Stomatin-Related Olfactory Protein, SRO, Specifically Expressed in the Murine Olfactory Sensory Neurons

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The Journal of Neuroscience, July 15, 2002, 22(14):5931-5937

Stomatin-Related Olfactory Protein, SRO, Specifically Expressed in the Murine Olfactory Sensory Neurons
Ko Kobayakawa, Reiko Hayashi, Kenji Morita, Kazunari Miyamichi, Yuichiro Oka, Akio Tsuboi, and Hitoshi Sakano
Department of Biophysics and Biochemistry, Graduate School of Science, University of Tokyo, Bunkyo-ku, Tokyo 113-0032, Japan

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We identified a stomatin-related olfactory protein (SRO) that is specifically expressed in olfactory sensory neurons (OSNs).The mouse sro gene encodes a polypeptide of 287 amino acids witha calculated molecular weight of 32 kDa. SRO shares 82% sequencesimilarity with the murine stomatin, 78% with Caenorhabditis elegansMEC-2, and 77% with C. elegans UNC-1. Unlike other stomatin-familygenes, the sro transcript was present only in OSNs of the mainolfactory epithelium. No sro expression was seen in vomeronasalneurons. SRO was abundant in most apical dendrites of OSNs, includingolfactory cilia. Immunoprecipitation revealed that SRO associateswith adenylyl cyclase type III and caveolin-1 in the low-densitymembrane fraction of olfactory cilia. Furthermore, anti-SRO antibodiesstimulated cAMP production in fractionated cilia membrane. SROmay play a crucial role in modulating odorant signals in the lipidrafts of olfactorycilia.

Key words: olfactory sensory neuron; olfactory cilia; stomatin; MEC-2; lipid rafts; adenylyl cyclase; caveolin

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The vertebrate olfactory system can discriminate hundreds of thousand of different odorants with odorant receptor (OR) moleculesexpressed in the olfactory sensory neurons (OSNs) within the olfactoryepithelium (OE). Each OSN expresses only one member of the ORgene family in a monoallelic manner (Chess et al., 1994; Malnicet al., 1999; Serizawa et al., 2000; Ishii et al., 2001). TheOSNs, expressing a given OR gene, project their axons to a pairof glomeruli: one on the lateral and the other on the medial side(Ressler et al., 1994; Vassar et al., 1994; Mombaerts et al.,1996). Thus, odorant stimuli that activate a specific set of OSNsin the OE are converted to a topographic map of activated glomerulion the olfactory bulb(OB).

Odorant perception initiates when odorant molecules interact with ORs on the surface of OSNs (Kurahashi 1989; Firestein andWerblin, 1989, Lowe and Gold, 1991; Mori and Yoshihara, 1995;Friedrich and Korsching, 1997; Zhao et al., 1998; Touhara et al.,1999). The major pathway of olfactory transduction involves theOR molecule, G-protein comprising the G_olf subunit, adenylyl cyclasetype III (ACIII), which generates cAMP, and olfactory-specificcyclic nucleotide-gated channel (OcNC), all of which are exclusivelyor predominantly expressed in OSNs and localized to the specializedchemosensory compartments, the olfactory cilia (Jones and Reed,1989; Bakalyar and Reed, 1990; Dhallan et al., 1990; Reed 1992;Wong et al., 2000).

To study the signaling and projection of OSNs, we prepared murine cDNA libraries from the OE and searched for genes that arespecifically expressed in the OE. Among prospective clones, wehave characterized a cDNA encoding a stomatin-related olfactoryprotein (SRO) that shares 82% amino acid sequence similarity withthe mouse stomatin (Schlegel et al., 1996). Stomatin was firstfound in red blood cells with a defect that caused hemolytic anemiacalled stomatocytosis (Stewart et al., 1993). Stomatin is detectedin various tissues other than red blood cells and appears to functionas a negative regulator of univalent cation permeability (Delaunayet al., 1999). In contrast to the stomatin gene, the sro geneis expressed specifically in OSNs. Furthermore, the sro transcriptis present in the mature OSNs in the main OE but not in the vomeronasalepithelium (VNE). Immunohistochemisty demonstrated that SRO islocalized to the olfactory cilia of mature OSNs. Here, we reportthe initial characterization of the sro gene and discuss the possibleroles of SRO in the signal transduction ofOSNs.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Cloning of the sro gene. Fluorescent differential display (FDD) was performed according to the published protocol (Ito etal., 1994). The prospective cDNA was cloned into a plasmid vectorpGEM-T (Promega, Madison, WI). Full-length cDNA was isolated fromthe mouse OE cDNA library in a phage vector $lambda$ ZAPII (Stratagene,La Jolla, CA) using the sro cDNA obtained by the FDD screeningas a probe. The cDNA inserts were isolated by in vivo excisionwith the ExAssist helper phage (Stratagene). The 5'-upstream regionof sro was isolated from the mouse genomic library in a phagevector $lambda$ EMBL3-SP6/T7 (Clontech, Palo Alto, CA), using the srocDNA as aprobe.

Northern blot analysis. Poly(A⁺) RNAs from various mouse tissues were extracted with a Fast Track Kit (Invitrogen, San Diego,CA). Poly(A⁺) RNA, 3 µg each, was electrophoresed in an agarose gel and transferredto Hybond N⁺ membrane (Amersham Biosciences, Little Chalfont, UK). The ³²P-labeled sro 3'-UTR region probe was prepared with MegaprimeDNA labeling systems (AmershamBiosciences).

In situ hybridization. In situ hybridization was performed as described (Tsuboi et al., 1999). The mouse sro, OMP, and stomatinprobe was prepared by RT-PCR using a pair of primers, sro F1 (5'-)and sro R1 (5'-), OMP F1 (5'-ccagaggtacctcagcagtg-3') and OMPR1 (5'-ggagggcacacagtctttat-3'), and stomatin F1 (5'-ccaccattgtcttccctctg-3')and stomatin R1 (5'-gtctaggctgtgtcccttgc-3'). The sro probe wasgenerated from the cDNA clone containing the 3'-untranslated sequence.Each PCR-amplified cDNA fragment was cloned into pGEM-T vectorand sequenced. cRNA probes were labeled with digoxigenin (DIG)-UTPusing DIG-RNA labeling kit(Roche).

Antibody production. Polyclonal antibodies for the mouse SRO were generated using the N-terminal peptide as an antigen (aminoacid residues 1-19 and a cysteine: MDSPEKLEKNNLVGTNKSR-C). Thepeptide was conjugated to keyhole limpet hemocyanin using theInject Maleimide-Activated mcKLH Kit (Pierce, Rockford, IL) andinjected into two guinea pigs. After three rounds of booster injection,whole bleeding was performed on the animal. Anti-SRO antibodieswere purified with a HiTrap affinity column (AmershamBiosciences).

Isolation of olfactory cilia from the OE. Olfactory cilia were prepared with the calcium shock method as described previously(Anholt et al., 1986). After washing the OE in ice-cold Ringer'ssolution, the tissue was gently stirred at 4°C for 20 min in thesame solution supplemented with 10 mM CaCl₂. The deciliated OEwas removed by centrifugation at 7700 × g for 10 min. The supernatantwas further centrifuged at 27,000 × g for 10 min to collect detachedcilia. The pellet (cilia) was resuspended in hypotonic TME buffer(10 mM Tris-HCl, pH 7.4, 3 mM MgCl2, 2 mM EGTA) and stored at $-$ 70°C.

Expression of SRO-green fluorescent protein fusion protein in human embryonic kidney 293 cells. The sro coding sequence flankedby the EcoRI (5') and SalI (3') ends was amplified with a pairof primers, 5'-gaattcatggattcaccggagaaact-3' and 5'-gtcgacttggctttagcagtgaccttct-3'.The amplified fragment was cloned into a plasmid vector pEGFP-N1(Clontech) and transfected into human embryonic kidney 293 (HEK293)cells using lipofectamine plus reagent (Invitrogen). After 3 dof incubation, the transfected and nontransfected (mock) cellswere harvested, dissolved in SDS sample buffer, and applied toSDS-PAGE.

Western blot and immunoprecipitation analyses. For subcellular fractionation, the mouse OE was homogenized in PBS with proteaseinhibitors. After unbroken cells and nuclei were removed by centrifugationat 500 × g for 5 min, the supernatant was collected and recentrifugedat 2000 × g for 15 min. The resulting supernatant was furthercentrifuged at 100,000 × g for 60 min. The pellet (membrane) andsupernatant fractions were separated by SDS-PAGE and transferredto Immobilon P membrane (Millipore, Bedford,MA).

The membrane fraction of the OE was incubated in PBS containing 1% Triton X-100 at 0°C for 15 min. Triton-soluble and -insolublefractions were separated by centrifugation at 30,000 × g for 30min at 4°C. An aliquot of the Triton-insoluble fraction was lysedfor 10 min on ice in immunoprecipitation buffer (50 mM Tris-HCl,pH 7.4, 100 mM NaCl, 1 mM phenylmethylsulfonyl fluoride, and 10µg/ml each of aprotinin, leupeptin, and pepstatin A) supplementedwith 60 mM n-octyl glucopyranoside. The lysate was centrifugedat 12,000 × g for 15 min at 4°C. The supernatant was incubatedovernight at 4°C with anti-SRO guinea pig serum conjugated withprotein G Sepharose (Amersham Biosciences), using preimmune guineapig serum as a control. The amounts of IgG in control guinea pigserum and anti-SRO antibodies were quantified by Western blotting,and the same amounts of antibodies were used for immunoprecipitationexperiments. Similar experiments were performed with anti-ACIIIand anti-caveolin-1 (cav-1) (Santa Cruz Biotechnology, Santa Cruz,CA) antibodies. After immunoprecipitated samples were washed withimmunoprecipitation buffer three times, bound proteins were elutedwith SDS-PAGE sample buffer. The eluted samples were subjectedto SDS-PAGE and subsequently to immunoblotting. As a negativecontrol, anti-transferrin receptor antibody (Zymed Labs, San Francisco,CA) was used in Western blotting of the immunoprecipitatedsamples.

Various tissues of the adult mouse were homogenized in PBS buffer containing 2% SDS. After the protein concentrations weremeasured, samples (~1 µg each) were separated by SDS-PAGE andtransferred to themembrane.

Immunohistochemistry. Frozen coronal sections of the mouse OE and OB (10 µm thick) were fixed in acetone/methanol (1:1) at $-$ 20°C for 15 min, treated with 0.2N HCl at room temperature for10 min, and washed in PBS three times (5 min each) at room temperature.Immunostaining was performed with the Vectastain ABC kit (VectorLaboratories, Burlingame, CA). For immunostaining, sections onthe slide glasses were blocked with 1× casein solution (VectorLaboratories) and treated with antisera against N-terminal peptideof SRO (diluted 1:1000 in 1× casein solution) at 4°C overnight.After they were washed in PBS three times (5 min each), the slideswere treated with biotinylated secondary antibodies for 30 min,washed three times (5 min each) in PBS, and reacted with the VectastainABC-AP reagent (Vector Laboratories) for 30 min. After they werewashed twice (5 min each) in PBS, the slides were incubated in100 mM Tris-HCl, pH 9.5, containing 5-bromo-4-chloro-3-indoryl-phosphate/4-nitrobluetetra-zolium chloridesubstrate.

Analysis of membrane fractions of olfactory cilia. Flotation analysis of the cilia membranes was performed as reported byBrückner et al. (1999). Cilia of OSNs were isolated from theOE of adult mice (12 weeks old) and lysed in 150 µl of TXNE buffer(50 mM Tris-HCl, pH 7.4, 150 mM NaCl, 5 mM EDTA, and 1% TritonX-100) supplemented with 10 mg/ml of leupeptin, aprotinin, andpepstatin, and 1 mM PMSF. The lysate was passed through a 22 gaugesyringe three times and incubated at 0°C for 20 min on a rockingplatform. The extract was mixed with 210 µl of 60% OptiPrep (NycomerdPharma, Oslo, Norway) in 1% Triton X-100 and put in an Sw55Tiultracentrifuge tube (Beckmann, Palo Alto, CA), followed by overlaywith 3.5 ml of 30% OptiPrep in TXNE and 0.4 ml of TXNE. Aftercentrifugation at 200,000 × g at 4°C for 4 hr, seven fractionswere collected from the top, precipitated with trichloroaceticacid, washed with acetone, and air dried. An aliquot of each fractionwas analyzed by Westernblotting.

Stimulation of cAMP production in olfactory cilia. Experiments were performed according to the instructions of SpinZyme acidicalumina devices (Pierce). Isolated cilia membranes were incubatedwith either anti-SRO antibodies or preimmune guinea pig IgG at0°C for 15 min. The sample without antibodies was also examinedas a control. For cAMP stimulation, cilia fractions (15 µg proteinin each reaction) were dissolved in 50 µl of reaction buffer containing8 mM HEPES, pH 7.4, 1.6 mM MgCl₂, 0.2 mM IBMX, 80 µg/ml BSA, 40µM cAMP, 0.4 mM ATP, 4 mM creatine phosphate, 40 U/ml creatinephosphokinase, 8 µM GTP, and 0.4 mM dithiothreitol. To stimulatethe cAMP production, either 10 µM GTP $gamma$ S or 5 µM forskolin wasadded. The reaction was performed at 37°C for 20 min in the presenceof $alpha$ -³²P-ATP, and terminated by adding 10 µl of carrier solution containing5 mg/ml cAMP (sodium salt) and 0.5N HCl. The amounts of cAMP weremeasured with SpinZyme acidic alumina devices(Pierce).

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Cloning of cDNA encoding the stomatin-related olfactory protein, SRO

A cDNA clone coding for the rat SRO was isolated from the OE of 3-week-old animals by the differential display method. Todetermine the tissue specificity of sro expression, we performedin situ hybridization of the rat olfactory tissues with the sroprobe. Strong hybridization signals were detected in the tissuesections of the OE but not of the brain. By assembling contigsof the mouse sro cDNAs isolated with the rat probe, the full-lengthmouse cDNA was estimated to be 1.83 kb. The mouse sro gene encodesa protein of 287 amino acid residues with a calculated molecularweight of 32 kDa. Homology search with the Protein IdentificationResource database revealed that the mouse sro gene is most homologousto the mouse stomatin gene (Fig. 1a). The mouse SRO shares 82%sequence similarity with the mouse stomatin, 78% with the C. elegansMEC-2, and 77% with the C. elegans UNC-1.

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Figure 1. Comparison of stomatin-family proteins. a, The predicted amino acid sequence of SRO compared with those of stomatin-family proteins. Amino acid sequences are shown in the single-letter code. Putative membrane-spanning domains are shaded. The stomatin signature sequence is boxed. Consensus cysteine residues for palmitoylation at positions 23, 46, and 80 are indicated by bold-faced letters. Asterisks indicate conserved residues with identical amino acids. Dots indicate conserved amino acid residues with similar properties. Sources of the genes are shown as C. elegans (C), mouse (M), and human (H). b, Dendrogram of stomatin-family proteins. Stomatin-family proteins from the mouse (M), human (H), and C. elegans (C) were analyzed by the CLUSTAL procedure. The lengths of branches are proportional to the sequence differences. The mouse SRO and stomatin belong to the cluster of UNC-1 and MEC-2 of C. elegans. c, Hydrophobicity profiles for the mouse SRO, mouse stomatin, and C. elegans UNC-1 using the Kyte-Doolittle algorithm. Vertical axis indicates hydrophobicity. Hydrophobic transmembrane regions are in boxes. Residue numbers are indicated. d, Secondary structures of SRO, stomatin, and UNC-1. Regions rich in the $beta$ -sheets and $alpha$ -helices are indicated by shaded and open bars, respectively. Residue numbers are shown on the top.

The predicted amino acid sequence of SRO

The deduced amino acid sequence of SRO was compared with the published sequences of the mouse stomatin, UNC-1 and MEC-2 ofC. elegans, and human podocin (Fig. 1a). These proteins all sharethe consensus sequence, RX₂(L/I/V)(S/A/N)X₆(L/I/V)DX₂TX₂WG(L/I/V)(K/R/H)(L/I/V)X(K/R)(L/I/V)E(L/I/V)(K/R), which defines the stomatin-family proteins. A CLUSTALanalysis revealed that SRO belongs to the same cluster as stomatin,MEC-2, and UNC-1 (Fig. 1b). From the hydrophobicity profile (Fig.1c) and motif search, SRO was shown to contain two N-terminalhydrophobic domains and three consensus sequences of Cys for palmitoylationat positions 23, 46, and 80 (Snyers et al., 1999). These features,characteristic of the stomatin-family proteins, suggest that SROcan intercalate directly into the lipid bilayer, like other stomatin-familyproteins. SRO also contains a unique combination of $beta$ -sheet-richand $alpha$ -helix-rich structures that is commonly found in other stomatin-familyproteins (Fig. 1d).

The sro gene is specifically expressed in the OE

To study the tissue distribution of sro mRNA, we performed Northern blot analysis of poly(A⁺) RNA extracted from the OE, brain, heart, lung, liver, spleen,thymus, kidney, and testis. The sro mRNA of 1.8 kb was detectedin the OE but not in other tissues examined so far (Fig. 2a).The size of the transcript (1.8 kb) indicates that the isolatedcDNA clone contains the full-length sequence of sro mRNA. RT-PCRanalyses demonstrated that the sro gene is expressed specificallyin the OE, whereas the stomatin transcript can also be found inother tissues, including the VNE, retina, and tongue (Fig. 2b).

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Figure 2. OE-specific transcription of the sro gene. a, Northern blot analysis of the sro transcripts. Poly(A⁺) RNA samples isolated from various tissues were electrophoresed in an agarose gel, transferred to nylon membranes, and hybridized with ³²P-labeled sro cDNA. Positions of size markers (kb) are indicated. The same membrane was washed and rehybridized with the $beta$ -actin probe. b, RT-PCR of the sro transcript. Total RNA was isolated from the OE, VNE, retina, and tongue. Samples were treated with RNase-free DNase I and then reverse transcribed with random hexamer primers. PCR was performed with the sro, stomatin, and tubulin primers. c, Olf-1 binding motifs. Upstream sequences are compared for various olfactory-specific genes encoding adenylyl cyclase type III (ACIII), G_olf, olfactory-specific cyclic nucleotide-gated channel (OcNC), olfactory marker protein (OMP), and stomatin-related olfactory protein (SRO). Olf-1 binding motifs are shaded. The consensus sequence is shown on the top.

The Olf-1 motif is commonly found in the promoter region of genes involved in olfactory signaling (Kudrycki et al., 1993;Wang and Reed, 1993; Wang et al., 1993). To examine whether theOlf-1 motif is present in the sro gene, we isolated the promoterregion of the mouse genomic sro gene and determined its nucleotidesequence. The human sro sequence was also obtained from the humangenome database (clone RP11-50D16: GenBank accession no. AL445590).In both mouse and human sro genes, Olf-1 binding sequences werefound in the putative promoter regions (Fig. 2c).

The sro gene is transcribed in the main OE but not in the VNE

To examine the sro expression in the olfactory tissues, we performed in situ hybridization using DIG-labeled antisense probes(Fig. 3). In the main OE, both sro and stomatin transcripts weredetected in all four zones, specifically in the OSN layer wherethe OMP gene is expressed. No hybridization signals were foundin the supporting cells, basal cells, or GAP43-positive immatureOSNs in the main OE. In the VNE, stomatin mRNA was detected inthe vomeronasal neurons. However, the sro transcript was not detectedin the VNE.

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Figure 3. In situ hybridization of the olfactory and vomeronasal epithelia. Coronal sections of the mouse OE and VNE were hybridized with the DIG-labeled antisense probes of OMP (a, e, i, m), stomatin (b, f, j, n), and sro (c, g, k, o). The sense probe of sro was also hybridized as a negative control (d, h, l, p). Both the low (a-d, i-l) and high (e-h, m-p) magnification view are shown. Enlarged areas are indicated by a box in a and i. The sro mRNA was detected in the mature OSNs in all four zones of the OE (c, g). In the vomeronasal neurons, stomatin mRNA (j, n) and OMP mRNA (i, m) were detected, whereas the sro mRNA (k, o) was not.

SRO is localized to olfactory cilia of OSNs

To study the localization of SRO protein in OSNs, polyclonal antibodies were raised against the region of the N terminus ofSRO, not homologous to that of stomatin. For Western blotting,total cell lysates of HEK293 (mock) and HEK293 expressing theSRO fusion protein with green fluorescent protein (GFP) were separatedby SDS-PAGE (Fig. 4a). Anti-SRO antibodies detected a strong bandof the 60 kDa protein and a few fainter bands of possible degradationproducts. The observed molecular weight (60 kDa) corresponds tothat calculated for the SRO-GFP fusion protein. Immunoblot analysisalso detected the endogenous SRO of 30 kDa in the OE (Fig. 4b).To examine the subcellular localization of the native SRO, theadult OE was fractionated into the cytosol (soluble), membrane,and olfactory cilia fractions. SRO was detected in the membranefraction and most significantly in the olfactory cilia (Fig. 4b).The SRO band of 30 kDa was specifically found in the OE but notin other tissues, including the OB, brain, heart, lung, liver,spleen, and thymus (Fig. 4c).

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Figure 4. Western blot analyses of SRO. a, Detection of the SRO-GFP fusion protein. Cell lysates of HEK293 (mock) and HEK293 tranfected with the sro-GFP gene (SRO-GFP) were separated by SDS-PAGE and subjected to Western blotting with polyclonal antibodies against the N-terminal peptide of SRO. A 60 kDa band (arrowhead) of the SRO-GFP fusion protein and a few fainter bands representing the degradation products were detected in the transfected cells. b, Detection of the endogenous SRO. Subcelluler fractions of the OE (soluble, membrane, and olfactory cilia) were separated by SDS-PAGE and analyzed by immunoblotting with anti-SRO polyclonal antibodies. A 30 kDa band (arrow), representing the native SRO, is present in the membrane and cilia fractions. c, OE-specific expression of 30 kDa SRO. Cell extracts from various tissues of the adult mouse were separated by SDS-PAGE and immunoblotted with anti-SRO polyclonal antibodies. The 30 kDa band of SRO is detected only in the OE.

Cellular localization of SRO was further examined by immunohistochemistry on fixed sections of the main OE, VNE, and OB isolatedfrom the adult mouse (Fig. 5). In the main OE, staining signalswere intense in most apical dendrites, including olfactory cilia,but were weak in the cell bodies of OSNs. The signals diminishedwhen the peptide antigen was applied. Very weak signals were detectedin the olfactory nerve and glomerular layers of the OB. Stainingwas not detected in the VNE, even in the microvilli of the vomeronasalneurons.

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Figure 5. Immunohistochemical detection of SRO. Tissue sections (16 µm thick) of the mouse main olfactory epithelium (OE) (a, b), vomeronasal epithelium (VNE) (e, f), and olfactory bulb (OB) (g, h) were analyzed with anti-SRO polyclonal antibodies. As a negative control, the OE section (c, d) was stained in the presence of the peptide antigen (+Ag). Low- and high-magnification views are shown in the top and bottom panels, respectively. Immunostaining signals were detected in the olfactory cilia (ci) of OSNs in the OE, but not in the microvilli (mv) of the VNE. The mitral cell layer (mcl), glomerulus layer (gl), and olfactory nerve layer (onl) are indicated in g.

Association of SRO with ACIII and caveolin-1

Stomatin is one of the major integral membrane proteins of erythrocyte lipid rafts (Salzer and Prohaska, 2001), which arecharacterized by the insolubility in cold nonionic detergentsand flotation on density gradients (Hooper, 1997). To examinewhether SRO is also present in lipid rafts, Triton X-100-solubleand -insoluble fractions of the cilia membrane were separatedin the flotation gradient and subjected to Western blotting. Ithas been reported that cav-1 is found in lipid rafts, whereastransferrin receptor (TrfR) is not (Smart et al., 1995). As shownin Figure 6a, SRO was detected in the low-density fractions thatcontain cav-1 but not TrfR. These results indicate that SRO islocalized in lipid rafts.

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Figure 6. Association of SRO with ACIII and caveolin-1 in the lipid raft. a, Detection of SRO in the lipid rafts of olfactory cilia. Olfactory cilia were isolated from the OE and lysed with 1% Triton X-100. The lysate was fractionated in an OptiPrep flotation gradient. Seven fractions were collected from the top to the bottom and were separated by SDS-PAGE. Gels were stained with Coomassie Brilliant Blue (CBB), transferred to an Immobilon-P membrane filter (Millipore), and subjected to immunoblotting using three different antibodies, anti-SRO, anti-caveolin-1 (cav-1), and anti-transferrin receptor (TrfR) antibodies. Cav-1 and TrfR serve as raft-associated and non-raft-associated controls, respectively. SRO and cav-1 were detected in the low-density fractions, 1 and 2, whereas TrfR was detected in the high-density fractions, 6 and 7. b, Immunocoprecipitation of SRO with ACIII and caveolin-1. Triton-insoluble fractions of the OE membrane were solubilized with n-octyl glucopyranoside and precipitated with anti-SRO, anti-cav-1, or anti-ACIII antibodies. Guinea pig serum (IgG) was used as a control. The precipitates were then analyzed by immunoblotting with anti-SRO, anti-cav-1, anti-ACIII, and anti-TrfR antibodies. OE membrane proteins without immunoprecipitation (OE membrane) were also analyzed. Antibodies used for the immunoprecipitation are indicated on the top. On the left, antibodies for immunoblotting are shown.

Because cav-1 is known to form a complex with other signaling components, e.g., ACIII (Schreiber et al., 2000), we testedwhether SRO is associated with the signaling complex by immunoprecipitationwith anti-cav-1, anti-ACIII, and anti-SRO antibodies. As shownin Figure 6b, Western blot analysis revealed that the immunoprecipitatewith anti-SRO antibodies contains ACIII and cav-1. Guinea pigIgG as a control did not give any background. In contrast, TrfRwas not detected in coprecipitates of SRO, cav-1, or ACIII (Fig.6b).

It has been reported that ACIII and cav-1 mediate the production of cAMP in the olfactory cilia (Schreiber et al., 2000).Because SRO was shown to interact with both ACIII and cav-1, weexamined the effect of anti-SRO antibodies on the cAMP productionin the cilia membrane fraction. As shown in Figure 7, SRO antibodiesenhanced cAMP production when the cilia fraction was stimulatedby GTP $gamma$ S and forskolin. Control antibodies, preimmune guinea pigIgG, did not affect the level of cAMP. These results indicatethat SRO is associated with both ACIII and cav-1 in the lipidrafts of olfactory cilia and may play an important role in modulatingthe odorant signals.

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Figure 7. Enhancement of cAMP production in olfactory cilia. Isolated cilia were treated with anti-SRO antibodies (anti-SRO Ab) or with preimmune guinea pig IgG (pre-Immune Ab) at 0°C for 15 min. Cilia samples without antibody treatment (without Ab) were also examined. Production of cAMP was induced by either 10 µM GTP $gamma$ S or 5 µM forskolin and measured after incubation at 37°C for 20 min. The vertical axis shows picomole amounts of cAMP per 1 mg of cilia proteins (pmol/mg protein). To examine whether the cAMP production was indeed enhanced by the SRO antibodies compared with preimmune Ab, Student's t values were calculated (GTP $gamma$ S, p < 0.004; forskolin, p < 0.000001).

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In the present study, we have isolated a novel cDNA clone encoding a stomatin-related olfactory protein, SRO, and characterizedits expression by in situ hybridization and immunohistochemistry.SRO is specifically expressed in mature OSNs in the main OE butnot in the VNE. This is in sharp contrast with stomatin, whichis found in various neuronal and non-neuronal tissues: OE, VNE,tongue, and eye. Like other olfactory-specific genes, such asfor OMP, G_olf, ACIII, and OcNC, the sro gene contains the Olf-1binding motif in the upstream regulatory region (Kudrycki et al.,1993; Wang and Reed, 1993; Wang et al., 1993).

In C. elegans, two stomatin-related genes, unc-1 and mec-2, have been identified by the genetic method. Their relative expressionpattern is somewhat similar to that between the stomatin and srogenes. In C. elegans, UNC-1 is widely present in the nervous system(Rajaram et al., 1999; Sedensky et al., 2001), whereas MEC-2 isexpressed only in six mechano-transductive neurons and OSNs (Huanget al., 1995). The mec-2 mutants have been reported to show defectivechemotaxis toward volatile odorants (Bargmann et al., 1993). Consideringthe high sequence homology and specific expression in OSNs, wepredict that the mouse sro, like the mec-2 in C. elegans, playsimportant roles in olfactorysignaling.

We have studied the subcellular localization of SRO by Western blotting and immunohistochemistry. Like other stomatin-familyproteins, SRO is most likely a membrane protein, because two transmembranedomains were predicted from the cDNA sequence. Western blot analysisindicated that SRO is localized to the membrane fraction of olfactorycilia. Immunostaining with anti-SRO antibodies confirmed thisnotion. SRO shares structural features with other stomatin-familyproteins, which consist of a short N-terminal domain, two transmembranedomains, and a large cytoplasmic C-terminal domain. Both the N-and C-terminal domains of stomatin as well as those of SRO arecytosolic, suggesting that their transmembrane domains form ahairpin-like structure. Furthermore, SRO contains conserved cysteineresidues within and adjacent to the transmembrane domains. Ithas been reported that stomatin forms a large homo-oligomericcomplex via the C terminus, and that two of the cysteine residuesin stomatin are palmitoylated (Snyers et al., 1999). These propertiesare thought to be important in increasing the affinity betweenstomatin and plasma membranes. Both stomatin and flotillin, whichbelong to the SPFH (stomatins, prohibitins, flotillins, and HflK/C)domain family (Tavernarakis et al., 1999), are major componentsof the erythrocyte lipid rafts, which are sphingolipid- and cholesterol-richmembrane microdomains. This structure acts as a platform for signalstransduced through the lipid bilayer (Simons and Ikonen, 1997;Brown and London, 1998). It has been reported that some key componentsfor the olfactory signaling, e.g., G_olf, ACIII, and caveolins,are found in the lipid rafts of olfactory cilia (Schreiber etal., 2000). Our immunoprecipitation studies indicate that SROis associated with ACIII and caveolin-1 in the lipid rafts. Furthermore,anti-SRO antibodies stimulated the cAMP production in the membranefraction of olfactory cilia. It is possible that SRO is presentin the lipid rafts of olfactory cilia, forming the supramolecularcomplex to generate odor-induced signals. However, it is yet tobe clarified exactly how SRO is involved in olfactory signaling.Because sro expression is highly specific to the OSNs, knock-outstudies and dominant-negative transgenic mice will be helpfulin elucidating the function ofSRO.

  FOOTNOTES

Received March 13, 2002; revised April 22, 2002; accepted April 29, 2002.

This work was supported by grants from Japan Science and Technology (JST) Corporation, Ministry of Education, Culture andScience, Mitsubishi Foundation, and Japan Foundation for AppliedEnzymology. This project is the Core Research for EvolutionalScience and Technology (CREST) funded by JST. R.H. is a postdoctoralfellow of the Japan Society for Promotion of Science. A.T. issupported by the Precursory Research for Embryonic Science andTechnology (PRESTO) program of JST. We thank Dr. Tetsuo Yamamoriand Hitomi Sakano for critical reading of this manuscript. TheDNA Data Bank of Japan accession number for the sro sequence isAB085692.

Correspondence should be addressed to Dr. Hitoshi Sakano, Room 116, Science Building #3, Department of Biophysics and Biochemistry,University of Tokyo, 2-11-16 Yayoi, Bunkyo-ku, Tokyo 113-0032,Japan. E-mail: sakano{at}mail.ecc.u-tokyo.ac.jp.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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