An upstream regulatory element of the NCAM promoter contains a binding site for homeodomains.

In the present study, we have analyzed an upstream regulatory element of the neural cell adhesion molecule (NCAM) promoter which is required for full promoter activity. It contains an ATTATTA motif that resembles the core recognition sequence of homeodomain (HD) proteins of the Antennapedia (Antp) and related types. Electrophoretic mobility shift (EMSA) and DNase I footprinting analyses revealed that the Drosophila HDs coded by the Antp and the zerknüllt (zen) genes bind this site in vitro.

Antennapedia homeobox peptide regulates neural morphogenesis.

We synthesized the 60-amino acid polypeptide corresponding to the sequence of the Drosophila antennapedia gene homeobox. This peptide (pAntp) recognized the consensus motif for binding to the promoter region of Hox-1.3.

Modulation of NCAM expression by transforming growth factor-beta, serum, and autocrine factors.

The expression of NCAM (neural cell adhesion molecule) is precisely regulated in terms of cell type specificity and developmental control. We searched for extracellular factors that may be involved in this regulation using N2A neuroblastoma and NIH 3T3 fibroblastic cells. Factors contained in FBS promoted a two- to threefold increase in NCAM protein and mRNA abundance in both cell lines.

Identification of positive and negative regulatory elements governing cell-type-specific expression of the neural cell adhesion molecule gene.

The neural cell adhesion molecule (NCAM) is one of the most prevalent cell adhesion molecules in vertebrates. Its expression is subject to complex cell-type- and developmental-stage-dependent regulation. To study this regulation at the level of transcription, we analyzed the promoter region of the mouse NCAM gene.

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.

Isolation of mouse N-CAM-related cDNA: detection and cloning using monoclonal antibodies.

Clones coding for the mouse neural cell adhesion molecule (N-CAM) were isolated from a cDNA library prepared in the expression vector lambda gt 11 from mRNA extracted from a mouse neuroblastoma cell line. This library was screened with two anti-N-CAM monoclonal antibodies directed against different sites on the molecule and with rabbit anti-N-CAM serum. Two clones were identified with the first monoclonal antibody, three with the second one, none reacted with both.

Structural and functional studies on N-CAM neural cell adhesion molecules.

The neural cell adhesion molecules N-CAM are to date the best characterized adhesion molecules of the nervous system. They have a high content of sialic acid residues which are present in the form of unusual sialic acid polymers. During development, a 3 fold decrease in the sialic acid content is observed.

Studies on the transmembrane disposition of the neural cell adhesion molecule N-CAM. The use of liposome-inserted radioiodinated N-CAM to study its transbilayer orientation.

The transmembrane orientation of the polypeptide chains present in preparations of adult and neonatal mouse N-CAM was studied using, as a model system, liposome-inserted purified N-CAM preparations. N-CAM purified from adult or neonatal mouse brain was 125I-labeled and reconstituted into artificial lipid vesicles. After trypsin digestion, the peptides that remained associated with the liposomes were isolated by floatation of the vesicles on sucrose gradients.

Studies on the transmembrane disposition of the neural cell adhesion molecule N-CAM. A monoclonal antibody recognizing a cytoplasmic domain and evidence for the presence of phosphoserine residues.

The N-CAMs are a group of surface glycoproteins involved in adhesive interactions of neurones. Related molecules of the mouse nervous system, identified in our laboratory, have been called BSP-2 and shown to act as ligands in adhesion of neuroblastoma cells. Results presented in this report show that they are immunochemically identical with N-CAM.

Adult and embryonic mouse neural cell adhesion molecules have different binding properties.

Interactions between neural cell surfaces seem to be of prime importance during neuroontogenesis, and responsible for the guidance of migrating neuroblasts and growing axons and for the formation of synapses. Little is known about the underlying molecular mechanisms, but most hypotheses imply the existence of cell-surface molecules that mediate the formation of transient or permanent bonds between neural cells. Recently, a membrane glycoprotein called neural cell adhesion molecule (N-CAM) has been characterized in chick and rodent nervous tissue that appears to act as a ligand in adhesion among neural cell bodies or neurites.

Occurrence of alpha 2-8 linked polysialosyl units in a neural cell adhesion molecule.

A brain cell surface protein (BSP-2) was isolated from mice of different ages by affinity chromatography using a monoclonal antibody. Analysis of glycopeptides obtained after pronase digestion revealed that the embryonal and neonatal forms of the antigen contained an unusually high proportion of sialic acid, which decreased during development. Methylation analysis of native and neuraminidase treated glycopeptides indicated that the sialic acid occurred as alpha 2-8 bound polysialosyl units, similar to those of the recently described developmentally regulated polysialosyl glycopeptides of rat brain.

Molecular heterogeneity and structural evolution during cerebellar ontogeny detected by monoclonal antibody of the mouse cell surface antigen BSP-2.

The monoclonal antibody anti-BSP-2 defines a set of glycoproteins present on the neuronal cell surface in dissociated mouse cerebellar cultures and on neurons and astrocytes in sections of the mouse cerebellum. This antibody was used in the present study to characterize the antigens recognized in cerebellar cultures and in the developing and adult mouse cerebellum in vivo. In extracts from cerebellar cultures and from late postnatal or adult cerebellum, the anti-BSP-2 antibody reacted with a triplet of glycosylated polypeptide chains of 180,000, 140,000 and 120,000 mol.

Tissue- and developmental stage-specific forms of a neural cell surface antigen linked to differences in glycosylation of a common polypeptide.

We have previously identified a cell surface glycoprotein of the mouse nervous system named brain cell surface protein-2 (BSP-2). Here we report that this antigen is not a single, discrete entity, but a family of antigenically and structurally related molecules. Three components of 180, 140, and 120 K were characteristic for more mature nervous tissues.

A new brain cell surface glycoprotein identified by monoclonal antibody.

Of 207 monoclonal antibodies produced against cultured mouse cerebellar cells, 16 reacted with cerebellar cell surfaces and 4 reacted with glycoproteins. One of them, called an anti-BSP-3 (Brain cell Surface Protein-3) defines a 48,000 molecular weight protein which can be iodinated at the surface of cultured cerebellar cells. Lectin-binding and sugar incorporation studies established the glycoprotein nature of the antigen.

Monoclonal antibody against cell surface glycoprotein of neurons.

A monoclonal antibody, named BSP-2, has been produced against glycoproteins extracted from neonatal mouse brain. Its reactivity with live cells established the surface location of the antigen. In primary cultures of dissociated cerebellar cells, the antibody bound to neuronal cell types, but not to astrocytes nor to fibroblasts.