Sodium/calcium exchanger in rat olfactory neurons

The chemo-electrical transduction process in olfactory neurons is accompanied by a rapid and transient increase in intracellular calcium concentrations. The notion that Na⁺/Ca²⁺ exchanger activities may play a major role in extruding calcium ions out of the cell and maintaining Ca²⁺ homeostasis in olfactory receptor cells was assessed by means of laser scanning confocal microscopy in combination with the fluorescent indicators Fluo-3 and Fura-Red. The data indicate that high exchanger acitivity, which was inhibited by amiloride derivatives, is located in the dendritic knob and probably in the olfactory cilia. This result was supported by experiments using specific antiserum raised against retinal Na⁺/Ca²⁺ exchanger protein which labelled an immunoreactive protein of 230 kDa in Western blots from olfactory tissue and strongly stained the ciliary layer of the olfactory epithelium.     

Bovine olfactory cilia preparation: thiol-modulated odorant-sensitive adenylyl cyclase

We have characterized the adenylyl cyclase activity in a newly developed preparation of isolated olfactory cilia from the bovine chemosensory neuroepithelium. Like its counterparts from frog and rat, the ciliary enzyme was stimulated by guanine nucleotides, by forskolin, and by a variety of odorants in the presence of GTP. The main difference between the bovine olfactory cilia preparation and the frog and rat olfactory cilia preparation is that odorant stimulation of the bovine olfactory adenylyl cyclase is strongly inhibited by submillimolar concentrations of dithiothreitol. This inhibition is a consequence of a concomitant increase in the GTP-stimulated level and the decrease of the odorant stimulation of the enzyme. Nasal respiratory cilia have a much lower level of adenylyl cyclase activity and show no odorant stimulation. Owing to the large quantities of material available, the bovine olfactory cilia preparation is advantageous for studies of the proteins involved in chemosensory transduction.     

A novel calcium-regulated membrane guanylate cyclase transduction system in the olfactory neuroepithelium

This report defines the identity of a calcium-regulated membrane guanylate cyclase transduction system in the cilia of olfactory sensory neurons, which is the site of odorant transduction. The membrane fraction of the neuroepithelial layer of the rat exhibited Ca(2+)-dependent guanylate cyclase activity, which was eliminated by the addition of EGTA. This indicated that the cyclase did not represent a rod outer segment guanylate cyclase (ROS-GC), which is inhibited by free Ca(2+). This interpretation was supported by studies with the Ca(2+) binding proteins, GCAPs (guanylate cyclase activating proteins), which stimulate photoreceptor ROS-GC in the absence of Ca(2+). They did not stimulate the olfactory neuroepithelial membrane guanylate cyclase. The olfactory neuroepithelium contained a Ca(2+) binding protein, neurocalcin, which stimulated the cyclase in a Ca(2+)-dependent fashion. The cyclase was cloned from the neuroepithelium and was found to be identical in structure to that of the previously cloned cyclase termed GC-D. The cyclase was expressed in a heterologous cell system, and was reconstituted with its Ca(2+)-dependent activity in the presence of recombinant neurocalcin. The reconstituted cyclase mimicked the native enzyme. Immunocytochemical studies showed that the guanylate cyclase coexists with neurocalcin in the apical region of the cilia. Deletion analysis showed that the neurocalcin-regulated domain resides at the C-terminal region of the cyclase. The findings establish the biochemical, molecular, and functional identity of a novel Ca(2+)-dependent membrane guanylate cyclase transduction system in the cilia of the olfactory epithelium, suggesting a mechanism of the olfactory neuroepithelial guanylate cyclase regulation fundamentally distinct from the phototransduction-linked ROS-GC.     

Comparison of mechanical agitation and calcium shock methods for preparation of a membrane fraction enriched in olfactory cilia

Calcium plays an important regulatory role in olfactory signal transduction. Many investigations into the regulation of the olfactory signaling pathway have been performed using fractions enriched in ciliary membranes from olfactory sensory neurons. The traditional method of preparing ciliary fractions uses high calcium concentrations, thought to dislodge cilia from the dendritic knobs of the olfactory neurons in the nasal epithelium. However, calcium, an important second messenger in the odorant signaling cascade, modulates the activity of many enzymatic reactions in this cascade. Pre-exposure of cilia to high calcium concentrations may modify these signaling events. Therefore, we sought to develop a method of isolating cilia-enriched membranes that avoids exposing the cilia to high calcium concentrations. Our method of isolation, referred to as the mechanical agitation method, involves mechanical disruption and sonication of the olfactory epithelium to dislodge the cilia. To evaluate this method of cilia preparation, basal adenylyl cyclase activity, as well as forskolin- and odorant-activated adenylyl cyclase, were analyzed. Specific activity of adenylyl cyclase and protein yield were compared for the mechanical agitation and the high calcium preparations. Immunoblots were analyzed for the presence of transduction components enriched in olfactory cilia: adenylyl cyclase type III (ACIII), heterotrimeric G-protein subunit Galphaolf and the 1 C2 isoform of phosphodiesterase (PDE 1 C2). Based on these analyses, the ciliary fraction prepared by the mechanical agitation method appears to be very similar to that prepared by the high calcium method, with a higher yield.     

Whole Mount Labeling of Cilia in the Main Olfactory System of Mice

The mouse olfactory system comprises 6-10 million olfactory sensory neurons in the epithelium lining the nasal cavity. Olfactory neurons extend a single dendrite to the surface of the epithelium, ending in a structure called dendritic knob. Cilia emanate from this knob into the mucus covering the epithelial surface. The proteins of the olfactory signal transduction cascade are mainly localized in the ciliary membrane, being in direct contact with volatile substances in the environment. For a detailed understanding of olfactory signal transduction, one important aspect is the exact morphological analysis of signaling protein distribution. Using light microscopical approaches in conventional cryosections, protein localization in olfactory cilia is difficult to determine due to the density of ciliary structures. To overcome this problem, we optimized an approach for whole mount labeling of cilia, leading to improved visualization of their morphology and the distribution of signaling proteins. We demonstrate the power of this approach by comparing whole mount and conventional cryosection labeling of Kirrel2. This axon-guidance adhesion molecule is known to localize in a subset of sensory neurons and their axons in an activity-dependent manner. Whole mount cilia labeling revealed an additional and novel picture of the localization of this protein.     

Olfactory transduction: cross-talk between second-messenger systems

Chemosensory cilia of olfactory receptor neurons contain an adenylate cyclase which is stimulated by high concentrations of odorants. Cyclic AMP produced by this enzyme has been proposed to act as second messenger in olfactory transduction. Here we report that olfactory cilia contain calmodulin and that calmodulin potently activates olfactory adenylate cyclase by a mechanism additive to and independent from direct stimulation by odorants. Activation by calmodulin is calcium dependent and enhanced by GTP. Thus, olfactory transduction may involve a second-messenger cascade in which an odorant-induced increase in intracellular calcium concentration leads to activation of adenylate cyclase by calmodulin.     

Cyclic AMP-Dependent Protein Phosphorylation in Chemosensory Neurons: Identification of Cyclic Nucleotide-Regulated Phosphoproteins in Olfactory Cilia

Chemosensory dendritic membranes (olfactory cilia) contain protein kinase activity that is stimulated by cyclic AMP and more efficiently by the nonhydrolyzable GTP analog guanosine-5'-O-(3-thio)triphosphate (GTP gamma S). In control nonsensory (respiratory) cilia, the cyclic AMP-dependent protein kinase is practically GTP gamma S-insensitive. GTP gamma S activation of the olfactory enzyme appears to be mediated by a stimulatory GTP-binding protein (G-protein) and adenylate cyclase previously shown to be enriched in the sensory membranes. Protein kinase C activity cannot be detected in the chemosensory cilia preparation under the conditions tested. Incubation of olfactory cilia with [gamma-32P]ATP leads to the incorporation of [32P]phosphate into many polypeptides, four of which undergo covalent modification in a cyclic nucleotide-dependent manner. The phosphorylation of one polypeptide, pp24, is strongly and specifically enhanced by cyclic AMP at concentrations lower than 1 microM. This phosphoprotein is not present in respiratory cilia, but is seen also in membranes prepared from olfactory neuroepithelium after cilia removal. Cyclic AMP-dependent protein kinase and phosphoprotein pp24 may be candidate components of the molecular machinery that transduces odor signals.     

Effects of Ca2+ and calmodulin on adenylyl cyclase activity in sheep olfactory epithelium

Sheep olfactory epithelium contains an adenylyl cyclase which is stimulated by many but not all odorants. Here we report that this enzyme is activated by calmodulin in a dose-dependent manner, and that calcium ions are required for this response. Odorant stimulation of adenylyl cyclase is unaffected by the complex Ca²⁺/calmodulin, as suggested by the results obtained both in Ca²⁺/calmodulin-depleted membranes and under calmodulin antagonist treatment; this confirms the prediction that the Ca²⁺ binding protein and odorants stimulate the olfactory adenylyl cyclase through parallel mechanisms. The persistent activation of the regulatory component of adenylyl cyclase by GppNHp does not alter the response of the enzyme to either odorant or Ca²⁺/calmodulin. In sheep olfactory epithelium a cAMP-phosphodiesterase activity is also present, which is highly inhibited by IBMX and aminophylline, searcely by RO 20-1724, and unaffected by Ca²⁺/calmodulin. The modulatory role exerted by calcium on cAMP system in sheep olfactory signal transduction is discussed.     

Guanylate cyclase in olfactory cilia from rat and pig

A guanylate cyclase was identified in cilia from rat and pig olfactory epithelia. Enzyme activities were 200-250 and 90-100 pmol/min.mg-1, respectively. Activity required the presence of non-ionic detergents, e.g., 0.1% Lubrol PX. MnGTP, not MgGTP was used as a substrate. Furthermore, 0.9 mM free Mn2+ was necessary for optimal activity indicating a regulatory site for a divalent cation. The guanylate cyclase displayed sigmoidal Michaelis-Menten kinetics suggesting cooperativity between MnGTP and enzyme. S0.5 was 160 microM MnGTP. The Hill coefficient of 1.7 indicates that more than one class of substrate-binding sites interact in a positive cooperative manner. ATP inhibited the enzyme and linearized plots of substrate kinetics with MnGTP. SH-Blocking agents reversibly inhibited enzyme activity. Sodium azide and nitroprusside were without effect as were several odorants. A guanylate cyclase activity in cilia from tracheal tissue had properties similar to the olfactory enzyme.     

Renal cystic disease proteins play critical roles in the organization of the olfactory epithelium

It was reported that some proteins known to cause renal cystic disease (NPHP6; BBS1, and BBS4) also localize to the olfactory epithelium (OE), and that mutations in these proteins can cause anosmia in addition to renal cystic disease. We demonstrate here that a number of other proteins associated with renal cystic diseases - polycystin 1 and 2 (PC1, PC2), and Meckel-Gruber syndrome 1 and 3 (MKS1, MKS3) - localize to the murine OE. PC1, PC2, MKS1 and MKS3 are all detected in the OE by RT-PCR. We find that MKS3 localizes specifically to dendritic knobs of olfactory sensory neurons (OSNs), while PC1 localizes to both dendritic knobs and cilia of mature OSNs. In mice carrying mutations in MKS1, the expression of the olfactory adenylate cyclase (AC3) is substantially reduced. Moreover, in rats with renal cystic disease caused by a mutation in MKS3, the laminar organization of the OE is perturbed and there is a reduced expression of components of the odor transduction cascade (G(olf), AC3) and α-acetylated tubulin. Furthermore, we show with electron microscopy that cilia in MKS3 mutant animals do not manifest the proper microtubule architecture. Both MKS1 and MKS3 mutant animals show no obvious alterations in odor receptor expression. These data show that multiple renal cystic proteins localize to the OE, where we speculate that they work together to regulate aspects of the development, maintenance or physiological activities of cilia.     

Formation and maturation of olfactory cilia monitored by odorant receptor-specific antibodies

The responsiveness of olfactory sensory neurons (OSNs) is based on odorant receptors (ORs) residing in the membrane of chemosensory cilia. It is still elusive as to when and how olfactory cilia are equipped with OR proteins rendering them responsive to odorants. To monitor the appearance of OR proteins in sensory compartments of OSNs, the olfactory epithelium of mice at various stages of prenatal development (lasting 19 days from conception) was investigated using immunohistochemical approaches and antibodies specific for different OR subtypes. These experiments uncovered that OR proteins accumulated in dendritic knobs of OSNs before the initiation of ciliogenesis (embryonic stage E12). As the first cilia were formed (E13), immunostaining in the knobs diminished. Cilia extended uprightly into the nasal cavity and were immunoreactive along the entire length, and particularly intense labeling was observed in expanded tips of cilia. During this phase of development (up to E18), the number of cilia per knob continuously increased. In the course of perinatal stages, longer cilia began to bend off and lie flat on the epithelial surface. The multiple cilia of a knob extended in length, and eventually the ciliary meshwork reached the characteristic complex pattern. In all stages, OR immunostaining was visible along the entire cilium. Thus, OR-specific antibodies allowed, for the first time, monitoring at the level of light microscopy the generation, outgrowth, and maturation of cilia in OSNs.     

Genetic Ablation of Type III Adenylyl Cyclase Exerts Region-Specific Effects on Cilia Architecture in the Mouse Nose

We recently reported that olfactory sensory neurons in the dorsal zone of the mouse olfactory epithelium exhibit drastic location-dependent differences in cilia length. Furthermore, genetic ablation of type III adenylyl cyclase (ACIII), a key olfactory signaling protein and ubiquitous marker for primary cilia, disrupts the cilia length pattern and results in considerably shorter cilia, independent of odor-induced activity. Given the significant impact of ACIII on cilia length in the dorsal zone, we sought to further investigate the relationship between cilia length and ACIII level in various regions throughout the mouse olfactory epithelium. We employed whole-mount immunohistochemical staining to examine olfactory cilia morphology in phosphodiesterase (PDE) 1C^-/-;PDE4A^-/- (simplified as PDEs^-/- hereafter) and ACIII^-/- mice in which ACIII levels are reduced and ablated, respectively. As expected, PDEs^-/- animals exhibit dramatically shorter cilia in the dorsal zone (i.e., where the cilia pattern is found), similar to our previous observation in ACIII^-/- mice. Remarkably, in a region not included in our previous study, ACIII^-/- animals (but not PDEs^-/- mice) have dramatically elongated, comet-shaped cilia, as opposed to characteristic star-shaped olfactory cilia. Here, we reveal that genetic ablation of ACIII has drastic, location-dependent effects on cilia architecture in the mouse nose. These results add a new dimension to our current understanding of olfactory cilia structure and regional organization of the olfactory epithelium. Together, these findings have significant implications for both cilia and sensory biology.     

Mechanisms of electromechanical and electrochemical coupling in olfactory cilia of the frog (<Emphasis Type="Italic">Rana temporaria</Emphasis>)

The mechanisms of electromechanical and electrochemical coupling in olfactory cilia of the frog (Rana temporaria) have been investigated. High-resolution optical television microscopy of live tissue and pharmacological analysis have been used to reveal the regulation of the motility of olfactory cilia in the absence of odorants; the entry of Ca²⁺ ions mediated by three types of ion channels (mechanosensitive, cyclic nucleotide gated, and voltage-gated) was shown to determine the motility of cilia. Stimulation of the olfactory adenylate cyclase by movements of the cilia in the absence of odors has been demonstrated and the regulation of cilia motility by membrane potential has been revealed. Membrane potential can affect olfactory acuity and the ability to perceive weak olfactory stimuli in the absence of adequate stimulation.     

Binding of the pheromonal steroid, 5alpha-androst-16-en-3-one, to membrane-enriched fractions of boar and rat olfactory epithelium; preliminary evidence for binding protein being a glycoprotein

A high degree of binding of 5alpha-[3H]-androstenone was recorded in membrane-enriched fractions of porcine olfactory tissue. The specific (i.e. high affinity, low capacity) binding had a mean Ka approximately 2x10(8)M(-1). A Hill plot of the data showed a Hill coefficient of approximately 2, possibly suggesting co-operativity of binding, with binding constants increasing from 8x10(7) to 1.6x10(9)M(-1) with increasing substrate concentration. The level of specific binding of 5alpha-[3H]-androstenone was nearly 10-fold higher than in corresponding respiratory tissue preparations and was markedly reduced in the presence of excess (approximately 1 microM) unlabelled 5alpha-androstenone. Corresponding fractions derived from rat olfactory tissue showed only 25% of the binding recorded for the pig. After incubation of 5alpha-[3H]-androstenone with solubilised olfactory cilial tissue (porcine), gel filtration and chromatography on a typical "glycoprotein" column (Concanavalin A-Sepharose B) were performed. Specific binding was recorded only in fractions corresponding to glycoproteins with Mr of approximately 70-90 kDa. In a third series of experiments, fractions containing high concentrations of cilia, some still attached to the dendritic endings (as shown by electron microscopy) were obtained by a novel method involving stripping them off the nasal epithelium. The basal adenylate cyclase (AC) activity was very significantly (P<0.01) higher in olfactory, compared with respiratory, cilia; storage at -70 degrees C for 3 weeks greatly reduced AC activity. When fresh male and female porcine olfactory cilia preparations were incubated with 5alpha-androstenone plus GTP, AC activity was increased fourfold (P<0.01). However, responses of porcine respiratory cilia were not significant statistically, neither were changes in basal levels of AC activities in rat olfactory cilia.     

Characterization of p26olf, a novel calcium-binding protein in the frog olfactory epithelium

We have previously shown that p26olf is a novel S100-like Ca(2+)-binding protein in the frog olfactory epithelium. In this paper, we characterized the Ca(2+) binding property of p26olf, examined the precise localization in the frog olfactory epithelium, and searched for the possible target proteins of p26olf. By flow dialysis experiments using (45)Ca, p26olf was suggested to bind approximately 4 Ca(2+). Circular dichroism measurement showed that binding of Ca(2+) to p26olf induces an increase in the apparent content of both alpha-helix and beta-sheet with an apparent K(d) value of 2.4 micrometer. Electron microscopic observation disclosed p26olf immunoreactivity in the cilia, dendritic knob, and dendrite of olfactory receptor cells. Blot overlay analysis and affinity purification of p26olf-binding proteins showed that p26olf binds to a frog beta-adrenergic receptor kinase-like protein in a Ca(2+)-dependent manner. These results suggested that p26olf has some roles in the olfactory transduction or adaptation.     

Olfactory adenylyl cyclase. Identification and purification of a novel enzyme form

Rat olfactory adenylyl cyclase has been identified by means of a monoclonal antibody BBC-2, which reacts with both Ca2+/calmodulin-sensitive and -insensitive forms of adenylyl cyclase (Mollner, S., and Pfeuffer, T. (1988) Eur. J. Biochem. 171, 265-271). The antibody recognized a 180-kDa polypeptide in olfactory cilia but not in decilitated olfactory epithelial membranes. A protein of the same mobility was observed when olfactory adenylyl cyclase was purified by forskolin-agarose affinity chromatography followed by radioiodination. Its identity was further established by cross-linking to [32P]ADP-ribosylated Gs alpha (GTP-binding protein), to yield a single radiolabeled product of Mr approximately 220. Olfactory adenylyl cyclase has a approximately 3-fold higher turnover number, as assessed from stoichiometric binding of [35S]guanosine 5'-(3-O-thio)triphosphate. Therefore, the considerably higher specific adenylyl cyclase activity in olfactory cilia must be due to a approximately 100-fold higher molar concentration of enzyme in this tissue.     

Ultrastructural localization of olfactory transduction components: the G protein subunit Golf alpha and type III adenylyl cyclase.

Electron microscopy and postembedding immunocytochemistry on rapidly frozen, freeze-substituted specimens of rat olfactory epithelia were used to study the subcellular localization of the transduction proteins Golf alpha and type III adenylyl cyclase. Antibody binding sites for both of these proteins occur in the same receptor cell compartments, the distal segments of the olfactory cilia. These segments line the boundary between organism and external environment inside the olfactory part of the nasal cavity. Therefore, they are the receptor cell regions that most likely first encounter odorous compounds. The results presented here provide direct evidence to support the conclusion that the distal segments of the cilia contain the sites of the early events of olfactory transduction.     

The odorant-sensitive adenylate cyclase of olfactory receptor cells. Differential stimulation by distinct classes of odorants

We have characterized odorant-stimulated adenylate cyclase activity in isolated chemosensory cilia prepared from frog and rat olfactory epithelium. Cilia from both species exhibit high levels of adenylate cyclase activity. Basal activity is stimulated approximately 2-fold by GTP and approximately 5-fold by guanosine 5'-(3-O-thio)triphosphate and forskolin. Odorants augment enzyme activity 30-65% above the basal level in a tissue-specific and GTP-dependent manner. Calcium reduces GTP-stimulated activity with a 50% effective concentration at 10 microM. Odorants vary in their influence upon olfactory adenylate cyclase activity. Most fruity, floral, minty, and herbaceous odorants stimulate the enzyme. 3,7-Dimethyl-2,6-octadienenitrile (citralva), menthone, D-carvone, L-carvone, and 2-isobutyl-3-methoxypyrazine display similar potencies in activating the adenylate cyclase upto concentrations of 100 microM. Putrid odorants, such as isovaleric acid, triethylamine, pyridine, thiazole, and methoxypyrazine, and odorous chemical solvents, do not stimulate enzyme activity. In homologous series of pyrazine, thiazole, and pyridine odorants, compounds with the longest hydrocarbon side chains are best able to enhance enzyme activity. The failure of certain odorants to affect adenylate cyclase activity suggests that additional transduction mechanisms besides the formation of cAMP are involved in olfaction.