Quantitative analysis of the olfactory pathway for drug delivery to the brain

Following intranasal administration to rats, wheat germ agglutinin-horseradish peroxidase (WGA-HRP) concentrated in the olfactory nerve and glomerular layers of the olfactory bulb resulting in a mean olfactory bulb concentration of 140 nM. A negligible amount of label was detected in the olfactory bulb following intravenous administration of WGA-HRP or intranasal administration of unconjugated HRP. This is the first quantitative assessment of intraneuronal transport of a protein into the brain using the olfactory route.     

The olfactory gonadotropin-releasing hormone immunoreactive system in mouse

The olfactory gonadotropin-releasing hormone (GnRH) system in mice was studied with immunofluorescence in combination with lesions of the olfactory bulb and retrograde transport of horseradish peroxidase (HRP) which was administered intravascularly, intranasally or into the subarachnoid space. GnRH-positive neurons were located in the two major branches forming the septal roots of the nervus terminalis, in the ganglion terminale, within the fascicles of the nervus terminalis throughout its extent, in a conspicuous band which connects the ventral neck of the caudal olfactory bulb with the accesory olfactory bulb in the nasal mucosa. GnRH-positive fibers were seen in all areas in which neurons were found, i.e. in the rostral septum, the ganglion and nervus terminalis and in the nasal subepithelium. In addition, a broad bundle of fibers was observed to surround the entire caudal olfactory bulb, connecting the rostral sulcus rhinalis with the ventrocaudal olfactory bulb. Fibers were seen in close association with the main and accessory olfactory bulb, with the fila olfactoria and with the nasal mucosa. Throughout the olfactory bulb and the nasal epithelium, an association of GnRH fibers with blood vessels was apparent. Intravascular and intranasal injection of HRP resulted in labeling of certain GnRH neurons in the septal roots of the nervus terminalis, the ganglion terminale, the nervus terminalis, the caudal ventrodorsal connection and in the accessory olfactory bulb. After placement of HRP into the subarachnoid space dorsal to the accessory olfactory bulb, about 50% of the GnRH neurons in the accessory olfactory bulb and in the ventrodorsal connection were labeled with HRP. Also, a few GnRH neurons in the rostral septum, the ganglion terminale and in the fascicles of the nervus terminalis had taken up the enzyme. Lesions of the nervus terminalis caudal to the ganglion terminale resulted in sprouting of GnRH fibers at both sites of the knife cut. Lesions rostral to the ganglion terminale induced sprouting mostly at the distal site of the knife cut while most but not all GnRH fibers proximal to the lesion had disappeared. The results of the present study indicate that the olfactory GnRH system is mostly associated with the nervus terminalis. This cranial nerve apparently projects to the central nervous system as well as the periphery. The results of the HRP uptake studies suggest that the GnRH neurons in the nervus terminalis have access to fenestrated capillaries in the subepithelial connective tissue of the nasal mucosa, to the nasal epithelium proper, and to the subarachnoid space. It is concluded that GnRH in the olfactory system of the mouse can influence different target sites either via the blood stream after release into the submucosal capillaries, or via the external cerebrospinal fluid or via synaptic/asynaptic contacts with, for example, the receptor cells in the nasal epithelium.     

Amphibian olfactory receptor neurons express olfactory marker protein

Expression of olfactory marker protein (OMP) in olfactory receptor neurons (ORNs) in two amphibians was investigated by immunohistochemical methods. The OMP immunoreactivity was observed in the cilia, apical dendritic knobs, dendrites and somas of ORNs; the axons of ORNs also showed intense immunoreactivity for OMP throughout their course from the olfactory epithelium to the glomerular layer of the olfactory bulb. Seven days after olfactory nerve transection in salamander, the number of OMP-positive ORNs was markedly reduced in the ipsilateral epithelium. The results demonstrate that amphibian ORNs express OMP and confirm its phylogenetic conservation across diverse species.     

Labelling of olfactory bulb glomeruli following horseradish peroxidase lavage of the nasal cavity

The transport of horseradish peroxidase (HRP) from the nasal cavity to the olfactory bulb was examined in rat. HRP was present primarily in the olfactory nerve and glomerular layer. In some animals the glomeruli were densely filled with product while in others there was considerable interglomerular variation in density. Examination of the decalcified noses revealed a restricted distribution of HRP in those rats with partially labelled olfactory bulbs. The presence of small groups of densely labelled glomeruli was also noted using the 2-deoxyglucose method to examine odor-induced metabolic activity.     

Neuronal nitric oxide synthase in the olfactory system of an adult teleost fish Oreochromis mossambicus

The aim of the present study is to explore the distribution of nitric oxide synthase in the olfactory system of an adult teleost, Oreochromis mossambicus using neuronal nitric oxide synthase (nNOS) immunocytochemistry and nicotinamide adenine dinucleotide phosphate diaphorase (NADPHd) histochemistry methods. Intense nNOS immunoreactivity was noticed in several olfactory receptor neurons (ORNs), in their axonal extensions over the olfactory nerve and in some basal cells of the olfactory epithelium. nNOS containing fascicles of the ORNs enter the bulb from its rostral pole, spread in the olfactory nerve layer in the periphery of the bulb and display massive innervation of the olfactory glomeruli. Unilateral ablation of the olfactory organ resulted in dramatic loss of nNOS immunoreactivity in the olfactory nerve layer of the ipsilateral bulb. In the olfactory bulb of intact fish, some granule cells showed intense immunoreactivity; dendrites arising from the granule cells could be traced to the glomerular layer. Of particular interest is the occurrence of nNOS immunoreactivity in the ganglion cells of the nervus terminalis. nNOS containing fibers were also encountered in the medial olfactory tracts as they extend to the telencephalon. The NADPHd staining generally coincides with that of nNOS suggesting that it may serve as a marker for nNOS in the olfactory system of this fish. However, mismatch was encountered in the case of mitral cells, while all are nNOS-negative, few were NADPHd positive. The present study for the first time revealed the occurrence of nNOS immunoreactivity in the ORNs of an adult vertebrate and suggests a role for nitric oxide in the transduction of odor stimuli, regeneration of olfactory epithelium and processing of olfactory signals.     

Anterograde transsynaptic transport of WGA-HRP in rat olfactory pathways

The transport of wheat germ agglutinin conjugated to horseradish peroxidase (WGA-HRP) was studied in rat olfactory pathways. After applications of tracer to the vomeronasal organ, the olfactory epithelium or injections into the olfactory bulb, WGA-HRP reaction product was observed in second-order neuron terminal areas of each pathway, e.g. within posteromedial cortical amygdaloid nucleus, primary olfactory cortex and contralateral primary olfactory cortex, respectively. The results indicate that anterograde transsynaptic transport of WGA-HRP occurs in olfactory pathways, as has been shown in visual, somatosensory and limbic systems, and thus, anterograde transsynaptic transport may be a mechanism for neurons to exchange materials and/or messages.     

Receptor-mediated transport of human recombinant nerve growth factor from olfactory bulb to forebrain cholinergic nuclei

Receptors for nerve growth factor are present in the olfactory bulb and in cholinergic nuclei that send projections to the olfactory bulb. The retrograde transport of¹²⁵I-labeled recombinant human nerve growth factor (rhNGF) was demonstrated in the rat 18 h following an injection of [¹²⁵I]rhNGF into the left olfactory bulb. In each of six animals, [¹²⁵I]rhNGF label was observed in the ipsilateral horizontal limb of the diagonal band and, in four of the 6 animals, in the vertical limb of the diagonal band. Label was not observed in any other brain region except within the injected olfactory bulb. The transport of label to the diagonal band was blocked by the injection of 170-fold greater concentration of unlabeled rhNGF. Emulsion autoradiography of hematoxylin/eosin counterstained sections revealed silver grains clustered over numerous cell profiles that resembled neurons. In contrast, cerebellar injections of [¹²⁵I]rhNGF, with or without unlabeled rhNGF, did not label diagonal band neurons, nor the lateral vestibular or red nuclei, from which originate the primary cholinergic afferents to cerebellum. The receptor-dependent transport of NGF from olfactory bulb to forebrain cholinergic nuclei suggests that this projection, unlike pontomesencephalic cholinergic pathways, may be responsive to endogenous NGF or exogenously administered rhNGF.     

Organization of projections from olfactory epithelium to olfactory bulb in the frog, Rana pipiens

One hypothesis for the coding of olfactory quality is that regions of the olfactory epithelium are differentially sensitive to particular odor qualities and that this regional sensitivity is conveyed to the olfactory bulb in a topographic manner by the olfactory nerve. A corollary to this hypothesis is that there is a sufficiently orderly connection between the epithelium and the olfactory bulb to convey this topographical coding. Thus we examined topography in the projection from epithelium to bulb in the frog, which has been the subject of numerous electrophysiological studies but has not yet been examined using modern neuroanatomical techniques. The tracer WGA-HRP was applied to the ventral or to the dorsal olfactory epithelium, or both. Anterograde transport of label to the olfactory bulb was seen after as few as 2 days; label was still present in the bulb as long as 21 days postinjection. In cases where WGA-HRP was applied to the entire epithelium, there was dense anterograde labelling of the ipsilateral olfactory bulb. In addition, a small medial portion of the contralateral bulb was labelled. Injections limited to either the ventral or dorsal epithelium produced patterns of anterograde labelling in the glomerular layer of the olfactory bulb, which varied with the size and location of the injection. With very large injections in either the dorsal or ventral epithelium, label appeared to be evenly distributed in the glomerular layer. With smaller injections in the ventral epithelium, there was heavier labelling in the lateral than in the medial portions of the glomerular layer, although light labelling was found in all regions of the glomerular layer. In contrast, injection sites restricted to the dorsal epithelium produced more anterograde labelling in the medial than lateral portions of the glomerular layer. These patterns extended throughout the dorsal-ventral extent of the bulb. Within the limits of the anterograde tracing technique used, we were unable to detect any systematic relationship between the pattern of labelling in the glomerular layer and the medial-lateral or rostral-caudal location of the injection site in either the ventral or dorsal epithelium. We conclude that in the frog, as in other amphibia, there is only a limited degree of topographic order between the epithelium and the olfactory bulb.     

Deafferentation-induced changes in the olfactory bulb of adult zebrafish

The influence of the olfactory organ on maintenance of olfactory bulb structure was examined in zebrafish, using peripheral deafferentation. This fish provides a model in which the olfactory organ is easily accessible for removal, the animals easily survive the surgery, and the olfactory bulbs are small enough to allow rigorous analysis of the resulting effects. Unilateral olfactory organ ablations were performed on anesthetized adult zebrafish using a small-vessel cautery iron. Fish were allowed to survive for 1, 3, or 6 weeks following the procedure. Analysis of deafferented animals revealed that most, if not all, of the olfactory organ was missing on the ablated side, and the structure did not regenerate. The morphology of the olfactory bulb was affected notably by the removal of its primary afferent innervation. The olfactory nerve layer was diminished at 1 week and absent by 3 weeks post-deafferentation. At all of the survival times the deafferented bulb appeared significantly smaller at the gross level, and there was a statistically significant effect on bulb size and cell number after 6 weeks. Tyrosine hydroxylase expression, as revealed by immunohistochemistry, was decreased noticeably on the ablated side. In conclusion, the olfactory organ is important in the preservation of normal olfactory bulb anatomy and neurochemistry in adult zebrafish. Thus, the influence of the periphery does not end with the formation of the mature olfactory bulb.     

Vagus nerve stimulation modifies the electrical activity of the olfactory bulb

Evoked potential and unit activity recording techniques were used to study the effects of the vagus nerve stimulation on the olfactory bulb. A biphasic potential was evoked in the olfactory bulb by a single pulse delivered to the vagus nerve. Half of the neurons studied decreased discharge frequency after single pulse or train stimulation. The interval during which neurons ceased activity corresponded to the duration of the negative wave of the evoked potential. Responsive neurons were marked with horseradish peroxidase applied iontophoretically. Responsive neurons were located in the periglomerular layer of the olfactory bulb. These results suggest the existence of a vagus nerve-olfactory bulb pathway. The functional significance of this pathway is discussed.     

Transport of molecules from nose to brain: Transneuronal anterograde and retrograde labeling in the rat olfactory system by wheat germ agglutinin-horseradish peroxidase applied to the nasal epithelium

Transneuronal anterograde labeling with the conjugate wheat germ agglutinin-horseradish peroxidase (WGA-HRP) has been documented in the mammalian and immature avian visual system [6,14]. Transneuronal retrograde labeling was significant only in the chick [6]. The present study was performed to determine whether transneuronal labeling could be shown in the mammalian olfactory system, whether the phenomenon was robust in adults, and whether transneuronal retrograde transport could label several transmitter-specific centrifugal afferent projections to the olfactory bulb. In addition we wished to learn whether molecules that enter the nasal cavity can undergo transport to brain neurons. Gelfoam implants soaked with 1% WGA-HRP, surgically implanted into the nasal cavity, produced transneuronal labeling patterns that affirmed all of these questions. Transneuronal anterograde transport labeled the appropriate zones in the olfactory bulb and in all second order olfactory targets. In addition, there was transneuronal retrograde labeling of neurons in the olfactory bulb, anterior olfactory nucleus and in transmitter-specific projection neurons from the diagonal band (cholinergic), raphe (serotonergic) and locus coeruleus (noradrenergic). Transneuronal labeling was robust and consistent. The patterns of labeling indicated that transneuronal anterograde and retrograde transport occurred along known, specific circuits in the olfactory system. The present results suggest that nasal epithelial application of WGA-HRP may be a useful tool for assessing regeneration of primary olfactory neurons and the status of central circuitry following regeneration. The method should also facilitate the study of central olfactory connections after surgical or genetic lesions of the olfactory bulb. Finally, these experiments suggest the possibility that inhaled molecules including, possibly substances of abuse, may be transported to, and, possibly, influence the function of neurons in the brain, including some (diagonal band, raphe, locus coeruleus) which have extensive projections to wide areas of the CNS.     

Locus coeruleus stimulation modulates olfactory bulb evoked potentials

Field-evoked potentials from the main olfactory bulb in response to stimulation of the olfactory nerve and lateral olfactory tract were measured without and with conditioning stimulation of the locus coeruleus noradrenergic system. The locus coeruleus conditioning stimulus suppressed or inhibited the late components of the olfactory bulb potential evoked by orthodromic olfactory nerve stimulation; this inhibitory effect was suppressed by the microinjection of the alpha-adrenergic blocker prazosin into the olfactory bulb. Results indicate that noradrenergic fibers projecting from the locus coeruleus exert modulatory influences on neuronal networks underlying orthodromic evoked responses in the main olfactory bulb.     

Glutathione levels in olfactory and non-olfactory neural structures of rats

Olfactory receptor neurons are a CNS entry point for a wide variety of airborne substances. Therefore, it is probable that detoxification mechanisms are present in these neurons to neutralize such agents. Glutathione (GSH) is an essential component of several detoxification schemes, and in this study we examined the distribution and levels of GSH in the olfactory epithelium, olfactory bulb, cortex, hippocampus and cerebellum in neonatal, weanling, adult and aged rats. We report that GSH is primarily localized to the olfactory receptor neurons and their oxons within the olfactory epithelium. It is also localized within the glomerular neuropil and granule cells of the olfactory bulb. Levels of GSH in the olfactory epithelium and hippocampus do not change as a function of age, although GSH levels decrease in several brain regions, including the olfactory bulb, cerebellum and cortex.     

Evaluation of projection patterns in the primary olfactory system of rainbow trout.

Topographic projections are important for coding sensory information in the visual, auditory, and somatosensory systems but are of uncertain importance in the coding of olfactory information. We searched for topographic projections between olfactory receptor cells and the olfactory bulb of the rainbow trout Oncorhynchus mykiss. Anterograde axonal tracing with HRP revealed that the olfactory axons arising from discrete regions of the olfactory epithelium travel together within the olfactory nerve. The abrupt resorting and redistribution of these axons at the interface between the olfactory nerve and olfactory bulb imply that local cues control and organize axonal projections. The sites of termination of HRP-labeled axons in the glomerular layer could not be predicted from the location of their cell bodies in the periphery. Retrograde tracing with fluorescently labeled latex beads, injected into glomerular subregions as small as 1% of the total glomerular volume, labeled receptor cells dispersed throughout the olfactory epithelium. The distributions of labeled receptor cells were uncorrelated with the bulbar injection sites. Double-labeling experiments revealed that even widely separated sites in the glomerular layer receive axons from comingled populations of receptor cells. Hence, the evidence indicates that the spatial arrangement of olfactory receptor cells in the epithelium is not preserved in the termination of their axons in the olfactory bulb. We conclude that the primary olfactory in trout lacks point-to-point or regionally topographic organization and that the entire extent of the olfactory epithelium contributes axons to each region of the glomerular layer.     

Peroxidase backfills suggest the mammalian olfactory epithelium contains a second morphologically distinct class of bipolar sensory neuron: the microvillar cell

The olfactory epithelium of man, rat and some other mammals consists of 4 cell types: ciliated olfactory receptors, microvillar cells, supporting (sustentacular) cells, and basal cells. Of these, the microvillar cell is least well understood: its function is unknown. In this study, a hypothesis is put forth: that the microvillar cells in the mammalian olfactory epithelium comprise a morphologically distinct class of sensory receptor. The hypothesis is tested by injecting the cytochemical tracer macromolecule horseradish peroxidase (HRP) into the olfactory bulb of the rat, and observing its pattern of uptake in the olfactory epithelium by light and electron microscopy. In these experiments, ciliated olfactory receptors and microvillar cells backfilled with HRP: supporting and basal cells did not. The data, which support the hypothesis, indicate the microvillar cells, along with the ciliated olfactory receptors, send axons to the olfactory bulb. Consequently, it is concluded that the microvillar cell is a sensory bipolar neuron, with the cell body in the olfactory epithelium, that sends a dendrite to the site of stimulus reception at the free surface of the olfactory epithelium, and an axon to the olfactory bulb in the brain. The similarity of microvillar cells in the olfactory epithelium to 'brush cells' found throughout the respiratory tract is discussed in detail.     

Immunohistochemical study of subclasses of olfactory nerve fibers and their projections to the olfactory bulb in the rabbit

The organization of the olfactory nerve projection to the olfactory bulb was studied immunohistochemically in the rabbit by using monoclonal antibodies (MAbs). Out of 42 MAbs raised against the homogenate of the olfactory bulb, two types of MAbs that strongly stained the olfactory nerve fibers (axons of olfactory receptor cells) were selected and their staining patterns were analysed in detail. MAbs of one type (represented by MAb R2D5) specifically labeled all olfactory receptor cells in the nasal epithelium and all olfactory nerve fibers and their terminal portions in the bulb. The other type of MAbs (represented by MAb R4B12) recognized only a subgroup of olfactory nerve fibers. The R4B12-positive fibers were distributed over the ventrolateral areas but not in the dorsomedial areas of the epithelium. Similarly in the bulb, the R4B12-positive fibers terminated in the glomeruli in the ventrolateral and the caudal regions but not in the dorsomedial region. These results demonstrate for the first time the cellular heterogeneity among olfactory receptor neurons at the molecular level. The segregated distribution of the subtypes of olfactory receptor cell axons both in the epithelium and the bulb indicates a defined topographical organization of the olfactory nerve projection. These results also suggest a functional division between dorsomedial and ventrolateral areas both in the epithelium and the bulb.     

Recovery of olfactory behavior. I. Recovery after a complete olfactory bulb lesion correlates with patterns of olfactory nerve penetration

The olfactory system is an excellent system in which to study issues related to potential functional recovery after a debilitating brain injury. The olfactory system is well-characterized, easily accessible and there are a vast number of studies available from a variety of perspectives. The experimental aim of this research is to examine the anatomical correlates associated with potential behavioral recovery in rats that receive complete olfactory bulb lesions as neonates or as adults. The results show that behavioral recovery occurs only when olfactory nerve penetration of the central nervous system is observed. Further, both olfactory nerve penetration and behavioral recovery are age-dependent phenomena. The olfactory nerve penetration only occurs when the olfactory bulb lesion is performed in neonates. Behavioral recovery of olfactory ability follows a linear trend and reaches near normal levels during the six week behavioral testing period. Histological analysis using an antibody for olfactory marker protein (an olfactory nerve-specific marker) reveals two potential candidates for the anatomical pathway responsible for behavioral recovery: olfactory nerve to orbital frontal cortex and olfactory nerve to olfactory peduncle. This report presents evidence that recovery of olfactory ability can occur in the absence of the olfactory bulb if the lesion is performed when the rat is still a neonate.     

Relations somatotopiques entre la muqueuse olfactive et le bulbe olfactif chez le triton

The axons of receptors located in the olfactory neuroepithelium are known to synapse with mitral cell dendrites in the glomerular layer of the ipsilateral olfactory bulb, but few previous studies showed a clear-cut topological organization of this projection. We therefore injected horseradish peroxidase (HRP) into restricted areas of the olfactory mucosa in adult tritons,Triturus cristatus. The animals were perfused with glutaraldehye 17 h later; the mucusa, the olfactory nerve and bulb were removed, serially cut and treated with diaminobenzidine to reveal the localization and extent of the injection and the areas in the glomerular layer of the bulb to which the injected HRP had been transported by anterograde axonal flow.Small injections of HRP tended to label a small area in the bulb, while larger injections projected to a wider zone. The results also indicated the existence of an orderly projection, with a transposition of the dorso-ventral axis of the neuroreceptor sheet into an essentially anteroposteriorly oriented axis in the bulb. Thus, the dorsally located areas of the olfactory mucosa project to the most anterior part of the glomerular layer, whereas the vomero-nasal mucosa, which is located near the most lateral part of the ventral mucosa, projects to the posterior enlargment of the glomerular layer in the bulb. The data also showed that nerve bundles within the olfactory nerve maintain an orderly position which depends upon their origin.It is postulated that this somatopic organization reflects the development undergone by the peripheral olfactory system during ontogenesis.     

Heterogeneous expression of connexin 36 in the olfactory epithelium and glomerular layer of the olfactory bulb

Gap junctions regulate a variety of cell functions by directly connecting two cells through intercellular channels. Connexins are gap junction channel-forming protein subunits. In this study, we studied the expression of connexin 36 (Cx36) in the olfactory epithelium and olfactory bulb of adult mice. In situ hybridization revealed that mRNA for Cx36 was expressed in the olfactory sensory epithelium, main olfactory bulb and accessory olfactory bulb. Expression of mRNA encoding Cx36 was observed in the olfactory epithelium mainly in ventral and lateral regions of the turbinates. Immunohistochemical determination of Cx36 protein expression showed sparse punctuate staining in the olfactory epithelial layer. Intense Cx36-like immunostaining was found in the olfactory nerve bundles underlying the olfactory epithelium and in the olfactory nerve layer and glomerular layer of the olfactory bulb. Mapping of the intensity of Cx36-like immunofluorescence in glomeruli throughout the main olfactory bulb indicated a heterogeneous distribution. A set of approximately 50 glomeruli located in the anterior and posterior limits of the olfactory bulb was more intensely labeled than other glomeruli. There was intense immunofluorescence signal in the glomerular layer of the accessory olfactory bulb and in the vomeronasal nerve. beta-Galactosidase distribution in the olfactory epithelium and olfactory bulb in Cx36 knockout mice (Deans et al. [2001] Neuron 31:477-485) supported the findings with immunofluorescence. Cx36-like immunofluorescence was absent in the olfactory nerve bundles in Cx36 knockout mice. The immunolocalization of Cx36 to the olfactory and vomeronasal nerves, and a subset of olfactory glomeruli suggest a functional role for Cx36 in odor coding.