OCAM: A New Member of the Neural Cell Adhesion Molecule Family Related to Zone-to-Zone Projection of Olfactory and Vomeronasal Axons

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Volume 17, Number 15, Issue of August 1, 1997 pp. 5830-5842
Copyright ©1997 Society for Neuroscience

OCAM: A New Member of the Neural Cell Adhesion Molecule Family Related to Zone-to-Zone Projection of Olfactory and Vomeronasal Axons

Yoshihiro Yoshihara¹^,²^,³, Miwa Kawasaki¹, Atsushi Tamada¹^,³, Hiroko Fujita³, Hideyuki Hayashi², Hiroyuki Kagamiyama², and Kensaku Mori¹^,³
¹ Department of Neuroscience, Osaka Bioscience Institute, Suita, Osaka 565, Japan, ² Department of Biochemistry, Osaka Medical College, Takatsuki, Osaka 569, Japan, and ³ Laboratory for Neuronal Recognition Molecules, Frontier Research Program, The Institute of Physical and Chemical Research (RIKEN), Wako, Saitama 351-01, Japan

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Zone-to-zone projection of olfactory and vomeronasal sensory axons underlies the topographic and functional mapping of chemoreceptorexpression zones of the sensory epithelia onto zonally arrangedglomeruli in the main and accessory olfactory bulbs. Here we identifiedOCAM (R4B12 antigen), an axonal surface glycoprotein expressedby subsets of both olfactory and vomeronasal axons in a zone-specificmanner. OCAM is a novel homophilic adhesion molecule belongingto the immunoglobulin superfamily with striking structural homologyto neural cell adhesion molecule. In both the main and accessoryolfactory systems, OCAM mRNA is expressed by sensory neurons inrestricted chemoreceptor expression zones, and OCAM protein-expressingaxons project to the glomeruli in the corresponding zones of themain and accessory bulbs. OCAM protein is expressed on subsetsof growing sensory axons in explant cultures even in the absenceof the target bulb. These results demonstrate a precisely coordinatedzonal expression of chemoreceptors and OCAM and suggest that OCAMmay play important roles in selective fasciculation and zone-to-zoneprojection of the primary olfactory axons.
Key words: OCAM; cell adhesion molecule; immunoglobulin superfamily; NCAM; olfactory system; odorant receptors; primary olfactory axons; zone-to-zone projection

INTRODUCTION

The mammalian olfactory system possesses sophisticated molecular and cellular mechanisms underlying discrimination among odormolecules and perception of olfactory images of objects (Shepherd,1994; Mori and Yoshihara, 1995; Buck, 1996). Odor ligands arerecognized by odorant receptors on the cilia of sensory neuronsin the olfactory epithelium (OE). To discriminate among odors,the central olfactory nervous system needs to determine whichof the numerous odorant receptors are activated by the odor molecules.One of the cellular bases for this task is that individual olfactorysensory neurons express a single or only a few odorant receptorgenes among as many as 1000 repertoires (Buck and Axel, 1991;Nef et al., 1992; Strotmann et al., 1992; Chess et al., 1994).Accordingly, to distinguish which receptors are activated by theodor molecules, the central olfactory system only needs to knowwhich sensory neurons have been activated. Another important cellularbasis lies in the pattern of olfactory axon connectivity withthe main olfactory bulb (MOB); all of the sensory neurons expressinga given odorant receptor project and converge their axons ontotwo glomeruli among the 1500-3000 within the MOB (Ressler et al.,1994; Vassar et al., 1994; Mombaerts et al., 1996). Thus, individualglomeruli seem to constitute functional units, each representingone type or a few types of odorant receptors. This axonal connectionpattern underlies the response specificity of the second-orderneurons in the MOB to odor molecules. Individual mitral/tuftedcells are activated only by a range of odor molecules with a similarchemical structure, which can bind to a given odorant receptor(Imamura et al., 1992; Mori et al., 1992; Katoh et al., 1993;Mori, 1995; Mori and Yoshihara, 1995).

In situ hybridization studies reveal yet another principle of odorant receptor expression. Sensory neurons expressing a givenodorant receptor gene are distributed sparsely within one specificcircumscribed zone out of the four zones in the OE (Ressler etal., 1993; Vassar et al., 1993; Strotmann et al., 1994). In addition,it has been hypothesized that olfactory sensory neurons withina given OE zone project their axons to glomeruli in a correspondingzone of the MOB: a zone-to-zone projection (Fig. 1) (Mori andYoshihara, 1995).
Fig. 1. Zonal organization of the main and accessory olfactory systems. Schematic dorsal view of the olfactory systems. Olfactorysensory neurons in the four zones (zone I, dark green; zone II,light green; zone III, light blue; zone IV, dark blue) of theolfactory epithelium (OE) project their axons to four correspondingzones of the main olfactory bulb (MOB). Similarly, vomeronasalsensory neurons in the two zones (apical, yellow; basal, pink)of the vomeronasal epithelium (VNE) project their axons to twozones (rostral, yellow; caudal, pink) of the accessory olfactorybulb (AOB). Note that olfactory axons from different zones alreadyare segregated spatially at the exit points of the OE, whereasthe vomeronasal axons from the different zones are intermingledin the vicinity of the VNE and become segregated gradually nearthe AOB. ON, Olfactory nerves; VNN, vomeronasal nerves; glom,glomeruli; m/t, mitral and tufted cells.
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A similar but distinct type of zone-to-zone projection has been suggested in the accessory olfactory system. Studies on theexpression of pheromone receptors (Dulac and Axel, 1995) and G-proteins(Halpern et al., 1995; Berghard and Buck, 1996) reveal that twozones (apical and basal) are stacked in the vomeronasal epithelium(VNE). Vomeronasal neurons in the apical zone project their axonsto glomeruli in the rostral zone of the accessory olfactory bulb(AOB), whereas sensory neurons in the basal zone send their axonsto glomeruli in the caudal zone (Fig. 1).

Monoclonal antibody (mAb) R4B12 recognizes a membrane protein expressed by subsets of rabbit primary olfactory axons in boththe main and accessory olfactory systems (Fujita et al., 1985;Imamura et al., 1985; Mori et al., 1985, 1987; Mori, 1993; Yoshiharaet al., 1993). mAb R4B12 labels olfactory axons that originatefrom sensory neurons located in a ventrolateral region, whichmay correspond to the odorant receptor expression zones II, III,and IV, whereas it does not bind olfactory axons in a dorsomedialregion presumably corresponding to the zone I (Mori and Yoshihara,1995). We report here the isolation of cDNAs encoding R4B12 antigenand its intimate relationship with neural cell adhesion molecule(NCAM). Because of the characteristic expression by olfactoryaxons and remarkable structural similarity to NCAM, we designateR4B12 antigen as OCAM. We demonstrate here that the OCAM expressionregion corresponds precisely with odorant receptor expressionzones.

MATERIALS AND METHODS
Purification of OCAM and peptide sequencing. mAb R4B12 (Fujita et al., 1985) was prepared from ascites fluid of hybridoma-injectedmice (BALB/c), purified with an EZ-Sep kit (Pharmacia, Piscataway,NJ), and coupled to CNBr-activated Sepharose 4B (Pharmacia). Thelarge form of OCAM was purified from CHAPS-solubilized membraneof rabbit brain by affinity chromatography with a mAb R4B12-Sepharose4B column. The purified material was subjected to reduced carboxymethylationand digested with lysyl-endopeptidase (Boehringer Mannheim, Indianapolis,IN). The peptide fragments were purified by reverse-phase HPLCwith a Cosmosil 5C18 column (Nacalai Tesque). Selected peptideswere subjected to microsequencing on a gas phase sequencer (AppliedBiosystems, Foster City, CA).

cDNA cloning of OCAM. Two degenerate oligonucleotides (5 $'$ -ga[ag]at[act]gcicciaci[at][cg]iga[ct]aa[ct]ga[ct]tt[ct]gg-3 $'$ and5 $'$ -tt[ct]tcna[ag]cca[ct]tg[ag]tc[ct]tc-3 $'$ ) corresponding to theamino acid sequences of OCAM peptide EIAPTSDNDFG and EDQWLEK,respectively, were synthesized and used in a PCR with rabbit,rat, and mouse brain cDNA as templates. The PCR product (545 bp)was cloned directly into pCRII vector (Invitrogen, San Diego,CA) and sequenced by the dideoxy chain termination method (Sangeret al., 1977) with a Sequenase kit (Amersham Japan, Tokyo, Japan).An adult mouse OE $lambda$ gt10 cDNA library was constructed and screenedwith the mouse OCAM PCR product labeled with ³²P by random priming (Boehringer Mannheim). Six positive clonesof 3.2 × 10⁵ recombinants screened were obtained and subcloned into the SalIsite of pBluescript II SK⁺ (Stratagene, La Jolla, CA). Restriction mapping and partial sequencingrevealed that they were categorized into two groups with partiallyidentical sequences. The complete nucleotide sequence was determinedfor both strands of the two clones 102 and 104.

Northern blot analysis. Total RNA was isolated from mouse (ddY) tissue by the acid guanidinium thiocyanate-phenol-chloroformmethod (Chomczynski and Sacchi, 1987), fractionated in 1% agarose-formaldehydegels, and transferred to nylon membranes (Hybond N⁺, Amersham Japan). Three cDNA fragments of OCAM were used as probes:480 nucleotides in the first and second Ig-like domains to detectboth OCAM-glycosylphosphatidylinositol (GPI) and OCAM-transmembrane(TM), 549 nucleotides in the GPI-anchoring domain and 3 $'$ -noncodingregion to detect OCAM-GPI specifically, and 822 nucleotides inthe cytoplasmic region to detect OCAM-TM specifically. The probeswere labeled by random priming. Hybridization and washing wereperformed as described previously (Yoshihara et al., 1994a).

Western blot analysis. Polyclonal antibodies against mouse OCAM were produced by immunizing a rabbit with the recombinantOCAM/Fc fusion protein. The antiserum was used for Western blotanalysis (3000× dilution) and immunohistochemistry (1000× dilution).Monoclonal anti-NCAM antibody (clone H28-123-16, rat IgG2a) waspurchased from Boehringer Mannheim. Brains from embryonic days(E) 13 and 18, postnatal days (P) 1, 7, and 21, and adult micewere homogenized and subjected to Western blot analysis as describedpreviously (Yoshihara et al., 1993).

Cell aggregation assay. L929 mouse fibroblast cells were grown in DMEM with 10% fetal bovine serum. A linearized plasmid (pEF-OCAM-TM)containing a full-length OCAM-TM cDNA subcloned into the mammalianexpression vector pEF-BOS (Mizushima and Nagata, 1990) was cotransfectedwith pSTneoB by using Lipofectamine (BRL, Bethesda, MD) accordingto the manufacturer's procedure. Stable transfectants were selectedin medium containing 400 µg/ml G418. Cells were screened for OCAM-TMexpression by Western blotting, and a cell line with the highestexpression of OCAM-TM was chosen and used for the aggregationassay. L1-expressing L929 cells (Miura et al., 1992) were kindlyprovided by Dr. H. Asou (Tokyo Metropolitan Institute of Gerontology,Tokyo, Japan). The cell aggregation assay was performed essentiallyas described (Miura et al., 1992; Yoshihara et al., 1994b). Briefly,cells in monolayer culture were dispersed into single cells at1 × 10⁶ cells per milliliter in Ca²⁺- and Mg²⁺-free HBSS. The cell suspension was incubated in a polystyrenetube at 37°C without rotation, and aliquots were taken at theindicated times after mixing by several gentle inversions. Thenumber of cell aggregates was counted in a hemocytometer.

Preparation of OCAM/Fc, NCAM/Fc, and OCAM/AP proteins. For preparation of recombinant soluble OCAM/Fc protein, the expressionplasmid was constructed with the extracellular region of mouseOCAM cDNA and the Fc region of the human IgG1 gene (Nishimuraet al., 1987) in pEF-BOS. The OCAM/Fc chimeric protein was producedin COS7 cells by the standard DEAE-dextran transfection methodand purified to near homogeneity from culture supernatants witha protein A-Sepharose 4FF column (Pharmacia). NCAM/Fc was producedin a similar manner. Levels of OCAM/Fc and NCAM/Fc fusion proteinsin the supernatants were in the range of 0.5-0.8 µg/ml. A fusionprotein OCAM/AP consisting of the extracellular region of mouseOCAM and the human placental alkaline phosphatase was preparedwith an AP-tag-1 expression vector as described previously (Chengand Flanagan, 1994). COS7 supernatant was concentrated with Centriprep30 (Amicon, Beverly, MA) and used for the protein binding assay.

OCAM-AP binding assay. Xenobind plastic plates (Xenopore) were coated with 1 µg/well goat anti-human Fc IgG (Sigma, St. Louis,MO) in PBS overnight at 4°C, blocked with 0.4% bovine serum albuminin PBS for 2 hr at room temperature, and then coated with OCAM/Fc,NCAM/Fc, or Fc in PBS for at least 2 hr at room temperature. Theconcentrated COS7 supernatant, which contains OCAM/AP, was addedto the Fc chimeric protein-coated wells and incubated for 60 minat 37°C. OCAM/AP that remained bound after three washes was visualizedby AP reaction with p-nitrophenyl phosphate as a substrate, andthe absorbance at 405 nm was measured after 24 hr.

In situ hybridization. Riboprobes (300-500 nucleotides in length) for OCAM, NCAM, olfactory marker protein (OMP), and odorantreceptors R15, R16, R36, and R38 were prepared with ³⁵S-UTP (Amersham Japan) and an RNA transcription kit (Stratagene).All steps of the in situ hybridization reactions were performedessentially according to Simmons et al. (1989). Frontal sections(15 µm) from paraformaldehyde-perfused P14 mouse nose were cutwith a cryostat and mounted on poly-L-lysine-coated glass slides(Matsunami). The sections were dried, treated with proteinaseK (10 µg/ml at 37°C for 30 min), acetylated, dehydrated, and air-dried.The sections were hybridized overnight at 56°C in a humidifiedchamber with 150-200 µl of hybridization solution per section(hybridization solution consists of 50% formamide, 20 mM Tris-HCl,pH 7.6, 1 mM EDTA, 0.3 M NaCl, 0.1 M dithiothreitol, 0.5 mg/mlyeast tRNA, 1× Denhardt's solution, and 10% dextran sulfate) containing1 × 10⁶ cpm/ml ³⁵S-labeled cRNA probe. After hybridization, sections were washedin 4× SSC, treated with RNase A (10 µg/ml at 37°C for 30 min),washed in 0.05× SSC, dehydrated with ethanol, and exposed to $beta$ maxx-ray film (Amersham Japan). After autoradiography, slides weredipped in NTB-2 emulsion, exposed, developed in Kodak D-19, fixedwith Ren Fix, and counterstained with cresyl violet.

Immunohistochemistry. Immunohistochemical analysis was performed essentially as described (Mori et al., 1987). Mice were anesthetizedwith pentobarbital sodium and perfused with PBS, followed by 3%paraformaldehyde in phosphate buffer. The OB was removed, post-fixedovernight at 4°C in the same fixative, and kept in cold PBS containing30% sucrose. Parasagittal sections (40 µm) were cut with a slidingmicrotome. The sections were blocked with PBS containing 10% normalgoat serum, incubated with primary antibodies overnight at roomtemperature, washed, and incubated with FITC-labeled (Cappel,West Chester, PA) or Cy3-labeled (Jackson Laboratories, Bar Harbor,ME) secondary antibodies. The primary antibodies used were asfollows: anti-mouse OCAM/Fc (rabbit antiserum, 1000×), anti-NCAM(clone OB11, mouse IgG, 100×; Sigma), and anti-G_o (rabbitIgG, 1 µg/ml; MBL). The sections were examined with a confocallaser scanning microscopy system (Bio-Rad MRC-600, Hercules, CA)equipped with a Zeiss Axiophot Fl microscope (Oberkochen, Germany).

Explant culture of olfactory and vomeronasal epithelia. E10, E11, or E13 BALB/c mouse noses were removed from the head, digestedwith 1% trypsin in TBS/EDTA for 1 hr on ice, and treated with10% FBS to stop the enzymatic reaction. Olfactory and vomeronasalepithelia were removed from the surrounding mesenchymal tissue,cut into small fragments (<500 µm in diameter), and cultured for3-4 d on coverslips coated with 100 µg/ml poly-L-lysine (Sigma)for 1 hr and then 100 µg/ml laminin (Koken) for 1-4 hr. The culturemedium was DMEM/F12 supplemented with 5 µg/ml insulin, 100 µg/mltransferrin, 20 nM progesterone, 20 nM hydrocortisone, 100 µMputrescine, and 20 nM sodium selenite. After fixation with 4%paraformaldehyde, cultured fragments were immunostained with bothanti-OCAM/Fc and anti-NCAM antibodies and photographed with aconfocal laser scanning microscopy.

RESULTS

Purification and cDNA cloning of OCAM
The large form of OCAM was isolated from a CHAPS extract of nine rabbit brains by immunoaffinity chromatography with a mAbR4B12-coupled Sepharose 4B column. Western blot analysis of thepurified material revealed that OCAM bears an HNK-1 carbohydrateepitope, which is shared by a number of cell adhesion moleculesin the nervous system (data not shown) (Yoshihara et al., 1991).The purified OCAM (~80 µg) was digested with Lys-endopeptidase,and the resulting peptides were separated by reverse-phase HPLCand subjected to amino acid sequencing. The sequences of ninedifferent peptides were determined.

Several degenerate oligonucleotides were synthesized on the basis of the peptide sequences and used as primers for PCR withcDNA from rabbit, mouse, and rat brains. One pair of the oligonucleotidesyielded a specific PCR product of 545 bp in samples of all threespecies. The deduced amino acid sequences of rabbit, mouse, andrat PCR products were highly homologous (>93% identity in allof the pairs) and probably represent species homologs of the samegene. The PCR product contained a part of the immunoglobulin (Ig)-likedomain and one and one-half of the fibronectin type III (FNIII)-likedomain. We used mouse OCAM for detailed analyses. To obtain afull-length sequence, we used the mouse PCR product as a probeto screen a $lambda$ gt10 cDNA library derived from mouse OE. Six positiveclones (101, 102, 103, 104, 106, and 107) were identified andclassified into two groups with partially different restrictionmaps (Fig. 2A).
Fig. 2. Structure of OCAM in comparison with NCAM. A, Organization of OCAM cDNAs and alignment of clones. OCAM exists in two formswith different membrane attachment modes: a GPI-anchoring formand a transmembrane form. Upper bars with columns show the overallstructure deduced from overlapping cDNA clones that are givenbelow. Restriction endonuclease sites are shown above the bars.Columns represent putative protein-coding regions. The five Ig-likeand two FNIII-like domains are indicated by Roman and Arabic numerals,respectively. Positions of the putative mRNA-destabilizing signals(ATTTA motifs) in the 3 $'$ noncoding regions are indicated by asterisks.SP, Signal peptide; GPI, GPI-anchoring region; TM, transmembraneregion. B, Amino acid sequence alignment of the extracellularand GPI-anchoring regions of OCAM and NCAM. The residues conservedbetween OCAM and NCAM are highlighted. The open circles denotepositions of the highly conserved Cys residues in the Ig-likedomains. The nine peptide sequences obtained from purified OCAMare shown by dashed overlines. C, Amino acid sequence alignmentof the transmembrane and cytoplasmic regions of OCAM and NCAM.The putative transmembrane segments are indicated by solid bars.The PEST sequences are shown by dotted lines with PEST scores(Rogers et al., 1986). The nucleotide sequences of mouse OCAM-GPIand OCAM-TM have been deposited into GenBank with accession numbersAF001286 and AF001287, respectively. D, Proposed model of thedomain structure of the transmembrane forms of OCAM and NCAM.The Roman and Arabic numerals indicate the Ig-like and FNIII-likedomains, respectively. The putative Asn-linked glycosylation sitesare shown by lollipop symbols (closed, conserved; open, nonconserved).The sequence conservation (percentage of amino acid identity)between OCAM and NCAM is shown between individual correspondingdomains.
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OCAM is a new member of the NCAM family
An analysis of the OCAM cDNA clones indicated that they encode two related proteins with different modes of plasma membraneanchorage. Two predicted proteins shared 692 identical amino acidsat the N terminus, which contains a putative signal peptide (19amino acids) and a long extracellular region with five Ig-likedomains and two FNIII-like domains (Fig. 2A,B). There were eightpotential Asn-linked glycosylation sites in the extracellularregion of OCAM (Fig. 2D). All of the peptide sequences determinedby microsequencing appeared in the deduced amino acid sequences(Fig. 2B, dashed overlines).

The OCAM cDNA clones diverged in sequence downstream of the second FNIII-like domain in two ways. Clones 101 and 102 terminatedin a short stretch of hydrophobic amino acids characteristic ofproteins attached to the plasma membrane via a GPI linkage (Fig.2A,B). On the other hand, clones 103, 104, 106, and 107 encodeda protein with a TM domain of a stretch of 20 hydrophobic aminoacids and a cytoplasmic region of 119 amino acids at the C terminus(Fig. 2A,C). The presence of two forms, OCAM-GPI and OCAM-TM,was in good agreement with the result of Western analysis thatmAb R4B12 recognized two protein bands, one of which was releasedfrom the membrane by the GPI-specific phospholipase C (Yoshiharaet al., 1993).

Within the analyzed 3 $'$ untranslated region (2.5 kb) of OCAM-GPI, there were nine ATTTA motifs (Fig. 2A, asterisks), whichare believed to confer instability to the mRNA (Shaw and Kamen,1986; Malter, 1989). In contrast, only two ATTTA motifs were foundin the 3 $'$ untranslated region (0.8 kb) of OCAM-TM. OCAM-TM containeda conserved PEST sequence in the cytoplasmic region (Fig. 2C).The PEST sequence is found in proteins with high turnover ratesand is postulated to be involved in protein degradation (Rogerset al., 1986; Rechsteiner, 1988). Thus, turnover of OCAM-GPI andOCAM-TM in cells may be rapid via a regulated degradation at mRNAand protein levels, respectively.

In the Ig superfamily OCAM is classified into the NCAM family, which includes vertebrate NCAM (Cunningham et al., 1987; Santoniet al., 1989), Aplysia apCAM (Mayford et al., 1992), and insectfasciclin II (Fas II) (Harrelson and Goodman, 1988; Grenninglohet al., 1991). All four molecules have a similar domain organizationand occur in both GPI and TM forms. In particular, the greatestsimilarity was found between OCAM and NCAM, with overall aminoacid identity of 45% (Fig. 2D). Both OCAM and NCAM showed similardegrees of identity (26-27%) with both apCAM and Fas II (Table1).

Table 1. Amino acid sequence identity of OCAM and NCAM with apCAM and fasciclin II

Total Ig-1 Ig-2 Ig-3 Ig-4 Ig-5 FN-1 FN-2 CP

OCAM versus apCAM 26 34 32 27 24 26 25 22 24

NCAM versus apCAM 27 25 25 30 30 23 25 23 32

OCAM versus Fas II 26 22 34 28 30 29 28 15 24

NCAM versus Fas II 26 22 33 27 28 29 27 16 24

Schwob and Gottlieb (1986) have reported a similar antigen molecule RB8, which is expressed by subsets of rat olfactory axonsprojecting to a ventrolateral area of the MOB. The reported N-terminal13 amino acid sequence of purified rat RB8 antigen (Schwob andGottlieb, 1988) completely matched that of mouse OCAM, indicatingthat RB8 antigen is a rat homolog of mouse OCAM.

Northern and Western blot analyses of OCAM
Northern blot analysis was performed to survey the distribution of OCAM mRNA in adult mouse tissue (Fig. 3A). By using a probefor the Ig-like domains of OCAM (which recognizes both GPI andTM forms), we detected OCAM transcripts not only in the OE butalso in the brain and retina. However, no signal was observedin the peripheral tissues such as lung, heart, thymus, liver,spleen, kidney, testis, and skeletal muscle. Distribution of GPIand TM forms of OCAM was compared by Northern analysis, usingGPI- and TM-specific probes (Fig. 3B). The OCAM-GPI-specific proberecognized a single band of 7.8 kb, which was expressed predominantlyby the OE. In contrast, the OCAM-TM-specific probe detected twomajor bands of 7.8 and 3.6 kb, with highest expression in thebrain.
Fig. 3. Northern and Western blot analyses of OCAM. A, Tissue distribution of OCAM mRNA expression. Total RNAs from a variety of tissuesof adult mouse were analyzed as described in Materials and Methods.The upper panel shows an autoradiogram of the blot probed withOCAM Ig-like domain cDNA, which recognizes both GPI and TM forms.The lower panel shows the same blot stained with methylene blue.The size of OCAM transcripts estimated from the mobility of RNAstandards is indicated on the left in kilobases. olf. epi., Olfactoryepithelium; skel. mus., skeletal muscle. B, Identification ofOCAM-GPI and OCAM-TM transcripts, using specific probes. Northernblot analysis was performed with isoform-specific probes for OCAM-GPI(left panel) and OCAM-TM (right panel). Note that the OCAM-GPItranscript (7.8 kb) was expressed predominantly in the olfactoryepithelium, whereas the OCAM-TM transcripts (7.8 and 3.6 kb) weredetected in all of the neural tissues tested. C, Ontogeny of OCAMprotein expression in comparison with NCAM. Total proteins frommouse brains of different ages (from E13 to adult) were subjectedto Western blot analysis with rabbit anti-OCAM/Fc antibody (leftpanel) and rat anti-NCAM antibody (right panel). NCAM in E18,P1, and P7 samples appeared as slowly migrating diffuse bandsbecause of polysialylation. Note that OCAM was detected as nonpolysialylatedsharp bands.
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Using an antibody against recombinant OCAM/Fc fusion protein (see below), we examined the ontogeny of OCAM expression in mousebrain by Western blot analysis in comparison with NCAM (Fig. 3C).OCAM-TM in the mouse brain was expressed more highly than OCAM-GPI,as previously reported for the rabbit brain (Yoshihara et al.,1993). OCAM protein was detectable at E18, increased thereafter,and reached maximal levels at P21. OCAM was detected as two sharpprotein bands. In contrast, NCAM was detected as diffuse proteinbands representing a highly polysialylated form in the embryonicand perinatal brains and gradually shifted to sharp bands representingthree isoforms of 180, 140, and 120 kDa (Rutishauser, 1996). Thisresult suggests that polysialic acid is absent on the carbohydratemoieties of OCAM.

OCAM is a homophilic adhesion molecule
On the basis of the striking structural similarity with NCAM, we speculated that OCAM would function as an adhesion moleculein the nervous system. To clarify whether OCAM can bind in a homophilicmanner, as several Ig superfamily molecules do (Brümmendorf andRathjen, 1994), we performed two experiments. First, we stablytransfected mouse OCAM-TM cDNA into mouse fibroblast L929 cells,which normally have little adhesive activity and do not expressOCAM. Adhesive properties of OCAM-expressing cells were examinedby a static cell aggregation assay, with parental L929 cells asa negative control and L1-expressing L929 cells as a positivecontrol. L1 is another member of the Ig superfamily, which mediateshomophilic adhesion in this assay system (Miura et al., 1992).As shown in Figure 4A-D, both the OCAM- and L1-expressing L929cells showed a marked aggregation in contrast to the parentalL929 cells, implicating a homophilic adhesive activity of OCAM.
Fig. 4. Homophilic binding activity of OCAM assessed by cell aggregation assay (A-D) and protein binding assay (E, F). A-C, Phase-contrastmicrographs. Parental (A), OCAM-expressing (B), or L1-expressing(C) L929 cells were dissociated in EDTA medium, incubated at 37°Cfor 30 min, and then photographed. D, Kinetics of cell aggregation.Values are the mean ± SEM for three independent experiments. N_tand N₀ are the total number of particles at incubation times tand 0, respectively. The extent of cell aggregation is representedby the index N_t/N₀. E, Schematic diagram of protein binding assay.OCAM/AP was added to wells precoated with OCAM/Fc, NCAM/Fc, orFc via anti- human Fc antibody and incubated for 60 min at 37°C.Bound OCAM/AP was visualized by a chromogenic reaction. F, Specificbinding of OCAM/AP to OCAM/Fc. OCAM/AP was added to wells precoatedwith the indicated concentration of recombinant chimeric proteins.Values are the mean ± SEM for three independent experiments. Notethat OCAM/AP (filled circles) specifically bound to OCAM/Fc, butnot to NCAM/Fc (shaded diamonds) and Fc (open circles).
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In the second experiment we directly measured the homophilic binding of OCAM by using recombinant soluble proteins. OCAM/APis a chimeric protein, consisting of the extracellular regionof OCAM fused to human placental alkaline phosphatase having anenzyme activity that can be traced quantitatively by a simplechromogenic assay (Cheng and Flanagan, 1994). OCAM/Fc comprisesthe extracellular region of OCAM fused to the Fc region of humanIgG1. NCAM/Fc also was prepared to examine the possibility ofheterophilic interaction between OCAM and NCAM. OCAM/AP was addedto wells precoated with Fc chimeric proteins via anti-human IgGpolyclonal antibod- ies (Fig. 4E). As shown in Figure 4F, OCAM/APspecifically bound to OCAM/Fc, but not to NCAM/Fc or Fc. The bindingof OCAM/AP was dependent on the amount of precoated OCAM/Fc. Thisresult strengthens the idea that OCAM is a homophilic adhesionmolecule and also suggests the absence of heterophilic bindingbetween OCAM and NCAM.

OCAM expression in the main olfactory system
To determine whether the OCAM expression region corresponds to the odorant receptor expression zones in the OE, we investigatedlocalization of OCAM mRNA and protein in the main olfactory systemby in situ hybridization and immunohistochemistry. The mammalianOE consists of at least four spatially segregated zones that aredefined by the expression of odorant receptor mRNAs (Ressler etal., 1993; Vassar et al., 1993). Individual types of odorant receptormRNA were expressed by olfactory sensory neurons that were distributedselectively within one zone among the four circumscribed zones(Fig. 5F-I). All four zones expressed NCAM mRNA (Fig. 5B,E) aswell as olfactory marker protein mRNA (Fig. 5C). In contrast,OCAM mRNA was expressed by sensory neurons within the three ventrolateralzones [zone II, III, and IV in Ressler et al. (1993); zone 3,2, and 1 in Mombaerts et al. (1996)], but not in the most dorsomedialzone [zone I in Ressler et al. (1993); zone 4 in Mombaerts etal. (1996)] (Fig. 5A). [In this paper we adopt the zone numberingscheme of Ressler et al. (1993) in Roman numerals I, II, III,and IV from dorsomedial to ventrolateral.] At higher magnificationOCAM mRNA expression revealed a clear boundary between zone II(OCAM-positive) and zone I (OCAM-negative) neurons (Fig. 5D, arrowheads).The precise correspondence of the OCAM expression region to zonesII, III, and IV was observed in all sections examined along therostrocaudal axis of the OE (data not shown).
Fig. 5. Zone-specific expression of OCAM in the main olfactory system. A-I, Autoradiographs (A-C and F-I) and bright-field micrographs(D, E) of coronal sections of P14 OE hybridized with OCAM (A,D), NCAM (B, E), olfactory marker protein (OMP, C), and four odorantreceptor (F-I) cRNA probes. Dorsal is at the top. The four circumscribedzones of the OE are visualized by differential expression of therepresentative odorant receptor mRNAs [R15 in zone I (F); R36in zone II (G); R38 in zone III (H); R16 in zone IV (I)]. Notethat OCAM mRNA is expressed in the three ventrolateral zones (zoneII, III, and IV), but not in the most dorsomedial zone (zone I),whereas NCAM and OMP mRNAs are expressed in all four zones. Theregion around the boundary of OCAM-positive and OCAM-negativezones (arrowheads in A) is magnified in D and E. Both OCAM (D)and NCAM (E) mRNAs are expressed by olfactory sensory neuronsin the middle layer of the OE, but not by supporting cells inthe most superficial layer or stem cells in the basal layer. J,K, Micrographs of a parasagittal section at the medial surfaceof adult MOB double-stained with anti-OCAM (J) and anti-NCAM (K)antibodies. Dorsal is at the top; rostral is at the left. AlthoughNCAM is expressed by all glomeruli at the terminal of olfactoryaxons, OCAM is expressed by caudoventral glomeruli, but not byrostrodorsal ones, showing the zone-to-zone projection of olfactoryaxons to the MOB. L, Micrograph of a parasagittal section of E13mouse double-stained with anti-OCAM (red) and anti-NCAM (green)antibodies. Dorsal is at the top; rostral is at the left. Notethat expression of OCAM is already restricted to olfactory axonsprojecting from the ventral region of the OE (shown in yellow),whereas NCAM is expressed by all olfactory axons (shown in greenand yellow). Blood cells show nonspecific autofluorescence. Scalebars: 1 mm for A-C and F-I; 50 µm for D, E; 500 µm for J, K; 200µm for L.
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Next, parasagittal sections of adult mouse MOB were double-labeled with anti-OCAM (Fig. 5J) and anti-NCAM (Fig. 5K) antibodies.The glomerular layer appeared tessellated in a parasagittal sectionof the medial part of the MOB. As shown in Figure 5J, strong expressionof OCAM protein was observed in the olfactory nerve layer andin the ventrocaudal glomeruli, but not in the dorsorostral glomeruli.A clear boundary between the glomeruli was apparent, reflectingthe segregated termination of OCAM-positive and OCAM-negativeaxons originating from olfactory sensory neurons in zone II (OCAM-positive)and zone I (OCAM-negative). In contrast, NCAM was present in allof the glomeruli (Fig. 5K). Thus, the zonal organization definedin the OE was preserved also in the MOB.

The distribution of OCAM and NCAM proteins in the developing olfactory system was examined in a parasagittal section of E13mouse when olfactory axons normally just reach the OB at the tipof the telencephalon (Fig. 5L). Axons projecting to the ventralregion of the OB expressed both OCAM and NCAM (Fig. 5L, yellow),whereas axons projecting to the rostrodorsal region were OCAM-negativebut NCAM-positive (Fig. 5L, green). OCAM already was expressedby subsets of olfactory axons in a region-specific manner at thisearly developmental stage, whereas NCAM was expressed by all ofthe olfactory axons.

OCAM expression in the accessory olfactory system
We investigated whether OCAM is expressed in a zone-specific manner in the accessory olfactory system also. The VNE consistsof two zones, apical and basal, that are defined by complementaryexpression of two G-protein $alpha$ subunits, G_i2 and G_o (Halpernet al., 1995; Berghard and Buck, 1996). Vomeronasal neurons inthe apical and basal zones projected their axons to two spatiallysegregated zones (rostral and caudal, respectively) in the AOB.OCAM mRNA was expressed specifically by vomeronasal neurons inthe apical zone, but not in the basal zone (Fig. 6A,C), whereasNCAM mRNA was present in all neurons of the VNE (Fig. 6B,D). Correspondingto the restricted localization of OCAM mRNA in the vomeronasalapical zone, the OCAM protein product was detected in vomeronasalnerve fibers terminating in glomeruli in the rostral zone of theAOB (Fig. 6E), complementary to the expression of G_o in thecaudal zone (Fig. 6G). NCAM was detected in all vomeronasal nervefibers and their terminals (Fig. 6F).
Fig. 6. Zone-specific expression of OCAM in the accessory olfactory system. In situ hybridization analysis of coronal sections ofthe VNE from a P14 mouse (A-D) and immunohistochemical analysisof parasagittal sections of adult AOB (E-G). A, B, Superimposedimages of bright-field and dark-field micrographs showing expressionof OCAM (A) and NCAM (B) mRNAs in the crescent-shaped VNE. Dorsalis at the top. C, D, High-power bright-field micrographs of thecenter region of the VNE. The lumen is located at the top. Thebasal lamina is shown by arrowheads. Note that OCAM is expressedin the apical zone (a) of the VNE, but not in the basal zone (b)or supporting cell layer (s) (C), whereas NCAM is expressed inboth the apical and basal zones of the VNE (D). E-G, Micrographsshowing expression of OCAM (E), NCAM (F), and G_o (G) proteinsin the adult mouse AOB. E and F are different images from a double-stainedsection. G is a section adjacent to E and F. Dorsal is at thetop; rostral is at the left. OCAM is expressed by a subset ofvomeronasal axons that project into glomeruli in the rostral zoneof the AOB (E), whereas NCAM is expressed by all vomeronasal axons(F). Complementary to OCAM, G_o is expressed in the caudalzone of the AOB (G). Scale bars: 200 µm for A, B; 20 µm for C,D; 200 µm for E-G.
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Zonal expression of OCAM by growing olfactory axons cultured without target MOB
Finally, we investigated how the zonal pattern of OCAM expression by olfactory axons is established during development. Onepossibility is that the zonal organization is determined by someretrograde signals from the target MOB after the axons innervateit. The other possibility is that whether or not an axon expressesOCAM is predetermined without the MOB at the time of axonal outgrowth.To check these possibilities, we dissected out and cultured OEat various embryonic stages for 3-4 d. All of the neurites extendingfrom the OE fragments were NCAM-positive and peripherin-positive(data not shown), indicating that the axons originated from olfactorysensory neurons. Cultured fragments of E13 OE extended both OCAM-positiveand OCAM-negative axons even in the absence of the MOB (Fig. 7A-C).Furthermore, most of the OE fragments extended either OCAM-positiveaxons or OCAM-negative axons exclusively (Fig. 7A-C), showingthat the spatial segregation of OCAM-positive and OCAM-negativeaxons found in vivo (Fig. 5L) also occurred in vitro. In contrast,OCAM-positive and OCAM-negative axons from cultured E13 VNE fragmentswere intermingled (Fig. 7D-F), consistent with the OCAM expressionpattern in the vomeronasal nerve in vivo (Imamura et al., 1985;Mori et al., 1987). Similar segregation of OCAM-positive and OCAM-negativeolfactory axons also was observed in cultured OE fragments ofE11 and E10 mice (data not shown), when no axons reach the primordialMOB. These results suggest that the formation of a zonal expressionpattern of OCAM in the main olfactory system does not requireany retrograde signals from the target but already has been determinedat the time of axonal projection.
Fig. 7. OCAM expression on olfactory and vomeronasal axons in explant cultures. Micrographs of cultured E13 olfactory (A-C) and vomeronasal(D-F) epithelial fragments that were double-labeled with anti-OCAMand anti-NCAM antibodies. A, D, Expression of OCAM. B, E, Expressionof NCAM. C, F, Superimposed images of OCAM (red) and NCAM (green)expressions. Note that OCAM is expressed on extending axons fromthe lower OE fragment, but not from the upper one, whereas NCAMis positive for both OE fragments (A-C). Note also that OCAM-positiveand OCAM-negative axons from the VNE fragment are intermingled(D-F). Similar results were obtained consistently in all of theOE explants examined. Of the 40 NCAM-positive OE fragments examined,most of the OE fragments extended either OCAM-positive axons (25fragments) or OCAM-negative axons (8 fragments) exclusively, whereasboth OCAM-positive and OCAM-negative axons were observed in sevenexplants. Scale bar, 200 µm.
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DISCUSSION

OCAM is a new member of the NCAM family
OCAM is a novel protein belonging to the Ig superfamily (Williams and Barclay, 1988), the structure of which is related mostclosely to that of NCAM (Edelman, 1986; Cunningham et al., 1987;Goridis and Brunet, 1992). OCAM and NCAM display the same domainorganization with overall amino acid identity of 45%, indicatingthat they are derived from a common ancestral gene and constitutea subgroup in the Ig superfamily. However, OCAM lacks severalstructural properties that are well documented in NCAM, such asan alternatively spliced TM form with a long cytoplasmic region,polysialylation in the fifth Ig-like domain, and a unique alternativelyspliced exon in the fourth Ig-like domain (data not shown).

OCAM shows significant structural homology also with apCAM and Fas II, two invertebrate members of the NCAM family. When theamino acid sequences of OCAM and NCAM are compared pairwise withthose of apCAM and Fas II, no significant difference is observed(26-27% identity in all pairs), indicating that OCAM and NCAMare related equally to apCAM and Fas II. In fact, OCAM sharesmany properties with apCAM and Fas II. First, OCAM is expressedby restricted subsets of neurons, as are apCAM (Keller and Schacher,1990) and Fas II (Harrelson and Goodman, 1988; Grenningloh etal., 1991). In contrast, NCAM shows a more widespread expressionpattern throughout the nervous system.

Second, OCAM, apCAM, and Fas II share another property: a neuronal activity-dependent downregulation at synaptic sites. Wepreviously reported that OCAM immunoreactivity in glomeruli ofthe rabbit MOB disappears after strong and prolonged odor stimulationof the OE in situ and speculated that the disappearance may beattributable to the internalization or conformational alterationof OCAM (Yoshihara et al., 1993). In Aplysia, a similar phenomenonhas been described in the serotonin- or cAMP-induced long-termfacilitation of the gill withdrawal reflex (Bailey et al., 1992;Mayford et al., 1992). Stimulation of Aplysia sensory neuronscauses downregulation (internalization) of apCAM, followed byan increase in the number of synaptic connections between sensoryneurons and motoneurons, leading to the long-term facilitationof synaptic efficacy. Fas II also is involved in stabilization,growth, and plasticity of synapses at the Drosophila neuromuscularjunction (Schuster et al., 1996a,b). A change in the level ofFas II expression leads to either an increase or decrease in sproutingof motoneuron axon terminals, resulting in alteration of synapticconnection strength. These similarities suggest that the disappearanceof OCAM after odor stimulation may relate to the reorganizationof synaptic connections within the glomeruli. Downregulation ofspecific cell adhesion molecules may be a common mechanism forthe development of synapses and the plastic changes that followneuronal activation in both vertebrates and invertebrates.

Role of OCAM in zone-to-zone projection of olfactory axons
In both the main and accessory olfactory system zone-to-zone projection is one of the basic principles in the formation andmaintenance of axonal connections from the sensory epithelia tothe brain. OCAM mRNA is expressed by olfactory sensory neuronsin the ventrolateral three zones (zones II, III, and IV), butnot at all in the most dorsomedial zone (zone I). Accordingly,OCAM protein is present on the surface membrane of olfactory axonsprojecting from zones II, III, and IV of the OE to correspondingzones of the MOB (Fig. 8). Thus, odorant receptors expressed inzone I of the OE are mapped to glomeruli in zone I (OCAM-negativezone) of the MOB, while receptors in zones II, III, and IV aremapped to zones II, III, and IV (OCAM-positive zones).
Fig. 8. Schematic diagram of zone-to-zone projection of olfactory and vomeronasal axons in relation to zone-specific expression ofOCAM. Left, In the main olfactory system four circumscribed zones(I-IV) in the dorsomedial-ventrolateral axis of the OE are definedby expression of odorant receptor genes. OCAM-positive neurons(red) are localized in the three ventrolateral zones (II-IV, yellow)of the OE and project their axons to the corresponding zones (yellow)of the MOB. OCAM-negative neurons (blue) in the most dorsomedialzone (I, light blue) send their axons to the corresponding zone(light blue) of the MOB. Right, In the accessory olfactory systemthe two zones, apical and basal, are stacked in the VNE as definedby the expression of G-proteins and pheromone receptor genes.OCAM-positive (red) and OCAM-negative (blue) vomeronasal neuronsare localized to the apical (yellow) and basal (light blue) zones,respectively. OCAM-positive and OCAM-negative vomeronasal axonsare intermingled in the vicinity of the VNE and gradually sortout to make synapses in glomeruli in the rostral (yellow) andcaudal (light blue) zones of the AOB, respectively.
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In the accessory olfactory system OCAM is expressed by vomeronasal sensory neurons in the apical zone that express G_i2and several hitherto identified pheromone receptors, whereas OCAM-negativeneurons in the basal zone correspond to those expressing G_oprotein (Dulac and Axel, 1995; Halpern et al., 1995; Berghardand Buck, 1996). In the AOB, OCAM-positive and OCAM-negative vomeronasalaxons terminate within glomeruli in the rostral and caudal zones,respectively. A zone-specific expression is one of the most characteristicproperties of OCAM in both the main and accessory olfactory system,as opposed to NCAM, which is expressed by all olfactory and vomeronasalneurons (Fig. 8).

OCAM appears at very early stages in the development of the olfactory system, when pioneering olfactory axons are growingtoward the primordial OB (Fig. 5L). The explant culture experimentsuggested that at the time of axonal outgrowth it already hasbeen determined whether or not individual olfactory axons expressOCAM. Thus, the zone-specific expression of OCAM is establishedat early stages of development without any retrograde instructionfrom the OB. This is supported by our preliminary study that OCAMis expressed in a zone-specific manner in the OE of Pdn/Pdn mutantmice in which olfactory axons fail to connect to the brain (Naruseand Keino, 1995; K. Mori and I. Naruse, unpublished observation).Target-independent pattern specification in the OE also was demonstratedby the zonal expression of odorant receptors (Sullivan et al.,1995).

What are the functions of OCAM expressed by olfactory and vomeronasal axons in a zone-specific manner? Immunoelectron microscopicalanalysis demonstrated that OCAM is localized to closely apposedsurface membranes of neighboring olfactory axons in a fascicle(Yoshihara et al., 1993). Because OCAM has a homophilic bindingactivity, it may mediate fasciculation of subsets of olfactoryand vomeronasal axons. A zonal expression of OCAM may serve tosort OCAM-positive and OCAM-negative axons into distinct fasciclesin nerve bundles. However, because OCAM commonly is expressedby olfactory axons in zones II, III, and IV, additional cell adhesionmolecules with different expression in these zones may be necessaryfor the establishment of complete zone-to-zone projection. Inthe accessory olfactory system the sorting of OCAM-positive andOCAM-negative axons in the course of vomeronasal nerve projectionseems to be especially critical in the development of zone-to-zoneprojections, because the two types of axons are intermingled inthe vicinity of the VNE and completely segregated at the surfaceof the AOB (Imamura et al., 1985; Mori et al., 1987).

In addition, OCAM might function as a zone-specific target recognition molecule that mediates specific synapse formation betweenpresynaptic terminals of primary olfactory axons and postsynapticdendrites of mitral/tufted cells. A search for an OCAM counter-receptorthat is expressed on dendrites of mitral/tufted cells in a zone-specificmanner and mediates specific heterophilic binding with OCAM mightprovide insight into the zone-specific connection between thefirst- and second-order olfactory neurons.

Then, what is the functional meaning of the zone-to-zone projection of olfactory and vomeronasal axons? Odorant receptorscan be classified into at least four groups, each being expressedin a specific zone of the OE. They also are categorized into severalsubfamilies from the primary structure (Ben-Arie et al., 1994).Subsets of receptors expressed in the same spatial zone tend tobelong to the same subfamilies with a high degree of sequencehomology (Sullivan et al., 1996). Because homologous receptorsare assumed to bind distinct but overlapping ranges of odor ligands,the zonal grouping of receptors might relate to olfactory qualitiesor submodalities. Electro-olfactogram (Ezeh et al., 1995) andCa²⁺ imaging techniques (Sato et al., 1994) have shown that olfactorysensory neurons with similar response specificity to odor moleculestend to be localized in a certain region (zone) of the OE. Thepresumptive zone-specific olfactory qualities may be representedin the four projection zones of the MOB. In accord with this idea,electrophysiological recording of mitral/tufted cells in rabbitMOB has demonstrated that the neighboring mitral/tufted cellsin a same zone of the MOB are tuned to similar chemical structuresof odor ligands, whereas the cells in different zones have systematicallydifferent response specificity to odor molecules (Imamura et al.,1992; Mori et al., 1992; Katoh et al., 1993; Mori, 1995; Moriand Yoshihara, 1995).

Olfactory axon guidance and cell adhesion molecules
Because of the continuous turnover of sensory neurons throughout the animal's life (Graziadei and Monti-Graziadei, 1979),the olfactory and vomeronasal axon projection provides an excellentmodel to study molecular mechanisms for the formation and maintenanceof functional neuronal connections. What molecules are responsiblefor the guidance of these axons to their target zones and targetglomeruli? One possibility is that the odorant and pheromone receptorsthemselves play a role in axon guidance (Singer et al., 1995).Mombaerts et al. (1996) developed a genetic approach to visualizeaxons from olfactory sensory neurons expressing a given odorantreceptor, demonstrating that the neurons expressing a particularreceptor converge their axons to only two topographically fixedglomeruli of the MOB. They also analyzed whether odorant receptorsare involved in axonal guidance by a receptor swap experiment.The coding region of an odorant receptor gene P2 was replacedby that of another receptor gene M12. This experiment yieldedthe unexpected result that axons of M12-expressing P2 neuronsconverged onto glomeruli distinct from either the normal P2 orM12 glomeruli, but very close to the normal P2 glomeruli, suggestingthat odorant receptors play an instructive role but cannot bethe sole determinant in the axon guidance mechanism. We speculatethat the function of zone-specific axonal adhesion molecules isa prerequisite for olfactory axon guidance. Because neurons expressingP2 and M12 receptors are distributed in different zones of theOE in the normal animal (P2 in zone II; M12 in zone I), the M12-expressingP2 neurons may have obeyed the instruction by a zone-specificguidance molecule, possibly OCAM, present on normal P2 axons butabsent from normal M12 axons. Thus, coordinated expression ofcell adhesion molecules with odorant receptors seems to be requiredfor the establishment of functional projections of olfactory axons.

Besides OCAM and NCAM, olfactory and vomeronasal axons express a variety of other Ig superfamily molecules, including L1 (Miragallet al., 1989), TAG-1 (Yamamoto and Schwarting, 1991), Thy-1 (Terkelsonet al., 1989), and BIG-2 (Yoshihara et al., 1995; Y. Yoshiharaand K. Mori, unpublished observation). It is tempting to speculatethat coordinated expression of chemoreceptors and cell adhesionmolecules is necessary not only for zone-to-zone projection butalso for glomerular convergence of axons from sensory neuronsexpressing the same type of chemoreceptor. If this is the case,we can expect a clear relationship between chemoreceptor selectionby individual sensory neurons and combinatorial expression ofcell adhesion molecules on their axons. A search for known andas yet unknown cell adhesion molecules expressed by specific functionalsubsets of primary olfactory axons will aid our further understandingof molecular mechanisms underlying olfactory and vomeronasal axonguidance.

FOOTNOTES

Received March 10, 1997; revised May 5, 1997; accepted May 12, 1997.

This work was supported in part by the Special Coordination Funds for Promoting Science and Technology from the Science andTechnology Agency of Japan and by grants-in-aid from the Ministryof Education, Science, and Culture of Japan. We thank T. K. Henschfor comments on this manuscript; Y. Watanabe for encouragement;S. Nagata, H. Sugino, H. Nagao, and H. von Campenhausen for discussions;S. Ishii for help in peptide sequencing; H. Asou for L1-expressingL929 cells; C. Goridis and H. Cremer for mouse NCAM cDNAs; andJ. G. Flanagan for AP-tag-1 vector.

Correspondence should be addressed to Dr. Yoshihiro Yoshihara, Department of Neuroscience, Osaka Bioscience Institute, 6-2-4Furuedai, Suita, Osaka 565, Japan, or to Dr. Kensaku Mori, Laboratoryfor Neuronal Recognition Molecules, Frontier Research Program,The Institute of Physical and Chemical Research (RIKEN), Wako,Saitama 351-01, Japan.

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