1,721,016 research outputs found
The F3/11 cell adhesion molecule mediates the repulsion of neurons by the extracellular matrix glycoprotein J1-160/180
No full textStudies 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
No full textTransfected F3/F11 neuronal glycoprotein mediates cell adhesion and promotes neurite outgrowth
No full textCharacterization of the 5’ and promoter region of the gene encoding the mouse neuronal cell adhesion molecule F3
No full textCharacterization of the 5’ and promoter region of the gene encoding the mouse neuronal cell adhesion molecule F3
No full textF3 is a 135 kDa neuronal cell surface adhesive glycoprotein belonging to the immunoglobulin supergene family (IgSF) which mediates heterophilic contact formation among neural cells and is involved in the control of neurite growth. F3 expression is regulated, during critical developmental periods, on neuronal subpopulations thus suggesting that control of F3 gene expression could be of morphogenetic relevance. To shed light on the mechanism involved in the control of F3 gene expression we isolated clones covering about 50 kilobases of the F3 gene which also included the promoter region. The study of F3 gene exon/intron organization revealed that, like other neural IgSF molecules, each of the first two F3 C2 domains is encoded by two exons while the N-terminus, the signal peptide and the 5' untranslated region are each encoded by distinct exons. A single transcription start site was identified, surrounded by a short 114 bp sequence able to direct reporter gene expression in both F3-expressing and -non-expressing cells. In addition, a cell type-specific enhancer, only active in F3-expressing cells, was found immediately upstream to it. structural analysis of the promoter region revealed consensus sequences for binding transcription factors involved in cell type-specific and/or developmental regulations. Most of them are homeobox containing transcription factors thus suggesting that regulation of F3 gene expression could be part of a large developmental program
F3/F11 cell surface molecule expression in the developing mouse cerebellum is polarized at synaptic sites and within granule cells
No full textThe distribution of the F3/F11 neuronal cell surface molecule was investigated in the developing and adult mouse cerebellum by immunocytochemistry at the light and electron microscopic levels. F3/F11 was confined to subsets of neuronal types, since the Purkinje cell body and dendritic arborization as well as the stellate cells were not immunoreactive. In the young developing cerebellum, the granule cell axons strongly express F3/F11 as soon as they begin to grow, consistent with a functional role in promoting directional outgrowth of neuronal processes. In 10-d-old and adult cerebella, the granule cell bodies and dendrites were not immunoreactive whereas the parallel fibers, which are the granule cell axons, were labeled including in their presynaptic varicosities. By contrast, dendrites, cell bodies, and axons of Golgi cells were labeled by anti-F3 antibodies. Hence, F3/F11 can either be expressed throughout the cell or be polarized to the axons. This raises the question of how segregation of the glypiated F3/F11 molecule between different subcellular compartments depending on the type of neuron is achieved. F3/F11 was found to be present at three types of synaptic sites, suggesting that it might play a role in the formation and maintenance of synapses. However, in each type of synpase, F3/F11 was present at only the pre- or postsynaptic site, never at both: the parallel fiber varicosities contained F3/F11 whereas the postsynaptic compartment in contact, that is, the Purkinje cell dendritic spines, did not. The granule cell dendrites were unlabeled while the mossy fiber terminals contacting them were immunoreactive, and finally, the Golgi cell dendrites and dendritic spines were labeled while the presynaptic compartment contacting them was not. If F3/F11 functions as an adhesion molecule in vivo as indicated by in vitro assays, F3/F11-mediated adhesion is likely to be heterophilic.</jats:p
The mouse neuronal cell surface protein F3: a phosphatidylinositol anchored member of the immunoglobulin superfamily related to chicken Contactin
No full textF3:a new developmentally regulated member of HNK-1 family of neuronal cell adhesion molecules
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