Intercellular adhesive selectivity. II. Properties of embryonic chick liver cell-cell adhesion

Studies directed at understanding the molecular basis of liver cell homotypic adhesion are presented. An assay which measures the rate of adhesion of isotopically labeled (32PO4) embryonic chick liver cells to liver cell aggregates, described in a companion paper, has been used to investigate the problem of intercellular adhesive selectivity. Cation requirements, the effects of various inhibitors of metabolism and protein synthesis, of chelators (EDTA and EGTA), and the effects of temperature on liver cell adhesion are reported. Two mechanisms of inhibition of liver intercellular adhesion are suggested. One involves destruction of cell-surface adhesion receptors (sensitivity to proteases); the other is an energy-dependent step which may involve alterations in plasma membrane conformation and/or membrane fluidity. Finally, a model is suggested for liver cell-cell adhesion that incorporates the early tissue selectivity of intercellular adhesion previously reported, followed by a multistep process which leads to histogenic aggregation.     

Intercellular adhesive selectivity. III. Species selectivity of embryonic liver intercellular adhesion

A species difference in the intercellular adhesive selectivity of mixtures of embryonic liver cells is reported. This is first quantitative assessment of species differences in the intercellular adhesive properties of embryonic cells. A collecting aggregate assay, a new double-label assay procedure, and histological and autoradiographic procedures were used to elucidate the intercellular adhesive selectivity of developing mammalian and avian liver cells. Evidence is presented that the reported adhesive differences are not due to the different cell types composing the respective embryonic mammalian and avian livers. Finally, such heterolgous-homotypic selectivity of adhesion is not a property of all tissues, since it is shown that developing brain cells (mesencephalon) do not exhibit the avove intercellular adhesive selectivity (mammalian vs. avian). These findings provide further support for the hypothesis that generic identity as well as cell type may play an important part in determining the intercellular adhesive behavior of heterologous-homotypic mixtures of embryonic cells. A possible evolutionary divergence of morphogenetic mechanisms is discussed.     

Studies on intercellular invasion in vitro using rabbit peritoneal neutrophil granulocytes. II. Adhesive interaction between cells.

A possible mechanism for intercellular invasion is that the strength of adhesion between host and invading cells is greater than the average of the strengths of homotypic adhesions. This hypothesis has been examined by a study of the kinetics of aggregation of dispersed populations of an invasive cell type (the rabbit peritoneal neutrophil granulocyte) and a host cell type (the chick embryo heart fibroblast) in shaken suspension culture. Since aggregation in mixed populations of the 2 cell types demonstrated tissue specificity, the hypothesis is not supported by these studies, heterotypic adhesions seem in fact to be weaker than homotypic adhesions.     

Enzymatic dissection of embryonic cell adhesive mechanisms: II. Developmental regulation of an endogenous adhesive system in the chick neural retina

Previous studies have demonstrated the presence of two functionally distinct intercellular adhesive systems operating among embryonic chick neural retina cells. These systems differ in their proteolytic sensitivity, protection by calcium against proteolysis, dependence on calcium for function, and in vitro morphogenetic potential. In this report we demonstrate that functional expression of the calcium-dependent adhesive system of embryonic chick neural retina cells is developmentally regulated between Days 7 and 16 of development, whereas the calcium-independent adhesive system is not. Age-dependent changes are described in terms of the ability to produce adhesive-competent cells bearing the calcium-dependent adhesive system and in terms of the responses of these cells during aggregation to perturbations with various drugs. Enzyme and ion combinations other than calcium and typsin are shown to yield calcium-dependent adhesive-competent cells. We also describe the protective effect of calcium on the histological and ultrastructural organization of trypsinized embryonic neural retina tissue. The possible role of the calcium-dependent adhesive system in retinal development is discussed.     

Use of preformed cell aggregates and layers to measure tissue-specific differences in intercellular adhesion

The binding of aggregates formed from various 7-day chick embryo tissues to cultured cell layers was analyzed 24 hr following trypsin dissociation of the tissues. The proprotion of aggregates binding is independent of the number of aggregates added, and changes with time over 60 min in a manner consistent with a first-order process. The adhesive parameter measured, the percentage of aggregates binding to cell layers per unit time, varies slightly with aggregate size but is not dependent upon the probability of collision of the aggregate with the layer. The rate of binding and the effect of modifiers of binding (temperature, inhibitors of oxidative metabolism and glutaraldehyde) are substantially different for neural retina interactions than for liver or heart interactions, suggesting that retina cells may form intercellular bonds via a mechanism distinct from that of liver or heart cells. The rate of binding between like tissue types is, with one exception, greater than between unlike types. Glutaraldehyde treatment of only one of the reactants abolishes this adhesive specificity. Aggregate binding provides a means of quantitatively assessing intercellular adhesion which has the advantage of reducing the effects of trypsinization on measurements of adhesion, and therefore lends itself to the investigation of cellular consequences of adhesion.     

Mapping the homotypic binding sites in CD31 and the role of CD31 adhesion in the formation of interendothelial cell contacts

CD31 is a member of the immunoglobulin superfamily consisting of six Ig- related domains. It is constitutively expressed by platelets, monocytes, and some lymphocytes, but at tenfold higher levels on vascular endothelial cells. CD31 has both homotypic and heterotypic adhesive properties. We have mapped the homotypic binding sites using a deletion series of CD31-Fc chimeras and a panel of anti-CD31 monoclonal antibodies. An extensive surface of CD31 is involved in homotypic binding with domains 2 and 3 and domains 5 and 6 playing key roles. A model consistent with the experimental data is that CD31 on one cell binds to CD31 on an apposing cell in an antiparallel interdigitating mode requiring full alignment of the six domains of each molecule. In addition to establishing intercellular homotypic contacts. CD31 binding leads to augmented adhesion via beta 1 integrins. The positive cooperation between CD31 and beta 1 integrins can occur in heterologous primate cells (COS cells). The interaction is specific to both CD31 and beta 1 integrins. Neither intercellular adhesion molecule-1 (ICAM- 1)/leukocyte function-associated antigen-1 (LCAM-1) nor neural cell adhesion molecule (NCAM)/NCAM adhesion leads to recruitment of beta 1 integrin adhesion pathways. Establishment of CD31 contacts have effects on the growth and morphology of endothelial cells. CD31(D1-D6)Fc inhibits the growth of endothelial cells in culture. In addition, papain fragments of anti-CD31 antibodies (Fab fragments) disrupt interendothelial contact formation and monolayer integrity when intercellular contacts are being formed. The same reagents are without effect once these contacts have been established, suggesting that CD31- CD31 interactions are critically important only in the initial phases of intercellular adhesion.     

Heterogeneity of intercellular adhesion in rat liver cells in culture

The intercellular homotypic adhesive properties of 14 clones derived from a nontumorigenic rat liver epithelial cell line (LEC), derived from neonatal Fischer rats, were examined and compared to those of the hepatoma H4-II-E cell line. Each clone was assayed also for the degree of chromosomal aneuploidy and the ability to grow in soft agar. Over 100-fold differences in adhesive properties were observed among the clones, but no correlation was observed between the degree of aneuploidy in the clones and intercellular adhesive properties. The parent LEC cell line and the clones derived from it were unable to grow in soft agar. The H4-II-E cells showed negligible capacity to reaggregate after dissociation into single cells and these cells readily formed colonies in soft agar. Many of the LEC clones were similar to the H4-II-E cells in their adhesive properties, which suggests that reduced cell-to-cell adhesiveness per se is not a necessary prerequisite of epithelial cells to be able to grow independent of anchorage. Two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) of concanavalin A (Con A)-binding glycoproteins in the "most adhesive" clone 67 and the "least adhesive" clone 201 showed markedly elevated amounts of acidic 105 and 67-kDa glycoproteins in clone 67. Proteins with similar migration patterns in 2D-PAGE have previously been reported to participate in specific homotypic intercellular adhesion of liver cells. The Con A-binding glycoprotein pattern in H4-II-E cells was markedly different from that of LEC cells with a set of six proteins missing and nine proteins appearing new in the H4-II-E cells. It is suggested that, in addition to identifying known epithelial cell polypeptides, systematic screening of cell surface-associated glycoproteins in normal and transformed epithelial cells in vitro and in vivo may lead to identification of novel polypeptides intimately associated with the transformed phenotype.     

Osteopontin-Enhanced Hepatic Metastasis of Colorectal Cancer Cells

Liver metastasis is a major cause of mortality from colorectal cancer (CRC). However, mechanisms underlying this process are largely unknown. Osteopontin (OPN) is a secreted phosphorylated glycoprotein that is involved in tumor migration and metastasis. The role of OPN in cancer is currently unclear. In this study, OPN mRNA was examined in tissues from CRC, adjacent normal mucosa, and liver metastatic lesions using quantitative real-time PCR analysis. The protein expression of OPN and its receptors (integrin αv and CD44 v6) was detected by using an immunohistochemical (IHC) method. The role of OPN in liver metastasis was studied in established colon cancer Colo-205 and SW-480 cell lines transfected with sense- or antisense-OPN eukaryotic expression plasmids by flow cytometry and cell adhesion assay. Florescence redistribution after photobleaching (FRAP) was used to study gap functional intercellular communication (GJIC) among OPN-transfected cells. It was found that OPN was highly expressed in metastatic hepatic lesions from CRC compared to primary CRC tissue and adjacent normal mucosa. The expression of OPN mRNA in tumor tissues was significantly related with the CRC stages. OPN expression was also detected in normal hepatocytes surrounding CRC metastatic lesions. Two known receptors of OPN, integrin αv and CD44v6 proteins, were strongly expressed in hepatocytes from normal liver. CRC cells with forced OPN expression exhibited increased heterotypic adhesion with endothelial cells and weakened intercellular communication. OPN plays a significant role in CRC metastasis to liver through interaction with its receptors in hepatocytes, decreased homotypic adhesion, and enhanced heterotypic adhesion.     

A role for fibronectin-leucine-rich transmembrane cell-surface proteins in homotypic cell adhesion

The fibronectin-leucine-rich transmembrane (FLRT) family of leucine-rich repeat (LRR) proteins is implicated in fibroblast growth factor (FGF) signalling, early embryonic development and neurite outgrowth. Here, we have analysed whether FLRTs may also function in cell adhesion. We find that FLRT proteins can physically interact and that FLRT-transfected cultured cells sort out from non-transfected cells, suggesting a change in adhesive properties. A similar sorting effect is also observed in Xenopus embryos and tissue aggregates. FLRT-mediated cell sorting is calcium dependent and substrate independent. Deletion analysis indicates that cell sorting requires the LRR domains, which are dispensable for FLRT-mediated FGF signalling. Conversely, sorting is independent of the cytoplasmic domain, which is essential for FLRT-induced signalling. Therefore, FLRT-mediated FGF signal transduction and homotypic cell sorting can be molecularly uncoupled. The results indicate that FLRT proteins have a dual role, promoting FGF signalling and modulating homotypic cell adhesion.     

Carcinoembryonic antigen, a human tumor marker, functions as an intercellular adhesion molecule

Carcinoembryonic antigen (CEA) is a member of a family of cell surface glycoproteins that are produced in excess in essentially all human colon carcinomas and in a high proportion of carcinomas at many other sites. The function of this widely used tumor marker and its relevance to malignant transformation is therefore of considerable interest. We demonstrate here that CEA mediates Ca2+-independent, homotypic aggregation of cultured human colon adenocarcinoma cells (LS-180) and rodent cells transfected with functional CEA cDNA. Furthermore, CEA can effect the homotypic sorting of cells in heterogeneous populations of aggregating cells. CEA can thus be considered a new addition to the family of intercellular adhesion molecules. We also show that, whereas CEA is localized mainly to epithelial cell membranes facing the lumen in normal adult intestine, it is found on adjacent cell membranes in both embryonic intestine and colonic tumors. A model for the role of CEA in the tissue architecture of adult, embryonic, and aberrant tumor intestinal epithelium is presented.     

Ligatin from embryonic chick neural retina inhibits retinal cell adhesion

Ligatin, a filamentous cell-surface protein purified from embryonic chick neural retina, has been found to inhibit the reassociation of dissociated retinal cells. This inhibition was demonstrated using two methods, a single cell disappearance assay and an improved monolayer collection assay utilizing microtiter plates. Monomeric ligatin at approximately 20 μg/ml inhibited rates of adhesion, but polymeric ligatin and tryptic fragments of ligatin were ineffective. Ligatin's inhibitory effect is suggested to be mediated through binding to retinal cell surfaces since preincubation of dissociated retinal cells with monomeric ligatin inhibited the cells' adhesiveness and removed the inhibitory activity from the culture media. Ligatin homologues prepared from mammalian tissues were ineffective in inhibiting retinal cell adhesion, suggesting a tissue and/or species specificity. Similarities in physicochemical and biological properties suggest that ligatin may be the inhibitor of adhesion previously described by Merrell et al.[Merrell, R., Gottlieb, D. I., and Glaser, L. (1975). J. Biol. Chem., 250, 4825].     

Do rates of intercellular adhesion measure the cell affinities reflected in cell-sorting and tissue-spreading configurations?

These experiments constitute the first experimental test of the hypothesis that the rates of adhesion between cells measure the intensities of adhesion or tissue affinities that could explain cell sorting and tissue spreading. For any set of relative adhesive intensities between cells in a heterogeneous population, a corresponding minimal free energy configuration can be calculated. This is the cell distribution toward which both cell sorting and tissue spreading should lead. Equilibrium configurations were determined for combinations of 7-day embryonic retina (R) with liver (L) and heart (H), both of which became completely enveloped by R. To produce these results, the adhesive intensities would have to fall in the sequences: L-L > L-R > R-R; and H-H > H-R > R-R. To determine whether the rates of adhesion fall into these same sequences, we have devised a new technique which measures the rates of adhesion between pairs of already-formed cell aggregates of like and unlike kinds. These fall in the sequence L-L > or = H-H > L-H > R-R > H-R > L-R. If these rates paralleled the corresponding intensities of adhesion at configurational equilibrium, both L and H should have become only partially enveloped by R. Thus the rates at which adhesions are initiated do not predict the relative adhesive intensities that could explain the observed tissue configurations.     

Enzymatic dissection of embryonic cell adhesive mechanisms

In this paper we describe a kinetic assay for cell adhesion which measures the formation of cell clusters. Cluster formation is dependent on both calcium and protein synthesis, two parameters essential for the formation of histotypic aggregates. We also describe modifications of the stndard method for trypsinization of tissues which result in populations of single cells that appear to bear intact and functional cell surface adhesive systems. These modifications involve the use of chymotrypsin and the inclusion of calcium during enzyme digestion of tissues with trypsin and chymotrypsin. Using the cluster formation assay and the modified tissue dissociation techniques, we demonstrate the presence of two functionally distinct adhesive systems operating among embryonic chick neural retina cells. These two systems differ in proteolytic sensitivity, protection by calcium against proteolysis, dependence on calcium for function and morphogenetic potential. Cells possessing one of these intact adhesive systems are capable of extensive morphogenetic interactions in the absence of protein synthesis.     

Utilization of -glutamine in intercellular adhesion: Ascites tumor and embryonic cells

-Glutamine is required for the synthesis of complex carbohydrates required for the intercellular adhesion of mouse teratoma cells. It remained to be seen if these pathways were of general importance in the adhesion of other cell types. In this study, using an electronic particle counter assay to measure cell adhesion, Ehrlich ascites, Sarcoma 180 and Taper liver ascites tumor cells require exogenous -glutamine to aggregate. This effect is concentration dependent and the amino sugar, -glucosamine, replaces the glutamine requirement. Structural analogs of the active compounds are substantially less effective and metabolic inhibitors block the activity of the effective compounds. Two specific glutamine antagonists, DON (6-diazo-5-oxo- -norleucine) and azaserine (O-diazoacetyl-serine) decrease the action of -glutamine but not of -glucosamine. Trypsin dissociated six day old chick embryo neural retina cells do not require -glutamine to reaggregate, though the rate of aggregation is enhanced after preincubation with glutamine. Dissociation of small clumps of neural retina and inhibition of reaggregation of these cells are facilitated by preincubation with azaserine for 3–5 h. -Glutamine reduces the effect of azaserine on retina cells. These results are consistent with known metabolic pathways and suggest that -glutamine is involved in the synthesis of complex carbohydrates necessary for adhesion in a variety of cell types. The defective adhesion of the tumor cells examined may result from inability to produce glutamine synthetase, or effectively store cr transport -glutamine.     

Brain histogenesis in vitro: Reconstruction of brain tissue from dissociated cells

Summary Comparative studies of the aggregative behavior of cells dissociated from different areas of embryonic chick and mouse brains show that each of the regionally differentiated lobes (cerebrum, optic tectum, and cerebellum), and the stem areas (diencephalon and medulla), form characteristic aggregates distinctive in size and shape. Bispecific co-aggregates are produced by commingling dissociated mouse cerebrum cells with chick cells from various brain regions, or from non-nervous tissues; the size of these co-aggregates and the extent of internal sorting out of cell types is closely related to the degree of homology between the interacting cell populations, e.g. co-aggregates of the closely homologous mouse and chick cerebral cell types contain homogeneous tissue fabrics of intermingled mouse and chick cells. Cell surface constituents involved in selective recognition and association of nerve cells were sought and cell-free supernatant preparations were obtained from short-term monolayer cultures of embryonic cerebrum cells (of either mouse or chick origin) which caused a striking, specific enhancement of aggregation of homologous cerebrum cells. These materials had no such effect on heterologous tissues tested: optic tectum, cerebellum, medulla, neural retina, liver, kidney or limb bud. These findings are discussed in relation to control mechanisms governing normal brain histogenesis and to the specificity of neural associations. This work was supported by United States Public Health Service research grant HD-01253 to Aron Moscona and by the Louis Block Fund of the University of Chicago.     

Experimental manipulation of cell surface to affect cellular recognition mechanisms.

The mechanism of selective cell adhesion was studied using Chinese hamster V79 and chick embryonic neural retinal cells. Both of these cell types have been shown to have two experimentally separable mechanisms of adhesion; Ca²⁺-dependent and Ca²⁺-independent. Cells can be dispersed so that either or both of the mechanisms remain intact by use of different treatments. A method of labeling cells with FITC was devised to identify one of the two types of cells in a binary cell population. When cells with one of the two adhesion mechanisms were mixed with cells with the other mechanism, they segregated completely, forming independent aggregates, not only in the heterotypic combination of these cell types but also in the homotypic combination of each cell type. In contrast, when cells were mixed with others with the same adhesion mechanism, either Ca²⁺-dependent or -independent, they formed chimeric aggregates, even in the heterotypic cell combination. These results suggest that the specificity in each of those two mechanisms of cell adhesion plays an important role in cellular recognition processes.     

CELL BEHAVIOUR AND MOLECULAR MECHANISMS OF CELL-CELL ADHESION

1. At the behavioural level, cell adhesion is generally non-specific. The search for molecular mechanisms of adhesion should be conducted on this basis.
2. Cells in general, be they from slime moulds or vertebrate epithelia, possess multiple molecular adhesive mechanisms. In epithelial cells this is shown by the number of their different ultrastructurally recognizable intercellular junctions. Elucidation of the structure and composition of such intercellular junctions will make a valuable contribution to the understanding of cell adhesion.
3. The measurement of cell adhesion is fraught with difficulties. Commonly used assays by aggregation cannot give a true representation of the normal adhesive interactions of cells in tissues, and the results they yield must be interpreted with caution. This is because it takes dissociated tissue cells up to 24 h to develop their full adhesiveness after making initial contact.
4. Cell-cell adhesion probably depends largely upon the interaction of complementary molecules on adjacent cell surfaces. Glycoproteins seem the most likely candidates but, as yet, there is no compelling evidence in any individual case and mechanisms of cell adhesion still remain obscure.     

A FIBRILLAR INTERCELLULAR MATERIAL BETWEEN REAGGREGATING EMBRYONIC CHICK CELLS

Lanthanum staining of embryonic chick cell reaggregates reveals an intercellular material composed of fibrils. Fibrillar arrays may be composed of parallel fibrils with a 35 A center-to-center spacing. Fibrils may also be disoriented, long, and tortuous. Newly dissociated cells show little lanthanum staining surface material, but appreciable amounts are present after 6 hr of reaggregation. Examination of intact tissue does not give the same clear evidence of a fibrillar matrix surrounding the cells, but treatment with a number of agents permits observation of intercellular fibrils, and in some cases there is evidence of orientation. Thus fibrillar material must be taken into account in considering mechanisms of cell aggregation.     

Specificity of intercellular adhesion mediated by various members of the immunoglobulin supergene family

The immunoglobulin supergene family members have been shown to be involved in cell-cell recognition and interaction during cell growth and differentiation. Neural cell adhesion molecule, myelin-associated glycoprotein, and carcinoembryonic antigen (CEA) are immunoglobulin supergene family members which can mediate cell adhesion. We show here that nonspecific cross-reacting antigen (NCA), a closely related CEA family member, is found on the surface of rodent cells transfected with functional NCA complementary DNA in different glycosylated forms, all of which can be deglycosylated to an Mr 35,000 core protein. Furthermore, NCA can mediate Ca2(+)-independent, homotypic aggregation of these NCA-producing transfectant cells. Since CEA has three internal repeated C2-set, immunoglobulin-like domains, whereas NCA has one, only one such domain is required for the intercellular adhesive function. We also demonstrate that NCA- and CEA-producing transfectants can form heterotypic aggregates, whereas mixtures of CEA or NCA transfectants and neural cell adhesion molecule or long form-myelin-associated glycoprotein transfectants sort themselves out into homotypic aggregates. The results suggest that subsets of the immunoglobulin superfamily, such as the CEA family, can be used in both homotypic and heterotypic cellular interactions, whereas less closely related members of the family can be used to separate different cell types by strictly homotypic interactions.     

Homophilic adhesion between Ig superfamily carcinoembryonic antigen molecules involves double reciprocal bonds

Both carcinoembryonic antigen (CEA) and neural cell adhesion molecule (NCAM) belong to the immunoglobulin supergene family and have been demonstrated to function as homotypic Ca(++)-independent intercellular adhesion molecules. CEA and NCAM cannot associate heterotypically indicating that they have different binding specificities. To define the domains of CEA involved in homotypic interaction, hybrid cDNAs consisting of various domains from CEA and NCAM were constructed and were transfected into a CHO-derived cell line; stable transfectant clones showing cell surface expression of CEA/NCAM chimeric-proteins were assessed for their adhesive properties by homotypic and heterotypic aggregation assays. The results indicate that all five of the Ig(C)-like domains of NCAM are required for intercellular adhesion while the COOH-terminal domain containing the fibronectin-like repeats is dispensable. The results also show that adhesion mediated by CEA involves binding between the Ig(V)-like amino-terminal domain and one of the Ig(C)-like internal repeat domains: thus while transfectants expressing constructs containing either the N domain or the internal domains alone were incapable of homotypic adhesion, they formed heterotypic aggregates when mixed. Furthermore, peptides consisting of both the N domain and the third internal repeat domain of CEA blocked CEA-mediated cell aggregation, thus providing direct evidence for the involvement of the two domains in adhesion. We therefore propose a novel model for interactions between immunoglobulin supergene family members in which especially strong binding is effected by double reciprocal interactions between the V-like domains and C-like domains of antiparallel CEA molecules on apposing cell surfaces.