Astrotactin provides a receptor system for CNS neuronal migration

CNS neuronal migration is a specialized form of cell motility that sets forth the laminar structure of cortical regions of brain. To define the neuronal receptor systems in glial-guided neuronal migration, an in vitro assay was developed for mouse cerebellar granule neurons, which provides simultaneous tracking of hundreds of migrating neurons. Three general classes of receptor systems were analyzed, the neuron-glial adhesion ligand astrotactin, the neural cell adhesion molecules of the IgG superfamily, N-CAM, L1 and TAG-1, and the beta 1 subunit of the integrin family. In the absence of immune activities, migrating cerebellar granule neurons had an average in vitro migration rate of 12 microns h-1, with individual neurons exhibiting migration rates over a range between 0 to 70 microns h-1. The addition of anti-astrotactin antibodies (or Fabs) significantly reduced the mean rate of neuronal migration by sixty-one percent, resulting in eighty percent of the neurons having migration rates below 8 microns h-1. By contrast, blocking antibodies (or Fabs) against L1, N-CAM, TAG-1 or beta 1 integrin, individually or in combination, did not reduce the rate of neuronal migration. By video-enhanced contrast differential interference contrast microscopy the effects of anti-astrotactin antibodies were seen to be rapid. Within fifteen minutes of antibody application, streaming of cytoplasmic organelles into the leading process arrested, the nucleus shifted from a caudal to a central position, and the extension of filopodia and lamellopodia along the leading process ceased. Correlated video and electron microscopy suggested that the mechanism of arrest by antiastrotactin antibodies involved the failure to form new adhesion sites along the leading process and the disorganization of cytoskeletal components. These results suggest astrotactin acts as a neuronal receptor for granule neuron migration along astroglial fibers.     

Demonstration of immunochemical identity between the nerve growth factor-inducible large external (NILE) glycoprotein and the cell adhesion molecule L1.

The nerve growth factor-inducible large external (NILE) glycoprotein and the neural cell adhesion molecule L1 were shown to be immunochemically identical. Immunoprecipitation with L1 and NILE antibodies of [3H]fucose-labeled material from culture supernatants and detergent extracts of NGF-treated rat PC12 pheochromocytoma cells yielded comigrating bands by SDS-PAGE. NILE antibodies reacted with immunopurified L1 antigen, but not with N-CAM and other L2 epitope-bearing glycoproteins from adult mouse brain. Finally, by sequential immunoprecipitation from detergent extracts of [35S]methionine-labeled early post-natal cerebellar cell cultures or [3H]fucose-labeled NGF-treated PC12 cells, all immunoreactivity for NILE antibody could be removed by pre-clearing with L1 antibody and vice versa.     

Weaver granule neurons are rescued by calcium channel antagonists and antibodies against a neurite outgrowth domain of the B2 chain of laminin

The weaver mutation impairs migration of the cerebellar granular neurons and induces neuronal death during the first two weeks of postnatal life. To elucidate the molecular mechanisms for the impaired neuronal migration, we investigated the rescue mechanisms of the weaver (wv/wv) granule neurons in vitro. We found that Fab2 fragments of antibodies against a neurite outgrowth domain of the B2 chain of laminin enhanced neurite outgrowth and neuronal migration of the weaver granule neurons on a laminin substratum and in the established cable culture system. The rescue of the weaver granule neurons by antibodies against the B2 chain of laminin may result from the neutralizing effect of these antibodies against the elevated B2 chain levels of the weaver brain. The L-type calcium channel blocker, verapamil (1-5 microM), also rescued the weaver granule neurons. High concentrations of MK-801 (10- 20 microM), a glutamate receptor antagonist and voltage-gated calcium channel blocker, rescued the weaver granule neurons similar to verapamil, but low concentrations of MK-801 (1 microM) had no rescue effect. Simultaneous patch-clamp studies indicated that the weaver granule neurons did not express functional N-methyl-D-aspartate receptors further indicating that the rescue of the weaver granule neurons by MK-801 resulted from its known inhibition of voltage-gated calcium channels. The present results indicate that antibodies against the B2 chain of laminin, verapamil, and high concentrations of MK-801 protect the weaver granule neurons from the otherwise destructive action of the weaver gene. Thus, both the laminin system and calcium channel function contribute to the migration deficiency of the weaver granule neurons.     

Immunoelectron microscopic localization of the neural cell adhesion molecules L1 and N-CAM during postnatal development of the mouse cerebellum

The cellular and subcellular localization of the neural cell adhesion molecules L1 and N-CAM was studied by pre- and postembedding immunoelectron microscopic labeling procedures in the developing mouse cerebellar cortex. The salient features of the study are: L1 displays a previously unrecognized restricted expression by particular neuronal cell types (i.e., it is expressed by granule cells but not by stellate and basket cells) and by particular subcellular compartments (i.e., it is expressed on axons but not on dendrites or cell bodies of Purkinje cells). L1 is always expressed on fasciculating axons and on postmitotic, premigratory, and migrating granule cells at sites of neuron-neuron contact, but never at contact sites between neuron and glia, thus strengthening the view that L1 is not involved in granule cell migration as a neuron-glia adhesion molecule. While N-CAM antibodies reacting with the three major components of N-CAM (180, 140, and 120 kD) show a rather uniform labeling of all cell types, antibodies to the 180-kD component (N-CAM180) stain only the postmigratory granule cell bodies supporting the notion that N-CAM180, the N-CAM component with the longest cytoplasmic domain, is not expressed before stable cell contacts are formed. Furthermore, N-CAM180 is only transiently expressed on Purkinje cell dendrites. N-CAM is present in synapses on both pre- and post-synaptic membranes. L1 is expressed only preterminally and not in the subsynaptic membranes. These observations indicate an exquisite degree of fine tuning in adhesion molecule expression during neural development and suggest a rich combinatorial repertoire in the specification of cell surface contacts.     

Intracellular localization of the P21rho proteins

We have surveyed the proteins expressed at the surface of different primary neurons as a first step in elucidating how axons regulate their ensheathment by glial cells. We characterized the surface proteins of dorsal root ganglion neurons, superior cervical ganglion neurons, and cerebellar granule cells which are myelinated, ensheathed but unmyelinated, and unensheathed, respectively. We found that the most abundant proteins are common to all three types of neurons. Reproducible differences in the composition of the integral membrane proteins (enriched by partitioning into a Triton X-114 detergent phase) were detected. These differences were most striking when the expression of glycosylphosphatidyl-inositol (GPI)-anchored membrane proteins by these different neurons was compared. Variations in the relative abundance and degree of glycosylation of several well known GPI-anchored proteins, including Thy-1, F3/F11, and the 120-kD form of the neural cell adhesion molecule (N-CAM), and an abundant 60-kD GPI-linked protein were observed. In addition, we have identified several potentially novel GPI-anchored glycoproteins on each class of neurons. These include a protein that is present only on superior cervical ganglion neurons and is 90 kD; an abundant protein of 69 kD that is essentially restricted in its expression to dorsal root ganglion neurons; and proteins of 38 and 31 kD that are expressed only on granule cell neurons. Finally, the relative abundance of the three major isoforms of N-CAM was found to vary significantly between these different primary neurons. These results are the first demonstration that nerve fibers with diverse ensheathment fates differ significantly in the composition of their surface proteins and suggest an important role for GPI-anchored proteins in generating diversity of the neuronal cell surface.     

Probable Identity of NILE Glycoprotein and the High-Molecular-Weight Component of L1 Antigen

We report here that anti-L1 antiserum, raised against material from embryonic brain, and anti-NILE antiserum, raised against purified NILE (nerve growth factor-inducible large external) glycoprotein of PC12 cells, immunoprecipitate from PC12 cells material of the same apparent molecular weight (230 kilodaltons) by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Furthermore, each of these immune reagents has the capacity to clear from a PC12 cell extract all of the 230-kilodalton antigen recognized by the other antiserum. Finally, in immunohistochemical staining of developing cerebellum the two antisera exhibit very similar staining patterns. We suggest that the NILE glycoprotein and the high-molecular-weight component of L1 antigen are closely related molecules, and probably the same.     

Progressive loss of neuronal src protein in postnatal weaver and staggerer cerebellum

Two forms of the c-src protein-tyrosine kinase, pp60c-src, are detectable in the central nervous system. One form pp60+, appears to be exclusively expressed in neurons and is characterized by insertion of 6 amino acids compared to its non-neuronal counterpart, pp60. These 2 proteins were studied in the mutant mouse strains weaver and staggerer with postnatal loss of cerebellar granular neurons. We found a continuous postnatal decline of the neuronal form of pp60c-src, pp60+, in the cerebellum of both mutants concomitant with the degeneration of cerebellar granule cells. This indicates that granular neurons provide the main source for pp60+ in the cerebellar cortex.     

The weaver gene encodes a nonautonomous signal for CNS neuronal differentiation.

In the neurological mutant mouse weaver, CNS precursor cells in the external germinal layer (EGL) of the cerebellar cortex proliferate normally, but fail to differentiate and die in the proliferative zone. To examine the autonomy of expression of the weaver gene, we carried out cell-mixing experiments in vitro. In homotypic, reaggregate cultures, weaver EGL precursor cells expressed the general neuronal markers N-CAM, L1, and MAP2, but failed to express the late neuronal antigens TAG-1 and astrotactin, to extend neurites or to migrate on glial fibers. After reaggregation with wild-type EGL precursor cells, weaver precursor cells extended neurites equivalent in length to wild-type cells, migrated along astroglial fibers, and expressed TAG-1 and astrotactin. Rescue of neurite production was also achieved by the addition of membranes from, but not by medium conditioned by wild-type cells. These findings suggest that the weaver gene acts non-autonomously, encoding a membrane-associated ligand that induces EGL neuronal differentiation.     

Two forms of cerebellar glial cells interact differently with neurons in vitro

Specific interactions between neurons and glia dissociated from early postnatal mouse cerebellar tissue were studied in vitro by indirect immunocytochemical staining with antisera raised against purified glial filament protein, galactocerebroside, and the NILE glycoprotein. Two forms of cells were stained with antisera raised against purified glial filament protein. The first, characterized by a cell body 9 microns diam and processes 130-150 microns long, usually had two to three neurons associated with them and resembled Bergmann glia. The second had a slightly larger cell body with markedly shorter arms among which were nestled several dozen neuronal cells, and resembled astrocytes of the granular layer. Staining with monoclonal antisera raised against purified galactocerebroside revealed the presence of immature oligodendroglia in the cultures. These glial cells constituted approximately 2% of the total cell population in the cultures and, in contrast to astroglia, did not form specific contacts with neurons. Staining with two neuronal markers, antisera raised against purified NILE glycoprotein and tetanus toxin, revealed that most cells associated with presumed astroglia were small neurons (5-8 microns). After 1-2 d in culture, some stained neurons had very fine, short processes. Nearly all of the processes greater than 10-20 micron long were glial in origin. Electron microscopy also demonstrated the presence of two forms of astroglia in the cultures, each with a different organizing influence on cerebellar neurons. Most neurons associated with astroglia were granule neurons, although a few larger neurons sometimes associated with them. Time-lapse video microscopy revealed extensive cell migration (approximately 10 microns/h) along the arms of Bergmann-like astroglia. In contrast, cells did not migrate along the arms of astrocyte-like astroglia, but remained stationary at or near branch points. Growth cone activity, pulsating movements of cell perikarya, and ruffling of the membranes of glial and neuronal processes were also seen.     

Antibodies that recognize astrotactin block granule neuron binding to astroglia

To provide a rapid, specific assay for receptor systems involved in the binding of cerebellar granule neurons to astroglia, granule cells, purified from early postnatal mice, or from E15-E16 chicks, were radiolabeled with [35S]methionine and plasma membranes were prepared. The kinetics of binding of radiolabeled material to primary mouse or chick glia or to the mouse G26-24 astrocytoma cell line was measured in the presence or absence of antibodies against astrotactin, neural cell adhesion molecules, cadherins, or integrins. Addition of Fab fragments of astrotactin antibodies reduced the amount of granule cell membrane binding to astroglia by 70%. In contrast, Fab fragments of antibodies against the neural adhesion molecules N-CAM, L1, and N-cadherin and against integrin did not reduce the level of granule cell membrane binding to astroglia. Combinations of antibodies against N-CAM, L1, N-cadherin, and integrin also did not impair neuron binding to glia.     

Development and expression of cytoplasmic antigens in Purkinje cells recognized by monoclonal antibodies

Summary Five monoclonal antibodies reacting with intracellular constituents of Purkinje cells were investigated by means of indirect immunofluorescence on fresh-frozen sections of the cerebellum and retina from developing and adult normal and mutant mice. Antibodies PC1, PC2 and PC3, which recognize Purkinje cells, but no other cerebellar neuron type, label these cells from day 4 onward. PC4 antigen is expressed in addition to Purkinje cells also in granule cells and neurons of deep cerebellar nuclei and appears in Purkinje cells at day 4. M1 antigen (Lagenaur et al. 1980) is first detectable in Purkinje cell bodies by day 5; it is also detectable in deep cerebellar neurons. In the adult retina, only PC4 antigen is detectably expressed and is localized in the inner segments of photoreceptor cells.The neurological mutants weaver, reeler,jimpy and wobbler show detectable levels of these antigens in Purkinje cells. However, the mutants staggerer and Purkinje cell degeneration are abnormal in expression PC1, PC2, PC3, and M1 antigens. Staggerer never starts to express the antigens during development, whereas Purkinje cell degeneration first expresses the antigens, but then loses antigen expression after day 23. PC4 antigen is detectable in the remaining Purkinje cells in staggerer and Purkinje cell degeneration mice at all ages tested in this study. Deep cerebellar neurons are positive for both antigens, PC4 and M1, in all mutants and at all ages studied. In retinas of staggerer and Purkinje cell degeneration mutants, PC4 antigen is normally detectable in the inner segments of photoreceptor cells, even when these have started to degenerate in the case of Purkinje cell degeneration.     

ATP-Dependent Glutamate Uptake into Synaptic Vesicles from Cerebellar Mutant Mice

The ATP-dependent glutamate uptake system in synaptic vesicles prepared from mouse cerebellum was characterized, and the levels of glutamate uptake were investigated in the cerebellar mutant mice, staggerer and weaver, whose main defect is the loss of cerebellar granule cells, and the nervous mutant, whose main defect is the loss of Purkinje cells. The ATP-dependent glutamate uptake is stimulated by low concentrations of chloride, is insensitive to aspartate, and is inhibited by agents known to dissipate the electrochemical proton gradient. These properties are similar to those of the glutamate uptake system observed in the highly purified synaptic vesicles prepared from bovine cortex. The ATP-dependent glutamate uptake system is reduced by 68% in the staggerer and 57-67% in the weaver mutant; these reductions parallel the substantial loss of granule cells in those mutants. In contrast, the cerebellar levels of glutamate uptake are not altered significantly in the nervous mutant, which has lost Purkinje cells, but not granule cells. In view of evidence that granule cells are glutamatergic neurons and Purkinje cells are GABAergic neurons, these observations support the notion that the ATP-dependent glutamate uptake system is present in synaptic vesicles of glutamatergic neurons.     

Inhibition of caspases protects cerebellar granule cells of the weaver mouse from apoptosis and improves behavioral phenotype

The homozygous mouse mutant weaver exhibits a massive loss of cerebellar granule neurons postnatally. The death of these cells is associated with a single amino acid mutation in the G protein-activated inwardly rectifying potassium channel, Girk2. Evidence suggests that both the mutated Girk2 channel and the calcium channel-associated N-methyl-d-aspartate receptor play important roles in the apoptotic death of weaver cerebellar granule cells, but the downstream events associated with this process are unknown. In this study, we demonstrate that the consequences of the mutation result in caspase activation. In addition, our results show that caspase inhibition in vivo decreases caspase activation and granule cell apoptosis and significantly improves behavioral deficits associated with the weaver's phenotype.     

Nerve growth factor enhances expression of neuron-glia cell adhesion molecule in PC12 cells

The neuron-glia cell adhesion molecule (Ng-CAM) has been identified in mammalian brain tissue and PC12 pheochromocytoma cells as Mr 200,000 and Mr 230,000 species, respectively. When PC12 cells were treated with nerve growth factor (NGF), the amount of Ng-CAM at the cell surface was increased approximately threefold, whereas the amount of the neural cell adhesion molecule (N-CAM) remained unchanged. An NGF-inducible large external glycoprotein (NILE) has been previously identified by its enhanced expression in NGF-treated PC12 cells. Ng-CAM and NILE are similar in molecular weight, expression during development, and responsiveness to NGF in PC12 cells, suggesting that the two molecules are related. In addition, antibodies to Ng-CAM and NILE cross-reacted and the molecules had similar peptide maps after limited proteolysis. Moreover, antibodies to Ng-CAM inhibited fasciculation of neurites, a functional property shared with NILE. The results show that cell adhesion molecules can respond selectively to growth factors and suggest that NILE is, in fact, mammalian Ng-CAM.     

Glutamic acid: A strong candidate as the neurotransmitter of the cerebellar granule cell

Free amino acids and cholinergic enzymes were investigated in the cerebellum of reeler and weaver mice in an attempt to identify the neurotransmitter characteristic of the granule cell population and to clarify any neurotransmitter abnormalities of their pre- and postsynaptic neurons induced by their depletion. The data indicate that glutamic acid may be the neurotransmitter of the granule cells. Pre- and postsynaptic neurotransmitter activity seemed not to be markedly altered in cerebellar granule cell dysgenesis.     

Neuronal inhibition of astroglial cell proliferation is membrane mediated

Previously we have used a microwell tissue culture assay to show that early postnatal mouse cerebellar astroglia have a flattened morphology and proliferate rapidly when they are cultured in the absence of neurons, but develop specific cell-cell contacts and undergo morphological differentiation when they are co-cultured with purified granule neurons (Hatten, M. E., 1985, J. Cell Biol., 100:384-396). In these studies of cell binding between neurons and astroglia, measurement with light and fluorescence microscopy or with [35S]methionine-labeled cells indicated that the kinetics of the binding of the neurons to astroglial cells are rapid, occurring within 10 min of the addition of the neurons to the growing glia. 6 h after neuronal attachment, astroglial DNA synthesis decreases, as shown by a two- to fivefold decrease in [3H]thymidine incorporation, and glial growth ceases. No effects on astroglial cell growth were seen after adding medium conditioned by purified cerebellar neurons cultured in the absence of astroglia, by astroglia cultured in the absence of neurons, or by a mixed population of cerebellar cells. This result was unchanged when any of these media were concentrated up to 50-fold, or when neurons and astroglia were cultured in separate chambers with confluent medium. Two groups of experiments suggest that membrane-membrane interactions between granule neurons and astroglia control astroglial cell growth. First, neurons fixed with dilute amounts of paraformaldehyde (0.5%) bound to the astroglia with the same kinetics as did living cells, inhibited DNA synthesis, and arrested glial growth within hours. Second, a cell membrane preparation of highly purified granule neurons also bound rapidly to the glia, decreased [3H]thymidine incorporation two- to fivefold and inhibited astroglial cell growth. The rate of the decrease in glial growth depended on the concentration of the granule neural membrane preparation added. A similar membrane preparation from purified cerebellar astroglial cells, PC12 cells, 3T3 mouse fibroblasts, or PTK rat epithelial cells did not decrease astroglial cell growth rates. Living neurons were the only preparation that both inhibited glial DNA synthesis and induced the astroglial cells to transform from the flat, epithelial shapes they have when they are cultured without neurons to highly differentiated forms that resemble Bergmann glia or astrocytes seen in vivo. These results suggest that membrane-membrane interactions between neurons and astroglia inhibit astroglial proliferation in vitro, and raise the possibility that membrane elements involved in glial growth regulation include neuron-glial interaction molecules.     

Neurotrophin-3 induced by tri-iodothyronine in cerebellar granule cells promotes Purkinje cell differentiation [published erratum appears in J Cell Biol 1998 Dec 28;143(7):following 2090]

Thyroid hormones play an important role in brain development, but the mechanism(s) by which triiodothyronine (T3) mediates neuronal differentiation is poorly understood. Here we demonstrate that T3 regulates the neurotrophic factor, neurotrophin-3 (NT-3), in developing rat cerebellar granule cells both in cell culture and in vivo. In situ hybridization experiments showed that developing Purkinje cells do not express NT-3 mRNA but do express trkC, the putative neuronal receptor for NT-3. Addition of recombinant NT-3 to cerebellar cultures from embryonic rat brain induces hypertrophy and neurite sprouting of Purkinje cells, and upregulates the mRNA encoding the calcium-binding protein, calbindin-28 kD. The present study demonstrates a novel interaction between cerebellar granule neurons and developing Purkinje cells in which NT-3 induced by T3 in the granule cells promotes Purkinje cell differentiation.     

Cerebellar plasma membrane proteins and their antisera

Plasma membranes have been isolated from neonatal through adult cerebella by a sequence of differential centrifugation, aqueous two-phase polymer fractionation and density gradient centrifugation. The protein composition of cerebellar membranes from various aged mice was compared by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis (PAGE). Increases in the relative amount of membrane proteins with molecular weights (X 10(-3)) of 400, 340, 270, 220, 54, 44, and 9.5 were most pronounced, while a protein of 66,000 Mr disappeared between birth and Day 25. The relationship of these proteins and others to specific cell types in the cerebellum was examined by preparing membrane fractions from isolated granule and Purkinje cells, as well as from the cerebella of neurological mutant mice: reeler, weaver, staggerer, and nervous. In addition, those membrane proteins on the surface of dissociated cerebellar cells were identified by lactoperoxidase-catalyzed iodination, while glycoproteins were identified by galactose oxidase treatment and NaB3H4 reduction. Rabbit antisera were prepared toward those SDS-PAGE membrane proteins which appeared cell specific or developmentally regulated. Sera from these rabbits were used with indirect immunoperoxidase and immunofluorescence to stain frozen sections of mouse cerebellum and dissociated cerebellar cell cultures. In tissue sections antiserum toward the 400,000 Mr protein (p400) and antiserum p14.7 gave strong reactions with Purkinje cells while anti-p130 reacted preferentially with Purkinje cell somas, anti-p220 stained small cells in the internal granule layer and anti-p30 displayed a coarse, grainy staining of the granule and molecular layers, characteristic of a synaptic localization. Only anti-p220 and anti-p130 bound to freshly dissociated cells or cultured cerebellar cells. Large phase-bright cells in the cultures bound antiserum p130. Anti-p220 reacted specifically with a subpopulation of small round viable cells that bound tetanus toxin and decreased in number from 9% at Day 3 to 0.5% of the cells by Day 11, suggestive of granule neurons.     

Role of Cdc42 in neurite outgrowth of PC12 cells and cerebellar granule neurons

Inactivation of Rho GTPases inhibited the neurite outgrowth of PC12 cells. The role of Cdc42 in neurite outgrowth was then studied by selective inhibition of Cdc42 signals. Overexpression of ACK42, Cdc42 binding domain of ACK-1, inhibited NGF-induced neurite outgrowth in PC12 cells. ACK42 also inhibited the neurite outgrowth of PC12 cells induced by constitutively activated mutant of Cdc42, but not Rac. These results suggest that Cdc42 plays an important role in mediating NGF-induced neurite outgrowth of PC12 cells. Inhibition of neurite outgrowth was also demonstrated using a cell permeable chimeric protein, penetratin-ACK42. A dominant negative mutant of Rac, RacN17 inhibited Cdc42-induced neurite outgrowth of PC12 cells suggesting that Rac acts downstream of Cdc42. Further studies, using primary-cultures of rat cerebellar granule neurons, showed that Cdc42 is also involved in the neurite outgrowth of cerebellar granule neurons. Both penetratin-ACK42 and Clostridium difficile toxin B, which inactivates all members of Rho GTPases strongly inhibited the neurite outgrowth of cerebellar granule neurons. These results show that Cdc42 plays a similar and essential role in the development of neurite outgrowth of PC12 cells and cerebellar granule neurons. These results provide evidence that Cdc42 produces signals that are essential for the neurite outgrowth of PC12 cells and cerebellar granule neurons. These authors contributed equally