Patterning of olfactory sensory connections is mediated by extracellular matrix proteins in the nerve layer of the olfactory bulb

In early rat embryos when axons from sensory neurons first contact the olfactory bulb primordium, lactosamine-containing glycans (LCG) are detected on neurons that are broadly distributed within the olfactory epithelium, but that project axons to a very restricted region of the ventromedial olfactory bulb. LCG(+) axons extend through channels defined by the coexpression of galectin-1 and beta2-laminin. These two extracellular matrix molecules are differentially expressed, along with semaphorin 3A, by subsets of ensheathing cells in the ventral nerve layer of the olfactory bulb. The overlapping expression of these molecules creates an axon-sorting domain that is capable of promoting and repelling subsets of olfactory axons. Specifically, LCG(+) axons preferentially grow into the region of the nerve layer that expresses high amounts of galectin-1, beta2-laminin, and semaphorin 3A, whereas neuropilin-1(+) axons grow in a complementary pattern, avoiding the ventral nerve layer and projecting medially and laterally. These studies suggest that initial patterning of olfactory epithelium to olfactory bulb connections is, in part, dependent on extracellular components of the embryonic nerve layer that mediate convergence and divergence of specific axon subsets.     

Rhinotopy is disrupted during the re-innervation of the olfactory bulb that follows transection of the olfactory nerve

Re-innervation of the olfactory bulb was investigated after transection of the olfactory nerve using monoclonal antibody RB-8 to assess whether rhinotopy of the primary olfactory projection is restored. In normal animals RB-8 heavily stains the axons, and their terminals, that project from the ventrolateral olfactory epithelium onto glomeruli of the ventrolateral bulb (termed RB-8(+)). In contrast, axons from dorsomedial epithelium are unlabeled (RB-8(-)) and normally terminate in the dorsomedial bulb. Sprague-Dawley rats underwent unilateral olfactory nerve transection and survived for 6 weeks prior to perfusion, sectioning and immunostaining with RB-8. Nerve lesion does not shift the position of the boundary between RB-8(+) and RB-8(-) regions of the epithelium. However, following transection and bulb re-innervation, the distribution of RB-8(+) and RB-8(-) axons is markedly abnormal. First, in all 10 experimental animals RB-8(-) axons displace RB-8(+) axons from anterior glomeruli. Furthermore, the usual target of the RB-8(-) fibers, i.e. the dorsomedial bulb at more posterior levels of the bulb, remains denervated, judging by the lack of staining with antibodies that label axons derived from all epithelial zones. Finally, RB-8(+) fibers invade foreign territory in the dorsolateral bulb on the lesioned side in some cases. The shifts in terminal territory in the bulb after transection contrast with the restoration of the normal zonal patterning of the projection after recovery from methyl bromide lesion, but is consistent with reports of mistargeting by a receptor-defined subset of neurons after transection.     

Expression of cell adhesion molecules in the olfactory system of the adult mouse: presence of the embryonic form of N-CAM

The expression of the neural cell adhesion molecules N-CAM and L1 was investigated in the olfactory system of the mouse using immunocytochemical and immunochemical techniques. In the olfactory epithelium, globose basal cells and olfactory neurons were stained by the polyclonal N-CAM antibody reacting with all three components of N-CAM (N-CAM total) in their adult and embryonic states. Dark basal cells and supporting cells were not found positive for N-CAM total. The embryonic form of N-CAM (E-N-CAM) was only observed on the majority of globose basal cells, the precursor cells of olfactory neurons, and some neuronal elements, probably immature neurons, since they were localized adjacent to the basal cell layer. Differentiated neurons in the olfactory epithelium did not express E-N-CAM. In contrast to N-CAM total, the 180-kDa component of N-CAM (N-CAM180) and E-N-CAM, L1 was not detectable on cell bodies in the olfactory epithelium. L1 and N-CAM180 were strongly expressed on axons leaving the olfactory epithelium. Olfactory axons were also labeled by antibodies to N-CAM180 and L1 in the lamina propria and the nerve fiber and glomerular layers of the olfactory bulb, but only some axons showed a positive immunoreaction for E-N-CAM. Ensheathing cells in the olfactory nerve were observed to bear some labeling for N-CAM total, L1, and N-CAM180, but not E-N-CAM. In the olfactory bulb, L1 was not present on glial cells. In contrast, N-CAM180 was detectable on some glia and N-CAM total on virtually all glia. Glia in the nerve fiber layer were labeled by E-N-CAM antibody only at the external glial limiting membrane. In the glomerular layer, E-N-CAM expression was particularly pronounced at contacts between olfactory axons and target cells. The presence of E-N-CAM in the adult olfactory epithelium and bulb was confirmed by Western blot analysis. The continued presence of E-N-CAM in adulthood on neuronal precursor cells, a subpopulation of olfactory axons, glial cells at the glia limitans, and contacts between olfactory axons and their target cells indicates the retention of embryonic features in the mammalian olfactory system, which may underlie its remarkable regenerative capacity.     

Reciprocal interactions between olfactory receptor axons and olfactory nerve glia cultured from the developing moth Manduca sexta

In olfactory systems, neuron-glia interactions have been implicated in the growth and guidance of olfactory receptor axons. In the moth Manduca sexta, developing olfactory receptor axons encounter several types of glia as they grow into the brain. Antennal nerve glia are born in the periphery and enwrap bundles of olfactory receptor axons in the antennal nerve. Although their peripheral origin and relationship with axon bundles suggest that they share features with mammalian olfactory ensheathing cells, the developmental roles of antennal nerve glia remain elusive. When cocultured with antennal nerve glial cells, olfactory receptor growth cones readily advance along glial processes without displaying prolonged changes in morphology. In turn, olfactory receptor axons induce antennal nerve glial cells to form multicellular arrays through proliferation and process extension. In contrast to antennal nerve glia, centrally derived glial cells from the axon sorting zone and antennal lobe never form arrays in vitro, and growth-cone glial-cell encounters with these cells halt axon elongation and cause permanent elaborations in growth cone morphology. We propose that antennal nerve glia play roles similar to olfactory ensheathing cells in supporting axon elongation, yet differ in their capacity to influence axon guidance, sorting, and targeting, roles that could be played by central olfactory glia in Manduca.     

Odorant receptor proteins in olfactory axons and in cells of the cribriform mesenchyme may contribute to fasciculation and sorting of nerve fibers

Odorant receptors (ORs) have been shown to be present not only in the chemosensory cilia of the olfactory sensory neurons, but also in their axon terminals. This observation has emphasized the notion that the receptor protein may contribute to the precise receptor-specific targeting of olfactory axons in the olfactory bulb. This concept implies a particularly important role for the axonal receptor protein during the onset and early phase of the wiring process during development. In the present study, we have demonstrated, by means of specific antibodies, that, as early as mouse embryonic day E12, the OR protein can be visualized in outgrowing axonal processes of the olfactory epithelium and in cells located in the cribriform mesenchyme. On their trajectory from the olfactory epithelium through the cribriform mesenchyme toward the forebrain, axons with strong OR immunoreactivity have only been seen in the dorsal part of the mesenchyme where they traverse the region of OR-positive cells. Upon visualization by specific antibodies, these cells have been revealed to have long protrusions extending along the surface of nerve fascicles. They are often located at bifurcations where two small axon fascicles merge to form a stronger bundle. Within this region, fascicles coalesce forming a coherent nerve. Moreover, within the now compact nerve bundle, axons visualized by the OR-specific antibody are no longer distributed evenly but are segregated from other axonal populations within the nerve. These findings suggest that OR proteins in the membrane of axonal processes and of cells in the cribriform mesenchyme are involved in crucial processes such as fasciculation and the sorting of outgrowing axons, both of which are fundamental for the initiation and establishment of the precise wiring of the olfactory system during early development. This work was supported by the Deutsche Forschungsgemeinschaft (SFB 495).     

Cell surface carbohydrates reveal heterogeneity in olfactory receptor cell axons in the mouse

Cell surface carbohydrates, both in the olfactory system and elsewhere, have been proposed to play critical roles in axon guidance and targeting. Recent studies have used plant lectins to study the heterogeneous distribution of carbohydrates in the olfactory system. One lectin, Dolichos biflorus agglutinin (DBA), heterogeneously labels subsets of glomeruli. In the olfactory epithelium DBA labeled a subset of olfactory sensory neurons (OSNs) including their cilia, dendrites, and somata. OSN axons were also labeled and readily observed in the olfactory nerve and bulb. The patterns of glomerular innervation by DBA labeled (DBA(+)) axons were diverse; some glomeruli contained many labeled axons, while others contained few or no labeled axons. To characterize the heterogeneous innervation of glomeruli, we double labeled olfactory bulbs with DBA and an antibody to olfactory marker protein (OMP). OMP colocalized in most, but not all, DBA(+) axons. To determine if those axons that did not express OMP were immature, we double labeled olfactory bulbs with DBA and anti-GAP-43. GAP-43 rarely colocalized with DBA, suggesting that DBA(+) axons are not, as a population, immature. Triple labeling with all three markers revealed a small subset of DBA(+) axons which did not express either OMP or GAP-43. Electron microscopy established that DBA labels axons in the olfactory nerve and DBA-labeled axons form typical glomerular axodendritic synapses.     

Development of a glial network in the olfactory nerve: role of calcium and neuronal activity

In adult olfactory nerves of mammals and moths, a network of glial cells ensheathes small bundles of olfactory receptor axons. In the developing antennal nerve (AN) of the moth Manduca sexta, the axons of olfactory receptor neurons (ORNs) migrate from the olfactory sensory epithelium toward the antennal lobe. Here we explore developmental interactions between ORN axons and AN glial cells. During early stages in AN glial-cell migration, glial cells are highly dye coupled, dividing glia are readily found in the nerve and AN glial cells label strongly for glutamine synthetase. By the end of this period, dye-coupling is rare, glial proliferation has ceased, glutamine synthetase labeling is absent, and glial processes have begun to extend to enwrap bundles of axons, a process that continues throughout the remainder of metamorphic development. Whole-cell and perforated-patch recordings in vivo from AN glia at different stages of network formation revealed two potassium currents and an R-like calcium current. Chronic in vivo exposure to the R-type channel blocker SNX-482 halted or greatly reduced AN glial migration. Chronically blocking spontaneous Na-dependent activity by injection of tetrodotoxin reduced the glial calcium current implicating an activity-dependent interaction between ORNs and glial cells in the development of glial calcium currents.     

Transregulation of erbB expression in the mouse olfactory bulb.

Previously, we have shown that erbB-3 expression is restricted to the ensheathing cells of the olfactory nerve layer, while erbB-4 is found in the periglomerular and mitral/tufted cells of the olfactory bulb and in cells coming out from the rostral migratory stream of the subependymal layer. In the present work, we have treated adult mice with zinc sulfate intranasal irrigation and analyzed erbB-3 and erbB-4 expression in the deafferented olfactory bulb. Following treatment, olfactory axons undergo degeneration, as indicated by the loss of OMP expression in the deafferented olfactory bulb. The thickness of the olfactory nerve layer is reduced, but the specific intensity of erbB-3 labeling in the remaining olfactory nerve layer is increased with respect to control. Interestingly, following deafferentation, erbB-4 immunoreactivity decreases specifically in cell types that normally make synaptic contacts with primary olfactory neurons in the glomeruli, i.e. periglomerular and mitral/tufted cells. Partial lesion of the olfactory epithelium allows regenerative axon growth of olfactory neurons to the olfactory bulb. Following olfactory axon regeneration, erbB-3 and erbB-4 immunoreactivity in the olfactory bulb is similar to control. Thus, like tyrosine hydroxylase, the down regulation of erbB-4 expression in the periglomerular cells is reversible.     

Histology and ultrastructure of the olfactory organ of the freshwater pulmonate Helisoma trivolvis

Summary The olfactory organ of Helisoma trivolvis is located on the surface of the body at the base of the cephalic tentacles. An evagination of skin, the olfactory plica, at the base of the tentacle extends over the olfactory organ dorsally. The epithelium of the olfactory organs contains unspecialized epithelial cells, ciliated epithelial cells, basal cells, mucous secretory cells, and sensory dendrites. The surface of the epithelium has a complex brush border of thick plasmatic processes, which branch to form several terminal microvillar twigs. Long slender cytoplasmic processes form a dense spongy layer among the plasmatic processes beneath the level of the terminal twigs. Bipolar primary sensory neurons clustered beneath the epithelium of the olfactory organ send dendrites through the epithelium to the free surface. Some sensory endings have a few short cilia, but most bear only microvilli. Cilia of sensory endings and epithelial cells extend beyond the brush border of the epithelium. Small axons arise from the perikarya of the sensory neurons and enter a branch of the olfactory nerve. HRP tracing indicates that the axons pass to the cerebral ganglion without interruption. Histochemical tests indicate that the sensory neurons are neither aminergic nor cholinergic.     

p59fyn and pp60 c-src modulate axonal guidance in the developing mouse olfactory pathway

The Src-family tyrosine kinases p59^fyn and pp60^c-src are localized on axons of the mouse olfactory nerve during the initial stages of axonal growth, but their functional roles remain to be defined. To study the role of these kinases, we analyzed the trajectory of the olfactory nerve in E11.5 homozygous null mutant mice lacking single src or fyn genes and double mutants lacking both genes. Primary olfactory axons of single and double mutants exited the olfactory epithelium and projected toward the telencephalon, but displayed differences in fasciculation. The fyn-minus olfactory nerve had significantly more fascicles than the src-minus nerve. Most strikingly, the primary olfactory nerve of src/fyn double mutants showed the greatest degree of defasciculation. These defects, identified by NCAM labeling, were not due to apparent changes in the size of the olfactory epithelium. With the exception of the src-minus mice, which had fewer fascicles than the wild type, no obvious differences were observed in coalescence of vomeronasal axons from mutant mice. The mesenchyme of the double and single mutants exhibited only subtle changes in laminin and fibronectin staining, indicating that the adhesive environment of the mesenchyme may contribute in part to defects in fasciculation. The results suggest that signaling pathways mediated by p59^fyn and pp60^c-src contribute to the appropriate fasciculation of axons in the nascent olfactory system, and comprise partially compensatory mechanisms for axonal adhesion and guidance. © 1998 John Wiley & Sons, Inc. J Neurobiol 36: 53–63, 1998     

A diffusible signal attracts olfactory sensory axons toward their target in the developing brain of the moth

The signals that olfactory receptor axons use to navigate to their target in the CNS are still not well understood. In the moth Manduca sexta, the primary olfactory pathway develops postembryonically, and the receptor axons navigate from an experimentally accessible sensory epithelium to the brain along a pathway long enough for detailed study of regions in which axon behavior changes. The current experiments ask whether diffusible factors contribute to receptor axon guidance. Explants were made from the antennal receptor epithelium and co-cultured in a collagen gel matrix with slices of various regions of the brain. Receptor axons were attracted toward the central regions of the brain, including the protocerebrum and antennal lobe. Receptor axons growing into a slice of the most proximal region of the antennal nerve, where axon sorting normally occurs, showed no directional preference. When the antennal lobe was included in the slice, the receptor axons entering the sorting region grew directly toward the antennal lobe. Taken together with the previous in vivo experiments, the current results suggest that an attractive diffusible factor can serve as one cue to direct misrouted olfactory receptor axons toward the medial regions of the brain, where local cues guide them to the antennal lobe. They also suggest that under normal circumstances, in which the receptor axons follow a pre-existing pupal nerve to the antennal lobe, the diffusible factor emanating from the lobe acts in parallel and at short range to maintain the fidelity of the path into the antennal lobe.     

Lotus Lectin Labels Subpopulation of Olfactory Receptor Cells

Experiments were performed to test the hypothesis that subsetsof olfactory receptor cells could be recognized based on theirlectin binding and that mapping of their projections onto theolfactory bulb would reveal details of anatomic organizationof the olfactory nerve projection to the olfactory bulb. Theresults from one lectin, Lotus, were examined in detail. Olfactoryreceptor cells in the lateral part of the main epithelium werelabeled, as well as scattered cells in the remainder of theepithelium. Glomeruli labled by Lotus were concentrated primarilyin the region of the olfactory bulb that receives its inputfrom the lateral epithelium, although scattered glomeruli couldbe identified in other regions. Within the terminal field ofthese axons there was a mosaic pattern, with some glomerulidensely labeled, some lightly labeled and others unlabeled.These findings support the notion that there are biochemicallydistinct populations of olfactory receptor cells having localizeddistributions in the epithelium, with axons that coalesce toterminate in specific glomeruli, rather than diffusely overtheir projection field. Chem. Senses 21: 13–18, 1996     

Study of regeneration in the garfish olfactory nerve

Previous studies of the olfactory nerve, mainly in higher vertebrates, have indicated that axonal injury causes total degeneration of the mature neurons, followed by replacement of new neuronal cells arising from undifferentiated mucosal cells. A similar regeneration process was confirmed in the garfish olfactory system. Regeneration of the nerve, crushed 1.5 cm from the cell bodies, is found to produce three distinct populations of regenerating fibers. The first traverses the crush site 1 wk postoperative and progresses along the nerve at a rate of 5.8 +/- 0.3 mm/d for the leading fibers of the group. The second group of fibers traverses the crush site after 2 wk postcrush and advances at a rate of 2.1 +/- 0.1 mm/d for the leading fibers. The rate of growth of this group of fibers remains constant for 60 d but subsequently falls to 1.6 +/- 0.2 for the leading population of fibers. The leading fibers in the third group of regenerating axons traverse the crush site after 4 wk and advance at a constant rate of 0.8 +/- 0.2 mm/d. The multiple populations of regenerating fibers with differing rates of growth are discussed in the context of precursor cell maturity at the time of nerve injury and possible conditioning effects of the lesion upon these cells. Electron microscopy indicates that the number of axons decreases extensively after crush. The first two phases of regenerating axons represent a total of between 6 and 10% of the original axonal population and are typically characterized by small fascicles of axons surrounded by Schwann cells and large amounts of collagenous material. The third phase of fibers represents between 50 and 70% of the original axonal population.     

Immunocytochemical localization of S-100 beta beta protein in olfactory and supporting cells of lamb olfactory epithelium

By immunocytochemistry, we have identified two novel cell types, olfactory and supporting cells of lamb olfactory epithelium, expressing S-100 beta beta protein. S-100 immune reaction product was observed on ciliary and plasma membranes, on axonemes and in the cytoplasm adjacent to plasma membranes and to basal bodies of olfactory vesicles. A brief treatment of olfactory mucosae with Triton X-100 before fixation is necessary for detection of S-100 beta beta protein within olfactory vesicles. In the absence of such a treatment, the immune reaction product is restricted to ciliary and plasma membranes. On the other hand, irrespective of pre-treatment of olfactory mucosae, S-100 beta immune reaction product in supporting cells is restricted to microvillar and plasma membranes. The anti-S-100 beta antiserum used in these studies does not bind to basal cells of the olfactory epithelium or to cells of the olfactory glands, whereas it binds to Schwann cells of the olfactory nerve. An anti-S-100 alpha antiserum does not bind to cellular elements of the olfactory mucosa, Schwann cells, or axons of the olfactory nerve. The present data provide, for the first time, evidence for the presence of S-100 beta beta protein in mammalian neurons (olfactory cells).     

The Response of Ornithine Decarboxylase During Neuronal Degeneration and Regeneration in Olfactory Epithelium

Mature olfactory neurons are continually replaced from a population of progenitor cells. Olfactory nerve section, bulbectomy, or treatment with certain chemicals induces degeneration of olfactory neurons followed in some cases by regeneration. Ornithine decarboxylase (ODC) activity was measured in mouse olfactory tissues as an indicator of cellular regeneration. ODC activity in olfactory tissue (0.2–0.4 nmol/mg protein/h) is 10-30 times higher than in a variety of other cerebral tissues. Within 3 h after unilateral olfactory nerve section, ODC activity in the epithelium declines to 50% of control followed by a slow return to basal activity by 6 days. In the same animals, ODC activity increases severalfold in bulb (1 day) with a gradual decline to normal (9 days). Except for an early transient increase, the effects of unilateral bulbectomy on epithelial ODC activity are similar to those seen after nerve section. The changes in ODC activity following intranasal irrigation with 10 mm -colchicine also closely mimic those seen after nerve section. The effects of intranasal irrigation on ODC activity with 0.5% Triton X-100 or 0.17 m -ZnSO₄ are more complex. Thus, when the mature neuronal population is degenerating after surgery or chemical treatments, ODC activity decreases in the epithelium. The subsequent increase of ODC activity prior to reconstitution of the mature neuronal population probably reflects the regeneration mechanism of the olfactory epithelium. The increase of ODC activity in the olfactory bulb after nerve section is best interpreted as a cellular injury response. These alterations in ODC activity in olfactory tissues after chemical and surgical treatments constitute the earliest biochemical events observed in these tissues in response to cellular damage.     

Tyrosine hydroxylase- and corticotropin releasing factor-immunoreactivity in the olfactory bulb of the opossum (Didelphis virgianina)

The nerve fiber layer of the opossum olfactory bulb, formed by axons originating from bipolar neurons in the olfactory epithelium, and glomeruli are intensely immunoreactive for olfactory marker protein. The surrounding extra-glomerular neuropil contains numerous periglomerular neurons immunoreactive for either tyrosine hydroxylase or corticotropin releasing factor. Dendrites of both types of immunoreactive neurons extend into the intraglomerular neuropil. CRF-immunoreactive neurons are fewer in number than TH-immunoreactive neurons and are observed primarily in the periglomerular region. Occasional, scattered TH-immunoreactive neurons are seen in the deeper layers of the olfactory bulb.     

Zonal organization of the mammalian main and accessory olfactory systems

Zonal organization is one of the characteristic features observed in both main and accessory olfactory systems. In the main olfactory system, most of the odorant receptors are classified into four groups according to their zonal expression patterns in the olfactory epithelium. Each group of odorant receptors is expressed by sensory neurons distributed within one of four circumscribed zones. Olfactory sensory neurons in a given zone of the epithelium project their axons to the glomeruli in a corresponding zone of the main olfactory bulb. Glomeruli in the same zone tend to represent similar odorant receptors having similar tuning specificity to odorants. Vomeronasal receptors (or pheromone receptors) are classified into two groups in the accessory olfactory system. Each group of receptors is expressed by vomeronasal sensory neurons in either the apical or basal zone of the vomeronasal epithelium. Sensory neurons in the apical zone project their axons to the rostral zone of the accessory olfactory bulb and form synaptic connections with mitral tufted cells belonging to the rostral zone. Signals originated from basal zone sensory neurons are sent to mitral tufted cells in the caudal zone of the accessory olfactory bulb. We discuss functional implications of the zonal organization in both main and accessory olfactory systems.     

The central pathway of primary olfactory axons is abnormal in mice lacking the N-CAM-180 isoform

Although N-CAM has previously been implicated in the growth and fasciculation of axons, the development of axon tracts in transgenic mice with a targeted deletion of the 180-kD isoform of the neural cell adhesion molecule (N-CAM-180) appears grossly normal in comparison to wild-type mice. We examined the organization of the olfactory nerve projection from the olfactory neuroepithelium to glomeruli in the olfactory bulb of postnatal N-CAM-180 null mutant mice. Immunostaining for olfactory marker protein revealed the normal presence of fully mature primary olfactory neurons within the olfactory neuroepithelium of mutant mice. The axons of these neurons form an olfactory nerve, enter the nerve fiber layer of the olfactory bulb, and terminate in olfactory glomeruli as in wild-type control animals. The olfactory bulb is smaller and the nerve fiber layer is relatively thicker in mutants than in wild-type mice. Previous studies have revealed that the plant lectin Dolichos biflorus agglutinin (DBA) clearly stains the perikarya and axons of a subpopulation of primary olfactory neurons. Thus, DBA staining enabled the morphology of the olfactory nerve pathway to be examined at higher resolution in both control and mutant animals. Despite a normal spatial pattern of DBA-stained neurons within the nasal cavity, there was a distorted axonal projection of these neurons onto the surface of the olfactory bulb in N-CAM-180 null mutants. In particular, DBA-stained axons formed fewer and smaller glomeruli in the olfactory bulbs of mutants in comparison to wild-type mice. Many primary olfactory axons failed to exit the nerve fiber layer and contribute to glomerular formation. These results indicate that N-CAM-180 plays an important role in the growth and fasciculation of primary olfactory axons and is essential for normal development of olfactory glomeruli. © 1997 John Wiley & Sons, Inc. J Neurobiol 32 : 643–658, 1997     

Electrical Activity and Histological Change in the Degenerating Olfactory Epithelium

Electrical activity and histological changes were studied in the degenerating olfactory epithelium of the bullfrog after the olfactory nerve had been sectioned. After nerve section, the electrical responses to odors disappeared in the olfactory epithelium in 8 days in the summer, in 11 days in the early autumn, and in 16 days in the early winter. In the degenerating olfactory epithelium a striking decrease in the number of olfactory cells was found, but not of supporting cells. The ratio of the number of olfactory cells to that of supporting cells was found to decrease from 5 or 6 to below 2 after the nerve section. At a ratio below 2, the electrical responses to odor disappeared. The histological changes in the bullfrog are compared with those in the mouse and rabbit. The localization of the olfactory pigment and the electrical activity of the supporting cell are discussed. It was concluded that all three types of responses to odors originate from the activity of the olfactory cell.     

Projection pattern of nerve fibers from the septal organ: DiI-tracing studies with transgenic OMP mice

The septal organ represents one of the three chemosensory subsystems found in most vertebrate species. Analyzing the projection pattern of septal organ neurons using the OMP-GFP transgenic mouse line revealed that axons navigate in highly variable fiber tracks across the main olfactory epithelium toward the main olfactory bulb. All septal organ axons cross through the cribriform plate at a spatially defined site and terminate exclusively in the posterior, ventromedial aspect of the bulb. Here, one portion of axons forms a dense network on the medial side where they apparently enter glomeruli which are mainly innervated by axons of olfactory sensory neurons from the main olfactory epithelium. Another significant portion of the axons targets a few glomeruli which appear to receive input exclusively from the septal organ neurons.