Ectopic expression of olfactory receptors and associated G-protein subunits in the head integument of the amphihaline migratory fish hilsa Tenualosa ilisha

The chemosensory nature of the tissue from the dorsal surface of the head (also termed sensory pad; SP) of the amphihaline diadromous fish hilsa Tenualosa ilisha was investigated for odorant receptor (OR), olfactory marker protein (OMP) and G-protein subunits (Gαs-olf, Gαq, Gαo, Gαi3) through immunolocalization and immunoblotting techniques. The immunolocalization of OR, OMP and G-protein subunits showed clear expression of these proteins in the tissues of the SP. Robust expressions of these proteins in the SP were detected with immunoblot analysis. The strong expression of these proteins in the SP indicates that the tissues from this area in riverine T. ilisha may play significant role in chemosensing and signalling through ectopic expression of olfactory receptor proteins which are otherwise reported in olfactory organs in vertebrates. Being migratory in nature, ectopic expression of these receptors in T. ilisha probably helps them to prevent damage to epidermal tissues of the SP, or they may also utilize them as a chemo and mechanosensory tool to optimize chemo-communications during migration.     

Regional expression patterns of taste receptors and gustducin in the mouse tongue

In order to understand differences in taste sensitivities of taste bud cells between the anterior and posterior part of tongue, it is important to analyze the regional expression patterns of genes related to taste signal transduction on the tongue. Here we examined the expression pattern of a taste receptor family, the T1r family, and gustducin in circumvallate and fungiform papillae of the mouse tongue using double-labeled in situ hybridization. Each member of the T1r family was expressed in both circumvallate and fungiform papillae with some differences in their expression patterns. The most striking difference between fungiform and circumvallate papillae was observed in their co-expression patterns of T1r2, T1r3, and gustducin. T1r2-positive cells in fungiform papillae co-expressed T1r3 and gustducin, whereas T1r2 and T1r3 double-positive cells in circumvallate papillae merely expressed gustducin. These results suggested that in fungiform papillae, gustducin might play a role in the sweet taste signal transduction cascade mediated by a sweet receptor based on the T1r2 and T1r3 combination, in fungiform papillae.     

Olfactory Marker Protein Expression Is an Indicator of Olfactory Receptor-Associated Events in Non-Olfactory Tissues

Olfactory receptor (OR)-associated events are mediated by well-conserved components in the olfactory epithelium, including olfactory G-protein (G_olf), adenylate cyclase III (ACIII), and olfactory marker protein (OMP). The expression of ORs has recently been observed in non-olfactory tissues where they are involved in monitoring extracellular chemical cues. The large number of OR genes and their sequence similarities illustrate the need to find an effective and simple way to detect non-olfactory OR-associated events. In addition, expression profiles and physiological functions of ORs in non-olfactory tissues are largely unknown. To overcome limitations associated with using OR as a target protein, this study used OMP with G_olf and ACIII as targets to screen for potential OR-mediated sensing systems in non-olfactory tissues. Here, we show using western blotting, real-time PCR, and single as well as double immunoassays that ORs and OR-associated proteins are co-expressed in diverse tissues. The results of immunohistochemical analyses showed OMP (+) cells in mouse heart and in the following cells using the corresponding marker proteins c-kit, keratin 14, calcitonin, and GFAP in mouse tissues: interstitial cells of Cajal of the bladder, medullary thymic epithelial cells of the thymus, parafollicular cells of the thyroid, and Leydig cells of the testis. The expression of ORs in OMP (+) tissues was analyzed using a refined microarray analysis and validated with RT-PCR and real-time PCR. Three ORs (olfr544, olfr558, and olfr1386) were expressed in the OMP (+) cells of the bladder and thyroid as shown using a co-immunostaining method. Together, these results suggest that OMP is involved in the OR-mediated signal transduction cascade with olfactory canonical signaling components between the nervous and endocrine systems. The results further demonstrate that OMP immunohistochemical analysis is a useful tool for identifying expression of ORs, suggesting OMP expression is an indicator of potential OR-mediated chemoreception in non-olfactory systems.     

An enhanced olfactory marker protein immunoreactivity in individual olfactory receptor neurons following olfactory bulbectomy may be related to increased neurogenesis

Olfactory marker protein (OMP) is a 19-kD acidic protein found throughout the cytoplasm of mature olfactory receptor neurons (ORNs). Its function remains unknown. Following olfactory bulbectomy, the proportion of ORNs mature enough to express OMP declines greatly. However, in the few remaining mature ORNs, it has been observed that the intensity of OMP immunoreactivity (IR) appears to increase over that of ORNs on the unoperated side. We have now investigated this phenomenon quantitatively in rats subjected to unilateral olfactory bulbectomy. Results show that at all postbulbectomy survival periods examined quantitatively (3 days to 6 months), a significant decrease (19–37%) occurs in the transmission of incident light through OMP(+)-ORNs in bulbectomized versus unoperated olfactory epithelium (OE). Further, we also observed a consistent side-to-side difference in OMP IR in control unoperated animals. Possible explanations for these observations and their relation to the still unknown function of OMP are discussed. To test the possibility that OMP might serve a mitogenic role in the OE, recombinant OMP was added to organotypic explant cultures of fetal olfactory mucosa. Addition of OMP resulted in a dose-dependent increase in the density of bromodeoxyuridine-positive cells in the cultures, with a 50% increase occurring at the plateau OMP concentration of 25 nM. © 1998 John Wiley & Sons, Inc. J Neurobiol 34: 377–390, 1998     

Immunohistochemical distribution of galectin-1, galectin-3, and olfactory marker protein in human olfactory epithelium

The expression pattern of galectin-1 and galectin-3 in the human olfactory epithelium was investigated in relation to olfactory marker protein (OMP) using confocal laser immunofluorescence in human specimens and postmortem biopsies. OMP expression was found in olfactory receptor neurons (ORNs) in the olfactory mucosa and in fibers of the olfactory nerve crossing the submucous connective tissue. Galectin-1 was expressed in both the connective tissue of the nasal cavity and in the basal layer of the olfactory epithelium. In contrast, galectin-3 expression was limited to cells of the upper one-third of the olfactory epithelium. Expression of galectin-3 occurred in a subset of OMP-positive cells. However, between areas of galectin-1 and galectin-3 expression in the lower and upper portion of the epithelium, OMP-positive ORNs did not stain for both galectins. Considering the potential role of galectin-1 and galectin-3 in cell differentiation and maturation, the differential localization of galectins in the olfactory epithelium appears to be consistent with a significant role of these molecules in the physiological turnover of ORNs. Accepted: 20 December 1999     

Genomic structure of swine taste receptor family 1 member 3, TAS1R3, and its expression in tissues

Taste receptor family 1 member 3, TAS1R3, is shown to be involved in sweet and umami tastes in mouse, and the nucleotide sequence of the gene has been reported in rat, gorilla, and human. Pigs are frequently used as models for human diseases, and are also considered to be source animals for xenotransplantation to humans due to their anatomical and physiological similarities to humans. Therefore, in the present study, the genomic structure of the swine TAS1R3 gene was determined, and TAS1R3 expression was studied in various swine tissues. The gene was shown to reside on swine chromosome 6q22-->q23, from which three types of mRNAs were generated: 3,752 bp derived from six exons in tongue, 3,704 bp from six exons and 3,630 bp from seven exons in testis. The 6 exons/5 introns were structurally similar to those of humans and mice, but the 7 exons/6 introns structure of TAS1R3 was first observed in swine. High expressions of TAS1R3 were revealed in tongue, kidney, and testis by real-time PCR. The expression profile of the tissues except for kidney was similar to that of mouse. When in situ hybridization using an RNA probe for TAS1R3 was performed on swine tongue and testis tissues, TAS1R3 expressions were revealed in tongue circumvallate papillae, fungiform papillae, mucosal epithelium, follicular B lymphocytes, lymphocytes in submucosal tissues of lingual tonsil, and spermatogenic cells. Using peripheral mature B lymphocytes, the expression of TAS1R3 in B lymphocytes was further confirmed by real-time PCR and sequencing of the real-time PCR product.     

Extraepithelial cells expressing distinct olfactory receptors are associated with axons of sensory cells with the same receptor type

During critical phases of mouse development, axons from olfactory sensory neurons grow out of the nasal neuroepithelium and navigate through the connective mesenchyme tissue towards their targets in the developing telencephalic vesicle. Between embryonic days E11 and E16, populations of cells are located in the mesenchyme which express distinct olfactory receptor genes along with the olfactory marker protein (OMP); thus they express markers characteristic for mature olfactory sensory neurons. These extraepithelial cells are positioned along the axon tracts, and each population expressing a given receptor gene is specifically associated with the axons of those olfactory sensory neurons with the same receptor type. The data suggest that they either might be guide posts for the outgrowing axons or migrate along the axons into the brain.     

Identification of an olfactory receptor neuron subclass: cellular and molecular analysis during development

Development of olfactory receptor neuron populations was studied using the previously described monoclonal antibody (Mab) 2B8 which binds to cell surface glycoproteins of presumptive olfactory receptor neurons. In order to definitively demonstrate that the cells recognized were olfactory receptor neurons and to better characterize these cells during development, a well-established receptor cell marker, olfactory marker protein (OMP), was studied at the same time as the 2B8 antigens in double-label immunofluorescence analyses of olfactory structures in rats from Day 13 of gestation (E13) to the early postnatal period. Olfactory epithelium cryostat sections of E13 rats showed binding of the 2B8 Mab to bipolar cells in caudal regions of the nasal cavity. The 2B8 Mab also recognized a large number of cells in the vomeronasal organ (VNO) at this stage. No specific binding of anti-OMP was seen until E15. At this time approximately half of the 2B8 reactive cells also expressed OMP. By birth, greater than 90% of the 2B8 reactive cells expressed OMP. The percentage of total fluorescent labeled cells which are double labeled remained relatively constant at 23-33% as the total number of cells increased between E15 and 2 days postnatal. 2B8 immunoreactivity can be found in the olfactory nerve layer of the olfactory bulb and the presumptive accessory olfactory bulb at E15. In double-label experiments the 2B8 Mab did not bind to all anti-OMP-labeled glomeruli of postnatal to adult rats. In summary, the 2B8 Mab recognizes cells early during development and appears to recognize a subclass of olfactory receptor cells and their axon terminals. Developmental changes in the electrophoretic profile of the olfactory 2B8 antigens were also studied. In the olfactory epithelium a single band at Mr of 200,000 was seen at E19. After birth three bands at 220,000, 180,000 and 110,000 were observed but in adults only two bands of Mr 215,000 and 163,000 were detected. During olfactory bulb development the Mr of the two major 2B8 reactive bands did not change but remained the same as the two major bands seen in the adult olfactory epithelium. The olfactory bulb band at Mr of 215,000 showed a 3 to 4-fold increase and the band at 163,000 showed a 10-fold increase in specific activity from birth to adulthood.     

Expression of olfactory receptors in the cribriform mesenchyme during prenatal development

Olfactory receptors (ORs) are expressed in sensory neurons of the nasal epithelium, where they are supposed to be involved in the recognition of suitable odorous compounds and in the guidance of outgrowing axons towards the appropriate glomeruli in the olfactory bulb. During development, some olfactory receptor subtypes have also been found in non-sensory tissues, including the cribriform mesenchyme between the prospective olfactory epithelium and the developing telencephalon, but it is elusive if this is a typical phenomenon for ORs. Monitoring the onset and time course of expression for several receptor subtypes revealed that 'extraepithelial' expression of ORs occurs very early and transiently, in particular between embryonic stages E10.25 and E14.0. In later stages, a progressive loss of receptor expressing cells was observed. Molecular phenotyping demonstrated that the receptor expressing cells in the cribriform mesenchyme co-express key elements, including Galpha(olf), ACIII and OMP, characteristic for olfactory neurons in the nasal epithelium. Studies on transgenic OMP/GFP-mice showed that 'extraepithelial' OMP/GFP-positive cells are located in close vicinity to axon bundles projecting from the nasal epithelium to the presumptive olfactory bulb. Moreover, these cells are primarily located where axons fasciculate and change direction towards the anterior part of the forebrain.     

Identification of members of the Bex gene family as olfactory marker protein (OMP) binding partners

Olfactory marker protein (OMP) expression is a hallmark of mature vertebrate olfactory receptor neurons (ORNs). Evidence for OMP function derives from altered behavioral and electrophysiological activities of OMP-KO mice. The molecular basis for the altered phenotype following the deletion of OMP is still unclear. Recent structural studies predict the involvement of OMP in protein-protein interaction. Here we report the identification of an OMP partner, Bex2, by phage-display screening of an olfactory mucosal cDNA-library. In situ hybridization demonstrates cellular co-localization of OMP mRNA with mRNAs for Bex1, Bex2, and Bex3 in ORNs of olfactory tissue of the mouse. The OMP/Bex interaction has been confirmed by demonstrating the chemical cross-linking of recombinant rat OMP with a synthetic peptide derived from the Bex amino acid sequence. The subcellular localization of Bex and OMP proteins was evaluated in transfected HEK293 cells. Bex is visualized in the nucleus and cytoplasm. Following co-transfection we observed the unexpected presence of some OMP in the nucleus along with Bex. Together, these data argue convincingly that we have identified Bex as an OMP partner whose further characterization will provide insight to the role of OMP and to the mechanism of the OMP/Bex interaction in ORN differentiation and function.     

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.     

Maturation of vomeronasal receptor neurons in vitro by coculture with accessory olfactory bulb neurons

To analyze the mechanisms of perception and processing of pheromonal signals in vitro, we previously developed a new culture system for vomeronasal receptor neurons (VRNs), referred to as the vomeronasal pocket (VN pocket). However, very few VRNs were found to express the olfactory marker protein (OMP) and to have protruding microvilli in VN pockets, indicating that these VRNs are immature and that VN pockets are not appropriate for pheromonal recognition. To induce VRN maturation in VN pockets, we here attempted to coculture VN pockets with a VRN target-accessory olfactory bulb (AOB) neurons. At 3 weeks of coculture with AOB neurons, the number of OMP-immunopositive VRNs increased. By electron microscopy, the development of microvilli in VRNs was found to occur coincidentally with OMP expression in vitro. These results indicate that VRN maturation is induced by coculture with AOB neurons. The OMP expression of VRNs was induced not only by AOB neurons but also by neurons of other parts of the central nervous system (CNS). Thus, VRN maturation requires only CNS neurons. Since the maturation of VRNs was not induced in one-well separate cultures, the nonspecific induction of OMP expression by CNS neurons suggests the involvement of a direct contact effect with CNS in VRN maturation.     

Expression of adenosine A2b receptor in rat type II and III taste cells

We previously demonstrated that equilibrative nucleoside transporter 1 was expressed in taste cells, suggesting the existence of an adenosine signaling system, but whether or not the expression of an adenosine receptor occurs in rat taste buds remains unknown. Therefore, we examined the expression profiles of adenosine receptors and evaluated their functionality in rat circumvallate papillae. Among adenosine receptors, the mRNA for an adenosine A2b receptor (A2bR) was expressed by the rat circumvallate papillae, and its expression level was significantly greater in the circumvallate papillae than in the non-taste lingual epithelium. A2bR-immunoreactivity was detected primarily in type II taste cells, and partial, but significant expression was also observed in type III ones, but there was no immunoreactivity in type I ones. The cAMP generation in isolated epithelium containing taste buds treated with 500 μM adenosine or 10 μM BAY60-6583 was significantly increased compared to in the controls. These findings suggest that adenosine plays a role in signaling transmission via A2bR between taste cells in rats.     

Localization of type II collagen in the lingual mucosa of rats during the morphogenesis of circumvallate papillae

Iwasaki, S., Aoyagi, H. and Yoshizawa, H. 2011. Localization of type II collagen in the lingual mucosa of rats during the morphogenesis of circumvallate papillae. —Acta Zoologica (Stockholm) 92 : 67–74. Immunoreactivity specific for type II collagen was recognized first in the mesenchymal connective tissue just beneath the circumvallate papilla placode in fetuses on E13. At this stage, most of the lingual epithelium was pseudostratified epithelium composed of one or two layers of cuboidal cells. However, the epithelium of the circumvallate papilla placode was composed of several layers of cuboidal cells. Immunoreactivity specific for type II collagen was detected mainly on the lamina propria just beneath the lingual epithelium of the rudiment of the circumvallate papilla in fetuses on E15 and on E17, and slight immunostaining was detected on the lamina propria around the rudiment. In fetuses on E19, immunoreactivity specific for type II collagen was widely and densely distributed on the connective tissue around the developing circumvallate papillae and on the connective tissue that surrounded the lingual muscle. Immunoreactivity specific for type II collagen was sparsely distributed on the lamina propria of central bulge. After birth, morphogenesis of the circumvallate papillae advanced gradually with the increase in size of the tongue. Immunoreactivity specific for type II collagen was distinctively distributed in the lamina propria around circumvallate papilla, in the central bulge, and in the connective tissue that surrounded the lingual muscle.