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The Journal of Neuroscience, May 15, 2002, 22(10):4025-4035
Aberrant Sensory Innervation of the Olfactory Bulb in
Neuropilin-2 Mutant Mice
Andreas
Walz,
Ivan
Rodriguez, and
Peter
Mombaerts
The Rockefeller University, New York, New York 10021
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ABSTRACT |
The mammalian olfactory system consists of two anatomically
segregated structures, the main olfactory system and the vomeronasal system, which each detect distinct types of chemical stimuli in the
environment. During development, sensory neurons establish precise
axonal connections with their respective targets within the olfactory
bulb. The specificity of the odorant or vomeronasal receptor expressed
by the sensory neuron is crucial in this process, yet it is less clear
which of the more conventional axon guidance molecules are involved.
Here, we show that neuropilin-2, a coreceptor for some of the class 3 semaphorins, is expressed in subpopulations of olfactory and
vomeronasal sensory neurons. We generated a knock-out mutation in the
neuropilin-2 gene by gene targeting in embryonic stem cells.
Neuropilin-2 mutant mice exhibit profound and distinct effects on
target innervation within the olfactory bulb. In the main olfactory
system, axons of olfactory sensory neurons penetrate into the deeper
layers of the main olfactory bulb. In the vomeronasal system, axonal
fasciculation within the vomeronasal nerve is affected; some axons are
misrouted and innervate glomeruli in an ectopic domain of the accessory
olfactory bulb.
Key words:
olfaction; smell; odor; olfactory bulb; vomeronasal
system; neuropilin; semaphorin; axon guidance
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INTRODUCTION |
The sense of smell depends on the
ability of specialized neurons to interact with and respond to a vast
variety of chemicals. In terrestrial mammals, olfactory sensory neurons
(OSNs) are located on the turbinates in the caudal aspect of the nasal
cavity and project their axons to the main olfactory bulb (MOB). There,
OSN axons synapse with second-order neurons (mitral and tufted cells) within specialized compartments of neuropil called glomeruli. OSNs
expressing a particular odorant receptor (OR) gene from the available
repertoire of ~1000 genes project their axons to a few common
glomeruli (Ressler et al., 1994 ; Vassar et al., 1994; Mombaerts et al.,
1996). In many mammalian species, a second olfactory system, the
vomeronasal system, is thought to be specialized in the perception of
stimuli related to social and reproductive behaviors (Halpern, 1987;
Keverne, 1999). The sensory neurons reside within an oblong-shaped structure, the vomeronasal organ (VNO), situated at the rostral end of
the nasal cavity. Axons of these vomeronasal sensory neurons (VSNs)
project to the accessory olfactory bulb (AOB), a structure that is
anatomically distinct from the MOB. Glomeruli also form the targets for
VSN axons, but the glomerular structures are less well defined in the
AOB compared with the MOB (Meisami and Bhatnagar, 1998). This high
degree of specificity of axonal connections poses a formidable task for
the developing olfactory system (Mombaerts, 2001).
Several axon guidance molecules have been described to be expressed in
both olfactory systems (Treloar et al., 1997; Yoshihara et al., 1997;
Pasterkamp et al., 1999; St. John and Key, 2001). Among these are
neuropilin-1 (NP1) and neuropilin-2 (NP2), coreceptors for a subfamily
of secreted repulsive guidance cues, class 3 semaphorins. NP1 was first
identified as a high-affinity receptor for class 3 semaphorins, and the
molecular cloning of NP2 helped explain some of the specificity of
semaphorin activities (Chen et al., 1997; He and Tessier-Lavigne, 1997;
Kolodkin et al., 1997; Giger et al., 1998). It is now thought that
homodimers of NP1 bind sema3A, whereas heterodimers of NP1 and NP2 act
as sema3C receptors, and homodimers of NP2 alone confer responsiveness
to sema3B and sema3F (Chen et al., 1998; Raper, 2000; Zou et al.,
2000). Neuropilins, however, do not possess a signal-transducing
activity but act together with other transmembrane proteins, plexins,
to induce collapsing activity by class 3 semaphorins (Winberg et al.,
1998; Takahashi et al., 1999). Neuropilins determine class 3 semaphorin specificity, as evidenced by the profound disruption of axonal pathfinding of several types of NP2-expressing neurons in the absence
of NP2 activity (Chen et al., 2000; Giger et al., 2000).
Here, we describe a novel targeted NP2 mutation in which the
axonal marker tau-green fluorescent protein (GFP) is placed under the
control of the NP2 promoter, precluding expression of
endogenous NP2. We show that deficiency of NP2 results in improper
axonal innervation of the MOB and AOB by OSNs and VSNs, respectively, providing functional evidence for a role of NP2 in axon pathfinding to
the olfactory bulb.
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MATERIALS AND METHODS |
Targeting vector. NP2-specific primers at
the 5' end of the coding region were used to generate a probe by
reverse transcription (RT)-PCR to screen a 129/SvJ mouse bacterial
artificial chromosome genomic library (Genome Systems, St.
Louis, MO). The primer sequences used are as follows: forward primer,
5'-ATGGATATGTTTCCTCTTACCTGG-3'; and reverse primer,
5'-GAGTTACTTCAGTATGAACGTCAG-3'. An AccI-XbaI fragment containing the 5' end of the NP2 gene was subcloned
into pBluescript II SK(+) (Stratagene, La Jolla, CA) and was
sequenced in its entirety. A PacI site was placed into a
KpnI site 992 bp into the first intron, and a
loxP site 272 bp upstream of the translation start site was
inserted by ligation of a loxP oligonucleotide into an
MluI site (plasmid NP2-PacI). A PmeI
site was generated at the 5' end of the targeting vector for
linearization of the construct. A new cassette was designed consisting
of loxP followed by tauGFP, a polyadenylation
site (pA+), and a pgk-neomycin
expression cassette flanked by FRT sites (FNF) and was placed into the PacI site of
a modified multiple cloning site of pBluescript II SK. The resulting
loxP-tauGFP-pA+-FNF cassette
was inserted into NP2-PacI. The version of GFP used was
enhanced GFP-1 (Clontech, Palo Alto, CA).
Gene targeting. The targeting vector was linearized with
PmeI. Electroporation and cell culture of E14 cells (Hooper
et al., 1987) were performed as described previously (Mombaerts et al., 1996). Genomic DNA from G418-resistant embryonic stem cell colonies was
digested with EcoRV and analyzed by Southern blot
hybridization with a 3' probe external to the targeting vector. Germ
line transmission was obtained for the NP2 mutation (clone
NP2-flox-neo). The neo-selectable marker was removed from
the targeted mutations by crossing heterozygous mice to
hACTB-Flp transgenic mice (Dymecki, 1996). Next, deletion of
exon 1 and the first part of intron 1 was achieved by crossing mice
heterozygous for the NP2-flox-neo allele to EIIa-Cre
transgenic mice (Lakso et al., 1996). Intercrossing of heterozygous
NP2- mice resulted in heterozygous and homozygous NP2- mice that
are devoid of the Cre and flp transgenes.
Analysis was performed on mice that did not carry either transgene.
Mice were in a mixed (129 × C57BL/6) background and showed 100%
penetrance of the olfactory phenotypes described.
Sections and immunohistochemistry. Mice were deeply
anesthetized and intracardially perfused with 4% paraformaldehyde, pH 7.4, and post-fixed on ice for 3 hr. They were then frozen in OCT
compound (Sakura Finetek, Torrance, CA), and 20 µm sections were cut on a cryostat. Alternatively, fixed brains were cryoprotected in 30% sucrose and 1% paraformaldehyde and sectioned on a sliding microtome. For Gi2 staining, primary
antibodies (Wako Pure Chemical Industries) were used at a 1:300
dilution, followed by a goat anti-rabbit IgG coupled to Texas Red
(Jackson ImmunoResearch, West Grove, PA). For
Go immunostaining, primary antibodies (Medical
and Biological Laboratories Co.) were used at a 1:500 dilution,
followed by the same secondary antibody. For lacZ immunostaining, primary antibodies (Cappel, Durham, NC) were used at a 1:500 dilution, followed by the same secondary antibody. For lacZ histochemistry, sections were treated as described previously (Mombaerts et al., 1996)
and counterstained with a 1% solution of neutral red in PBS (Sigma,
St. Louis, MO).
LacZ and GFP expression and quantification. For taulacZ
whole-mount analysis, tissues were processed as described previously (Mombaerts et al., 1996), except that the fixation was performed on ice
for 10 min. We note that the VRi2
gene (Rodriguez et al., 1999) has been renamed V1rb2 (Del
Punta et al., 2000). For tauGFP whole mounts, mice were killed by
CO2 asphyxiation, and the olfactory bulb was
exposed.
5-bromo-4-chloro-3-indolyl- -D-galactoside
(X-gal)-stained whole-mount specimens were examined with a Zeiss
(Thornwood, NY) SV11 stereomicroscope, and sections were examined with
a Zeiss Axioplan 2 microscope; images were taken with a Zeiss AxioCam CCD camera. GFP whole mounts, sections, and immunostained sections were
examined with a Zeiss LSM 510 confocal microscope. Image files were
processed with Adobe Photoshop 6.0, and surface measurements to
quantify the area of tauGFP expression in the AOB were performed in
Canvas 6.0.
RT-PCR and in situ hybridization. RT-PCR was
performed with total RNA isolated from freshly dissected VNO, main
olfactory epithelium, or complete olfactory bulb. cDNA was generated
using oligo(dT) primers from the SuperScript kit (Invitrogen,
Rockville, MD). Specific primers for NP2 splice variants and for the
first three exons of the open reading frame (ORF) were designed using publicly available sequence information. The resulting PCR products for
the splice variants were then subcloned into pGEM-Teasy vector (Promega, Madison, WI) and sequenced from both ends to verify their identity.
DNA fragments spanning the first 800 bp of the sema3B,
sema3C, and sema3F ORFs were amplified by RT-PCR
from mouse olfactory bulb total RNA and were used as templates to
synthesize probes. Specific oligonucleotides were designed from
publicly available sequence information. Digoxigenin-labeled probes
were prepared by a DIG RNA-labeling kit (Roche Molecular
Biochemicals, Indianapolis, IN). Three- to 5-week-old mice were killed
by CO2 asphyxiation, and their brains were
removed for embedding in OCT. Coronal or sagittal sections were cut on
a cryostat at 20 µm thickness. The procedures used for hybridization,
washings, antibody reaction, and color reaction were performed as
described previously (Hirota et al., 1992). Images were taken on a
Zeiss Axioplan 2 microscope connected to a Zeiss AxioCam CCD camera.
Image files were processed with Adobe Photoshop 6.0. With the exception
of minor adjustments in brightness and contrast, the images were not altered.
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RESULTS |
Genomic structure and targeted disruption of NP2
The mouse NP2 gene consists of 18 exons spanning ~108
kb on chromosome 1c2 (Fig.
1A). The exon-intron
structure is similar to that of the human gene (Rossignol et al., 2000)
and features several alternatively spliced exons at the 3' end (Fig.
1C). These splice variants result in proteins with different
transmembrane and cytoplasmic domains and have been described in the
mouse before (Chen et al., 1997). To identify the particular splice
variants present in the olfactory system, RT-PCR was performed with
specific primers for NP2a and NP2b isoforms, respectively, using cDNA
prepared from either main olfactory or VNO epithelium. Both epithelia
express the same three of the possible six variants, indicating that
OSNs and VSNs use the same NP2 isoforms (Fig.
1E).
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Figure 1.
Genomic organization and targeted mutagenesis of
the NP2 locus in mouse. A, Exon-intron
structure of the NP2 locus on mouse chromosome
1c2 according to the Celera database. The coding region
is spread over 18 exons with alternatively spliced exons 16a, 16b, I,
and II at the 3' end. No other genes are predicted within the
NP2 locus. B, Targeting vector for
conditional disruption of NP2. A
loxP-tauGFP-pA+-FNF
cassette is inserted into the KpnI site 1 kb into the
first intron. A corresponding loxP site is inserted into a
MluI site 270 bp upstream of the start codon
(NP2-flox-neo). The position of the external probe for
Southern blot analysis is indicated. After flp recombination, the
pgk-neo expression cassette (FNF)
is removed, and after Cre recombination, part of exon 1 including the
start codon is removed, and tauGFP-pA+ is placed
immediately downstream of the NP2 promoter
(NP2-). C, Possible NP2 splice
variants. Two major isoforms (NP2a, NP2b)
are created by alternative splicing of either exon 16a or exon 16b. In
addition, exon 15 contains an internal splice acceptor site to create
two isoforms omitting five amino acids from NP2(5) to
create NP2(0). Finally, exon II coding for an additional
17 amino acids in intron 16 can be added to NP2a to
yield NP2a(17) and NP2a(22),
respectively. Because exon II is 3' to exon 16b, these isoforms are not
possible for NP2b. D, 5' RT-PCR of
wild-type and NP2- homozygous mice. cDNA prepared from NP2-
homozygous (lanes 1, 2) and wild-type (lanes 3, 4) mice was used to amplify PCR products spanning exon 1 to exon 2 (lanes 1, 3) and exon 2 to exon 3 (lanes 2, 4). No product is detectable in
lane 1, indicating that, as expected, NP2 mRNA from
NP2- homozygous mice does not contain the first exon of NP2.
E, RT-PCR of NP2 splice variants from VNO and main
olfactory epithelium (MOE) shows that of six possible
isoforms, both epithelia express only NP2a(0),
NP2a(17), and NP2b(0), indicating that
splicing at exon-intron boundary 15 occurs exclusively at the internal
splice acceptor site.
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A targeted mutation of the NP2 locus was created by
homologous recombination in embryonic stem cells using a combined
Cre-loxP; flp-FRT approach. The axonal marker tauGFP
(Rodriguez et al., 1999), preceded by a loxP sequence and
followed by a polyadenylation site and a neomycin expression
(pgk-neo) cassette flanked by FRT sites,
was placed 1 kb into the first intron. An upstream loxP site
was inserted 270 bp 5' of the translational start site (Fig. 1B). The resulting mutant allele,
NP2-flox-neo, was crossed to a mouse line carrying a
ubiquitously expressed flp-recombinase transgene to remove
the pgk-neo expression cassette. Subsequently, the first
exon corresponding to the first 24 amino acids encompassing the
complete signal sequence of NP2 can be removed by crossing to a mouse
line carrying a Cre-recombinase transgene expressed either
from a ubiquitous (as is the case here) or from a specific promoter.
The final recombined allele, NP2-, thus encodes an mRNA
lacking half of the first exon of NP2 (Fig.
1B), greatly reducing, if not precluding, the ability
of the mutant NP2 to be targeted to the plasma membrane. The loss of
the coding sequence encoding the signal peptide in the NP2
mRNA was verified by RT-PCR (Fig. 1D). In addition,
Cre recombination brings the axonal marker tauGFP under the control of
the NP2 promoter. Because tauGFP is followed by a
polyadenylation site, the chances of the formation of a functional NP2
protein are further reduced drastically. Consistent with a null
phenotype, no NP2 protein could be detected in immunostained sections
of homozygous NP2- brains (data not shown).
Heterozygous NP2- mice were intercrossed, and their offspring were
examined in a mixed (129 × C57BL/6) genetic background. Homozygous pups are born alive and indistinguishable from their heterozygous and wild-type littermates. Genotypic analysis reveals, however, that homozygous NP2- pups are obtained less frequently (10.9% homozygous, 27.3% wild-type, and 61.8% heterozygous;
n = 165), but no increased mortality is observed in
juveniles and adults. Homozygous NP2- mice often are not able to
reproduce. Another striking phenotype in NP2- mice consists of
dramatically slowed growth of homozygous pups. A reduction of overall
body size is apparent after 2-3 d and results in mice of approximately one-half the normal size at 3 weeks of age. On weaning, homozygous mice
catch up with their littermates in body size and are indistinguishable from their siblings after 6-8 weeks. Finally, hydrocephalus is often seen in homozygous but never in heterozygous NP2- mice (63.6%; n = 11; compared with 0%; n = 27). Together, the NP2- allele produces a mutant phenotype similar
to another targeted NP2 mutation (Giger et al., 2000).
Neuronal NP2 expression
In heterozygous NP2- mice, axonal projections of NP2-expressing
neurons can be visualized as a result of the expression of tauGFP from
the mutant allele; the other allele produces NP2 but not tauGFP. In the
CNS, tauGFP-positive cells are found in areas previously reported to
express NP2 (Chen et al., 1997; Giger et al., 1998, 2000; Chen et al.,
2000). Outside the olfactory system, these include the Purkinje cells
of the cerebellum, cells inside the deep cerebellar nuclei and several
other brainstem nuclei, the hippocampal formation (Fig.
2A), and non-neuronal
cells such as the lining of blood vessels and the choroid plexus of the
fourth ventricle (data not shown). In the olfactory system, cells in the anterior olfactory nucleus (Fig. 2B) and piriform
cortex (data not shown) express tauGFP. In the peripheral olfactory
system, a subset of OSNs express tauGFP in graded patterns from a high lateral level (Fig. 2C) to lower medial levels (Fig.
2D,E), as has been described for NP2 before (Norlin
et al., 2001). TauGFP is also detected in VSNs of the apical
(Gi2-expressing) layer of the VNO (Fig.
2F). Mitral and tufted cells in the AOB (see Fig.
6A,B) and early in development also in the MOB (data
not shown) are tauGFP-positive.
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Figure 2.
NP2-expressing and NP2-deficient brain
areas in heterozygous and homozygous mice. A, B, Several
areas in the brain positive for tauGFP, including the dentate gyrus in
the hippocampus (HIP) and the anterior olfactory
nucleus (AON). C, Sixty micrometer
coronal section through the main olfactory epithelium
(OE) of a P21 heterozygous NP2- mouse. Strongly
tauGFP-expressing OSNs are located throughout the lateral epithelium
and extend dendrites ending in knobs within the nasal cavity.
D, Intermediate area of the OE with a boundary
between an area with greater numbers of tauGFP-expressing OSNs
(left) and an area of fewer tauGFP-expressing OSNs
(right). Additionally, OSNs on the right
express tauGFP at lower levels compared with OSNs on the
left. E, Medial area of the OE with
sparse presence of tauGFP-expressing OSNs. Single tauGFP-positive cells
can be seen (arrow) among many tauGFP-negative cells.
F, Twenty micrometer coronal section through the VNO of
a heterozygous NP2- mouse (+/ ). TauGFP-expressing VSNs are located
in the apical layer (aL) and extend dendrites ending in
knobs at the luminal surface. No tauGFP-positive cell bodies are
present in the basal layer (bL). G,
Twenty micrometer coronal section through the VNO of a homozygous
NP2- mouse (/). No gross changes in zonal distribution are
detected. Medial is at top. Scale bar: A,
B, 1000 µm; C-G, 200 µm.
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Axonal projections of OSNs
Next, we determined whether the loss of NP2 has any effect on the
sensory projections to the MOB and AOB. OSNs project their axons
through the cribriform plate to the MOB, coursing within the outer
nerve layer until they reach their target glomeruli (Mombaerts et al.,
1996). NP2-positive axons form a set of glomeruli located in two
ventral areas, the most anterior tip of the bulb and more prominently
in the posterior part close to the border to the telencephalon (Fig.
3A,B). This distribution of
tauGFP-positive glomeruli is not grossly changed in homozygous NP2-
mice compared with heterozygous mice. However, individual OSN axons
overshoot their glomerular target and extend into the external
plexiform layer (Fig. 3C). These axons are only seen in
proximity to tauGFP-positive glomeruli and are more abundant in the
lateral MOB (Fig. 3D). They rarely penetrate the mitral cell
layer and are not observed in heterozygous mice (Fig. 3B).
To confirm that the tauGFP-positive fibers within the external
plexiform layer are OSN axons, we crossed NP2 mutant mice to
OMP-taulacZ mutant mice, in which all mature OSNs express taulacZ
(Mombaerts et al., 1996). Labeling of tauGFP-expressing axons inside
the external plexiform layer with an anti--galactosidase antibody
confirmed that most green fluorescent axons also express taulacZ,
indicating that they are misguided OSN axons (Fig. 3E,F, small arrows). Interestingly, a minority of
tauGFP-expressing axons do not label with the anti--galactosidase
antibody (Fig. 3E,F, large arrows). It is not
clear whether these axons represent axons of OMP-negative OSNs or
whether limited penetration of antibody into the tissue is responsible
for the lack of labeling of these axons. No taulacZ-positive,
tauGFP-negative fibers are seen within the external plexiform layer,
likely reflecting a cell-autonomous effect of the loss of NP2 on axon
guidance.
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Figure 3.
NP2-positive axonal innervation of the ventral MOB
in heterozygous and homozygous mice. A, Sixty micrometer
sagittal sections through the main olfactory bulb (MOB)
and accessory olfactory bulb (AOB) of a P27 heterozygous
NP2- mouse (+/). TauGFP-positive glomeruli are indicated by
arrows. B, Sixty micrometer sagittal
section through the ventral MOB of a P35 heterozygous NP2- mouse.
Glomeruli innervated by tauGFP-positive OSNs are mainly located at the
posterior end of the MOB (to the right). No
tauGFP-positive fibers are visible in the external plexiform layer
(EPL) or mitral cell layer (MCL).
C, Sixty micrometer sagittal section through the ventral
MOB of a P35 homozygous NP2- mouse (/). TauGFP-positive
glomeruli appear approximately in the same area as in heterozygous
mice. Arrows indicate tauGFP-positive fibers extending
into the EPL. D, Higher magnification of ventral
glomeruli in the lateral MOB of a homozygous NP2- mouse.
TauGFP-positive axons protrude from tauGFP-positive glomeruli
(Gl) into the external plexiform layer.
E, Higher magnification of a glomerulus located
ventroanteriorly in the MOB (left). Three individual
tauGFP-positive axons protrude into the EPL (small, large
arrows). F, Same section as in E
and immunolabeled for -galactosidase. Two of the three axons
emitting GFP fluorescence are also labeled with anti--galactosidase
antibodies (small arrows), whereas one tauGFP-positive
axon is not labeled (large arrow). Dorsal is at
top; anterior to the left. Scale bar
A, 1000 µm; B, C, 500 µm;
D, 200 µm; E, F, 50 µm.
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A second set of tauGFP-positive glomeruli are found in the caudal
region of the dorsal MOB (see Fig. 5B). They are
identifiable by their anatomical appearance as belonging to the
specialized groups called the modified glomerular complex and the
necklace glomeruli, respectively (see Fig. 5A). Sensory
neurons innervating these glomeruli are biochemically distinct from
other OSNs by using cGMP instead of cAMP in their odorant signal
transduction cascade (Juilfs et al., 1997) and are thought to be
involved in suckling behavior (Greer et al., 1982). Necklace glomeruli
are named for their appearance forming a ring of glomeruli surrounding the AOB that are connected by sensory axons like pearls on a string, whereas the modified glomerular complex is formed just anteriorly as a
group of two or three medial, closely joined glomeruli (see Fig.
5A). In contrast to other NP2-expressing glomeruli in the MOB, the positions of the modified glomerular complex and the necklace
glomeruli are shifted along the mediolateral axis in homozygous NP2-
mice, and sensory innervation of these glomeruli appears to be somewhat
diminished (see Fig. 5C,D). The number of glomeruli in these
two substructures usually remains the same.
Axonal projections of VSNs
Sensory neurons in the VNO can be subdivided into two distinct
groups depending on the location of their cell body in the apical or
basal layer of the epithelium. Neurons with cell bodies situated in the
apical layer express a distinct class of vomeronasal receptors, the
V1rs (Dulac and Axel, 1995). Furthermore, they can be distinguished by
their expression of the G-protein subunit Gi2
versus Go, which is expressed by neurons in
the basal layer (Jia and Halpern, 1996). Only sensory neurons of the apical layer express NP2, as revealed by tauGFP expression in heterozygous NP2- mice (Fig. 2F). Axon fascicles
emanating from the apical layer of the VNO follow several parallel
tracts along the septum to reach the olfactory bulb. After penetrating
the cribriform plate, axons in heterozygous NP2- mice form two or three tightly fasciculated bundles that migrate across the medial surface of the MOB on a straight trajectory toward the AOB, which is
located caudally to the MOB (Fig.
4A). Hence
tauGFP-positive VSN axons approach the AOB from the medial aspect of
the border between the anterior and posterior halves; once they enter
their target area, they turn anteriorly to innervate the anterior AOB exclusively (Figs. 5B,
6A). Unlabeled axons from the basal,
Go-expressing layer of the VNO innervate the
posterior half of the AOB (Figs. 5B, 6A).
This innervation pattern, as revealed by tauGFP expression, is apparent
from the first postnatal day and is maintained throughout early adult
life.
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Figure 4.
Defasciculation of the vomeronasal nerve in
NP2-deficient mice: whole-mount view of the medial surface of the MOB.
A, GFP fluorescence of VSN axon tracts from the apical
layer of the VNO in a P49 heterozygous NP2- mouse (+/). They
penetrate the cribriform plate (left) and form tightly
fasciculated bundles traversing over the surface of the MOB in a
straight trajectory to reach the AOB (right). Weaker
fluorescence in the ventral part (asterisk) corresponds
to NP2-positive innervation of the ventral MOB. B, VSN
axons crossing the surface of the MOB in a P49 homozygous NP2- mouse
(/). TauGFP-positive axons are much less fasciculated and are
spread over a greater area. Ultimately these axon tracts reach the
posterior part of the MOB (right), but they arrive at
unusual angles. Other areas of GFP fluorescence are found in the lining
of blood vessels (arrows). C-E,
V1rb2-expressing VSN projections across the MOB in various NP2
backgrounds, as visualized by X-gal staining. Normal fasciculation and
trajectories are seen in wild-type (+/+) and heterozygous (+/) mice.
In homozygous (/) mice, V1rb2-positive axons are much less
fasciculated and take a broader approach to the AOB. Dorsal is at
top; anterior to the left. Scale bars,
500 µm.
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Figure 5.
Aberrant sensory innervation of the caudal
olfactory bulb. A, Whole-mount view of the left dorsal
olfactory bulb of an OMP-taulacZ mouse after X-gal staining. The AOB
comprises of the anterior (aAOB) and posterior
(pAOB) halves and is located in the caudal region
of the olfactory bulb. The necklace glomeruli
(nGl) form a ring-shaped structure encircling the
AOB, whereas the modified glomerular complex (mGC)
consists of a group of medial, closely joined glomeruli. Anterior is at
top; medial to the right.
B, GFP fluorescence of NP2-expressing axons of a P34
heterozygous NP2- mouse (+/). Axon tracts from the apical layer of
the VNO arrive medially to innervate the aAOB exclusively. Weak
fluorescence in the pAOB is attributable to dendritic staining of
tauGFP-positive mitral and tufted cells. In addition, the mGC and the
nGl are also tauGFP-positive. C, Innervation pattern of
the same region in a P34 homozygous NP2- mouse (/). VSN axons
are now spreading over the medial half of the pAOB in addition to their
normal aAOB target. Also small GFP-fluorescent axon bundles extend
through the lateral half of the pAOB (large arrow). In
the MOB, the mGC is shifted and less well innervated compared with
heterozygous NP2- mice, and the nGl have a more disorganized
appearance. D, Another example of a homozygous NP2-
mouse. The NP2-expressing VSN axonal tracts approach the AOB from a
very posterior direction. Also, the mGC has shifted in the opposite
direction compared with the previous example. nGl are disorganized or
missing. E-H, V1rb2-expressing VSN innervation of the
aAOB in different NP2 backgrounds as visualized by X-gal staining. A
normal innervation pattern of the anterior AOB is seen in wild-type
(+/+) and heterozygous (+/) mice. All axons remain anterior. In
homozygous (/) mice, V1rb2 axons are misrouted into the pAOB
(G, small arrows) and sometimes form
glomerular-like structures (H, small
arrows). Innervation patterns in the anterior AOB are
comparable with +/+ and +/ mice. Red dots demarcate
aAOB from pAOB. Anterior is at top; medial to the
right. Scale bars, 250 µm.
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In homozygous NP2- mice, tauGFP-positive axons follow identical
tracts through the septum to reach the cribriform plate compared with
heterozygous NP2- littermates (data not shown). Across the medial
surface of the MOB, however, these axons form many more bundles, which
spread over a greater area (Fig. 4B). These bundles do reach the AOB, although many approach it from abnormal directions (Figs. 4B, 5C,D).
The most dramatic phenotype is observed in NP2-positive axon
innervation of the AOB. Whereas NP2-expressing VSN axons normally only
innervate the anterior half of the AOB, axons of NP2-deficient VSNs not
only innervate the anterior AOB but also the medial half of the
posterior AOB. Quantification reveals that the area covered by
tauGFP-positive fibers in the AOB increases by approximately one-half:
from 45.1 ± 2.3% (SEM; n = 6) in heterozygous
mice to 65.4 ± 4.7% (n = 5) in homozygous mice.
Moreover, apparently lost axons are seen to cross the lateral half of
the posterior AOB en route to the anterior AOB (Fig. 5C,D).
In sections, it is obvious that this inappropriate projection is not
confined to the nerve layer alone but extends to the glomerular layer
of the posterior AOB (Fig.
6B). Because there
appears to be massive innervation by NP2-positive axons of glomeruli in
the posterior AOB, which is normally occupied by
Go-expressing axons, we asked whether these
misrouted axons originate from the Gi2 layer
and examined the fate of the Go-expressing
axons from the basal layer of the VNO. Invariably, tauGFP-positive
axons also express Gi2, even if they innervate
the posterior AOB, as is demonstrated by a complete overlap of
anti-Gi2 antibody labeling and GFP fluorescence in homozygous NP2- mice (Fig. 6C).
Furthermore, no obvious alteration of the epithelial VNO layers is
detected (Fig. 2G). Double labeling of the AOB with an
anti-Go antibody shows that there is no double
staining between tauGFP-positive axons in the posterior AOB and the
endogenous Go-positive axons (Fig.
6D). Together, these results indicate that the
aberrant innervation of axons of VSNs from the apical layer of the VNO to the glomeruli of the posterior AOB results in a displacement of
axons originating from the basal layer of the VNO.
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Figure 6.
Aberrant sensory innervation of the accessory
olfactory bulb: sagittal sections through the AOB. A,
Sixty micrometer sagittal section through the AOB of a P29 heterozygous
NP2- mouse (+/). VSN axons terminate in the anterior AOB
(aAOB) and remain clear of the posterior AOB
(pAOB). Axons of tauGFP-positive mitral and
tufted cells are visible at the ventral edge of the AOB (large
arrows). B, Sixty micrometer sagittal section
through the AOB of a P29 homozygous NP2- mouse (/). Obvious
misrouting of tauGFP-positive axons can be seen in the pAOB in addition
to normal innervation of the aAOB. Misrouted axons penetrate from the
nerve layer (NL) into the glomerular layer
(GL). TauGFP-positive mitral and tufted cell bodies are
indicated by small arrows. C, Twenty
micrometer section through the nerve layer and glomerular layer of the
AOB of a P35 homozygous NP2- mouse (/) stained with an antibody
to Gi2. There is complete overlap between tauGFP
(green) and Gi2
(red) expression, resulting in yellow.
D, Twenty micrometer section through the AOB of a P35
homozygous NP2- mouse stained with an antibody to Go.
There is no overlap between tauGFP (green) and
Go (red) expression. E,
Innervation of V1rb2-expressing VSNs of the aAOB in an NP2 wild-type
(+/+) background, as visualized by X-gal staining. A normal innervation
pattern of the anterior AOB is seen. All axons in the NL and glomeruli
in the GL remain anterior. F, In homozygous (/)
mice, V1rb2 axons are misrouted to the pAOB where they form
glomerular-like structures. Anterior is to the left;
dorsal is at top. Scale bar, 200 µm.
|
|
To determine how the loss of NP2 affects target innervation at the
level of individual sensory neurons expressing a specific V1r gene, we crossed NP2- mice to a mouse strain in which
V1rb2 is tagged with the axonal marker taulacZ (Rodriguez et
al., 1999). This allows us to visualize the behavior of
V1rb2-expressing VSNs in an NP2 mutant background by relying on the
surrogate taulacZ marker. Normally, V1rb2-expressing VSN axons follow
the same path to their target region, as is seen with tauGFP axon
tracts (Fig. 4C,D). They innervate the anterior AOB in
variable patterns, as has been described previously (Rodriguez et al.,
1999) (Figs. 5E,F, 6E). In a homozygous
NP2- background, axons of V1rb2-expressing VSNs again mirror the
behavior observed with NP2-deficient, tauGFP-positive axonal tracts
(Fig. 4B). Axons of V1rb2-expressing, NP2-deficient OSNs reach the MOB, where they fan out over a greater surface area
(Fig. 4E) compared with wild-type and
NP2-heterozygous backgrounds (Fig. 4C,D). Consistent with
the general behavior of NP2-deficient VSNs (Fig. 4B),
axons of V1rb2-expressing, NP2-deficient VSNs reach the AOB from many
different directions. These atypical approaches of innervation may have
routed axons over inappropriate areas, causing them to innervate the
posterior AOB (Fig. 5D,H). However, even when the
axons arrive closer to the midline, they turn posteriorly to innervate
the wrong part of the AOB (Fig. 5C,G). Interestingly, innervation of the anterior AOB by axons of V1rb2-expressing, NP2-deficient VSNs is similar to that of wild-type or heterozygous mice, although some V1rb2-positive axons form glomerular-like structures in inappropriate areas (Figs 5H,
arrows, 6F). It is not clear, however,
whether these ectopic structures represent functional glomeruli. The
phenotypes described above persist throughout adult life: there appears
to be no correction of the pathfinding errors both in the MOB and AOB
in mice as old as 4 months.
Sema3 expression in the olfactory bulb
NP2 was first described as a homolog to NP1, which was identified
as a coreceptor for the class 3 semaphorin family of secreted axon
pathfinding molecules (He and Tessier-Lavigne, 1997; Kolodkin et al.,
1997). Subsequently, NP2 was implicated in mediating the repulsive
activity of two members of the class 3 semaphorin family, sema3B and
sema3F, and together with NP1, a coreceptor for another class 3 semaphorin, sema3C (Chen et al., 1997; Giger et al., 1998; Zou et al.,
2000). Sema3F was shown to be moderately expressed in a
medial-to-lateral gradient across the MOB during development but was
reported to be completely absent in the AOB (Giger et al., 1998).
Because both OSNs and VSNs are continuously renewed and send new axons
toward their glomerular targets during all of adult life (Graziadei and
Monti Graziadei, 1978), we visualized sema3B, sema3C, and sema3F gene expression in later-stage
olfactory bulbs. At postnatal day 21 (P21) and P37, in situ
hybridization shows expression of sema3B (Fig.
7A) and sema3C
(Fig. 7B) mostly by mitral cells and the immediately
underlying layers of granule cells in the MOB but not anywhere in the
AOB (Fig. 7D; data not shown). Interestingly, in contrast to
sema3F during development (Giger et al., 1998), sema3B and
sema3C signals are uniform across the medial-to-lateral
aspects of the MOB (Fig. 7E; data not shown). No
sema3F is detected above the background level in both the
MOB and AOB at this stage, by both RT-PCR and in situ
hybridization (Fig. 7C). Together with the continued
expression of NP2 in a subset OSNs and VSNs, these results indicate a
possible role for these sema3 family members in the observed phenotypes
in the MOB both during development and in adult life.
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Figure 7.
Localization of semaphorins in the olfactory bulb
by in situ hybridization. A, Sagittal
section of a P21 olfactory bulb hybridized with a sema3B
antisense probe. Signal is present in the mitral cell layer
(MCL) of the MOB and in the subset of granule cells
within the granule cell layer (GCL) that immediately
underlies the MCL. No expression is seen in the external plexiform
layer (EPL) or within glomeruli
(Gl). Scale bar, 50 µm. B,
Sagittal section of a P21 olfactory bulb hybridized with a
sema3C antisense probe. A similar expression pattern as
with sema3B is detected. C, Sagittal
section of a P21 olfactory bulb hybridized with a sema3F
antisense probe. No signal above background level is observed.
D, Sagittal section of a P36 olfactory bulb hybridized
with a sema3C antisense probe. Signal is present in the
mitral cell layer (MCL) of the MOB and in the subset of
granule cells immediately underlying the MCL within the GCL. No
expression is seen in and beyond the EPL and anywhere in the AOB.
Dorsal is at top; anterior to the left.
Scale bar, 500 µm. E, Coronal section of a P36
olfactory bulb hybridized with a sema3C antisense probe.
Uniform signal is seen within the MCL and the outer
portion of the GCL. Dorsal is at top; medial to the
left. Scale bar, 250 µm.
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|
| |
DISCUSSION |
Axon guidance to the MOB
The mechanisms whereby OSNs establish a precise map of innervation
onto glomerular targets in the MOB are poorly understood (Mombaerts,
2001). The odorant receptors themselves perform a crucial role in
guiding sensory axons to the correct site in the bulb (Mombaerts et
al., 1996; Wang et al., 1998). OSNs expressing a given OR are located
within one of four distinct zones of the olfactory epithelium (Ressler
et al., 1993; Vassar et al., 1993). So far, however, only one candidate
guidance molecule, the olfactory cell adhesion molecule, OCAM, is
expressed in a zonal manner (Yoshihara et al., 1997). Other guidance
molecules are expressed in glomeruli that reside in discrete bulbar
domains, but these do not correspond directly to the epithelial zones
(Nagao et al., 2000). Each glomerulus could potentially be assigned a
combinatorial code for its position within the olfactory bulb, with the
corresponding OR specifying the final "address" within increasingly
broader areas of expression of other guidance molecules.
Among the established guidance molecules expressed in the olfactory
system are two coreceptors for class 3 semaphorins, NP1 and NP2. Most
efforts to date have been focused on elucidating the role of NP1 in the
establishment of OSN connections to the bulb. These efforts have been
hampered by embryonic lethality resulting from loss of NP1 function
before any olfactory axonal outgrowth (Kitsukawa et al., 1997). The use
of a dominant negative NP1 mutation, however, indicates a role for NP1
in preventing premature innervation of OSNs into the early chick
telencephalon (Renzi et al., 2000). Removal of the optimal NP1 ligand
sema3A results in formation of NP1-positive glomeruli in inappropriate locations (Schwarting et al., 2000). NP1 is not expressed in the VNO or
the AOB (He and Tessier-Lavigne, 1997; Kolodkin et al., 1997).
The involvement of NP2 in establishing sensory innervation of the MOB
and AOB has not yet been investigated. Of the two previously described
NP2 mutations, one completely removes NP2 expression but does not allow
visualization of NP2-expressing cells (Giger et al., 2000). The other
mutation includes a cellular and axonal marker but leaves ~0.5% of
NP2 expression intact, thus creating a severe hypomorph but not a null
mutation (Chen et al., 2000). Both studies describe axonal pathfinding
errors in multiple CNS areas. Although they both report high expression
of NP2 in the olfactory system, analysis of OSN or VSN axonal
innervation in NP2 mutant mice has not been presented.
Differential effects of NP2 deficiency on OSN subpopulations
We show that NP2 is expressed in a subset of OSNs projecting to a
restricted set of glomeruli mostly in the anterior tip and the
ventroposterior region of the MOB. These NP2-positive regions of the
MOB overlap but are distinct from the NP1-positive zones described
previously (Nagao et al., 2000), hence adding another potential
parameter to the combinatorial definition of glomerular positions. The
loss of NP2 does not appear to affect grossly this glomerular
positioning, with NP2-positive glomeruli still present in the
ventroposterior and anterior areas. It will be interesting to determine
the effect of the loss of NP2 on OSNs expressing defined, genetically
tagged ORs (Mombaerts et al., 1996), but unfortunately, none of the
tagged OSN subsets that we can study expresses NP2 (data not shown).
Loss of NP2 does affect, however, the ability of individual OSN axons
to remain within the glomerular layer. This type of overshooting into
the external plexiform layer has been reported to occur on rare
occasions during development but not in adult animals (Royal and Key,
1999). Indeed, mature glomeruli appear to trap sensory axons well
within their borders, as was demonstrated by prolonged overexpression
of GAP43 in OSNs under control of the OMP promoter (Holtmaat
et al., 1995). These axons targeted their glomeruli but continued to
grow inside the glomerulus until they hit the interior border, yet they
never overshot into the external plexiform layer (Holtmaat et al.,
1995). The expression of three NP2 ligands, sema3B and sema3C
continuously and sema3F early on (Giger et al., 1998), in both mitral
and granule cells located immediately underneath may explain the
reluctance of NP2-expressing OSN axons to penetrate too deeply into the
MOB. Indeed, both of these cell types extend their dendrites close to
the glomerular layer, ideally suited to release the secreted semaphorins.
One noted exception to the above-described phenotype of overshooting
are the necklace glomeruli and the modified glomerular complex. In
addition to the obvious distinct glomerular appearance, OSNs projecting
to these glomeruli use a different set of signaling molecules (cGMP vs
cAMP) for odorant detection (Juilfs et al., 1997) and have been
implicated in mediating suckling behavior (Greer et al., 1982). In an
NP2-deficient background, both the position and level of innervation of
these specialized glomeruli are affected.
Loss of NP2 results in misrouting of vomeronasal axons of the
apical layer
VSNs in the two layers of the VNO express two unrelated classes of
putative pheromone receptors, or vomeronasal receptors, V1rs and V2rs,
and express distinct subunits of G-protein. NP2 expression is restricted to the apical V1r- and
Gi2-expressing layer, whereas VSNs in the
basal V2r- and Go-expressing layer are
NP2-negative. Our results confirm that NP2-positive VSNs from the
apical layer innervate the anterior half of the AOB exclusively (Jia
and Halpern, 1996). The first phenotype resulting from the loss of NP2
was observed in axons of apical VSNs traversing the medial surface of
the MOB. These axons fan out over a larger area and appear generally
less directed in their trajectory toward the AOB. It is tempting to
speculate that the presence of sema3B and sema3C, and sema3F during
development (Giger et al., 1998), in the MOB induces the very directed
and fasciculated growth of NP2-positive VSN axons. In fact, mechanisms
of how repulsive cues can induce directed growth instead of complete
growth cone collapse were demonstrated in other systems before (Fan and
Raper, 1995; Zou et al., 2000). A combination of attractive and
repulsive cues could induce the formation of tight and directed
fascicles across the medial surface of the MOB.
Gi2-expressing axons eventually reach the AOB
in an NP2-mutant background, indicating the presence of NP2-independent
cues that attract them to their proper target area.
Once within the AOB, NP2-deficient VSN axons originating from the
apical layer display a profound misrouting phenotype, invading the
posterior aspect of the AOB. Although the inappropriate innervation pattern can be partially explained by the obscure angles of approach, it is evident that some axons actively turn posteriorly to invade the
wrong area of the AOB, yet three established NP2 ligands, sema3B,
sema3C, and sema3F, could not be detected in the AOB in this or in
previous studies (Chen et al., 1997; Giger et al., 1998, 2000; Chen et
al., 2000), ruling out a direct repulsive mechanism for the observed
misrouting phenotype. On the other hand, sema3F was shown to be present
at high levels in the VNO, indicating a possible cell-autonomous mode
of action (Giger et al., 1998). It is not clear, however, how such a
mechanism would produce the observed phenotype in the AOB of homozygous
NP2- mice. But neuropilin signaling and ligand binding are
exceedingly complex; so far, neuropilins have been shown to bind some
members of the class 3 semaphorins with varied affinities depending on their partners for dimerization (Chen et al., 1998; Raper, 2000), but
not all class 3 semaphorins, some of which are expressed in the
olfactory system (Miyazaki et al., 1999), have been investigated. Furthermore, neuropilin binding of one class 3 semaphorin can be
modified by other members of the same family (Takahashi et al., 1998),
and signal transduction depends on the interaction of the
semaphorin-neuropilin complex with yet another class of transmembrane
molecules, plexins, adding another level of specificity (Winberg et
al., 1998; Takahashi et al., 1999; Tamagnone and Comoglio, 2000).
Finally, under certain circumstances, some class 3 semaphorins can act
as attractive guidance cues in the olfactory system (de Castro et al.,
1999). Interactions between NP1 and the neural cell adhesion molecule
L1 have been reported, indicating the possibility of indirect actions
of neuropilins on other pathfinding molecules (Castellani et al.,
2000). It has also not been ruled out that neuropilins may act as cell
adhesion molecules themselves. In this respect, it is interesting to
note that a study of the effects of ephrin5A mutant mice on
the projections of apical sensory neurons to the anterior AOB shows a
very similar misrouting phenotype, and that this finding seems to
contradict the normal mechanisms proposed for ephrin signaling (Knoll
et al., 2001). There is, however, no direct evidence for an interaction
between NP2 and ephrinA5 to date. It is thus possible that we have not
examined the proper combination of ligands and coreceptors for NP2, and that there may be yet other mechanisms of NP2 activity.
| |
FOOTNOTES |
Received Dec. 11, 2001; revised Feb. 13, 2002; accepted Feb. 15, 2002.
This work was supported by the National Institutes of Health. We thank
H. Nagao and K. Mori (University of Tokyo, Tokyo, Japan) for
sharing the NP2 antiserum, J. Miwa and T. Ishii for technical help, and
P. Feinstein, J. Miwa, and L. Vosshall for helpful discussion.
Correspondence should be addressed to Peter Mombaerts, The Rockefeller
University, 1230 York Avenue, New York, NY 10021. E-mail: peter{at}rockefeller.edu.
Dr. Rodriguez's present address: Department of Zoology and Animal
Biology, University of Geneva, 1211 Geneva 4, Switzerland.
| |
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TOP
ABSTRACT
INTRODUCTION
