Urs Rutishauser

Polysialic acid in the vertebrate nervous system: a promoter of plasticity in cell-cell interactions

Polysialic acid (PSA), a homopolymer attached to the neural cell adhesion molecule (NCAM), serves as a modulator of cell interactions. Polysialic acid exhibits a highly regulated expression pattern. During embryonic development its abundant expression is closely correlated with axon pathfinding and targeting, and with certain aspects of muscle formation. Its level also can be altered by synaptic activity. During neonatal development and in the adult brain, PSA expression is more restricted, being primarily associated with regions capable of morphological or physiological plasticity. The ability to perturb PSA in vivo by a specific glycosidase and by the creation of NCAM-deficient mice has led to extensive analysis of its biological function. These studies suggest that the primary role of PSA is to promote changes in cell interactions and thereby facilitate plasticity in the structure and function of the nervous system.

Genetic deletion of a neural cell adhesion molecule variant (N-CAM-180) produces distinct defects in the central nervous system

N-CAM is abundantly expressed in the nervous system in the form of numerous structural variants with characteristic distribution patterns and functional properties. N-CAM-180, the variant having the largest cytoplasmic domain, is expressed by all neurons. The N-CAM-180-specific exon 18 has been deleted to generate homozygous mice unable to express this N-CAM form. The most conspicuous mutant phenotype was in the olfactory bulb, where granule cells were both reduced in number and disorganized. In addition, precursors of these cells were found to be accumulated at their origin in the subependymal zone at the lateral ventricle. Analysis of the mutant in this region suggests that the mutant phenotype involves a defect in cell migration, possibly through specific loss of the polysialylated form of N-CAM-180, which is expressed in the migration pathway. Subtle but distinct abnormalities also were observed in other regions of the brain.

Polysialic acid in the plasticity of the developing and adult vertebrate nervous system

Polysialic acid (PSA) is a cell-surface glycan with an enormous hydrated volume that serves to modulate the distance between cells. This regulation has direct effects on several cellular mechanisms that underlie the formation of the vertebrate nervous system, most conspicuously in the migration and differentiation of progenitor cells and the growth and targeting of axons. PSA is also involved in a number of plasticity-related responses in the adult CNS, including changes in circadian and hormonal patterns, adaptations to pain and stress, and aspects of learning and memory. The ability of PSA to increase the plasticity of neural cells is being exploited to improve the repair of adult CNS tissue.

N-CAM mutation inhibits tangential neuronal migration and is phenocopied by enzymatic removal of polysialic acid

The mutation of N-CAM in mice produces a phenotype dominated by an undersized olfactory bulb and accumulation of precursors in the subependymal layer. We demonstrate here that this defect can be duplicated by injection of an enzyme that specifically destroys the polysialic acid (PSA) moiety associated with N-CAM. Studies of BrdU-labeled and pyknotic cells suggest that this defect reflects a decrease in the rostral migration of olfactory precursors and not a change in the proliferation or rate of death of these cells. In addition to their ectopic location, these cells had fewer growth cone-like processes oriented along the migration route. In contrast to tangential movement, radial migration of granule cells in the olfactory bulb was not affected by loss of PSA. These results support the proposed role for PSA in cell translocation, discriminate between different mechanisms of cell migration, and provide insight as to the nature of the N-CAM mutant phenotype.

Guidance of optic axons in vivo by a preformed adhesive pathway on neuroepithelial endfeet

Antibodies against the neural cell adhesion molecule (NCAM) were used in vivo both to localize NCAM antigenic determinants in developing tissues of the chicken visual system and to perturb cell-cell adhesion during growth of optic fibers to the tectum. The immunohistochemical studies revealed a staining pattern on neuroepithelial cells which coincided with certain regions of the presumptive route for optic axons, not only with respect to the overall pathway from the eye to the tectum, but also in the preferential distribution of the antigen on the marginal endfeet which are contacted by optic axon growth cones. The antibody-perturbation studies, which involved intraocular injection of anti-NCAM Fab at embryonic Day 3.5, demonstrated that inhibition of NCAM-mediated adhesion results in a dramatic distortion of growth cone-neuroepithelial cell relationships and consequently of the optic pathway. Together, these studies suggest that guidance of optic axons along the margin of the brain is at least in part influenced by a preformed adhesive pathway on neuroepithelial cells associated with NCAM antigens.

The Role of Polysialic Acid in Migration of Olfactory Bulb Interneuron Precursors in the Subventricular Zone

Transplantation studies have been used to show that tangential migration of olfactory bulb interneuron precursors is retarded in NCAM-mutant mice, and that this defect reflects loss of NCAM polysialic acid (PSA). In contrast, radial migration of cells within the bulb did not require PSA. Reciprocal transplantations between wild-type and mutant mice have revealed that the mutation affects the in vivo migration environment in the subventricular zone, and not movement of individual cells. However, in vitro migration of the cells into a PSA-negative collagen matrix environment was also PSA dependent. The surprisingly similar results obtained in the in vivo and in vitro environments is consistent with the observation that migration of subventricular cells occurs as streams of closely apposed cells in which the PSA-positive cells appear to serve as their own migration substrate.

Polysialic acid as a regulator of intramuscular nerve branching during embryonic development

The role of polysialic acid (PSA) during initial innervation of chick muscle was examined. Previously, the adhesion molecules L1 and N-CAM were shown to be important in balancing axon-axon and axon-muscle adhesion during this process. Here we demonstrate developmental changes in the pattern of innervation that are not correlated with levels of L1 or N-CAM expression, but rather with the amount of PSA at the axon surface. Removal of PSA by a specific endoneuraminidase (Endo-N) increased axon fasciculation and reduced nerve branching. In contrast, the nerve trunk defasciculation and increased branching produced by neuromuscular activity blockade were associated with an increase in axonal PSA levels. Furthermore, Endo-N prevented these inactivity-induced effects on branching. Together these results illustrate the potential of PSA as a regulator of cell-cell interactions and provide a direct example of a molecular link between the morphogenic effects of adhesion-mediated and synaptic activity-dependent processes.

Maturation of astrocytes in vitro alters the extent and molecular basis of neurite outgrowth.

In the developing mammalian central nervous system astrocytes have been proposed as an important substrate for axon growth. In the adult central nervous system following injury, astrocytes are a major component of the gliotic response which has been proposed to block axon growth. Experimental transplantation studies using cultured astrocytes have suggested that immature but not mature cultured astrocytes have the capacity to support axon outgrowth when transplanted into the adult rodent CNS. These observations suggest that astrocyte maturation is accompanied by changes in the functional capacity of these cells to support axon outgrowth. To determine whether this functional change reflects an intrisic astrocyte property, the extent and molecular bases of neurite outgrowth from embryonic rat cortical and chick retinal neurons on cultures of purified immature and mature astrocytes have been compared in vitro. The rate and extent of neurite outgrowth from both neuronal populations are consistently greater over the surface of immature than over the surface of mature astrocytes. Furthermore, antibodies to NCAM and G4/L1 significantly reduce neurite outgrowth on immature but not mature astrocytes, while antibodies to the integrin B1 receptor reduced outgrowth on both immature and, to a lesser extent, mature astrocytes. These results suggest that in vitro mature astrocytes have a reduced capacity and different molecular bases for supporting neurite outgrowth compared to immature astrocytes and are consistent with the proposal that functional changes during astrocyte maturation may partially contribute to regulating axon growth in the mammalian CNS.

Polysialic acid regulates growth cone behavior during sorting of motor axons in the plexus region

Removal of polysialic acid (PSA) from N-CAM during the time when chick motoneuron axons are segregating into target-specific fascicles at the base of the limb was previously shown to result in motoneuron projection errors. Here, it is established that these errors are associated with altered growth cone behavior in the plexus. In contrast to control embryos, in which individual axons were observed to exhibit dramatic changes in direction and extensive divergence, axonal trajectories following the removal of PSA were relatively straight. To determine whether enhanced axon-axon fasciculation following PSA removal had prevented growth cones from responding appropriately to guidance cues at the base of the limb, we also examined the role of L1, a major mediator of axon-axon fasciculation in this system. Anti-L1 reversed the effects of PSA removal on both growth cone trajectories and projection errors. These results indicate that PSA plays a permissive role, attenuating axon-axon interactions in the plexus and thereby allowing the axonal reorganization that is essential for the formation of specific motoneuron projections.

Distinct roles for adhesion molecules during innervation of embryonic chick muscle

In vitro studies have suggested that the cell adhesion molecules NCAM and G4/L1 contribute to a variety of events during neural development. We have directly tested the role played by these molecules in the process of initial nerve ingrowth and ramification in the embryonic chick iliofibularis muscle by in ovo injections of specific adhesion-blocking antibodies and analysis of the resultant nerve branching pattern in muscle whole mounts. Antibodies against both molecules produced axonal defasciculation, which resulted in an enhanced transverse projection to the fast region of the muscle. In the case of anti-G4/L1, we also observed a large increase in the number of side branches that form from nerve trunks in the slow region and an enhancement of nerve branching in the fast region. Conversely, anti-NCAM produced a striking decrease in both the number and length of side branches in the slow region, and a reduction in nerve branching in the fast region. A similar reduction of nerve branching was obtained following injection of an endosialidase, which removes sialic acid from NCAM, and which was observed to enhance fiber-fiber apposition, presumably by increasing cell adhesion. Based on their biochemical properties in vitro and their in vivo distribution, both NCAM and G4/L1 are in a position to contribute to axon-axon adhesive interactions, whereas NCAM would be expected to also promote axon-myotube interactions. Our observations in fact indicate that these two adhesion molecules play different but complementary roles during muscle innervation and, specifically, that axon-axon fasciculation is influenced by both NCAM and G4/L1 in an anatomically distinct manner to regulate the overall pattern of nerve branching and that NCAM-mediated axon-myotube interactions are necessary for the attainment of the normal stereotyped pattern of nerve branching in both fast and slow regions of this muscle.