UNIPROT:P06889 - FACTA Search

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Query: UNIPROT:P06889 (Mol)
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Axonin-1 is a glycoprotein that is released from axons of cultured neurons (Stoeckli, E. T., P. F. Lemkin, T. B. Kuhn, M. A. Ruegg, M. Heller, and P. Sonderegger. 1989. Eur. J. Biochem. 180:249-258). It has recently been purified from the ocular vitreous fluid of the chicken embryo (Ruegg, M. A., E. T. Stoeckli, T. B. Kuhn, M. Heller, R. Zuellig, and P. Sonderegger. 1989. EMBO (Eur. Mol. Biol. Organ.) J. 8:55-63). Immunohistochemistry localized axonin-1 prevalently in developing nerve fiber tracts. The presence of anti-axonin-1 Fab fragments during axon growth in vitro resulted in antibody binding to the axonal surfaces and in a marked perturbation of the fasciculation pattern. Hence, a fraction of axonin-1 is associated with axonal membranes and, by operational criteria, qualifies as a cell adhesion molecule. The major proportion of membrane-associated axonin-1 co-solubilized with the integral membrane proteins. By physico-chemical, immunological, and protein-chemical criteria, the integral membrane form was found to be highly similar to soluble axonin-1. In common with a number of other cell adhesion molecules, both soluble and membrane-bound axonin-1 express the L2/HNK-1 and the L3 epitopes. Radioactive pulse-chase and double-labeling experiments revealed that the released form was not derived from the membrane-bound form by shedding from the membrane surface, but directly secreted from an intracellular pool. Due to its high degree of similarity to the membrane-associated form and the presence of the L2/HNK-1 and L3 epitopes, reported to be ligands in adhesive cell interactions, adhesive properties are postulated for secreted axonin-1. As a soluble adhesive protein, it may function as a regulator of cell adhesion around its most likely site of secretion, the growth cone.
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PMID:A homologue of the axonally secreted protein axonin-1 is an integral membrane protein of nerve fiber tracts involved in neurite fasciculation. 250 84

Lectin affinity chromatography combined with mAb production was used to identify chick neural cell surface molecules related to L1 antigen, a mouse neural glycoprotein implicated in cell-cell adhesion (Rathjen, F. G., and M. Schachner, 1984, EMBO (Eur. Mol. Biol. Organ.) J., 3:1-10). A glycoprotein, G4 antigen, isolated by mAb G4 from adult chick brain is described which comprises a major 135-kD component, a minor doublet at 190 kD, and diffusely migrating bands at 80 and 65 kD in SDS PAGE. This molecule is structurally related to mouse L1 antigen according to NH2-terminal amino acid sequence (50% identity) as well as the behavior of its components in two-dimensional IEF/SDS PAGE gels. A second chicken glycoprotein, F11 antigen, was isolated from adult chick brain using mAb F11. This protein has also a major 135-kD component and minor components at 170 kD and 120 kD. Both immunotransfer analysis with polyclonal antibodies to mAb G4 and to mAb F11 isolate and the behavior on IEF/SDS PAGE gels indicates that the major 135-kD component of F11 antigen is distinct from G4 antigen components. However, the 135-kD component of F11 antigen shares with G4 antigen and the neural cell adhesion molecule (NCAM) the HNK-1/L2 carbohydrate epitope. In immunofluorescence studies, G4 and F11 antigenic sites were found to be associated mainly with the surface of process-bearing cells, particularly in fiber-rich regions of embryonic brain. Although Fab fragments of polyclonal antibodies to mAbs G4 or F11 immunoaffinity isolate only weakly inhibit the Ca2+-independent aggregation of neural cells, they strongly inhibit fasciculation of retinal axons. Together these studies extend the evidence that bundling of axons reflects the combined effects of a group of distinct cell surface glycoproteins.
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PMID:Membrane glycoproteins involved in neurite fasciculation. 380 23

The question of how the cell surface molecules may be specifically delivered to subdomains of neurons is of particular interest considering that polarized sorting to the axon could enable adhesion glycoproteins to induce fasciculation of axonal tracts, guidance to the target cell, and the establishment of synaptic contacts. It was recently proposed that GPI-anchored molecules undergo preferential delivery to the axonal surface, implicating a similar polarized sorting of glycoproteins in neurons and epithelial cells (Dotti and Simons, 1990; Dotti et al., 1991). This review focuses on the cellular and subcellular localization of several glypiated adhesion molecules (Thy-1, TAG-1, F3/F11, P-31) in the developing and adult cerebellar cortex of the mouse. We conclude that the cellular distribution of GPI-anchored adhesion molecules within neurons is very complex and depends on: 1. The neuronal cell types, for example, F3/F11 is localized in axons in granule cells but is present in all compartments of Golgi cells. 2. The molecule itself: Thy-1, TAG-1, and P-31 are present on the granule cell body, whereas at the same developmental stage, F3/F11 is restricted to the axon. 3. The differentiation state: Thy-1 delivery to the axon correlates with postsynaptic target maturation.
Mol Neurobiol 1993
PMID:Are the glypiated adhesion molecules preferentially targeted to the axonal compartment? 810 Apr 20

The development of the nervous system in insects, as in most other higher animals, is characterized by the high degree of precision and specificity with which synaptic connectivity is established. Multiple molecular mechanisms are involved in this process. In insects a number of experimental methods and model systems can be used to analyze these mechanisms, and the modular organization of the insect nervous system facilitates this analysis considerably. Well characterized molecular elements involved in axogenesis are the cell-cell adhesion molecules that underlie selective fasciculation. These are cell-surface molecules that are expressed in a regional and dynamic manner on developing axon fascicles. Secreted molecules also appear to be involved in directing axonal navigation. Nonneuronal cells, such as glia, provide cellular and noncellular substrates that are important pathway cues for neuronal outgrowth. Once outgrowing processes reach their general target regions they make synapses with the appropriate postsynaptic cells. The molecular mechanisms that allow growth cones to recognize their correct target cells are essential for neuronal specificity and are being analyzed in neuromuscular and brain interneuron systems of insects. Candidate synaptic recognition molecules with remarkable and highly restricted expression patterns in the developing nervous system have recently been discovered.
Mol Neurobiol
PMID:Molecular correlates of neuronal specificity in the developing insect nervous system. 817 43

In the peripheral nervous system, neurons derived from specific rostrocaudal levels of the neuraxis selectively synapse on targets that arise from corresponding body positions. To identify molecules involved in such position-dependent connectivity, we used subtractive hybridization to isolate genes selectively expressed in rostral or caudal skeletal muscle. One mRNA that was more abundant in neck than in hindlimb muscles encoded the mouse ortholog of human AL-1 and chick RAGS, membrane-associated ligands of Eph tyrosine kinases that have recently been implicated in cortical axon fasciculation and retinotectal connectivity, respectively. We show here that mouse AL-1 is expressed in discrete regions of the central and peripheral nervous systems and in a subset of developing skeletal muscles. The abundance of AL-1 RNA in immortalized myogenic cell lines derived from rostral muscles is higher than in caudally derived lines, suggesting that levels are heritably maintained. Growth of neurites from cultured sensory ganglia and spinal cords is specifically inhibited by cells expressing AL-1, suggesting that this molecule could serve to guide peripheral axons. The inhibitory effects of AL-1 are position dependent, such that axons derived from caudal (lumbar) ganglia are more affected than those derived from rostral (cervical) ganglia. Together, these results support the notion that Eph kinases and their ligands regulate topographically appropriate neural connectivity in the peripheral nervous system, as well as in the central nervous system.
Mol Cell Neurosci 1996
PMID:The Eph kinase ligand AL-1 is expressed by rostral muscles and inhibits outgrowth from caudal neurons. 891 34

The Eph family of receptor tyrosine kinases and their cell surface bound ligands have been implicated in a number of developmental processes, including axon pathfinding and fasciculation, as well as patterning in the central nervous system. To better understand the complex signaling events taking place, we have undertaken a comparative analysis of ligand-receptor interactions between a subset of ligands, those that are tethered to the cell surface via a transmembrane domain, and a subset of Eph receptors, the so-called Elk subclass. Based on binding characteristics, receptor autophosphorylation, and cellular transformation assays, we find that the transmembrane-type ligands Lerk2 and Elf2 have common and specific receptors within the Elk subclass of receptors. The common receptors Cek10 and Elk bind and signal in response to Lerk2 and Elf2, whereas the Myk1 receptor is specific for Elf2. Elf2, however, fails to signal through Cek5 in a cellular transformation assay, suggesting that Lerk2 may be the preferred Cek5 ligand in vivo. A recently identified third transmembrane-type ligand, Elf3, specifically, but weakly, binds Cek10 and only induces focus formation when activated by C-terminal truncation. This suggests that the physiological Elf3 receptor may have yet to be identified. Knowledge regarding functional ligand-receptor interactions as presented in this study will be important for the design and interpretation of in vivo experiments, e.g., loss-of-function studies in transgenic mice.
Mol Cell Neurosci 1996
PMID:Similarities and differences in the way transmembrane-type ligands interact with the Elk subclass of Eph receptors. 891 35

F3 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.
Mol Cell Neurosci 1996
PMID:F3 neuronal adhesion molecule controls outgrowth and fasciculation of cerebellar granule cell neurites: a cell-type-specific effect mediated by the Ig-like domains. 892 55

In the peripheral nervous system, neurons derived from specific rostrocaudal levels of the neuraxis selectively synapse on targets that arise from corresponding body positions. To identify molecules involved in such position-dependent connectivity, we used subtractive hybridization to isolate genes selectively expressed in rostral or caudal skeletal muscle. One mRNA that was more abundant in neck than in hindlimb muscles encoded the mouse ortholog of human AL-1 and chick RAGS, membrane-associated ligands of Eph tyrosine kinases that have recently been implicated in cortical axon fasciculation and retinotectal connectivity, respectively. We show here that mouse AL-1 is expressed in discrete regions of the central and peripheral nervous systems and in a subset of developing skeletal muscles. The abundance of AL-1 RNA in immortalized myogenic cell lines derived from rostral muscles is higher than in caudally derived lines, suggesting that levels are heritably maintained. Growth of neurites from cultured sensory ganglia and spinal cords is specifically inhibited by cells expressing AL-1, suggesting that this molecule could serve to guide peripheral axons. The inhibitory effects of AL-1 are position dependent, such that axons derived from caudal (lumbar) ganglia are more affected than those derived from rostral (cervical) ganglia. Together, these results support the notion that Eph kinases and their ligands regulate topographically appropriate neural connectivity in the peripheral nervous system, as well as in the central nervous system.
Mol Cell Neurosci 1996 Aug
PMID:The Eph Kinase Ligand AL-1 Is Expressed by Rostral Muscles and Inhibits Outgrowth from Caudal Neurons 895 32

The Eph family of receptor tyrosine kinases and their cell surface bound ligands have been implicated in a number of developmental processes, including axon pathfinding and fasciculation, as well as patterning in the central nervous system. To better understand the complex signaling events taking place, we have undertaken a comparative analysis of ligand-receptor interactions between a subset of ligands, those that are tethered to the cell surface via a transmembrane domain, and a subset of Eph receptors, the so-called Elk subclass. Based on binding characteristics, receptor autophosphorylation, and cellular transformation assays, we find that the transmembrane-type ligands Lerk2 and Elf2 have common and specific receptors within the Elk subclass of receptors. The common receptors Cek10 and Elk bind and signal in response to Lerk2 and Elf2, whereas the Myk1 receptor is specific for Elf2. Elf2, however, fails to signal through Cek5 in a cellular transformation assay, suggesting that Lerk2 may be the preferred Cek5 ligand in vivo. A recently identified third transmembrane-type ligand, Elf3, specifically, but weakly, binds Cek10 and only induces focus formation when activated by C-terminal truncation. This suggests that the physiological Elf3 receptor may have yet to be identified. Knowledge regarding functional ligand-receptor interactions as presented in this study will be important for the design and interpretation of in vivo experiments, e.g., loss-of-function studies in transgenic mice.
Mol Cell Neurosci 1996 Aug
PMID:Similarities and Differences in the Way Transmembrane-Type Ligands Interact with the Elk Subclass of Eph Receptors 895 33

The neural cell adhesion molecule L1 is a transmembrane glycoprotein of approximately 200 kDa molecular weight that is a member of the immunoglobulin super family. Multiple functions of L1 have been reported, including cell-cell interactions, neurite elongation, axonal fasciculation, cell migration, and myelination. L1 plays important roles in neural development and axonal regeneration in the peripheral nervous system (PNS), however, in the adult it is only present on neurons in the central nervous system (CNS). In the present study we have used defective herpes simplex virus (HSV) vectors to express full-length human or rat L1 in cultured primary rat cortical astrocytes. Rat cerebellar granule cells, a rather homogeneous population of neurons, co-cultured on a substrate layer of L1-expressing astrocytes demonstrated increased migration and neurite extension compared with neurons co-cultured on lacZ-expressing astrocytes of uninfected astrocytes. There was no detectable difference between human and rat L1. Because this vector system can be used to confer phenotypic changes in primary nervous system cells it will be useful for in vitro and in vivo studies of neural regenerative sprouting and plasticity in the CNS.
Brain Res Mol Brain Res 1996 Dec 31
PMID:Expression of L1 in primary astrocytes via a defective herpes simplex virus vector promotes neurite outgrowth and neural cell migration. 903 47

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