Mechanisms of axonal plasticity: lessons from the olfactory pathway.

The olfactory pathway has emerged recently as an effective model for studying general principles of axon extension and regeneration. A variety of both trophic as well as repulsive molecules are found in the olfactory pathway and are being characterized for their roles in promoting the high capacity for plasticity and growth in olfactory receptor cell axons. In addition, olfactory ensheathing cells, which line the olfactory nerve, have been shown to promote axon extension not only in the olfactory pathway but also in the injured spinal cord. This review summarizes some of our current knowledge of these mechanisms and how they may function collectively to promote axon plasticity.

Glomerular formation in the developing rat olfactory bulb.

Using the confocal microscope together with markers for the cellular components of glomeruli, we examined the spatiotemporal cellular interactions that occur between the axons of olfactory receptor cells, their dendritic targets, and glial cells during the critical period of glomerular formation. We have employed markers of immature and mature olfactory receptor cell axons, mitral/tufted cell dendrites, and glial cells as well as a synapse-associated protein for double- and triple-label immunocytochemistry. Axons of olfactory receptor cells grew into a dense dendritic zone of the olfactory bulb (comprising the dendrites of both mitral and tufted cells) between E17 and E18. At E19, these axons coalesced into protoglomeruli, which continued to develop until birth, when the basic anatomical structure of adult glomeruli emerged. Neither mitral/tufted cell dendrites nor olfactory bulb astrocytes became specifically associated with these protoglomeruli until E21. Ensheathing cells remained restricted to the outer nerve fiber layer and did not appear to contribute to glomerular formation. Finally, the synaptophysin staining has shown that synaptic constituents are expressed as early as E17, prior to the appearance of mature olfactory receptor cell axons. Based on these data, we have established a time line detailing the temporal and spatial interactions that occur between cell types during late embryonic rat olfactory bulb development. We conclude that the initial event in the formation of glomeruli is the penetration of the mitral/tufted cell dendritic zone by olfactory receptor cell axons. The coalescence of dendritic and glial processes into glomerular structures appears secondary to the arrival of the olfactory receptor cell axons.

Expression of extracellular matrix molecules in the embryonic rat olfactory pathway.

Primary olfactory neurons arise from placodal neuroepithelium that is separate from the neuroepithelial plate that forms the neural tube and crest. The axons of these neurons course along a stereotypical pathway and invade the rostral telencephalic vesicle where they induce the formation of the olfactory bulb. In the present study we examined the expression of several extracellular matrix constituents during formation of the olfactory nerve pathway in order to identify putative developmentally significant molecules. Double-label immunofluorescence was used to simultaneously map the trajectory of growing primary olfactory axons by expression of growth associated protein 43 (GAP-43) and the distribution of either laminin, heparan sulfate proteoglycans (HSPG), or chondroitin sulfate proteoglycans (CSPG). At embryonic day 12.5 (E12.5) primary olfactory axons have exited the olfactory neuroepithelium of the nasal pit and formed a rudimentary olfactory nerve. These axons together with migrating neural cells form a large mass outside the rostral surface of the telencephalon. This nerve pathway is clearly defined by a punctate distribution of laminin and HSPG. CSPG is selectively present in the mesenchyme between the olfactory nerve pathway and the nasal pit and in the marginal zone of the telencephalon. At E14.5 primary olfactory axons pierce the telencephalon through gaps that have emerged in the basement membrane. At this age both laminin and HSPG are colocalized with the primary olfactory axons that have entered the marginal zone of the telencephalon. CSPG expression becomes downregulated in this same region while it remains highly expressed in the marginal zone adjacent to the presumptive olfactory bulb. By E16.5 most of the basement membrane separating the olfactory nerve from the telencephalon has degraded, and there is direct continuity between the olfactory nerve pathway and the central nervous system. This strict spatiotemporal regulation of extracellular matrix constituents in the olfactory nerve pathway supports an important role of these molecules in axon guidance. We propose that laminin and HSPG are expressed by migrating olfactory Schwann cells in the developing olfactory nerve pathway and that these molecules provide a conducive substrate for axon growth between the olfactory neuroepithelium and the brain. CSPG in the surrounding mesenchyme may act to restrict axon growth to within this pathway. The regional degradation of the basement membrane of the telencephalon and the downregulation of CSPG within the marginal zone probably facilitates the passage of primary olfactory axons into the brain to form the presumptive nerve fiber layer of the olfactory bulb.

Expression and localization of FGF-1 in the developing rat olfactory system.

Primary olfactory axons project from the nasal olfactory neuroepithelium to glomeruli in the olfactory bulb where they synapse with mitral cells, the second-order olfactory neurons. We have shown that the heparin-binding growth factor FGF-1 is expressed by olfactory nerve ensheathing cells which surround fascicles of primary olfactory axons en route to the olfactory bulb. These cells are believed to modulate olfactory axon growth between the olfactory neuroepithelium and the olfactory bulb. During late embryogenesis, FGF-1 expression is turned on in the mitral cells, and the FGF-1 peptide becomes confined to layers of synaptic neuropil in the postnatal olfactory bulb. FGF-1 is selectively present in glomeruli and the external plexiform layer. In cultures of olfactory neuroepithelial cells, complexes between FGF-1 and an appropriate activating heparan sulfate proteoglycan stimulated morphological differentiation of both olfactory nerve ensheathing cells and primary sensory olfactory neurons. Thus, the spatiotemporal expression and the functional properties of FGF-1 in this system suggest that this molecule plays an important regulatory role in the formation of the olfactory pathway.