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Expression and release of phosphatidylinositol anchored cell surface molecules by a cell line derived from sensory neurons
No full textF3 neuronal adhesion molecule controls outgrowth and fasciculation of cerebellar granule cell neurites: A cell-type-specific effect mediated by the Ig-like domains
No full textF3 is a glycane phosphatidylinositol-anchored neuronal adhesion glycoprotein which consists of immunoglobulin (Ig) domains and fibronectin type III repeats. Here we showed that total F3 or F3-Ig domains when presented as membrane components of CHO transfected cells influenced growth cone morphology, strongly inhibited outgrowth, and induced fasciculation of cerebellar granule cell axons. An F3-Ig-Fc chimera induced neurite fasciculation from cerebellar neuron aggregates when used as a coated substrate but not in the soluble form. The F3 effect on neurite elongation is highly specific for neuronal cell types since under the same experimental conditions it did not modify neurite outgrowth of hippocampal neurons and was shown to stimulate elongation of neurites from sensory neurons in both membrane-anchored and soluble form. Our results provide evidence to extend the proposed role of F3 and strongly suggest that axonal-growth-controlling molecules may quite generally exert dual actions which are likely to depend on the receptor repertoire of the responding neuron
Different domains of the F3 neuronal adhesion molecule are involved in adhesion and neurite outgrowth promotion
No full textThe mouse F3 cell surface protein is preferentially expressed on axons of subpopulations of neurons and is anchored to the membrane by a glycosyl-phosphatidylinositol group. It consists of six immunoglobulin-like domains and four fibronectin type III homologous repeats, and can be found both in membrane-anchored and soluble forms. We have previously established that F3 fulfils the operational criteria of a cell adhesion molecule when anchored to the plasma membrane and that its soluble form stimulates neurite initiation and neurite outgrowth. To further characterize F3-mediated adhesion and to investigate whether adhesion and neurite outgrowth promoting activities are displayed by different parts of the molecule, we (i) selected F3 transfected CHO cells expressing increasing levels of F3 at their surface and (ii) prepared transfectants expressing an F3 molecule with its fibronectin type III repeats deleted. We show that the F3 molecule mediates divalent-cation-independent, temperature-dependent binding. The levels of aggregation of F3 transfectants are proportional to the level of F3 expression. Transfectants expressing F3 deleted of the fibronectin type III repeats lose their adhesive properties; conversely, cells expressing wild-type F3 and treated with collagenase, specifically removing the immunoglobulin-like domains, are still able to aggregate. Therefore, in this model adhesion site(s) mapped to the fibronectin type III repeats. By contrast, transfectants expressing deleted F3, as well as the soluble forms of this F3 deleted molecule, were able to stimulate neurite outgrowth of sensory neurons similarly to wild-type F3. Our data indicate that F3 is a multifunctional molecule and that adhesion and neurite outgrowth promoting properties are expressed by distinct and independent domains
Transfected F3/F11 neuronal glycoprotein mediates cell adhesion and promotes neurite outgrowth
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The F3 cell adhesion molecule modulates neurite outgrowth and fasciculation. A cell-type specific effect
No full textDifferent domains of the F3 neuronal adhesion molecule are involved in adhesion and neurite outgrowth promotion.
No full textF3/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
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