The Grueneberg ganglion of the mouse projects axons to glomeruli in the olfactory bulb

First described in 1973, the Grueneberg ganglion (GG) is an arrow-shaped neuronal structure at the anterior end of the nasal cavity. It lines both sides of the nasal septum, within the nasal vestibule, close to the opening of the naris. The functions of the GG and the pattern of projections to the brain are not known. Here, we report that neurons of the mouse GG express olfactory marker protein, which is normally expressed in mature olfactory or vomeronasal sensory neurons. The approx. 500 cells in each GG are arranged in several densely packed cell clusters. Individual cells give rise to single axons, which fasciculate to form a nerve bundle that projects caudally. The axons terminate in glomeruli of the olfactory bulb, one or two large glomeruli associated with a semicircle of up to 10 smaller, somewhat diffusely organized glomeruli that surround the most anterior part of the accessory olfactory bulb. Development of the GG starts around embryonic day 16 and appears to be completed at birth; cell numbers then undergo a minor decrease during postnatal development. The strategic location of the GG, expression of olfactory marker protein, axonal projections to glomeruli at particular locations in the olfactory bulb and early development suggest that this neuronal structure performs specific chemosensory functions at neonatal stages.     

Distinct subsets of sensory olfactory neurons in mouse: Possible role in the formation of the mosaic olfactory projection

The axons of the primary sensory olfactory neurons project from the olfactory neuroepithelium lining the nasal cavity, onto glomeruli covering the surface of the olfactory bulb. Neuroanatomical studies have shown previously that individual olfactory glomeruli are innervated by neurons that are dispersed widely within the nasal cavity. The aim of the present study was to test the hypothesis that phenotypically unique subsets of primary sensory olfactory neurons, scattered throughout the nasal cavity, project to a subset of glomeruli in specific olfactory bulb loci. Immunochemical and histochemical analyses in neonatal mice revealed that the plant lectin, Dolichos biflorus agglutinin, bound to a subset of mature primary sensory olfactory neurons which express the olfactory marker protein. This subset of neurons was principally located in the rostromedial and dorsal portions of the nasal cavity and projected specifically to a subset of glomeruli in the rostromedial and caudodorsal portions of the olfactory bulb. Analysis of Dolichos biflorus-reactive axons revealed that these axons coursed randomly, with no evidence of their selective fasciculation, within the olfactory nerve. It was only at the level of the rostral olfactory bulb that a significant reorganisation of their trajectory was observed. Within the outer fibre layer of the bulb, discrete bundles of lectin-reactive axons began to coalesce selectively into fascicles which preferentially oriented toward the medial side of the olfactory bulb. These data demonstrated that a phenotypically distinct subset of primary sensory olfactory neurons exhibits a topographical projection from the olfactory epithelium to the olfactory bulb, and suggests that these, and other subsets, may form the basis of the mosaic nature of this pathway. Moreover, it appears that the outer nerve fibre layer in the rostral olfactory bulb plays an important instructive role in the guidance and fasciculation of olfactory sensory axons. © 1993 Wiley-Liss, Inc.     

Cell and explant culture of olfactory chemoreceptor cells

An in vitro system for the study of maturation of rat and chick embryonic olfactory receptor cells is presented. A variety of dissociating agents, culture media and substrata were tried in attempts to obtain a preparation of mature living olfactory receptor cells readily visible in the microscope. Maturation was judged by the development of axons greater than 1 mm long, by the presence of cilia at the end of the dendrites and, in the rat, by the presence of immunohistochemically demonstrable olfactory marker protein, a protein present only in olfactory receptor cells. By these criteria, dissociated cells did not mature in vitro, though occasional bipolar cells with relatively short axons were seen. In explant culture, small fragments of rat tissue were positive for all 3 criteria after 6 days. In 9-day cultures, the axons had grown up to 3 mm long in both rat and chick cultures. Olfactory bulb fragments co-cultured close to the olfactory epithelium had no influence on the direction of outgrowth of axons from the olfactory receptor cells. Preliminary experiments with intracellular electrodes on the fragment cultures suggest that there are two cell types in the epithelium; one with a potential of -25 to -30 mV and, the other, -12 to -15 mV.     

Characterization of olfactory receptor neurons and other cell types in dissociated rat olfactory cell cultures

In dissociated cell cultures, control over the cellular environment facilitates study of the differentiation of mature cellular phenotypes. Central to this approach is a rigorous characterization of the cells that reside in culture. Therefore, we have used a battery of cell type-specific antibody markers to identify the cell types present in dissociated cultures of olfactory mucosal cells (containing cells from both the epithelium and lamina propria). To identify olfactory receptor neurons in the cultures, staining with antibodies against neuron-specific tubulin was compared to staining with antibodies to neuron-specific enolase, the neural cell adhesion molecule, N-CAM, and the adhesion molecule, Ll. Staining of mature olfactory neurons in culture, with an antibody against the olfactory marker protein, was compared to staining with antibodies to carnosine. In contrast to tissue section staining, the overlap between carnosine and olfactory marker protein staining was not complete. Olfactory nerve glial cells were immunoreactive for the S100β protein and nestin, an intermediate filament found in early neuronal progenitor cells and Schwann cells. Antibodies to nestin did not label olfactory neurons or progenitor cells. An antibody to an oligodendrocyte-Schwann cell enzyme, 2′,3′-cyclic nucleotide 3′-phosphodiesterase, did not label olfactory glia, but did label oligodendrocyte-like cells that appeared to be derived from the CNS glial feeder layer. An antibody against the heavy (200 kDa) neurofilament protein stained a minor subset of cells. The cultures also contained muscle cells, cartilage cells and macrophages (and/or microglia). These results demonstrate that multiple cell types either maintain or re-establish differentiated, cell type-specific phenotypes in dissociated olfactory cell cultures.     

Projection of the Grüneberg ganglion to the mouse olfactory bulb

In mammals, sensory neurons from the main olfactory and vomeronasal systems project their axons to the olfactory bulbs in the brain. We here report that a cluster of neurons, distinct from these two systems, located at the very tip of the mouse nose and called the Grüneberg ganglion expresses the mature olfactory-sensory neuron-specific marker olfactory marker protein (OMP), but is unlikely to express known odorant or pheromone receptors. The ganglion is present at birth and maintained during adult life. Tracing experiments indicate that these neurons target ipsilaterally to a specific set of glomeruli located on the caudal part of the olfactory bulb, and that this connection is necessary for the survival of the ganglion. The glomerular targets are structures previously proposed to be associated with suckling behaviour. These observations strongly suggest that this peculiar olfactory neuronal population plays a sensory role, possibly linked to chemoperception.     

Cellular expression of H and B antigens in the rat olfactory system during development

Developmental expression of H and B antigens in the rat olfactory system was studied from the embryonic day 14 up to the postnatal day 30. The H antigen was detected in the olfactory and vomeronasal epithelia as early as fetal day 14, whereas the B antigen first appeared 2 days later. The anti-H reagent reacted strongly with sensory receptors and weakly with supporting cells in both epithelia, whereas the anti-B reagent was specific for olfactory receptors. In the main olfactory epithelium, the H antigen was expressed from fetal day 19 by most of the receptor cells, whereas the B determinant was expressed from fetal day 16 to postnatal day 3 by only a few neuroreceptors mostly located near the epithelial surface. After the postnatal day 3, B positive neurons increased in number from the periphery toward the deeper mucosal layers and they were distributed over 3/4 of the epithelial thickness in 15- and 30-day-old rats. In the main olfactory bulb, a widespread glomerular B staining with variable binding intensity between adjacent glomeruli was already observed at birth. The vomeronasal receptor cells and their axon terminals in the accessory olfactory bulb exhibited a comparable developmental expression of the B antigen. Results suggest that the B antigen could be regarded as a marker of neuronal maturation of both the olfactory and vomeronasal receptor cells; moreover, its first appearance in the receptor cells might be temporally related to the formation of synapses between receptor axons and deutoneurons in the bulb.     

Olfactory epithelial organotypic slice cultures: A useful tool for investigating olfactory neural development

Anin vitro slice culture was established for investigating olfactory neural development. The olfactory epithelium was dissected from embryonic day 13 rats; 400μm slices were cultured for 5 days in serum-free medium on Millicell-CM membranes coated with different substrates. The slices were grown in the absence of their appropriate target, the olfactory bulb, or CNS derived glia. The cultures mimic many features ofin vivo development. Cells in the olfactory epithelium slices differentiate into neurons that express olfactory marker protein (OMP). OMP-positive cells have the characteristic morphology of olfactory receptor neurons: a short dendrite and a single thin axon. The slices support robust axon outgrowth. In single-label experiments, many axons expressed neural specific tubulin, growth-associated protein 43 and OMP. Axons appeared to grow equally well on membranes coated with type I rat tail collagen, laminin or fibronectin. The cultures exhibit organotypic polarity with an apical side rich in olfactory neurons and a basal side supporting axon outgrowth. Numerous cells migrate out of the slices, of which a small minority was identified as neurons based on the expression of neural specific tubulin and HuD, a nuclear antigen, expressed exclusively in differentiated neurons. Most of the migrating cells, however, were positive for glial fibrilary acidic protein and S-100, indicating that they are differentiated glia. A subpopulation of these glial cells also expressed low-affinity nerve growth factor receptors, indicating that they are olfactory Schwann cells. Both migrating neurons and glia were frequently associated with axons growing out of the slice. In some cases, axons extended in advance of migrating cells. This suggests that olfactory receptor neurons in organotypic cultures require neither a pre-established glial/neuronal cellular terrain nor any target tissue for successful axon outgrowth. Organotypic olfactory epithelial slice cultures may be useful for investigating cellular and molecular mechanisms that regulate early olfactory development and function.     

Localization of tyrosine hydroxylase and olfactory marker protein immunoreactivities in the human and macaque olfactory bulb.

These studies utilized specific antisera to examine the distribution and characteristics of tyrosine hydroxylase and olfactory marker protein in the olfactory bulb of the human and macaque monkey. The macaque displayed immunoreactive profiles to both antisera comparable to those described previously for other mammals. Olfactory marker protein antiserum labeled the olfactory nerve layer and glomeruli. Within the glomeruli, labeled processes were interdigitated with unlabeled processes believed to be the postsynaptic dendrites of olfactory bulb neurons. Tyrosine hydroxylase antisera labeled somata surrounding the glomeruli as well as putative dendritic processes with the glomerular neuropil. It appeared that only a subset of juxtaglomerular neurons were immunoreactive. A similar pattern was observed in the human for both antibodies. Fascicles of olfactory marker protein immunoreactive olfactory nerves often coursed long distances into the olfactory bulb prior to arborizing within a glomerulus. The data suggest that olfactory receptor cell axons destined for specific glomeruli fasciculate into bundles prior to reaching the target glomeruli. The immunoreactivity in the human to tyrosine hydroxylase was qualitatively similar to the macaque and other mammals although the number of labeled somata and intraglomerular processes appeared lower. As in the macaque, it appeared that only a subset of juxtaglomerular neurons were labeled.     

Early olfactory enrichment and deprivation both decrease β-adrenergic receptor density in the main olfactory bulb of the rat

The density of noradrenergic locus coeruleus projections and β-adrenergic receptors in the main olfactory bulb of the rat increases with age. Both β₁ and β₂ receptor subtypes exhibit laminar distributions, with focal regions of high receptor density present within the neuropil of individual glomeruli. Since the first synaptic contacts between olfactory receptor neurons and bulbar neurons occur within the glomeruli, early olfactory experiences possibly could influence the density or distribution of β-adrenergic receptors in the bulb. We therefore investigated the effects of olfactory deprivation and early olfactory enrichment on the density and distribution of β-adrenergic receptors in the main olfactory bulb. Animals were subjected to either unilateral naris closure on postnatal day 1 or odor training from postnatal days 1–18. Bulbs were removed on postnatal day 19 and subjected to quantitative autoradiography using the β-adrenergic receptor antagonist [¹²⁵I]iodopindolol and specific receptor subtype antago nists ICI 118,551 (β₂-antagonist) and ICI 89,406 (β₁-antagonist). Unilateral naris occlusion decreased both the number of β₂ glomerular foci and the density of β₁ and β₂ receptors in the deprived bulb compared to the nondeprived bulb. Early odor training resulted in a significant decrease in the number, area, and receptor density of ₂ glomerular foci in the midlateral region of the bulb. The distribution of ₂ glomerular foci also differs with these two sensory manipulations. Changes in β-adrenergic receptor density in response to both early learning and olfactory deprivation may be induced by a transient increase in olfactory bulb norepinephrine. © 1995 Wiley-Liss, Inc.     

Neurotrophin-3 is expressed in a discrete subset of olfactory receptor neurons in the mouse

In transgenic neurotrophin-3 lacZ-neo (NT-3(lacZneo)) mice, in which the coding region for NT-3 is replaced by Eschericia coli lacZ, the expression of beta-galactosidase faithfully mimics the expression of NT-3 (Vigers AJ, Baquet ZC, Jones KR [2000], J Comp Neurol 416:398-416). During embryonic and early postnatal development, beta-galactosidase is detected in the olfactory system, beginning at embryonic day 11.5 in the nasal epithelium and at embryonic day 16.5 in the olfactory bulb. Levels of beta-galactosidase rise with age, reaching a peak during the second postnatal week, when beta-galactosidase reactivity is visible in up to 50% of the glomeruli. As the animal matures, the beta-galactosidase levels decline, but staining remains present in axons and cell bodies of a specific subset of olfactory receptor neurons (ORNs) projecting to a limited subset of glomeruli. The heavily labeled ORNs do not follow the typical OR expression zones in the epithelium but appear similar to the "patch" expression pattern of mOR37 receptors. The most heavily reactive glomeruli exhibit a striking reproducible pattern in the ventral olfactory bulb (OB). Some glomeruli of the OB contain calcitonin gene-related peptide (CGRP)-immunoreactive fibers of the trigeminal nerve. However, double-label immunocytochemistry for CGRP and beta-galactosidase rendered no correlation between trigeminal innervation and the degree of innervation by NT-3-expressing ORNs. Thus, the timing and presence of beta-galactosidase in a subset of ORNs suggests that NT-3 plays a role in synaptogenesis and/or synapse function in a specific subset of ORNs within the olfactory bulb.     

Number of olfactory marker protein-containing receptor cells is influenced by developmental stage of the olfactory bulb

In vitro studies on E15 rat embryos have shown that the number of receptor neurons containing olfactory marker protein (OMP) is markedly increased when olfactory mucosa (OM) is cultured in direct contact with the presumptive olfactory bulb (POB). This facilitatory influence is tissue-specific; that is, it is absent when the POB is substituted with other nervous or non-nervous tissues. In the present quantitative immunohistochemical study, we show that the enhancing influence of the POB is also a stage-specific phenomenon. The number of OMP-containing receptor cells is greatest when E15 OM is cultured with POB of the same age. If the POB was taken from a less mature (E13) or from a more mature (E17) embryo, the number of OMP-containing cells was greatly reduced.     

A novel brain receptor is expressed in a distinct population of olfactory sensory neurons

Three novel G-protein-coupled receptor genes related to the previously described RA1c gene have been isolated from the mouse genome. Expression of these genes has been detected in distinct areas of the brain and also in the olfactory epithelium of the nose. Developmental studies revealed a differential onset of expression: in the brain at embryonic stage 17, in the olfactory system at stage E12. In order to determine which cell type in the olfactory epithelium expresses this unique receptor type, a transgenic approach was employed which allowed a coexpression of histological markers together with the receptor and thus visualization of the appropriate cell population. It was found that the receptor-expressing cells were located very close to the basal membrane of the epithelium; however, the cells extended a dendritic process to the epithelial surface and their axons projected into the main olfactory bulb where they converged onto two or three glomeruli in the dorsal and posterior region of the bulb. Thus, these data provide evidence that this unique type of receptor is expressed in mature olfactory neurons and suggests that it may be involved in the detection of special odour molecules.     

Subzonal organization of olfactory sensory neurons projecting to distinct glomeruli within the mouse olfactory bulb

Olfactory sensory neurons located in the nasal neuroepithelium send their axons directly into the olfactory bulb, where they contact the dendrites of second-order neurons in specialized spherical structures called glomeruli; each sensory neuron projects to a single glomerulus. All neurons expressing the same odorant receptor gene are confined to distinct zones within the epithelium and converge their axons onto a small number of common glomeruli. In the present study, we analyzed transgenic mouse lines in which the projection of a neuron population expressing a particular receptor gene can be visualized as a result of axonal markers that are coexpressed. The target glomeruli could thus reproducibly be identified and allowed to deposit retrograde tracers precisely. After an appropriate incubation time, olfactory sensory neurons within distinct areas of the olfactory epithelium were labeled. The two subpopulations of neurons retrogradely stained by differently colored fluorescent dyes deposited at the dorsal and the dorsomedial glomerulus, respectively, were found to be segregated within distinct areas of the expression zone, where the cells expressing the same receptor type displayed a stochastic distribution.     

Semaphorin 3A-mediated axon guidance regulates convergence and targeting of P2 odorant receptor axons

Semaphorins are known to play an important role in axon guidance of vertebrate olfactory sensory neurons to their targets in specific glomeruli of the olfactory bulb (OB). However, it is not clear how semaphorin-mediated guidance contributes to a systematic hierarchy of cues that govern the organization of this system. Because of the putative role that odorant receptor molecules such as P2 could play in establishing appropriate glomerular destinations for growing olfactory axons, we have also determined the spatial organization of P2 glomeruli in semaphorin 3A (Sema3A) mutant mice. First, in the postnatal OB of control and Sema3A(-/-) mice, we analysed the trajectories of olfactory axons that express the Sema3A receptor, neuropilin-1 (npn-1) and the positions of npn-1(+) glomeruli. Sema3A at the ventral OB midline guides npn-1(+) axons to targets in the lateral and medial OB. Absence of Sema3A permits many npn-1 axons to terminate aberrantly in the rostral and ventral OB. Second, in Sema3A(-/-) mice, many P2 axons are abnormally distributed throughout the ventral OB nerve layer and converge in atypical locations compared with littermate controls where P2 axons converge on stereotypically located lateral and medial glomeruli. In addition to their radically altered spatial distribution, P2 glomeruli in Sema3A(-/-) mice are significantly smaller and more numerous than in heterozygote littermates. These data show that Sema3A is an important repulsive olfactory guidance cue that establishes restricted npn-1(+) subcompartments in the olfactory bulb. Furthermore, Sema3A plays a key role in the convergence of axons expressing the odorant receptor P2 onto their appropriate targets.     

Linear correlation between the number of olfactory sensory neurons expressing a given mouse odorant receptor gene and the total volume of the corresponding glomeruli in the olfactory bulb

Chemosensory specificity in the main olfactory system of the mouse relies on the expression of ～1,100 odorant receptor (OR) genes across millions of olfactory sensory neurons (OSNs) in the main olfactory epithelium (MOE), and on the coalescence of OSN axons into ～3,600 glomeruli in the olfactory bulb. A traditional approach for visualizing OSNs and their axons consists of tagging an OR gene genetically with an axonal marker that is cotranslated with the OR by virtue of an internal ribosome entry site (IRES). Here we report full cell counts for 15 gene‐targeted strains of the OR‐IRES‐marker design coexpressing a fluorescent protein. These strains represent 11 targeted OR genes, a 1% sample of the OR gene repertoire. We took an empirical, “count every cell” strategy: we counted all fluorescent cell profiles with a nuclear profile within the cytoplasm, on all serial coronal sections under a confocal microscope, a total of 685,673 cells in 56 mice at postnatal day 21. We then applied a strain‐specific Abercrombie correction to these OSN counts in order to obtain a closer approximation of the true OSN numbers. We found a 17‐fold range in the average (corrected) OSN number across these 11 OR genes. In the same series of coronal sections, we then determined the total volume of the glomeruli (TGV) formed by coalescence of the fluorescent axons. We found a strong linear correlation between OSN number and TGV, suggesting that TGV can be used as a surrogate measurement for estimating OSN numbers in these gene‐targeted strains. J. Comp. Neurol. 524:199–209, 2016. © 2015 Wiley Periodicals, Inc.     

NADPH-diaphorase histochemistry reveals heterogeneity in the distribution of nitric oxide synthase-expressing interneurons between olfactory glomeruli in two mouse strains

The expression of nitric oxide synthase (NOS) in the olfactory bulb was compared between two mouse strains, CD-1 and BALB/c, that differ in the connectivity within their olfactory glomeruli, their content of tyrosine hydroxylase, and their response to olfactory deafferentation. Labelled cells were qualitatively and quantitatively analyzed by both immunohistochemistry for NOS and histochemistry for nicotinamide adenine dinucleotide phosphate (NADPH)-diaphorase (ND). Both periglomerular cells and short-axon cells were observed with both techniques employed, and their colocalization in the same neurons demonstrated that ND is a reliable marker for NOS-expressing cells in the mouse olfactory bulb (OB). The histochemical technique differentiates two types of glomeruli: ND-positive and ND-negative. Olfactory glomeruli in the CD-1 strain were about 7% larger than those in the BALB/c animals. While the density of NOS/ND-containing periglomerular cells was similar between both strains studied, more NOS/ND-labelled cells were observed in the ND-positive glomeruli (P = 0.002). Since periglomerular cells in the BALB/c strain do not receive direct olfactory receptors synapses, the present results indicate that such inputs do not regulate the expression of NOS and ND activity in the periglomerular cells. The different densities of NOS/ND-expressing periglomerular cells may indicate that nitric oxide is implicated in a differential modulation of the odor response within both types of chemically distinct glomeruli in the mouse olfactory bulb. J. Neurosci. Res. 53:239–250, 1998. © 1998 Wiley-Liss, Inc.     

Septal organ of Grüneberg is part of the olfactory system

The olfactory system in rodents and many other mammals is classically divided into two anatomically separate, and morphologically distinct, sensory systems: the main olfactory system and the accessory olfactory system. We have now identified a novel third population of olfactory marker protein-expressing sensory neurons that is located in a discrete pocket of the rostral nasal septum, which we refer to as the septal organ of Grüneberg (SOG). Neurons in this region of the septum are located in the submucosa, in small grape-like clusters, rather than in a pseudostratified neuroepithelium, as seen in both the olfactory and vomeronasal neuroepithelia. Despite their unusual location, axons projecting from the SOG neurons fasciculate into several discrete bundles and terminate in a subset of main olfactory bulb glomeruli. These glomeruli most likely represent a subset of atypical glomeruli that are spatially restricted to the caudal main olfactory bulb. The unique rostral position of the SOG suggests that the SOG may be functionally specialized for the early detection of biologically relevant odorants.     

Alteration of carnosine expression in olfactory system of mouse after unilateral naris closure and partial bulbectomy

To investigate the function of the dipeptide carnosine in the olfactory system, alterations of carnosine in the primary olfactory nerve after unilateral naris closure or olfactory bulb semilesion were studied by means of immunocytochemistry. After unilateral naris closure, carnosine staining showed no alteration, but immunoreactivity of tyrosine hydroxylase (TH), the rate-limiting enzyme for biosynthesis of dopamine in dopaminergic neurons, decreased dramatically in periglomerular neurons. This behavior of carnosine is consistent with that reported for the olfactory marker protein (OMP). On the other hand, following partial lesion of the olfactory bulb, ordinary to strong carnosine expression was seen in newly innervated glomeruli that exceeded that seen in the conventional targets. Ectopic, TH-positive, periglomerular cell-like neurons appeared around the newly formed glomeruli. These data suggest that carnosine may have some role in regulating TH expression in post-synaptic neurons. © 1993 Wiley-Liss, Inc.     

Localization and regulation of low affinity nerve growth factor receptor expression in the rat olfactory system during development and regeneration

Nerve growth factor (NGF), a classic neurotropic factor, promotes neuronal survival, maintenance, regeneration and differentiation in the peripheral nervous system and parts of the central nervous system. NGF activity is mediated by cell surface bound receptors including the low affinity NGF receptor (LNGFr) which is expressed by some peripheral and central neurons and is present on peripheral nerve Schwann cells during development and regeneration. The olfactory system is a useful model for the study of the role of LNGFr in neuronal development and regeneration. The growth of olfactory axons into the brain begins in the embryo and continue through the first few postnatal weeks. In mature animals there is persistent turnover and generation of olfactory receptor neurons (ORNs) and continuous growth of new axons into the oflfactory bulb. These new axons grow along the preexisting olfactory pathway. In the mature olfactory system, LNGFr has been observed in the glomerular layer of the olfactory bulb, the target of ORNs. However, neither the cellular localization nor the development expression of LNGFr has been characterized. Her, we tested the hypothesis that LNGFr expression is developmentally regulated in the olfactory nerve and is reinduced following injury to the mature olfactory nerve. LNGFr-immunoreactivity (IR) was first observed in the olfactory mucosa at embryonic day (E)13 and in the olfactory nerve at E14. LNGFr-IR increased in the nerve during embryonic development, began to decrease at around postnatal day (P)5 and was scarcely detectable in normal adults. The staining patterns suggests that LNGFr is located on the olfactory nerve Schwann cells. Streaks of LNGFr-IR were present in the adult olfactory nerve. We reasoned that these streaks might represent transient reexpression of LNGFr associated with normal olfactory neurons turnover and replacement. Consistent with this hypothesis, LNGFr was robustly reexpressed in the adult olfactory nerve following lesion of the olfactory epithelium. Starting late in development (E21) and in the adult, LNGFr-IR was also observed on fibres in deep layers of the olfactory bulb. LNGFr-IR was also observed in neurons of the nucleus of the diagonal band (NDB) in the basal forebrain. NDB is the sole source of cholingeric afferents of the olfactory bulb. Thus, we tested the hypothesis that LNGFr in the deep layers of the olfactory bulb is located on NDB axons by making lesions of NDB. Following the lesion, LNGFr-IR disappeared in the deep layers of the olfactory bulb but remained in the glomerular layer. We conclude that LNGFr-IR is associated with several distinct populations of cells in the olfactory system. This suggests that LNGFr-IR plays several distinct functional roles in the olfactory system, including support of olfactory axon growth and regeneration and maintenance of cholinergic innervation of the olfactory bulb. © 1994 Wiley-Liss, Inc.