E-cadherin regulates the function of the EphA2 receptor tyrosine kinase

EphA2 is a member of the Eph family of receptor tyrosine kinases, which are increasingly understood to play critical roles in disease and development. We report here the regulation of EphA2 by E-cadherin. In nonneoplastic epithelia, EphA2 was tyrosine-phosphorylated and localized to sites of cell-cell contact. These properties required the proper expression and functioning of E-cadherin. In breast cancer cells that lack E-cadherin, the phosphotyrosine content of EphA2 was decreased, and EphA2 was redistributed into membrane ruffles. Expression of E-cadherin in metastatic cells restored a more normal pattern of EphA2 phosphorylation and localization. Activation of EphA2, either by E-cadherin expression or antibody-mediated aggregation, decreased cell-extracellular matrix adhesion and cell growth. Altogether, this demonstrates that EphA2 function is dependent on E-cadherin and suggests that loss of E-cadherin function may alter neoplastic cell growth and adhesion via effects on EphA2.

Dynamic interaction of PTPmu with multiple cadherins in vivo

There is a growing body of evidence to implicate reversible tyrosine phosphorylation as an important mechanism in the control of the adhesive function of cadherins. We previously demonstrated that the receptor protein tyrosine phosphatase PTPmu associates with the cadherin-catenin complex in various tissues and cells and, therefore, may be a component of such a regulatory mechanism (Brady-Kalnay, S. M., D.L. Rimm, and N.K. Tonks. 1995. J. Cell Biol. 130:977- 986). In this study, we present further characterization of this interaction using a variety of systems. We observed that PTPmu interacted with N-cadherin, E-cadherin, and cadherin-4 (also called R-cadherin) in extracts of rat lung. We observed a direct interaction between PTPmu and E-cadherin after coexpression in Sf9 cells. In WC5 cells, which express a temperature-sensitive mutant form of v-Src, the complex between PTPmu and E-cadherin was dynamic, and conditions that resulted in tyrosine phosphorylation of E-cadherin were associated with dissociation of PTPmu from the complex. Furthermore, we have demonstrated that the COOH-terminal 38 residues of the cytoplasmic segment of E-cadherin was required for association with PTPmu in WC5 cells. Zondag et al. (Zondag, G., W. Moolenaar, and M. Gebbink. 1996. J. Cell Biol. 134: 1513-1517) have asserted that the association we observed between PTPmu and the cadherin-catenin complex in immunoprecipitates of the phosphatase arises from nonspecific cross-reactivity between BK2, our antibody to PTPmu, and cadherins. In this study we have confirmed our initial observation and demonstrated the presence of cadherin in immunoprecipitates of PTPmu obtained with three antibodies that recognize distinct epitopes in the phosphatase. In addition, we have demonstrated directly that the anti-PTPmu antibody BK2 that we used initially did not cross-react with cadherin. Our data reinforce the observation of an interaction between PTPmu and E-cadherin in vitro and in vivo, further emphasizing the potential importance of reversible tyrosine phosphorylation in regulating cadherin function.

Schwann cells express NDF and SMDF/n-ARIA mRNAs, secrete neuregulin, and show constitutive activation of erbB3 receptors: evidence for a neuregulin autocrine loop

Cultured Schwann cells secreted low levels (30 pg/ml/1.5 x 10(6) cells) of a 45-kDa neuregulin protein and showed constitutive activation of a neuregulin receptor, Erb-B3, suggesting the existence of an autocrine loop involving neuregulins in Schwann cells. RT-PCR analyses indicated that Schwann cells and fibroblasts in culture produced SMDF/n-ARIA and NDF but not GGF neuregulin messages. Schwann cell and fibroblast neuregulin messages encoded both beta and alpha domains; Schwann cell transcripts encoded only transmembrane neuregulin forms while fibroblast messages encoded transmembrane and secreted forms. SMDF/n-ARIA and NDF messages were also expressed in early postnatal rat sciatic nerve, suggesting a role for neuregulins in peripheral nerve development. An anti-neuregulin antibody inhibited the mitogenic response of Schwann cells to cultured neurons and to extracts of cultured neurons or embryonic brain, consistent with the accepted paracrine role of neuregulins on Schwann cells. Surprisingly, the same antibody inhibited Schwann cell proliferation stimulated by several unrelated mitogens including bFGF, HGF, and TGF-beta1. These data implicate both paracrine and autocrine pathways involving neuregulin form(s) in Schwann cell mitogenic responses.

E-cadherin mediates adhesion and suppresses cell motility via distinct mechanisms

Expression of the calcium-dependent adhesion molecule E-cadherin suppresses the invasion of cells in vitro, but the mechanism of this effect is unknown. To investigate this mechanism, we analyzed the effects of expressing E-cadherin in mouse L-cells and rat astrocyte-like WC5 cells. Increased cellular adhesion mediated by E-cadherin reduced invasion in WC5 cells and in some L-cells, but not in others. In all cases, suppression of invasion was correlated with decreased cell movement as assessed in an in vitro wound-filling assay and a transwell motility assay. To define the relationship between adhesion mediated by E-cadherin and suppression of motility, we analyzed the effects of deleting different regions of the E-cadherin cytoplasmic domain. E-cadherin lacking the entire cytoplasmic domain did not mediate calcium-dependent adhesion and did not reduce cell motility when expressed in WC5 cells. E-cadherin lacking a portion of the catenin-binding domain did not associate with the cytoskeleton and did not promote adhesion, yet still suppressed the motility of WC5 cells. In addition, E-cadherin that retains an intact catenin-binding domain, but lacks a juxtamembrane portion of the cytoplasmic domain, mediated effective adhesion, but did not suppress motility. These results indicate E-cadherin mediates adhesion and suppresses cell motility via distinct of E-cadherin plays a key role in suppressing motility.

Induction of L1 mRNA in PC12 cells by NGF is modulated by cell-cell contact and does not require the high-affinity NGF receptor

We examined the effects of nerve growth factor (NGF) and cell-cell contact on expression of the neural cell adhesion molecule L1 in PC12 cells. After 7 d exposure to NGF, but not after exposure to EGF, FGF, TGF beta, or dibutyryl cAMP (dbcAMP), L1 mRNA levels increased fourfold. This increase was not blocked by K252a, an inhibitor of the high-affinity NGF receptor, although neurite extension was completely inhibited. L1 mRNA levels also increased in NGF-treated mutant PC12 cells (PC12nnr5) that lack the high-affinity NGF receptor. The effect of NGF on L1 mRNA was greatest in cells cultured at high density, but its effect on cells cultured at low density was augmented by antibody to L1 (to mimic L1 homophilic binding). Various extracellular matrix components had no differential effects on L1 mRNA levels in either the presence or absence of NGF. Together, these findings suggest that NGF regulates L1 expression by a mechanism that is independent of the high-affinity NGF receptor and that this regulation is modulated by cell-cell contact but not by cell-extracellular matrix interactions.

Suppression of tumorigenicity, but not invasion, in glioblastoma/HeLa cell hybrids

Somatic cell hybrids between SNB-19 human glioblastoma cells and human D98OR HeLa cells were produced and analyzed for their ability to form tumors in nude mice and to invade reconstituted extracellular matrix (Matrigel). Whereas both the SNB-19 and D98OR HeLa parental cells form tumors, four of six hybrid lines did not form tumors, even after periods up to six months, suggesting that each cell type can complement the tumorigenicity of the other. SNB-19 cells showed high rates of Matrigel invasion at all cell densities examined, whereas D98OR HeLa cells showed lower rates of invasion that were further reduced at high cell density. All six hybrid cell lines displayed a combination of these properties: at low cell density, the hybrids showed high rates of invasion, similar to the SNB-19 cells, but the invasion rate diminished at higher cell densities, similar to the D98OR HeLa cells. Taken together, these results provide new experimental evidence that several distinct genetic changes are involved in generating the tumorigenic and invasive phenotype of glioblastoma cells.

Myelin glycoprotein P0 is expressed at early stages of chicken and rat embryogenesis

Although previous studies suggest that P0 is expressed only in myelinating Schwann cells, monoclonal antibody 1E8 reacts with P0, yet also stains early Schwann cell precursors and non-myelinating Schwann cells (Bhattacharyya et al.: Neuron 7:831-844, 1991). We therefore characterized the 1E8 epitope and analyzed P0 mRNA expression during development. Immunoblot analyses of P0 fusion proteins and of deglycosylated P0 indicated that the 1E8 epitope is polypeptide. Northern blot and polymerase chain reaction (PCR) analyses revealed that P0 is encoded by a single mRNA that is expressed in chicken embryos as early as E4 and in rat embryos as early as E14. These data indicate that the antigen recognized by 1E8 in early chicken embryos is P0 and that, during development of both chickens and rats, P0 mRNA is expressed long before myelination.

Axons arrest the migration of Schwann cell precursors

The neural crest gives rise to a variety of cell types including Schwann cells of the peripheral nervous system. Schwann cell precursors begin to differentiate early and migrate along specific pathways in the embryo before associating with nerve trunks. To determine whether motor axons direct the migration of Schwann cell precursors along specific pathways, we tested the effect of ablating the ventral half of the neural tube, which contains motor neuron cell bodies. The ventral neural tube was removed unilaterally from lumbar regions of chicken embryos at stage 17, when neural crest cells are just beginning to migrate and before motor axons have extended out of the neural tube. At several stages after ventral tube ablation, sections of the lumbar region of these embryos were stained with anti-acetylated tubulin to label developing axons, HNK-1 to label migrating neural crest cells and 1E8 to label Schwann cell precursors. In many embryos the ablation of motor neurons was incomplete. The staining patterns in these embryos support the idea that some Schwann cells are derived from the neural tube. In embryos with complete motor neuron ablation, at stage 18, HNK-1-positive neural crest cells had migrated to normal locations in both control and ablated sides of the embryo, suggesting that motor axons or the ventral neural tube are not required for proper migration of neural crest cells. However, by stage 19, cells that were positive for HNK-1 or 1E8 were no longer seen in the region of the ventral root, nor ventral to the ventral root region. Because Schwann cell precursors require neural-derived factors for their survival in vitro, we tested whether neural crest cells that migrate to the region of the ventral root in ventral neural tube-ablated embryos then die. Nile Blue staining for dead and dying cells in ventral neural tube-ablated embryos provided no evidence for cell death at stage 18. These results suggest that motor axons arrest the migration of Schwann cell precursors during neural crest migration.

Cell adhesion molecules and the migration of LHRH neurons during development

During embryogenesis, LHRH neurons arise in the olfactory epithelium, migrate along the olfactory nerve, and enter the forebrain. We have examined the distribution of several cell adhesion molecules (CAMs) in the developing chick olfactory system and brain to determine whether differential distributions of these adhesion molecules might be important in pathway choices made by migrating LHRH neurons. Single- and double-label immunocytochemical studies indicated that high levels of N-CAM and N-cadherin were expressed throughout the olfactory epithelium and not restricted to the medial half of the olfactory epithelium where most of the LHRH neurons originate. Further, high levels of N-CAM, Ng-CAM, and N-cadherin were uniformly expressed throughout the entire olfactory nerve while migrating LHRH neurons were confined to the medial half of the nerve. However, once LHRH neurons reach the brain, they migrate dorsally and caudally, tangential to the medial surface of the forebrain, along a region enriched in N-CAM and Ng-CAM. After this first stage of migration within the brain, LHRH neurons migrate laterally. At this stage, there is no correlation between the intensity of N-CAM and Ng-CAM immunostaining and the location of LHRH neurons. These results suggest that N-CAM, Ng-CAM, and N-cadherin do not play a guiding role in LHRH neuronal migration through the olfactory epithelium and olfactory nerve but that migrating LHRH neurons may follow a "CAM-trail" of N-CAM and Ng-CAM along the medial surface of the forebrain.

Increasing N-CAM-mediated cell-cell adhesion does not reduce invasion of RSV-transformed WC5 rat cerebellar cells

The WC5 rat cerebellar cell line, infected with a Rous sarcoma virus (RSV) that is temperature-sensitive for pp60v-src transformation, expresses high levels of the neural cell adhesion molecule, N-CAM, when grown at the non-permissive temperature for pp60v-src activity. At the permissive temperature, N-CAM expression is 4- to 10-fold reduced and the cells aggregate poorly. To evaluate the effects of variations in N-CAM expression, we compared the invasive ability of transformed WC5 cells that express low levels of N-CAM with transformed cells in which N-CAM-mediated adhesion was restored. WC5 cells were transfected with expression vectors containing cDNAs encoding the 120 or 180 kDa forms of chicken N-CAM linked to constitutive promoters. Several permanently transfected lines that expressed chicken N-CAM at the cell surface were isolated. These cell lines showed enhanced aggregation at the permissive temperature relative to untransfected WC5 cells or cells transfected with control constructs. By comparing the ability of control and transfected WC5 cells to invade reconstituted extracellular matrix, we tested the effect of variations in N-CAM-mediated adhesion on invasion. Clones that expressed high levels of N-CAM showed invasion rates that were similar to control cells, indicating that increasing N-CAM-mediated adhesion does not inhibit the invasiveness of RSV-transformed WC5 cells.

Neuron-Schwann cell signals are conserved across species: purification and characterization of embryonic chicken Schwann cells

A monoclonal antibody, 1E8, which recognizes the peripheral myelin protein, P0, specific for chicken Schwann cells and their precursors (Bhattacharyya et al., Neuron 7:831-844, 1991), was used to immunoselect Schwann cells from embryonic day 14 (E14) chicken sciatic nerve. When cultured, these immunoselected cells displayed properties characteristic of perinatal rodent Schwann cells, including S100-immunoreactivity and O4 antigen-immunoreactivity. In addition, the purified chicken Schwann cells divided slowly when cultured alone, but when co-cultured with chicken or rat sensory neurons, they bound to axons and proliferated. Proliferation was also stimulated by the addition of bovine brain membrane extracts or chicken brain membranes. The 1E8 monoclonal antibody was also used to test the effect of axonal contact on P0 expression. Chicken Schwann cells purified using the 1E8 monoclonal antibody gradually lost P0 when cultured alone. These cells remained 1E8-negative even after prolonged co-culture with embryonic rat dorsal root ganglion neurons or chicken sensory ganglia. These results demonstrate that chicken Schwann cells behave like rodent Schwann cells in their expression of specific antigens, interactions with axons, and regulation of P0 expression. In addition, chicken Schwann cells respond to neuronal signals from the rat and cow, illustrating the cross-species conservation of these signals.

Conserved regulatory elements in the promoter region of the N-CAM gene

Genomic clones containing 5'-flanking sequences, the first exon, and the entire first intron from the chicken N-CAM gene were characterized by restriction mapping and DNA sequencing. A > 600-bp segment that includes the first exon is very G + C-rich and contains a large proportion of CpG dinucleotides, suggesting that it represents a CpG island. SP-1 and AP-1 consensus elements are present, but no TATA- or CCAAT-like elements were found within 300 bp upstream of the first exon. Comparison of the chicken promoter region sequence with similar regions of the human, rat, and mouse N-CAM genes revealed that some potential regulatory elements including a "purine box" seen in mouse and rat N-CAM genes, one of two homeodomain binding regions seen in mammalian N-CAM genes, and several potential SP-1 sites are not conserved within this region. In contrast, high CpG content, a homeodomain binding sequence, an SP-1 element, an octomer element, and an AP-1 element are conserved in all four genes. The first intron of the chicken gene is 38 kb, substantially smaller than the corresponding intron from mammalian N-CAM genes. Together with previous studies, this work completes the cloning of the chicken N-CAM gene, which contains at least 26 exons distributed over 85 kb.

Development of olfactory nerve glia defined by a monoclonal antibody specific for Schwann cells

Although there is considerable interest in the possible role of olfactory glia in the pathfinding abilities of olfactory nerve axons, the complete development of these glia in vivo has not been described. Using a specific Schwann cell marker, the 1E8 antibody, we have found that olfactory nerve glia can be identified throughout development. These glia appear to originate in the olfactory placode and migrate initially into the periphery of the olfactory nerve, and later into the center of the nerve. Olfactory nerve glia enter the presumptive olfactory bulb with the olfactory receptor neuron axons and distribute themselves along the edge of the olfactory nerve layer. The fact that olfactory nerve glia are specifically immunostained by the 1E8 monoclonal antibody, which recognizes the Schwann cell-specific protein P0, suggests that these cells more closely resemble Schwann cells than astrocytes or enteric glia. These results support and extend previous findings suggesting that olfactory nerve glia have distinctive developmental and anatomical features which may be important to the regenerative capacity of the olfactory system.

S100 is present in developing chicken neurons and Schwann cells and promotes motor neuron survival in vivo

We used polyclonal antisera recognizing S100, a small acidic protein highly enriched in nervous tissue, to stain sections of embryonic chicken lumbosacral spinal cord and hindlimb. S100 immunoreactivity was detected in developing sensory neurons of the dorsal root ganglia (DRG) and motor neurons of the ventral spinal cord as early as embryonic day (E) 5, and staining persisted through hatching. In contrast, expression of S100 first became apparent in Schwann cells at E13, just before myelination, and was not detected in developing skin or muscle. Since S100 beta was present in motor and sensory neurons and is known to promote neuronal survival and neurite extension in vitro (Winningham-Major, Staecker, Barger, Coats, and Van Eldik, 1989), we tested the ability of S100 to promote neuron survival in an in ovo survival assay. Addition of S100 to chick embryos in ovo during the period of naturally occurring motor neuron cell death resulted in a significant increase in motor neuron survival, but had no effect on the in vivo survival of sensory neurons in the DRG. The findings that S100 is present in spinal motor neurons and that the addition of S100 enhances the survival of these cells in vivo are consistent with the possibility that S100 may act as a naturally occurring neuron survival factor during development.

P0 is an early marker of the Schwann cell lineage in chickens

We have generated a monoclonal antibody, termed 1E8, that is specific for myelinating and nonmyelinating Schwann cells in mature chickens. 1E8 first stains cells at the edge of the neural crest; later, cells located between the neural tube and somites and in the sclerotome are immunopositive. Double labeling with HNK-1 indicates that these 1E8-positive cells represent a subset of neural crest cells in the ventral migratory pathways. 1E8-positive cells are later associated with the dorsal and ventral roots and with extending nerve trunks. In Western blots, 1E8 reacts with proteins comigrating with P0. Immunodepletion experiments establish that all P0 molecules carry the 1E8 determinant. The developmental distribution of P0, as determined by 1E8 immunoreactivity, differs from that reported for P0 in mammals and suggests that, in chicken, P0 is an early marker for the Schwann cell lineage.

Invasion by WC5 rat cerebellar cells is independent of RSV-induced changes in growth and adhesion

The WC5 rat cerebellar cell line, which is infected with a Rous sarcoma virus that is temperature-sensitive for pp60src transformation, shows temperature-dependent expression of the neural-cell-adhesion molecule (N-CAM) and glial fibrillary acidic protein (GFAP). We found that WC5 cells maintained at the non-permissive temperature in both monolayer cultures and spheroids are subject to density-dependent inhibition of growth, whereas cells maintained at the permissive temperature continued to grow. The movement of isolated WC5 cells at both temperatures was similar, while the migration of WC5 cells out of 3-dimensional aggregates was faster at the non-permissive temperature. We tested whether the RSV-induced changes affect the invasion of the WC5 cells in 2 in vitro assays: the chorio-allantoic-membrane assay and the chick-heart-fragment assay. In both assays, WC5 cells grown at either temperature were invasive. These results indicate that growth rate is unrelated to invasion and that loss of N-CAM-mediated cell-cell adhesion is not necessary for invasion.

Invasion of Rous sarcoma virus-transformed retinal cells: role of cell motility

Transformation of retinal neuro-epithelial cells by Rous sarcoma virus (RSV) leads to many alterations in cell phenotype, including changes in cell movement, cell-cell adhesion and protease secretion. To define and quantitate the alterations in cell movement, we analyzed video recordings of cultured cells using the computer-assisted Dynamic Morphology System (DMS). Control neuro-epithelial cells showed very low levels of translocation and membrane activity. After transformation, neuro-epithelial cells exhibited increased membrane activity, although directed cell translocation remained low. Developing retinas also contain a small proportion of Müller glial cells, which were purified by repeated passaging of control cultures. In contrast to neuro-epithelial cells, both control and RSV-transformed glial cells showed high levels of translocation and membrane activity. To analyze how different kinds of cell movement affect invasive behavior, we compared the ability of control and RSV-transformed cells to invade the chorio-allantoic membrane of developing chicken embryos. Control neuro-epithelial cells were not invasive. RSV-transformed neuro-epithelial cells, which showed low levels of translocation as revealed by DMS, were invasive. Similarly, RSV-transformed glial cells were invasive while control glial cells, which translocated, were not invasive. These results suggest that high levels of cell translocation are not necessary for invasion. In addition, the results suggest that elevated membrane activity in neuro-epithelial cells may be important for their invasion.

Expression of neural cell adhesion molecules in normal and pathologic tissues

Because cell-cell and cell-matrix interactions directly affect the growth, differentiation, and morphogenesis of neural tissue, abnormal changes in these processes could have severe pathologic consequences. Over the last few years, it has become possible to investigate these interactions at the molecular level due to advances in the identification and characterization of matrix components and receptors and cell adhesion molecules (CAMs). Emerging evidence suggests that two broad classes of CAMs are represented by the neural CAM, N-CAM, and the epithelial CAM, L-CAM. N-CAM and several other neural adhesion molecules contain immunoglobulin-like domains and do not require calcium for binding. In contrast, L-CAM, N-cadherin, and P-cadherin depend on calcium for activity and share structural features that differ from those of the N-CAM family. All of these CAMs are expressed in early embryos and in a variety of tissues throughout development, although each has a characteristic pattern. Initial studies suggest that injury, oncogenic transformation, and some genetic neurologic disorders are accompanied by changes in CAM expression that alter the adhesive or migratory behavior of cells.

Neural cell adhesion molecule: structure, immunoglobulin-like domains, cell surface modulation, and alternative RNA splicing

The neural cell adhesion molecule, N-CAM, appears on early embryonic cells and is important in the formation of cell collectives and their boundaries at sites of morphogenesis. Later in development it is found on various differentiated tissues and is a major CAM mediating adhesion among neurons and between neurons and muscle. To provide a molecular basis for understanding N-CAM function, the complete amino acid sequences of the three major polypeptides of N-CAM and most of the noncoding sequences of their messenger RNA's were determined from the analysis of complementary DNA clones and were verified by amino acid sequences of selected CNBr fragments and proteolytic fragments. The extracellular region of each N-CAM polypeptide includes five contiguous segments that are homologous in sequence to each other and to members of the immunoglobulin superfamily, suggesting that interactions among immunoglobulin-like domains form the basis for N-CAM homophilic binding. Although different in their membrane-associated and cytoplasmic domains, the amino acid sequences of the three polypeptides appear to be identical throughout this extracellular region (682 amino acids) where the binding site is located. Variations in N-CAM activity thus do not occur by changes in the amino acid sequence that alter the specificity of binding. Instead, regulation is achieved by cell surface modulation events that alter N-CAM affinity, prevalence, mobility, and distribution on the surface. A major mechanism for modulation is alternative RNA splicing resulting in N-CAM's with different cytoplasmic domains that differentially interact with the cell membrane. Such regulatory mechanisms may link N-CAM binding function with other primary cellular processes during the embryonic development of pattern.

Conversion of embryonic form to adult forms of N-CAM in vitro: results from de novo synthesis of adult forms

During normal development, the neural cell adhesion molecule N-CAM changes at the cell-surface from a sialic acid-rich embryonic, or E form, to several adult, or A forms that have less sialic acid (E-to-A conversion). To investigate the cellular and molecular mechanisms that underlie these changes, we have established conditions under which E-to-A conversion occurs in cultured explants of central nervous system tissues. Mouse cerebellum, chick spinal cord, and chick retina that express the E form of N-CAM were dissected and cultured on collagen gels. After 3-6 d in culture, increased proportions of A forms were synthesized, as revealed by specific immunoprecipitation and immunoblotting. The rate of E-to-A conversion and the proportions of the different A forms synthesized in vitro were similar to those observed for the tissues in vivo at comparable times. In addition, the explants incorporated radioactive precursors of amino sugars into N-CAM, and the electrophoretic mobilities of the E and A forms of N-CAM were altered by treatment with neuraminidase in a way comparable to that found for N-CAM obtained directly from tissue. These results suggest that the post translational processing in vitro was similar to that in vivo. Logistic studies on cell division and death in the explants suggested that E-to-A conversion resulted mainly from a specific increase in synthesis of A forms in individual cells rather than as a consequence of differential birth or death within distinct cell populations. The data were consistent with the possibility that the increase in synthesis of A forms occurred either in cells that had previously synthesized E forms or in a distinct population of cells that already synthesized A forms. Cells dissociated from embryonic central nervous system tissues and cultured in vitro were also found to undergo E-to-A conversion at the same rate as the explant cultures, which suggests that if intercellular signals were responsible for initiation of the change in synthetic pattern, they had already occurred in vivo before the time of culture. In pulse-chase experiments, the E form of N-CAM that was synthesized during the first day after explantation persisted as E form for several days, at times when newly synthesized N-CAM was predominantly in A forms. These results indicate that in cultured neural tissue, the E form of N-CAM is not processed into A forms but is gradually degraded and replaced by newly synthesized A forms.(ABSTRACT TRUNCATED AT 400 WORDS)

Molecular mechanisms of cell adhesion in normal and transformed cells

Alterations in the adhesive mechanisms of cancer cells are likely to play an important role in determining the invasive or metastatic potential of these cells. An understanding of these alterations at the molecular level is now within reach, due to recent progress in the identification and characterization of several cell adhesion molecules (CAMs). Two of these molecules, the neural cell adhesion molecule N-CAM and the liver cell adhesion molecule L-CAM, are expressed on a variety of cell types from early embryos and throughout adult life, and appear to play several important roles in early inductive events, formation of specific intercellular connections, and maintenance of adult tissues. Two other molecules, the neuron-glia adhesion molecule Ng-CAM and a molecule involved in the specific adhesion of lymphocytes, appear to be more restricted in their developmental expression and function. The molecular characterization of N-CAM made possible for the first time an examination of the effects of transformation on the expression of a defined cell adhesion molecule. In both established cell lines from rat cerebellum and embryonic chick neuroepithelial cells, transformation by Rous sarcoma virus caused a large reduction in expression of N-CAM. In both cases, the N-CAM-mediated adhesion was correspondingly reduced. The neuroepithelial cells also became more highly motile after transformation. The decrease in N-CAM coupled with this increase in cell motility may significantly enhance the invasiveness of these cells. Other surface antigens have also been identified that may be involved in essential steps of invasion and metastasis. Such studies represent the initial step toward a detailed understanding of the role of CAMs in the various steps of metastasis. The accessibility of CAMs on tumor cell surfaces, and the availability of specific antibodies to these components suggests that reagents may become available in the near future that will offer new opportunities for preventing the formation of metastases.

Phenotypic changes and loss of N-CAM-mediated adhesion in transformed embryonic chicken retinal cells

Transformation of 6-d-old embryonic chicken retinal cells by Rous sarcoma virus (RSV) was found to cause significant changes in several cellular properties including adhesiveness, motility, and state of differentiation. The alterations in cell adhesivity were analyzed by means of specific antibodies to the calcium-independent neural cell adhesion molecule, N-CAM. In the RSV-transformed cells the amount of N-CAM present at the cell surface was significantly decreased relative to normal cells, as assessed by immunofluorescent staining, specific immunoprecipitation, and immunoblotting experiments. This decrease was reflected in a marked reduction in N-CAM-mediated adhesiveness measured in vitro. A different, calcium-dependent, adhesive system also present on neurons was not detectably altered by RSV transformation and, in contrast with previous studies on normal neurons, this adhesive system was detected without treatment by proteases. In culture, the transformed cells formed fewer and less compact colonies than the normal retinal cells. Observation of the RSV-transformed retinal cells by time-lapse cinematography confirmed the reduction in adhesiveness and also revealed that the transformed cells were more highly motile than their normal counterparts. In addition, RSV transformation appeared to alter the differentiation of the cultured retinal cells. Immunofluorescent staining studies indicated that in contrast to mature neurons, transformed neural retinal cells expressed the 34,000-mol-wt tyrosine kinase substrate and reduced amounts of a neuron-specific ganglioside recognized by monoclonal antibody A2B5. These characteristics are shared by untransformed glial cells. In double immunofluorescent staining experiments, many cells expressed both N-CAM and pp60src shortly after viral infection, which implies that the N-CAM-positive neuroepithelial cells were transformed by RSV. In addition, a highly purified population of N-CAM-positive neural retinal cells, selected using a fluorescence-activated cell sorter, was rapidly and extensively transformed by RSV at rates comparable to those of the unfractionated population. These results established that the transformed cells were largely derived from RSV-infected neuroepithelial cells rather than from a small population of retinal glial cells present in the primary culture. The findings suggest reconsideration of the possible origin of tumors classified by morphological criteria as derived from glia and raise the possibility that the normal homologue of pp60src may play a role in the commitment of neuroepithelial cells to neuronal or glial differentiation pathways.

Changes in the distribution of the 34-kdalton tyrosine kinase substrate during differentiation and maturation of chicken tissues

We examined the distribution of the 34-kilodalton (34-kD) tyrosine kinase substrate in tissues of adult and embryonic chicken using both a mouse monoclonal antibody and a rabbit polyclonal antibody raised against the affinity purified 34 kD protein. We analyzed the localization by immunoblotting of tissue extracts, by immunofluorescence staining of frozen tissue sections, and by staining sections of paraffin-embedded organs by the peroxidase antiperoxidase method. The 34-kD protein was present in a variety of cells, including epithelial cells of the skin, gastrointestinal, and respiratory tracts, as well as in fibroblasts and chondrocytes of connective tissue and mature cartilage, and endothelial cells of blood vessels. The 34-kD protein was also found in subpopulations of cells in thymus, spleen, bone marrow, and bursa. The protein was not detected in cardiac, skeletal, or smooth muscle cells, nor in epithelial cells of liver, kidney, pancreas, and several other glands. Although most neuronal cells did not contain the 34-kD protein, some localized brain regions did contain detectable amounts of this protein. The 34-kD protein was not detected in actively dividing cells of a number of tissues. Changes in the distribution of the 34-kD protein were observed during the differentiation or maturation of cells in several tissues including epithelial cells of the skin and gastrointestinal tract, fibroblasts of connective tissue, and chondroblasts.

Alteration of neural cell adhesion molecule (N-CAM) expression after neuronal cell transformation by Rous sarcoma virus

The effect of transformation by Rous sarcoma virus on the neural cell adhesion molecule N-CAM was assessed by immunoblotting, immunofluorescence staining, and an in vitro cell-cell aggregation assay using highly specific antibodies to the adhesion molecule. Expression of N-CAM was found to be temperature dependent in several rat cerebellar cell lines infected with a mutant Rous sarcoma virus that is temperature sensitive for transformation. At the nonpermissive temperature, these cells displayed significant quantities of N-CAM and aggregated rapidly by an N-CAM-mediated mechanism. However, when the cell lines were grown at the permissive temperature, they were morphologically transformed, contained much lower amounts of N-CAM, and aggregated poorly. A similar temperature dependence of N-CAM expression was not observed in cultured primary rat cerebellar cells nor in a chemically transformed neuronal cell line. In all of the cell lines, N-CAM occurred in the adult forms; the embryonic form has so far been observed in normal embryonic tissues and a few regions of the adult brain. The findings show that N-CAM prevalence at the cell surface can be modulated by transformation with clear-cut effects on cell-cell adhesion.

Chemical characterization of a neural cell adhesion molecule purified from embryonic brain membranes

A neural cell adhesion molecule (N-CAM) was purified in milligram quantities from detergent extracts of embryonic chick brain membranes. N-CAM has an unusual carbohydrate content and structure, is polydisperse in solution, and is associated with proteolytic activity leading to its spontaneous cleavage. The carbohydrate composition of N-CAM includes 13 mol of sialic acid but only 1.4 mol of galactose/100 mol of amino acids, suggesting the presence of a sialic acid to protein linkage not previously observed in higher organisms. N-CAM appears to be an integral membrane protein in that its extraction from membranes required detergent. Although soluble, the purified molecule was aggregated (Mr = 0.5 to 1.2 X 10(6)) and polydisperse in detergent-free solutions. N-CAM from brain also migrated as a broad but continuously stained region from Mr = 200,000 to Mr = 250,000 on sodium dodecyl sulfate-polyacrylamide gel electrophoresis; the molecule from retina was similar but had a somewhat faster mobility. Desialation of N-CAM did not significantly change its behavior in solution, but converted both brain and retinal N-CAM to components migrating on sodium dodecyl sulfate-polyacrylamide gel electrophoresis as material of about Mr = 140,000. Despite the apparent heterogeneity, amino acid sequence analysis and comparison of proteolytic fragments suggest that all forms of the glycoprotein are derived from the same polypeptide chain. On prolonged incubation at neutral pH, N-CAM undergoes apparent proteolysis to yield a polypeptide that contains little sialic acid and has a Mr = 65,000 on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, a separate sialic acid-rich component, and a variety of small peptides. The 65,000-dalton polypeptide appeared to contain all of the antigenic determinants of intact N-CAM that neutralize the adhesion-blocking ability of anti-retinal cell Fab' fragments.

Distinct calcium-independent and calcium-dependent adhesion systems of chicken embryo cells

Three criteria have been used to distinguish among different systems of embryonic cell adhesion: dependence on Ca2+, involvement of particular cell-surface molecules, and binding specificity. The characterization of the adhesion with respect to cell-surface molecules was carried out by using specific antibodies against the neural and liver cell adhesion molecules (N-CAM and L-CAM) and antibodies raised against retinal cells prepared by limited trypsinization in the presence of Ca2+ (called "T/Ca cells"). Aggregation of cells prepared from retina or brain without Ca2+ did not require Ca2+ and was inhibited by anti-(N-CAM) antibodies but not by anti-(L-CAM) or anti-T/Ca cell antibodies. In contrast, cells obtained from the same tissues in the presence of Ca2+ did require Ca2+ to aggregate. This aggregation was inhibited by anti-T/Ca cell antibodies but not by anti-(N-CAM) or anti-(L-CAM) antibodies. Hepatocyte aggregation also required Ca2+ and was inhibited only by anti-(L-CAM) antibodies. These results define three antigenically distinct cell adhesion systems in the embryo and raise the possibility that additional systems will be found. The neural Ca2+-independent system displayed a limited tissue specificity, mediating binding to neural but not liver cells. In contrast, the Ca2+-dependent systems of both neural and liver cells caused binding to all cell types tested. The Ca2+-dependent system was most active in retinal cells from 6-7 day embryos, whereas the Ca2+-independent system was most active at later times during development. In addition, treatments that inhibited the Ca2+-independent or Ca2+-dependent systems had very different effects on the fasciculation of neurites from dorsal root ganglia. All of the results suggest that Ca2+-independent and Ca2+-dependent adhesion systems play different functional roles during embryogenesis.

Adhesion among neural cells of the chick embryo. III. Relationship of the surface molecule CAM to cell adhesion and the development of histotypic patterns

We have previously identified a molecule (named cell adhesion molecule [CAM]) that is involved in the in vitro aggregation of neural cells from chick embryos. In the present report, specific anti-CAM antibodies have been used to demonstrated that CAM is localized in neural tissues, and is associated with the plasma membrane of retinal cells and neurites. Furthermore, it has been shown by antibody absorption techniques that the decreased adhesiveness of cultured retinal cells obtained originally from older embryos is correlated with a decrease in the density or accessibility of cell adhesion molecules on the surface of these cells. The central role of CAM in neural cell aggregation has been established by the observation that anti-CAM Fab' fragments inhibit adhesion between neural cells in a variety of assays. To investigate the function of CAM and cell adhesion in developing tissues, aggregates of retinal cells that are capable of forming histotypic patterns in vitro were cultured in the presence and absence of anti-CAM Fab'. The Fab' was found to inhibit sorting out of cell bodies and neurites and to decrease the number of membrane-membrane contacts, suggesting that CAM is associated with cell-cell, cell-neurite, and neurite-neurite interactions.

Adhesion among neural cells of the chick embryo. I. An immunological assay for molecules involved in cell-cell binding

An immunologically based method for the quantitative assay of molecules involved in cell adhesion is described. Three observations served as a basis for this assay: (a) cells obtained by trypsinization of retinal tissue aggregated rapidly, provided they had been allowed to recover in culture from the dissociation process; (b) treatment of chick retinal cells with Fab' fragments from rabbit antibodies against these cells prevented their aggregation; and (c) incubation of these antibody fragments with antigens released by retinal cells in culture neutralized their ability to inhibit aggregation. The amount of neutralizing antigen was determined by measuring the rates of cell aggregation in the presence and absence of antibody and antigen using a particle counter. Although adhesion was inhibited by anti-retinal cell antibodies, it was not affected by lectins or anti-carbohydrate antibodies that also were bound to the cell surface. Together, the results suggest that the inhibition involved blockade or inactivation of particular cell surface molecules and that the retinal cell antigens capable of neutralizing the antibodies represented these molecules or their fragments. In the accompanying paper, we describe the use of this assay for the purification from culture supernatants of a cell surface molecule involved in cell to cell adhesion.

Adhesion among neural cells of the chick embryo. II. Purification and characterization of a cell adhesion molecule from neural retina

The aggregation of cells from dissociated neural retinas of chick embryos can be inhibited by antibodies prepared against whole retinal cells. In order to identify the antigens involved, substances released by retinal tissues in culture were tested for their ability to neutralize specifically the inhibition by antibody of cell adhesion. Using this assay, three active polypeptides from the culture supernatant were purified 500-fold by gel filtration and polyacrylamide gel electrophoresis. Rabbit antibodies prepared against these purified supernatant activities inhibited cell adhesion and reacted only with the three polypeptides. Immunoprecipitation by the specific antibodies of 3H-labeled proteins from a detergent extract of embryonic retinal cell membranes yielded a polypeptide having a Mr of 140,000 in sodium dodecyl sulfate. This precipitation was inhibited in the presence of the three culture supernatant polypeptides that had activity, suggesting that they contained antigenic determinants in common with the 140,000 Mr surface component. They therefore represent all or parts of this cell surface molecule that were released into solution during tissue culture. The data are consistent with the hypothesis that the 140,000 Mr polypeptide is intimately involved in initial adhesion among neural cells.

Mechanisms of adhesion among cells from neural tissues of the chick embryo

In order to analyze the molecular mechanisms of cell adhesion during development, proteins on the surface of chick embryonic neural cells were compared with proteins released after placing these cells in culture. One of the components released into culture, F1 (molecular weight, Mr 140,000), was derived by proteolytic cleavage of a cell surface precursor with a molecular weight of at least 240,000. Another protein, F2, recovered from culture as a dimer (Mr 1110,000), appeared to be a product of limited proteolytic cleavage of F1. Cells in retinal tissue possessed a surface protein of Mr 150,000 that also appeared to be derived by limited proteolytic cleavage of the cell surface precursor. Antibodies to F2 interacted with determinants on the cell surface protein of Mr 150,000, and specifically prevented homologous and heterologous binding among dissociated retinal and brain cells. In contrast, antibodies to F1 failed to prevent cell-cell adhesion and did not crossreact with F2. These data suggest that the cell surface protein of Mr 150,000 generated by limited proteolysis is involved in adhesion of both retinal and brain cells. Cell-cell binding of both retinal and brain cells varied as a function of developmental age and brain cells acquired their binding properties at an earlier time than retinal cells. Similar results were obtained in experiments on the binding of retinal and brain cells of different ages to nylon fibres coated with antibodies to F2. The results of the molecular and cellular experiments are incorporated in a model for cell adhesion invoking both proteolytic activation and modulation of cell surface ligands.

Mutant of Dictyostelium discoideum defective in cell contact regulation of enzyme expression

Previous work has shown that aggregation and disaggregation of cells during development of D. discoldeum significantly affects the expression of certain developmentally regulated enzymes. We have examined this cell contact regulation in a previously isolated mutant, Fr-17, and found that during the course of its developmental sequence it becomes specifically defective in this function.