GRGDSPC-peptide, but neither beta 1-containing integrins nor C-CAM had any affinity either for this peptide or for a large cell-binding fragment of fibronectin. C-CAM and integrin beta 1 behaved differently when platelets were labeled with 125I, solubilized by detergent, and immunoprecipitated. Significant amounts of labeled C-CAM was precipitated when the platelets were first solubilized with detergent and then 125I-labeled. Almost no labeled C-CAM could be precipitated when intact platelets, that were unactivated or activated by ADP, were labeled. In contrast, labeled integrin beta 1 was immunoprecipitated when unactivated platelets were surface-labeled. However, when platelets that were activated by ADP and calcium ions were labeled almost no labeled integrin beta 1 could be immunoprecipitated. These data indicate 1) that C-CAM in intact platelets is inaccessible to surface-labeling and 2) that beta 1 integrin is less accessible to surface-labeling after platelet activation in the presence of calcium ions.

Distribution and dynamics of cell surface-associated cellCAM 105 in cultured rat hepatocytes

The cellular location of cellCAM 105 was studied by indirect immunofluorescence microscopy of primary rat hepatocytes grown in monolayer culture. Staining corresponding to cellCAM 105 was seen both in cell-cell contact areas and on the upper surfaces of the cells. In the cell-cell contact areas the antigen was not accessible to the antibodies unless the cells were either permeabilized with detergent or incubated in a calcium-free medium. Removal of calcium from the medium caused the cells to separate from each other. Within a few minutes wide intercellular clefts were formed, and upon further incubation the cells became stellate-shaped and finally remained in contact with each other only via thin cellular processes. These processes were cellCAM 105-positive and at sites where they attached to the bodies of the contracted cells a granular fluorescence pattern appeared. After 24-48 h of culture, intercellular channels resembling bile canaliculi were sometimes formed in the hepatocyte monolayers. The membranes of these intercellular channels were stained for cellCAM 105. After culture for several days the hepatocytes lost their polygonal shape and gradually acquired a more fibroblast-like morphology. This morphological change was accompanied by a decrease in cellCAM 105-specific fluorescence, both in the cell-cell contact areas and on the free cell surfaces.

Structural assessment of the N-linked oligosaccharides of cell-CAM 105 by lectin-agarose affinity chromatography

The N-linked oligosaccharides of cell-CAM 105, a glycoprotein involved in the intercellular adhesion between rat hepatocytes, were studied by sequential lectin-agarose affinity chromatography of desialylated, [14C]-labelled glycopeptides. These glycopeptides were obtained by extensive pronase digestion followed by N-[14C]acetylation of the peptide moieties and desialylation by mild acid hydrolysis. Assuming that all glycopeptides were radiolabelled to the same specific radioactivity, Concanavalin A-Sepharose chromatography indicated that the majority of the glycans (84%) were of the complex-type of which approximately half were bi-antennary structures. The remainder of the glycans comprised oligomannose-type structures and/or incomplete bi-antennary structures. Pisum sativum lectin-agarose chromatography revealed that part of the bi-antennary glycans contained a fucose residue alpha(1-6)-linked to the N-acetylglucosamine which is attached to asparagine. Furthermore, the presence of tri-, and tetra- and/or tri'-antennary complex-type glycans was demonstrated by chromatography on immobilized Phaseolus vulgaris leukoagglutinating phytohemagglutinin and Aleuria aurantia lectin (AAL). AAL-agarose chromatography furthermore indicated the presence of alpha(1-3)-linked fucose in part of these glycopeptides, whereas no alpha(1-6)-linked fucose could be detected in these structures. The degree of beta-galactosylation of the complex-type glycans was investigated by chromatography on Ricinus communis agglutinin-agarose. The results indicated that only part of the bi-antennary glycans were completely beta-galactosylated. Similarly, at least three beta-galactose residues were present in only a part of the tri-, and tetra- and/or tri'-antennary glycans.

Cell-surface location and molecular properties of cell-CAM 105 in intestinal epithelial cells

Cell-CAM 105 is involved in intercellular adhesion of isolated rat hepatocytes in vitro. In addition to liver, cell-CAM 105 occurs in several different epithelia, in platelets, and in granulocytes. In this paper we present a detailed analysis of cell-CAM 105 in the small intestinal mucosa. Isolated rat intestinal epithelial cells and brush-borders were investigated by indirect immunofluorescence. A strong fluorescence occurred in the brush-border region and a much weaker staining was seen in the lateral cell surfaces. The brush-border staining was heterogeneous and concentrated to the periphery where brush-border microvilli from adjacent cells are in contact with each other. It is suggested that cell-CAM 105 might mediate binding between the outer surfaces of neighboring microvilli. Immunoblotting and electrophoretic analyses of the biochemical properties of intestinal cell-CAM 105 demonstrated significant differences compared with cell-CAM 105 isolated from liver. Intestinal cell-CAM 105 was smaller than liver cell-CAM 105 under reducing conditions, whereas it was larger than liver cell-CAM 105 under non-reducing conditions. Chemical reduction decreased the size of intestinal cell-CAM 105, but increased the size of liver cell-CAM 105. Our interpretation of these data is that intestinal cell-CAM 105 occurs as a part of a macromolecular complex. This interpretation was supported by electrophoretic analyses of intestinal cell-CAM 105 isolated by immunoaffinity chromatography on anti-cell-CAM antibodies. In addition to cell-CAM 105, this material contained several other proteins of lower molecular weight than cell-CAM 105. These data suggest that intestinal cell-CAM 105 participates in cell-surface interactions that may regulate the structure and function of the apical brush-border regions of the intestinal epithelial cells.

The cell-surface expression of the cell adhesion molecule cellCAM 105 in rat fetal tissues and regenerating liver

In the present investigation we have used a sensitive immunohistochemical technique to study the appearance and cell-surface distribution of cellCAM 105 in rat fetal tissues and in regenerating liver. CellCAM 105 is an integral membrane glycoprotein that is involved in cell-cell adhesion of mature rat hepatocytes in vitro. In 12-day-old rat fetuses no cellCAM 105 was detected. CellCAM 105 then appeared on Day 13 in megakaryocytes of the fetal liver, on Day 16 in the liver parenchyme, and on Day 17 in the epithelial cells of the proximal kidney tubules and of the small intestinal mucosa. In the liver parenchyme cellCAM 105 first appeared in immature bile canaliculi. During Days 19-21 a significant staining also occurred on the contiguous sides of the hepatocytes, which at that time became closely associated when the blood-forming cells disappeared. This surface staining then gradually disappeared and 2-3 weeks after birth cellCAM 105 was expressed in the bile canalicular area which is typical of mature hepatocytes. In regenerating liver the amount of cellCAM 105 decreases to a minimum 2-3 days post-hepatectomy, then increases and reaches the normal concentration 10-15 days post-hepatectomy [Odin and Obrink (1986) Exp. Cell Res. 164, 103-114]. The cell-surface distribution of cellCAM 105 also changed, and on Days 3-5 post-hepatectomy it appeared on all faces of the hepatocytes which then were closely associated without obvious sinusoids in between. This staining pattern then slowly changed toward the normal pattern of mature liver, which appeared about 15 days post-hepatectomy. A theoretical analysis of the mode of hepatocyte cell division during liver regeneration suggested that the surface of the postmitotic hepatocytes should become unpolarized with respect to macromolecular composition. This is in agreement with the observed surface distribution of cellCAM 105. The results support the hypothesis that cell-surface interactions mediated by cellCAM 105 might contribute to the regular organization of hepatocytes in the normal, mature liver plates.

Functional reconstitution of the canalicular bile salt transport system of rat liver

Recent studies have suggested that the canalicular bile salt transport system of rat liver corresponds to a 100-kDa membrane glycoprotein. In the present study we attempted to functionally reconstitute the 100-kDa protein into artificial proteoliposomes. Canalicular membrane proteins were solubilized with octyl glucoside in the presence of asolectin phospholipids. The extracts were treated with preimmune serum or the 100-kDa protein selectively immunoprecipitated with a polyclonal antiserum. Proteins remaining in the supernatant were then incorporated into proteoliposomes by gel-filtration chromatography. Canalicular proteoliposomes containing the 100-kDa protein exhibited transstimulatable taurocholate uptake that could be inhibited by 4,4'-diisothiocyanato-2,2'-stilbenedisulfonic acid (DIDS). In contrast, no DIDS-sensitive transstimulatable taurocholate uptake was found in 100-kDa protein-free canalicular proteoliposomes. However, when the immunoprecipitated 100-kDa protein was dissociated from the antibodies and exclusively incorporated into liposomes, reconstitution of DIDS-sensitive transstimulatable and electrogenic taurocholate anion transport was again positive. Although incorporation of solubilized basolateral membrane proteins into liposomes also resulted in a prompt reconstitution of Na+ gradient-driven taurocholate uptake, the anti-100-kDa antibodies had no effects on the reconstituted transport activity of basolateral proteins. Thus, the findings establish that the previously characterized canalicular-specific 100-kDa protein is directly involved in the transcanalicular secretion of bile salts.

Antagonistic effects of laminin and fibronectin in cell-to-cell and cell-to-matrix interactions in MCF-7 cultures

During morphogenesis, tumor progression and metastasis, cell adhesion, dissociation, and migration result from a complex balance between cell-to-cell and cell-to-matrix interactions. Two different organization patterns of MCF-7 cells were induced by different extracellular matrix proteins. When plated on plastic or polymeric type I collagen gel used as a model of interstitial matrix, MCF-7 cells spread and grew in monolayer. When cultured on a solid gel of basement membrane (BM) proteins (85% laminin) used as a model of BM, cells formed clusters attached to the matrix. Matrix proteins regulated these two types of cell organization by preferentially promoting cell-to-cell or cell-support interactions. On plastic in the presence of soluble laminin or on laminin-coated dishes, cells also formed clusters. Addition of soluble fibronectin induced spreading of the cells, suggesting that laminin and fibronectin have competitive antagonistic effects on MCF-7 cell morphology. Antilaminin antibodies inhibited cluster formation and attachment, emphasizing the important role of this glycoprotein not only in promoting cluster attachment but also in cell-to-cell contact formation. Such effects of extracellular matrix proteins could play significant roles in tumor progression and metastasis.

Quantitative determination of the organ distribution of the cell adhesion molecule cell-CAM 105 by radioimmunoassay

We have previously identified a 105,000-Da plasma membrane glycoprotein, denoted cell-CAM 105, that is involved in intercellular adhesion of reaggregating rat hepatocytes. In this communication we report on the development of a radioimmunoassay for cell-CAM 105, employing purified cell-CAM 105, specific antisera against the molecule, and formalin-fixed protein A-containing staphylococci for precipitation of the immune complexes. The assay was shown to be sensitive, specific, precise, rapid, and easy to perform. We used this radioimmunoassay in investigations of the occurrence of cell-CAM 105 in different rat organs. Cell-CAM 105 was present in a wide spectrum of organs in varying amounts. The highest concentrations were found in the gastrointestinal tract, liver, some secretory glands, vagina, kidney, and lung. In addition, cell-CAM 105 was detected in blood, where it was shown to reside mainly in the platelets. Other tissues, particularly the central nervous system and muscle tissues, were cell-CAM-negative. The results were confirmed by immunoblotting, which revealed one distinct protein component, corresponding to cell-CAM 105, in each positive organ.