Developmentally regulated expression of the neural cell adhesion molecule (NCAM) by mouse thymocytes

The expression of the neural cell adhesion molecule (NCAM) has been investigated during thymus ontogeny. NCAM mRNA was readily detectable at day 19 of gestation, the youngest age studied. Its level declined after birth to become undetectable at 3 weeks of age. Cell surface expression of NCAM protein was detected on 14% of day 15 fetal thymocytes and peaked during the perinatal period, when around 40% of the thymocytes expressed low to medium levels of NCAM. At postnatal day 2, the vast majority of the NCAM+ cells were also CD4+ and CD8+. At embryonic day 15, NCAM appeared also to be expressed by CD4- thymocytes since 14% of the cells were already NCAM+ whereas CD4 was virtually undetectable. In frozen section of the newborn thymus, surface staining for NCAM was present on a subpopulation of cells in the cortex, rare in the medulla and absent from the sub-capsular area. In conjunction with other cell adhesion molecules, NCAM could play a role in cell interactions during thymic development.

Differential exon usage involving an unusual splicing mechanism generates at least eight types of NCAM cDNA in mouse brain

The murine neural cell adhesion molecule (NCAM) is known to exist in three isoforms of different size, NCAM-180, -140 and -120 coded for by four transcripts of 6.9, 6.1, 4.8 and 2.7 kb in length. Since the differences between these isoforms are due to alternative splicing in the coding region for the transmembrane and cytoplasmic domains, the extracellular, N-terminal portion of NCAM seemed to be shared by all three protein forms. Here we report that the coding region for N-terminal domains of NCAM also contains at least two sites of alternative splicing, termed alpha and pi. Short additional sequences of 3, 18 and 30 nt in length can be introduced at these sites, which are located in the membrane-proximal 'stem' between the Ig-like domains and the membrane attachment site and within the Ig-like domain IV, respectively. Proof for at least eight different mRNAs has been found by sequencing and S1 nuclease protection assays of selected independent cDNA clones, and Northern blot analyses. If most combination of the splice patterns identified so far in mouse brain occurred, 24 different mRNAs could be generated coding for 18 different proteins. The shortest extra-sequence found inserted at splice site alpha consisted only of the trinucleotide AAG, raising questions about the mechanism of this particular insertion.

Identification and cDNA cloning of a new member of the L2/HNK-1 family of neural surface glycoproteins

Rabbit antibodies raised against a 135- to 140-kD glycoprotein isolated from the culture medium of mouse forebrain explants were used for the identification and cloning of a complex of mouse neural cell surface glycoproteins. The antibodies recognized a 135-kD surface protein which shared the L2/HNK-1 epitope with several neural cell adhesion molecules. Three homologous complementary deoxyribonucleic acid (cDNA) clones were isolated from a mouse brain cDNA library prepared in the expression vector lambda gt11, one of which was sequenced and found to lack sequence homologies with known proteins. In Northern blots, this clone hybridized with a single 6.3 kb messenger ribonucleic acid (mRNA). In immunoblots of mouse brain extracts, antibodies raised in rabbits against the fusion protein encoded by it stained two glycoproteins of 135 and 90 kD, which we designated F3.135 and F3.90. In the developing mouse cerebellum, F3 antigenic sites were found predominantly on parallel fibers and on postmitotic neurons. In fetal brain cell cultures, F3 antigen was detected at the surface of cells with neuronal morphology, but the antibodies also stained some non-neuronal cells in a pattern characteristic of matrix components. Because all proteins carrying the L2/HNK-1 epitope identified so far have a role in cell adhesion, it can be anticipated that the F3 surface proteins also are involved in cell-interaction phenomena.

Complete sequence and in vitro expression of a tissue-specific phosphatidylinositol-linked N-CAM isoform from skeletal muscle

Neural cell adhesion molecules (N-CAMs) are a family of cell surface sialoglycoproteins encoded by a single copy gene. A full-length cDNA clone that encodes a nontransmembrane phosphatidylinositol (PI) linked N-CAM of Mr 125 × 10(3) has been isolated from a human skeletal muscle cDNA library. The deduced protein sequence encodes a polypeptide of 761 amino acids and is highly homologous to the N-CAM isoform in brain of Mr 120 × 10(3). The size difference between the 125 × 10(3). The size difference between the 125 × 10(3) Mr skeletal muscle form and the 120 × 10(3) Mr N-CAM form from brain is accounted for by the insertion of a block of 37 amino acids called MSD1, in the extracellular domain of the muscle form. Transient expression of the human cDNA in COS cells results in cell surface N-CAM expression via a putative covalent attachment to PI-containing phospholipid. Linked in vitro transcription and translation experiments followed by immunoprecipitation with anti-N-CAM antibodies demonstrate that the full-length clone of 761 amino acid coding potential produces a core polypeptide of Mr 110 × 10(3) which is processed by microsomal membranes to yield a 122 × 10(3) Mr species. Taken together, these results demonstrate that the cloned cDNA sequence encodes a lipid-linked, PI-specific phospholipase C releasable surface isoform of N-CAM with core glycopeptide molecular weight corresponding to the authentic muscle 125 × 10(3) Mr N-CAM isoform. This is the first direct correlation of cDNA and deduced protein sequence with a known PI-linked N-CAM isoform from skeletal muscle.

Molecular modelling of the immunoglobulin-like domains of the neural cell adhesion molecule (NCAM): implications for the positioning of functionally important sugar side chains

The neural cell adhesion molecule (NCAM) is thought to mediate cell-cell adhesion by a homophilic mechanism involving binding sites located in the N-terminal region of the protein. This region of the molecule consists of five domains that are homologous to each other and share conserved residues with immunoglobulin domains. We report here secondary structure predictions for the five NCAM domains and three-dimensional models for two of them. The results are entirely consistent with an immunoglobulin-like folding of the NCAM domains into seven strands forming two beta-sheets. NCAM-NCAM binding may thus be analogous to the pairwise associations of immunoglobulin constant domains, which are involved in dimer formation. Insertions and deletions are located mostly in beta-turn regions. Two alpha-helical regions in the third and fourth domain are predicted with high probability. NCAM bears two kinds of functionally important sugar side chains, sialic acid polymers in the fifth domain, which modulate NCAM binding, and the L2 moiety, which is involved in cell adhesion and can be assigned to the third domain. Three-dimensional modelling of the corresponding domains indicates that two of the three sites for N-linked glycosylation in the fifth and the single site in the third domain are located on the face of the domain, which in immunoglobulin constant regions engages in intermolecular interactions.

Reexpression of poly(sialic acid) units of the neural cell adhesion molecule in Wilms tumor

A unique structural feature of the neural cell adhesion molecule N-CAM is the presence of homopolymers of alpha (2----8)-linked sialic acid units. We have used two specific probes for the detection of poly(sialic acid) in normal human kidney and Wilms tumor: a monoclonal antibody against meningococci group B capsular polysaccharide (homopolymers of alpha (2----8)-linked sialic acid units), which shows no crossreactivity with polynucleotides and denaturated DNA, and bacteriophage-induced endosialidases specifically hydrolyzing alpha (2----8)-linked poly(sialic acid) units. Additionally, for the detection of N-CAM, antibodies recognizing the polypeptide portion of the molecule and biotinylated antisense RNA transcribed from a cDNA clone for N-CAM were applied. Poly(sialic acid) was regionally detectable in human embryonic kidney but undetectable in normal adult kidney, as already reported for rat kidney. The malignant Wilms tumor, which is characterized by the presence of structural components resembling those found in embryonic kidney, reexpressed poly(sialic acid) units and showed positive immunostaining for the polypeptide portion of N-CAM. Immunoblot analysis of Wilms tumor as well as human embryonic kidney and brain with the monoclonal anti-poly(sialic acid) antibody revealed in each case the same high molecular mass broad band. In situ hybridization demonstrated the presence of mRNA for N-CAM in Wilms tumor. We conclude that poly(sialic acid), most probably present on N-CAM, is an oncodevelopmental antigen in human kidney.

Neural cell adhesion molecules during embryonic induction and development of the kidney

The neural cell adhesion molecules (N-CAM) are a family of related glycoproteins with Mr of 180, 140 and 120 × 10(3) (180K etc.). In the embryo, they are often highly sialylated and migrate as a diffuse band of 170–250K. N-CAM are found in non-neural tissues and we have now studied the expression of N-CAM in the developing mouse kidney. During kidney development, a unique conversion of a mesenchyme to an epithelium occurs and it is thought that this is mediated by an increase in cell adhesivity. By immunofluorescence, we show that N-CAM is present already at onset of kidney development on the cells of the uninduced nephrogenic mesenchyme. After induction, when the cells convert into an epithelium, they lose N-CAM gradually and instead begin to express uvomorulin, another primary CAM. By using an organ culture model, we could rather precisely show that N-CAM and uvomorulin are coexpressed for a short period, but, when epithelial cell polarization is evident, only uvomorulin is present on the epithelium, whereas N-CAM is confined to the surrounding mesenchyme. Immunoblotting for N-CAM revealed that the ‘embryonic’ form of N-CAM, the broad 170–250K band was not present in the embryonic kidney, which instead expressed the three distinct 180K, 140K and 120K bands typical of adult neurones. The 180K and 140K bands were gradually lost during development and were no longer detectable in adult kidneys. By using an N-CAM cDNA, we detected three different mRNAs of 7.4, 6.7 and 4.3 kb in the developing kidney, but this expression was restricted to the embryonic and early postnatal stages. No transcripts were detectable in adult kidneys. The studies do not support the hypothesis that N-CAM expression in the kidney is turned on by embryonic induction. Rather, we suggest that N-CAM are important adhesives for the predetermined, but not yet induced, nephrogenic mesenchyme.

Differential splicing and alternative polyadenylation generates distinct NCAM transcripts and proteins in the mouse

The neural cell adhesion molecule (NCAM) exists in at least three different protein isoforms which are selectively expressed by different cell types and at different stages of development. They are encoded by four to five different transcripts that are derived from a single gene. Here we report the exon--intron structure of the 3' part of the mouse NCAM gene. This region contains six exons. The 5' exon is constitutively expressed in all four prominent size classes of NCAM mRNAs detected in the mouse brain. The second exon contains the poly(A) addition sites for the two smaller mRNAs of 5.2 and 2.9 kb which differ in the length of their 3' non-coding regions and seem both to encode NCAM-120. This second exon is absent in the largest 7.4 kb transcript which encodes NCAM-180; in the 6.7 kb mRNA, which appears to code for NCAM-140, the second and the fifth exon have been spliced out. This data explains how the prominent four transcripts and three protein isoforms of mouse NCAM are generated from a single gene. The alternatively spliced fifth exon is surrounded by inverted repeats potentially capable of secondary structure formation, that may sequester this exon in a loop.

A 140-kilodalton protein is released from cultured astrocytes by phosphatidylinositol phospholipase C

Astrocytes in culture synthesize a 140-kilodalton (140-kD) protein (protein 140) that is released into the medium on incubation with phosphatidylinositol phospholipase C. This molecule therefore belongs to the class of proteins anchored to the external side of the cell membrane through a glycolipid moiety. Protein 140 is present in astrocyte cultures derived from two different regions of the brain and is not expressed by neurons in vitro. It differs from neuronal cell adhesion molecule 120 or 140 and is probably identical to a protein of 140 kD present in C6 glioma cells.

Biosynthesis, membrane association, and release of N-CAM-120, a phosphatidylinositol-linked form of the neural cell adhesion molecule

The neural cell adhesion molecule (N-CAM) of rodents comprises three distinct proteins of Mr 180,000, 140,000, and 120,000 (designated N-CAM-180, -140, and -120). They are expressed in different proportions by different tissues and cell types. but the individual contribution of each form to cell adhesion is presently unknown. Previous studies have shown that the two N-CAM species of higher relative molecular mass span the membrane whereas N-CAM-120 lacks a transmembrane domain and can be released from the cell surface by phosphatidylinositol-specific phospholipase C. In this report, we provided evidence that N-CAM-120 contained covalently bound phosphatidylinositol and studied N-CAM-120 from its biosynthesis to its membrane insertion and finally to its release from the cell surface. Evidence was presented showing that the lipid tail of N-CAM-120 contained ethanolamine as is the case for other lipid-linked molecules. The phospholipid anchor was attached to the protein during the first minutes after completion of the polypeptide chain. This process took place in the endoplasmic reticulum as judged from endoglycosidase H digestion experiments. Immediately after a 2-min pulse with [35S]methionine, we detected also a short-lived precursor that had not yet acquired the lipid tail. Pulse-chase studies established that N-CAM-120 was transported to the cell surface from which it was slowly released into the extracellular milieu. The molecules recovered in the incubation medium appeared to have lost all of their bound fatty acid but only around half of the ethanolamine. Upon fractionation of brain tissue, approximately 75% of N-CAM-120 was recovered with a membrane fraction and approximately 25% in a membrane-free supernatant. A small proportion (approximately 6%) was found to be resistant to extraction by non-ionic detergent. A major posttranslational modification of N-CAM is polysialylation. Our results showed that also N-CAM-120 was polysialylated in the young postnatal brain and released in this form from cultured cerebellar cells. The presence of N-CAM in a form that can be released from the cell surface and accumulates in the extracellular fluid suggests a novel mechanism by which N-CAM-mediated adhesion may be modulated.

Analysis of cDNA clones that code for the transmembrane forms of the mouse neural cell adhesion molecule (NCAM) and are generated by alternative RNA splicing

The neural cell adhesion molecule (NCAM) exists in at least three different isoforms. In the mouse, NCAM proteins with apparent Mr's of 180,000, 140,000 and 120,000 have been distinguished. These are encoded by 4 to 5 different transcripts. Here we report the full amino acid sequence of an isoform which most likely represents NCAM-140. The N-terminal extracellular portion of the 829-residue polypeptide appears to be identical to all three NCAM proteins. The Mr of 91,276 is considerably smaller than the estimate based on SDS-gel electrophoresis. The 147 C-terminal residues are distinct from NCAM-120 and contain the putative transmembrane and cytoplasmic domains. The transcript encoding NCAM-140 contains almost 3.2 kb non-coding sequence with a canonical polyadenylation signal. While the 5' sequences of NCAM-140 hybridize with all NCAM mRNAs, the 3' probes recognize only the two larger transcripts of 7.4 and 6.7 kb. From S1 nuclease protection analyses and hybridization studies of several NCAM cDNA clones with genomic NCAM sequences one can conclude that the different NCAM transcripts are generated by alternative splicing. In addition to the two alternative splice sites in the sequence encoding the extracellular domains, a third one can be predicted approximately 320 nt downstream of the start of the NCAM-140-specific sequence portion. This finding is in agreement with the existence of an extra exon in the chicken NCAM-180. Comparison between mouse and chicken NCAM amino acid sequences revealed the highest homology in the second and fifth Ig-like domains and in the cytoplasmic parts suggesting that these regions serve highly conserved functions.

Characterization of neural cell adhesion molecules (NCAM) expressed by Ewing and neuroblastoma cell lines

The status of the neural cell adhesion molecule NCAM gene which is mapped to human chromosome 11q23-24 has been investigated in Ewing-tumor-derived cell lines which present the t(11;22)(q23-24;q12) translocation characteristic of this malignancy. No rearrangement was detected when 2 different non-overlapping probes to mouse NCAM were used. The expression of the NCAM gene was analysed at both the protein and messenger levels in material extracted from Ewing cell lines, human neuroblastoma cell line and fetal mouse brain. Immune blot and immunoprecipitation studies showed that the neuroblastoma cell line contained more NCAM material than the Ewing lines. In neuroblastoma but not in Ewing, the NCAM material had the electrophoretic characteristics of molecules with long polysialic acid chains. After treatment with endosialidase, the diffusely migrating neuroblastoma material was resolved into 3 discrete bands of 120, 140 and 180 kDa. In Ewing extract, high-molecular-weight NCAM species were also detected with a 3-band pattern more reminiscent of mature brain. Endoglycosidase F treatment of Ewing NCAM indicated that all 3 species were largely N-glycosylated. Northern blot analysis confirmed that NCAM was expressed more abundantly in neuroblastoma than in Ewing cell lines. Among the 4 NCAM messengers (7.0, 6.5, 4.3 and 4.1 kb) detected in the neuroblastoma, the 6.5 kb species was largely predominant. The Ewing messenger RNA pattern was clearly different as the largest 7.0-kb species was virtually absent and the other bands were of similar intensities.

An IgG monoclonal antibody to group B meningococci cross-reacts with developmentally regulated polysialic acid units of glycoproteins in neural and extraneural tissues

The structurally similar polysialic acid capsules of group B meningococci and Escherichia coli K1 are poor immunogens, and attempts are currently being made to improve their immunogenicity by chemical modifications. An IgG monoclonal antibody to these polysialic acid capsules was used for the study of the presence of structurally similar components in tissue glycoproteins to investigate the reasons for the poor immunogenicity and to evaluate potential dangers in active or passive immunization. By immunoblotting polysialic acid was detected outside the brain in newborn rat kidney, heart, and muscle. It appeared in immunoblots as one component and with similar mobility to the neural cell adhesion molecule N-CAM. Specificity studies of the antibody and endosialidase treatment showed that the polysialic acid glycans detected were composed of chains as long as eight sialic acid residues or more. The polysialic acid was not detected in the corresponding tissues of the adult animal. These results indicate that polysialic acid units are developmentally regulated components of both neural and extraneural tissues, and are bound to components with properties similar to a known cell-adhesion molecule. This together with the presence of low amounts of polysialic acid even in the adult brain, suggests potential hazards in vaccination trials and suggested immunotherapy of meningitis caused by group B meningococci or E. coli K1, which should be carefully assessed.

An IgG monoclonal antibody to group B meningococci cross-reacts with developmentally regulated polysialic acid units of glycoproteins in neural and extraneural tissues

The structurally similar polysialic acid capsules of group B meningococci and Escherichia coli K1 are poor immunogens, and attempts are currently being made to improve their immunogenicity by chemical modifications. An IgG monoclonal antibody to these polysialic acid capsules was used for the study of the presence of structurally similar components in tissue glycoproteins to investigate the reasons for the poor immunogenicity and to evaluate potential dangers in active or passive immunization. By immunoblotting polysialic acid was detected outside the brain in newborn rat kidney, heart, and muscle. It appeared in immunoblots as one component and with similar mobility to the neural cell adhesion molecule N-CAM. Specificity studies of the antibody and endosialidase treatment showed that the polysialic acid glycans detected were composed of chains as long as eight sialic acid residues or more. The polysialic acid was not detected in the corresponding tissues of the adult animal. These results indicate that polysialic acid units are developmentally regulated components of both neural and extraneural tissues, and are bound to components with properties similar to a known cell-adhesion molecule. This together with the presence of low amounts of polysialic acid even in the adult brain, suggests potential hazards in vaccination trials and suggested immunotherapy of meningitis caused by group B meningococci or E. coli K1, which should be carefully assessed.

Isolation and nucleotide sequence of mouse NCAM cDNA that codes for a Mr 79,000 polypeptide without a membrane-spanning region

The neural cell adhesion molecule (NCAM) exists in several isoforms which are selectively expressed by different cell types and at different stages of development. In the mouse, three proteins with apparent Mr's of 180,000, 140,000 and 120,000 have been distinguished that are encoded by 4-5 different mRNAs. Here we report the full amino acid sequence of a NCAM protein inferred from the sequences of overlapping cDNA clones. The 706-residue polypeptide contains, towards its N-terminus, 5 domains that share structural homology with members of the immunoglobulin supergene family. The sequence does not encode a typical membrane-spanning segment, but ends with 24 uncharged amino acids followed by two stop codons. This fact, together with size considerations, make it highly likely that our sequence represents NCAM-120, which lacks transmembrane or cytoplasmic domains and is attached to the membrane by phospholipid. Probes from the 5' region detect all four NCAM gene transcripts present in mouse brain consistent with the notion that the extracellular domains are common to most NCAM forms. However, a 3' probe corresponding to the hydrophobic tail and non-coding region hybridizes specifically with the smallest mRNA species. S1 nuclease protection experiments indicate that this region is encoded by exon(s) spliced out from the other mRNAs. Furthermore, our clones that are highly homologous to a published chicken NCAM sequence which codes for putative transmembrane and cytoplasmic domains elsewhere, diverge from it at the presumptive splice junction. It appears thus that alternate use of exons determines whether NCAM proteins with membrane-spanning domains are synthesized.(ABSTRACT TRUNCATED AT 250 WORDS)

Neuroectoderm-associated antigens on Ewing's sarcoma cell lines

The histogenesis of Ewing's sarcoma, the second most frequent primary bone tumor in humans, remains controversial. Ten Ewing cell lines were analyzed by immunological methods. Surface antigens recognized on Ewing cells were found to be related to the neuroectoderm lineage. They included ganglioside GD2, a marker of neuroectodermal tissues and tumors, and an acidic glycolipid detected by monoclonal antibody HNK-1 in the nervous system. The P61 rat monoclonal antibody that reacts with a peptide moiety of neural cell adhesion molecule (N-CAM) and a rabbit antiserum raised to purified mouse N-CAM also stained Ewing cells. Flow cytometry analysis performed using these reagents allowed the definition of four distinct Ewing phenotypes: all reagents equally stained group 1 lines; group 2 lines were strongly reactive with anti-N-CAM reagents, by contrast with a fainter staining with HNK-1 and anti-GD2 antibodies; all reagents but P61 were strongly reactive with group 3 lines; in group 4, Ewing lines were stained by P61 but only poorly by the anti-N-CAM antiserum. Several antibodies to melanoma and neuroblastoma associated antigens including two monoclonal antibodies to the nerve growth factor receptor were also found to react with Ewing cells. By contrast, all antibodies detecting antigens specifically expressed in hematopoietic cell lineages were totally unreactive. HLA class II antigens were never detected while the level of expression of class I antigens varied to a large extent. Ewing cells are characterized by a specific t(11;22)(q23-24;q12) translocation also observed in neuroepithelioma, a neuroectodermal tumor. Thus, Ewing's sarcoma cells share antigenic and karyotypic features with derivatives of the neuroectoderm possibly indicating a related histogenesis.

Distribution of the adhesion molecules N-CAM and L1 on peripheral neurons and glia in adult rats

There is considerable evidence that the cell surface glycoproteins N-CAM and L1 are important mediators of cell-cell adhesion in the nervous system, at least during development. Numerous studies have been devoted to the molecular properties of these proteins and their adhesion role in embryonic and early postnatal development. Much less is known about their importance in mature tissues. A rigorous and comprehensive description of the cell distribution of these molecules in the adult nervous system would clearly form a useful baseline for functional and biochemical studies. In the present work we have addressed this issue and studied the distribution of N-CAM and L1 throughout adult, as opposed to developing, rat peripheral nervous tissue. Particular attention was paid to the ganglia of the enteric nervous system, since adhesion mechanisms within these ganglia are likely to be placed under unusual demands. We report, for the first time, the presence of N-CAM and L1 on mature sensory, sympathetic and enteric neurons in adult rats. Thus, immunostaining of cell suspensions or short-term cultures showed N-CAM and L1 surface labelling on sympathetic and both large and small dorsal root sensory neurons. Both antigens were also present on the surface of enteric neurons in cultures prepared from 10-day-old rats and neonatal guinea pigs. Immunostaining of sections of enteric ganglia from adults indicated that both molecules were also expressed by mature enteric neurons. In sections of mature sciatic nerve neither N-CAM nor L1 immunoreactivity were detected at the site where the plasma membrane of myelinated axons meets the ad-axonal plasma membrane of the myelin-forming Schwann cell. Thus, both N-CAM and L1 were detected on all major classes of peripheral neurons, while their levels in the plasma membrane of myelinated axons may be significantly down-regulated. Similarly, both N-CAM and L1 were present on all major classes of non-myelin-forming peripheral glia in adult rats. This includes the enteric glial cells of the myenteric ganglia, non-myelin-forming Schwann cells in the sciatic nerve, sympathetic trunk and fine autonomic nerves in the gut wall, and the satellite glial cells of sympathetic and dorsal root sensory ganglia. In contrast, myelin-forming Schwann cells did not express detectable levels of N-CAM and only very low levels of L1, which was mainly located near the nodes of Ranvier.(ABSTRACT TRUNCATED AT 400 WORDS)

Phosphatidylinositol is involved in the membrane attachment of NCAM-120, the smallest component of the neural cell adhesion molecule

The rodent neural cell adhesion molecule (NCAM) consists of three glycoproteins with Mr of 180,000, 140,000 and 120,000. The Mr 120,000 protein (NCAM-120) has been shown to exist in membrane-bound and soluble forms but the nature of its membrane association and release has remained obscure. We show here that phosphatidylinositol-specific phospholipase C (PI-PLC), but not a phospholipase C of different specificity, releases a substantial proportion of NCAM-120 from brain membranes and solubilizes almost quantitatively NCAM-120 present at the surface of C6 astroglial cells. The PI-PLC effect was highly selective since only one other protein species was detectably released from C6 cells. These results suggest that NCAM-120 is held in the membrane by covalently bound phosphatidylinositol or a closely related lipid in a way similar to several other surface proteins from eukaryotic cells. The presence of NCAM in a form which can be released from the cell surface by a highly selective mechanism raises additional possibilities for modulation and control of cell--cell adhesion.

Experimental modification of postnatal cerebellar granule cell migration in vitro

Histotypic migration of [3H]thymidine pulse-labeled granule cell neurons in cerebellar folium explants was monitored in the presence of antibodies to cell adhesion molecules and quantified by automatic image analysis. When explants were cultured in the presence of monovalent antibody fragments to cell adhesion molecules L1 and N-CAM, an inhibition of cell migration of 33.3 +/- 4.4% and 13.9 +/- 2.1%, respectively, was observed. In the presence of an equimolar mixture of monovalent antibody fragments to L1 antigen and N-CAM no additive effects in inhibition of cell migration were seen. Antibodies to the L2 carbohydrate epitope which is common to L1, N-CAM and other cell surface glycoproteins showed a similarly small effect on cell migration as antibodies to N-CAM. Monoclonal antibodies to cell surface antigen M2 and polyclonal antibodies to mouse liver membranes reacting with the surface of all cerebellar cell types did not alter the migratory behavior of granule cells. Cultivation of explants in the presence of neuraminidase, ganglioside binding toxins, as well as glycosaminoglycans and glycosaminoglycan degrading enzymes, also did not modify the extent of cell migration under the culture conditions used.

Differential expression of mouse neural cell-adhesion molecule (N-CAM) mRNA species during brain development and in neural cell lines

The cell-adhesion molecules N-CAM (neural cell-adhesion molecule) are ligands in the formation of cell-cell bonds and have been shown to play important roles during neuro-ontogenesis. They exist in several molecular forms which differ at the protein and carbohydrate levels. The regulation of the expression of these different forms is an important issue that bears on such questions as to how adhesive interactions between cells are modulated during morphogenesis. In the present study we have used N-CAM cDNA clones to investigate the expression of the cognate mRNAs in the mouse and rat brain and in 2 neural cell lines. The results were compared with the levels of the different N-CAM proteins. We made the following observations. A complex set of 5 size classes of mRNAs--which show developmental, regional, and cell-type-dependent variations in their expression--hybridize to 1 of our cDNA probes. While embryonic brain contains N-CAM gene transcripts 7.4, 6.7, and 4.3 kilobases (kb) in length, 2 additional mRNAs of 5.2 and 2.9 kb appear postnatally. Transformed brain cells of an astrocytic character express predominantly mRNAs of 6.7, 4.3, and 2.9 kb and a neuroblastoma line those of 7.4, 6.7, 4.3, and 2.9 kb. There are important quantitative changes in the amount of N-CAM message expressed during brain development, with a peak around birth, suggesting that N-CAM synthesis is controlled at the transcriptional level. A comparison of N-CAM protein and mRNA levels reveals a striking correlation between the relative concentrations of the Mr 120,000 N-CAM protein (N-CAM120) and the 5.2 kb transcript.(ABSTRACT TRUNCATED AT 250 WORDS)

Interferon-alpha, beta and -gamma induce (2'-5') oligoadenylate synthetase in cultured mouse brain cells

Basal and interferon (IFN)-induced levels of (2'-5') oligoadenylate synthetase activity were measured in astrocyte cultures from the mouse cerebral cortex, in neurone-enriched and mixed cerebellar cultures, and in two continuous neural cell lines by a radioimmunoassay procedure. All untreated cultures contained measureable enzyme activity. Both purified IFN-alpha, beta and recombinant IFN-gamma induced the enzyme in all cultures with the exception of the C8S cell line which did not respond to IFN-gamma. IFN-alpha, beta was more effective than IFN-gamma. The amplitude of induction by IFN-alpha, beta was highest in the cell lines, intermediate in cortical astrocytes and lowest in mixed and neurone-enriched cultures from the cerebellum.

Localization of the human NCAM gene to band q23 of chromosome 11: the third gene coding for a cell interaction molecule mapped to the distal portion of the long arm of chromosome 11

cDNA clones containing sequences coding for the murine neural cell adhesion molecule (N-CAM) were used in Southern hybridizations on human genomic DNA and demonstrated approximately 90% homology between human and murine NCAM genes. In situ hybridization with one of these clones was performed on human metaphase chromosomes and allowed the localization of the human NCAM gene to band q23 of chromosome 11. The genes for two other cell surface molecules believed to be involved in cell-cell interactions, Thy-1 and the delta chain of the T3-T cell receptor complex, have recently been localized to the same region of chromosome 11 in man. Moreover, this region of the human chromosome 11 appears to be syntenic to a region of murine chromosome 9 that also contains the staggerer locus: staggerer mice show abnormal neurological features which may be related to abnormalities in the conversion of the embryonic to the adult forms of the N-CAM molecule.

Molecular forms of N-CAM and its RNA in developing and denervated skeletal muscle

The neural cell adhesion molecule (N-CAM) is present in both embryonic and perinatal muscle, but its distribution changes as myoblasts form myotubes and axons establish synapses (Covault, J., and J. R. Sanes, 1986, J. Cell Biol., 102:716-730). Levels of N-CAM decline postnatally but increase when adult muscle is denervated or paralyzed (Covault, J., and J. R. Sanes, 1985, Proc. Natl. Acad. Sci. USA., 82:4544-4548). To determine the molecular forms of N-CAM and N-CAM-related RNA during these different periods we used immunoblotting and nucleic acid hybridization techniques to analyze N-CAM and its RNA in developing, cultured, adult, and denervated adult muscle. As muscles develop, the extent of sialylation of muscle N-CAM decreases, and a 140-kD desialo form of N-CAM (generated by neuraminidase treatment) is replaced by a 125-kD form. This change in the apparent molecular weight of desialo N-CAM is paralleled by a change in N-CAM RNA: early embryonic muscles express a 6.7-kb RNA species which hybridizes with N-CAM cDNA, whereas in neonatal muscle this form is largely replaced by 5.2- and 2.9-kb species. Similar transitions in the desialo form of N-CAM, but not in extent of sialylation, accompany differentiation in primary cultures of embryonic muscle and in cultures of the clonal muscle cell lines C2 and BC3H-1. Both in vivo and in vitro, a 140-kD desialo form of N-CAM and a 6.7-kb N-CAM RNA are apparently associated with myoblasts, whereas a 125-kD desialo form and 5.2- and 2.9-kb RNAs are associated with myotubes and myofibers. After denervation of adult muscle, a approximately 12-15-fold increase in the levels of N-CAM is accompanied by a approximately 30-50-fold increase in N-CAM RNA, suggesting that N-CAM expression is regulated at a pretranslational level. Forms of N-CAM and its RNA in denervated muscle are similar to those seen in perinatal myofibers.

Phenotypic characterization of Ewing sarcoma cell lines with monoclonal antibodies

The histogenesis of Ewing sarcoma, the second most frequent bone tumor in humans, remains controversial. Four Ewing cell lines were analyzed by immunological methods. A panel of antibodies directed to T, B, and myelomonocytic markers gave negative results. Surface antigens recognized on Ewing cells were found to be related to the neuroectoderm lineage. Ganglioside GD2, a marker of neuroectodermal tissues and tumors, was present on all lines. These were also stained by the mouse monoclonal antibody HNK-1, which detects a carbohydrate epitope present on several glycoconjugates of the nervous system, including two glycoproteins, the myelin-associated glycoprotein and the neural cell-adhesion molecule (N-CAM), and an acidic glycolipid of the peripheral nervous system. The P61 monoclonal antibody, which reacts with a peptide moiety of N-CAM, and a rabbit antiserum, raised to purified mouse N-CAM and not recognizing the HNK-1-defined epitope, were also reactive. By contrast, all antibodies specific for hematopoietic cell surface antigens were totally negative. Besides these antigenic features, Ewing sarcoma cells are characterized by a specific t(11;22)(q24;q12) translocation also observed in neuroepithelioma, a neuroectodermal tumor, suggesting a possible evolutionary related origin. The recent finding that the human N-CAM gene is located at the vicinity of the breakpoint on chromosome 11 indicates that it might be involved in genetic rearrangements occurring in this region.