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First published online 24 January 2007
doi: 10.1242/dev.02791
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1 Carnegie Institution of Washington, Department of Embryology, 3520 San Martin
Drive, Baltimore, MD 21218, USA.
2 Howard Hughes Medical Institute and Division of Basic Science, Fred Hutchinson
Cancer Research Center, 1100 Fairview Avenue N., Box 19024 Seattle, WA 98109,
USA.
* Author for correspondence (e-mail: halpern{at}ciwemb.edu)
Accepted 8 December 2006
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SUMMARY |
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 TOP SUMMARY INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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Key words: Brain asymmetry, Diencephalon, Epithalamus, Interpeduncular nucleus, Axon guidance, Semaphorin, Neuropilin, Zebrafish
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INTRODUCTION |
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TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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;
Ponnio and Conneely, 2004;
ten Donkelaar et al., 2004).
Left-right (L-R) differences in fiber tracts have been correlated with
hemispheric specialization of the brain
(Nucifora et al., 2005), and
presumably underlie asymmetries in axonal connections. How differences in
connectivity could arise between the left and right sides of the brain is a
question that remains largely unexplored.
The zebrafish provides a simple model to study the molecular and
developmental basis of anatomical asymmetry in the developing brain. The
epithalamus of the dorsal diencephalon consists of the habenular nuclei and
the pineal complex. The habenulae exhibit L-R differences in their size,
volume of dense neuropil and patterns of gene expression
(Concha et al., 2000;
Concha et al., 2003;
Gamse et al., 2003). For
example, leftover (lov) and right-on
(ron), two members (kctd12.1 and kctd12.2,
respectively - Zebrafish Information Network) of the KCTD (potassium channel
tetramerisation domain containing) gene family, are expressed more extensively
by the left and right habenula, respectively
(Gamse et al., 2003;
Gamse et al., 2005). Previous
work has shown that habenular asymmetry is mediated by the parapineal, an
accessory organ to the pineal that is situated on the left side of the brain
in over 95% of zebrafish larvae. Even earlier in development, lateralized
Nodal signaling influences the directional asymmetry of the parapineal
(Concha et al., 2000;
Concha et al., 2003;
Gamse et al., 2003) and, in
the absence of this signaling, the location of the parapineal becomes
randomized (i.e. approximately 50% of larvae develop the parapineal on the
left side of the brain and 50% on the right).
The majority of habenular efferents project to the interpeduncular nucleus
(IPN) in the midbrain tegmentum through the prominent fasciculus retroflexus
(FR) fiber bundle, as part of a highly conserved conduction system in the
vertebrate brain (Cajal, 1995;
Herrick, 1948;
Sutherland, 1982).
Differential labeling of the zebrafish habenulae with fluorescent dyes or
immunodetection of the Lov and Ron proteins reveals that efferents from the
left habenula terminate throughout the dorsoventral (D-V) extent of the IPN,
whereas right habenular neurons only project to the more ventral region
(Aizawa et al., 2005;
Gamse et al., 2005). In this
manner, a distinct D-V pattern of innervation is established by neurons from
the left and right sides of the brain. How differential target recognition is
accomplished by habenular neurons is unknown, but a likely mechanism is
through differences in the distribution of, or receptivity to, growth cone
guidance cues.
Previously, class III Semaphorins (Sema3s) were shown to be important
signals for axonal tract formation in the vertebrate forebrain, and notably
for the habenulointerpeduncular connection. The FR is defasiculated in mice
with targeted mutations in sema3F or nrp2
(Chen et al., 2000;
Giger et al., 2000;
Sahay et al., 2003). Sema3F
and Nrp2, along with netrin1 and Dcc (deleted in colorectal cancer) may also
guide growing habenular axons toward the IPN
(Funato et al., 2000).
Class III Sema3s are highly conserved secreted molecules that bind
specifically to receptors from the Neuropilin (Nrp) protein family, which
require Plexin family members to transduce guidance signals
(He et al., 2002;
Kolodkin et al., 1993;
Pasterkamp and Kolodkin, 2003;
Tamagnone and Comoglio, 2000;
Yu and Kolodkin, 1999). Growth
cones can interpret Semaphorins as repulsive or attractive cues, depending on
the dynamics of the receptor complex expressed on the membrane of the
responding neuronal processes. Both attraction and repulsion by Sema3B are
crucial for the development of the forebrain anterior commissure
(Falk et al., 2005). Sema3A
attracts the Nrp1-expressing apical dendrites of pyramidal neurons to grow
towards the pial surface of cortical slices
(Polleux et al., 2000). By
contrast, high levels of Sema3A prevent pontocerebellar axons from innervating
the hemispheric lobules (Solowska et al.,
2002).
In zebrafish, four Nrp-related proteins (Nrp1a, Nrp1b, Nrp2a, Nrp2b) and
six Sema3s (Sema3Aa, Sema3Ab, Sema3D, Sema3Fa, Sema3Ga and Sema3Gb) have been
described so far (Bovenkamp et al.,
2004; Martyn and
Schulte-Merker, 2004; Yu et
al., 2004; Yu and Moens,
2005). Consistent with studies from other organisms, these
proteins play diverse roles during zebrafish embryonic development, in axon
guidance, cell migration and angiogenesis. Sema3D inhibits ventral retinal
ganglion cells from extending into the ventral tectum
(Liu et al., 2004;
Sakai and Halloran, 2006), and
prevents medial longitudinal fascicles from growing rostrally
(Wolman et al., 2004).
Zebrafish Nrp1a is involved in formation of the anterior commissure and in
motor axon outgrowth from the spinal cord
(Feldner et al., 2005;
Wolman et al., 2004). Other
Sema and Nrp family members regulate cranial neural crest cell migration
(Yu and Moens, 2005) and have
been implicated in vascular development
(Lee et al., 2002;
Martyn and Schulte-Merker,
2004; Shoji et al.,
2003; Torres-Vazquez et al.,
2004).
We report here that nrp1a is selectively expressed in the left habenula of zebrafish larvae at the time when left and right habenular neurons are establishing different D-V projections onto the IPN. As with other habenular asymmetries, Nodal signaling and the left-sided parapineal mediate this L-R difference in nrp1a expression. Loss of Nrp1a prevents dorsal innervation of the IPN by left habenular neurons, as does depletion of a specific Semaphorin, Sema3D. Conversely, Sema3D overexpression results in ectopic axonal projections from the left habenula that extend beyond the IPN. These results indicate that Sema3D signaling through the asymmetrically distributed Nrp1a receptor in left and right habenular neurons mediates the differential D-V innervation of their shared synaptic target.
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MATERIALS AND METHODS |
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TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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). The AB
wild-type strain (Walker,
1999), and the transgenic lines
Tg(flh:GFP)c161, Tg(flh:GFP)c162
(Gamse et al., 2003) and
Tg(foxd3:GFP)fkg17
(Gilmour et al., 2002) were
used in this study.
In situ hybridization and sema3D mRNA production
The nrp1a, nrp1b, nrp2a, nrp2b, sema3Aa, sema3Ab, sema3D, sema3Fa,
sema3Ga and sema3Gb cDNA clones used for synthesis of antisense
digoxigenin or fluorescein RNA probes were as previously described
(Yu and Moens, 2005). RNA in
situ hybridization was performed as described
(Gamse et al., 2002).
Bright-field images were captured by an Axiocam digital camera mounted on an
Axioskop (Carl Zeiss). The nrp1a+3'UTR construct for mRNA
production was generated by cloning the PCR-amplified open reading frame (ORF)
from the nrp1a clone into the pCRIITOPO vector (Invitrogen), followed
by the addition of the reverse transcription-PCR (RT-PCR) -generated
3'UTR fragment. The sema3D+3'UTR construct for mRNA
production was generated by RT-PCR from the ORF, followed by addition of the
3'UTR from the sema3D clone described above. The
sema3Gb+3'UTR construct for mRNA production was generated by
PCR from the sema3Gb clone, followed by subcloning into the pCRIITOPO
vector. Sense mRNAs were generated utilizing the mMESSAGE mMachine Kit
(Ambion); approximately 0.25-0.5 ng of mRNA was injected into 1- to 2-cell
stage embryos.
Morpholino injections
Sequences of antisense morpholino oligonucleotides (MOs; Gene Tools,
Philomath, OR) targeting the nrp1a translation initiation site were
reported previously (Wolman et al.,
2004; Yu and Moens,
2005). MOs designed in both studies were effective at perturbing
IPN innervation at similar concentrations; however, less non-specific toxicity
at high doses was observed using the nrp1a MO sequence of Wolman et
al. (Wolman et al., 2004).
Antisense MOs targeting sema3Aa, sema3Ab, sema3D, sema3Fa, sema3Ga
and sema3Gb were synthesized as described
(Yu and Moens, 2005). Optimal
concentrations of nrp1a and sema3D MOs were determined by
assaying titrations from 3.0 to 0.3 ng. Optimal concentrations for
sema3Aa, sema3Ab, sema3Fa, sema3Ga and sema3Gb were
determined by assaying titrations from 8 to 3 ng. Desired concentrations were
achieved by diluting stock solutions of MO (10-20 mg/ml) in RNase-free water
containing Phenol Red (0.2%). Approximately 1 nl was injected into embryos at
the 1- to 2-cell stage. The specificity of each MO was tested previously
(Wolman et al., 2004;
Yu and Moens, 2005) and, in
the present study, in rescue experiments in which 0.5 ng of in
vitro-translated nrp1a or sema3D mRNA was combined with
0.6-0.8 ng of Nrp1a or Sema3D MO, respectively. For mock-injected controls, 1
nl of Phenol Red (0.2%) was injected into sibling embryos. Injection of the
southpaw (spaw) MO was performed as previously described
(Gamse et al., 2005). Details
of MO injection experiments are shown in
Table 1.
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; Gamse et al.,
2003), with a minor modification. For Lov and Ron antibody
staining only, embryos were permeabilized in 100% acetone at -20°C for 20
minutes before rehydration and blocking. Immunolabeled embryos and larvae were
mounted between bridged coverslips in glycerol and images were collected on a
Leica SP2 confocal microscope. Double labeling to detect protein and
nrp1a RNA localization was performed as described
(Gamse et al., 2005).
Laser-mediated cell ablation
Parapineal ablation was performed on Tg(flh:GFP)c161 or
Tg(flh:GFP)c162 embryos at 28-32 hours post-fertilization
as previously described (Gamse et al.,
2003).
Dye labeling
Individual larvae were anesthetized with tricaine (4 mg/ml) at 4 days
post-fertilization and mounted dorsal side up in 1.2% low-melting (LM) agarose
(Cambrex) on a glass slide. The lipophilic dyes DiI and DiO (Molecular Probes)
were dissolved in dimethylformamide (DMF) at 5 mg/ml by heating at 50°C
for 5-10 minutes, and the solutions back-loaded into glass needles. Each dye
was pressure-injected into the left or right habenula of larvae after the
habenular commissure had been severed with a tungsten needle. Progression of
the dye from the habenulae to the IPN was monitored under a Leica MZFLIII
stereomicroscope. Once the dye had reached the IPN (typically within 1-3
hours), the larva was remounted in 1.2% LM agarose with the left side facing
upward. Lateral view images of axonal endings on the IPN were collected using
a Leica SP2 confocal microscope.
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RESULTS |
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TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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;
Gamse et al., 2005). We
examined when this stereotypic D-V pattern is established in the larval CNS by
comparing the two methods for labeling L-R habenular efferents. As in the
adult, DiI-labeled axons from the left habenula innervate both the dorsal and
ventral IPN (Gamse et al.,
2005); whereas DiO-labeled axons from the right habenula were
found to innervate only the ventral IPN of 4-day larvae
(Fig. 1A-D). This D-V
innervation pattern of the IPN is reproduced by anti-Lov and anti-Ron
immunofluorescence at 4 days (Gamse et
al., 2005), suggesting that labeling earlier stages with these
antibodies would accurately reflect the developmental progression of the
habenulointerpeduncular connection. Although Lov+ and
Ron+ axons were detected at 2 days within the FR
(Fig. 1E-H), the first evidence
for differences in growth cone morphology was not observed until 3 days, at
which time Lov+ filopodial processes begin to extend dorsally
(Fig. 1I-L). Between 3 and 4
days, left and right habenular axons established their differential D-V
projections onto the IPN (Fig.
1M-P). Thus, if asymmetric guidance cues underlie the L-R
difference in IPN connectivity, then these cues should be present during this
time period.
nrp1a is asymmetrically expressed in the habenular nuclei
We took a candidate approach to search for molecules involved in
differential target recognition by L-R habenular neurons by examining the gene
expression patterns of several known axon-guidance molecules in the zebrafish
larval brain. As a starting point, expression of zebrafish genes encoding
Neuropilin receptors and their Semaphorin binding partners was re-evaluated
because of their known role in FR formation in the mouse
(Chen et al., 2000;
Giger et al., 2000;
Sahay et al., 2003). We
discovered that nrp1a, which encodes a known receptor for secreted
class III Semaphorins (He et al.,
2002; Pasterkamp and Kolodkin,
2003; Tamagnone and Comoglio,
2000; Yu and Kolodkin,
1999), is expressed asymmetrically in the diencephalon
(Fig. 2A,B); specifically,
within the left habenular nucleus (Fig.
2C). Many, but not all, left habenular neurons were found to
express nrp1a, as revealed by double labeling with Lov and Ron
antisera (Fig. 2D,E). Asymmetry
in nrp1a expression could be distinguished as early as 2 days
(Fig. 2A), which precedes D-V
innervation of the IPN by habenular neurons. In contrast to nrp1a,
none of the other known Nrp genes (nrp1b, nrp2a and nrp2b)
was expressed asymmetrically in the habenulae at corresponding stages
(Fig. 2F-H).
L-R differences in habenular gene expression are under the influence of the
left-sided parapineal organ. Nodal signaling biases the position of the
parapineal, which, in turn, directs laterality of the habenulae, including
their asymmetric expression of Lov and Ron and D-V axonal projections to the
IPN (Concha et al., 2003;
Gamse et al., 2005;
Gamse et al., 2003).
Perturbation of the zebrafish Nodal signal Southpaw by injection of an
antisense MO (Gamse et al.,
2005; Long et al.,
2003) also resulted in L-R randomization of nrp1a
expression, with the direction of asymmetry corresponding to parapineal
laterality (Fig. 2I,J).
Approximately half of Spaw MO-injected populations (
56%, n=96)
expressed nrp1a in the left habenula, as compared with 95% of
mock-injected controls (n=89). Moreover, parapineal ablation resulted
in the loss of habenular nrp1a expression
(Fig. 3G,H). The data support
the hypothesis that, under the influence of Nodal signaling and the left-sided
parapineal, asymmetric Nrp1a selectively guides left habenular axons.
Depletion of Nrp1a perturbs innervation of the dorsal IPN by left habenular axons
To test the role of asymmetric nrp1a expression in habenular axon
guidance, embryos were injected with an antisense MO that inhibits Nrp1a
translation. Habenular asymmetry was not affected
(Fig. 3A,B); however, depletion
of Nrp1a resulted in a reduction of left habenular projections to the dorsal
IPN, as demonstrated by a decrease in Lov-immunoreactive
(Fig. 3C,D) or DiI-labeled
(Fig. 3E,F) axonal endings.
Approximately 75% of MO-injected larvae (n=150) exhibited a loss in
dorsal IPN that was only rarely observed in mock-injected controls (3.5%
of larvae, n=202; see Table
1). Similarly, the absence of nrp1a expression in the
left habenula following ablation of the parapineal
(Fig. 3G,H) correlated with a
decrease in projections to the dorsal IPN from the left habenula (76% of
larvae, n=24; Fig.
3I). These observations indicate that the asymmetric distribution
of the Nrp1a receptor accounts for the L-R differences in habenular
connectivity with the IPN.
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;
Yu and Moens, 2005), and some
sema genes are expressed in cells along the trajectory of the FR and in the
vicinity of the IPN (see Fig. S1 in the supplementary material). This
precludes identification of the specific signal that most likely guides
Nrp1a-expressing axons from the left habenula.
To address this issue, we examined whether the IPN projection pattern was
perturbed following injection of antisense MOs specific for each of the Sema3
transcripts. Because Neuropilins and Semaphorins are involved in many
different contexts in axon guidance and cell migration
(Sakai and Halloran, 2006;
Wolman et al., 2004;
Yu and Moens, 2005), we first
assessed whether the overall pattern of axonal projections and, more
specifically, the asymmetric habenular projection to the IPN was disrupted by
MO treatments. Brain morphology and organization, as assayed by immunolabeling
for acetylated tubulin (Fig.
4A-H), appeared grossly normal at the concentrations of Nrp1a and
Sema MOs determined to be optimal (see Materials and methods;
Fig. 5). Expression of
nrp1a and sema3D in the brain was also unaffected by Sema3D
or Nrp1a MO injection (data not shown). Habenular projections along the FR, as
demonstrated by Lov immunofluorescence, were also intact
(Fig. 4A-H). However, this
analysis revealed that injection of a MO directed against one Sema, Sema3D,
resulted in a phenotype at the IPN resembling that generated by the Nrp1a MO
(Fig. 4, compare B with E).
Double labeling with Ron and Lov antisera or direct DiI labeling of the left habenula further confirmed that depletion of Sema3D disrupted innervation of the dorsal IPN by left habenular neurons. Although habenular L-R asymmetry was maintained (Fig. 4I,J), the majority of Lov+ axons were coextensive with Ron+ axons (Fig. 4, compare L with M) and predominantly projected to the ventral IPN (Fig. 4, compare O with P) in larvae that had received Sema3D or Nrp1a MOs. By contrast, MO-mediated depletion of Sema3Aa, Sema3Ab, Sema3Fa, Sema3Ga or Sema3Gb did not affect axonal projections from the left habenula to the dorsal IPN, which were indistinguishable from mock-injected controls (Fig. 4R-V). Taken together, the data suggest that Sema3D is the key ligand responsible for guidance of Nrp1a-expressing left habenular axons to the dorsal IPN.
Synergistic action of Nrp1a and Sema3D
The effect of Nrp1a and Sema3D MO injections on the formation of left
habenular connections with the dorsal IPN was determined to be
concentration-dependent and could be rescued by co-injection of the
corresponding mRNA (Fig. 5 and
see Table 1). Moreover, the
combined injection of both MOs at sub-threshold doses proved significantly
more effective at disrupting innervation of the dorsal IPN than either MO
alone (Fig. 4N,Q,
Fig. 5;
Table 1). The synergistic
effect of the Nrp1a and Sema3D MOs provides additional support for the role of
this receptor-ligand pair in guiding left habenular axons to the dorsal
IPN.
Sema3D overexpression results in ectopic axonal projections
To test whether the Sema3D ligand can influence the axonal projections of
Nrp1a-expressing neurons, global overexpression was performed by injecting
sema3D mRNA into 1- to 2-cell stage zebrafish embryos. Habenular
efferents at the IPN were examined in the resultant 4-day-old larvae by Lov
and Ron immunofluorescence or by direct dye labeling of the left habenula.
Using either labeling method, axonal processes were sometimes visualized not
only at the dorsal IPN, but extending abnormally beyond it
(Fig. 6, compare A,D with B,E;
9% of larvae, n=64). The ectopic processes were directed toward the
dorsal midbrain where endogenous sema3D is expressed
(Fig. 6G,H).
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DISCUSSION |
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TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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; Gamse et al.,
2003). One notable difference is in the connections that habenular
axons form with the midbrain interpeduncular nucleus: axon terminals from
right habenular neurons are confined to the ventral IPN, whereas left
habenular neurons innervate ventral as well as dorsal regions
(Aizawa et al., 2005;
Gamse et al., 2005). In this
study, we have shown that asymmetric expression of the Nrp1a receptor mediates
this difference in connectivity between left and right habenular efferents,
through their differential response to the guidance cue Sema3D. Although it is
known that axon-guidance molecules play essential roles in the establishment
of neuronal connections in the developing nervous system, this is the first
demonstration of their function in directing differences in target recognition
between neurons on the left and right sides of the vertebrate brain.
Antisera directed against the Leftover and Right-on proteins have proven to
be valuable tools to determine when habenulointerpeduncular connections are
first formed. In the adult (Gamse et al.,
2005) and larval (this study) zebrafish brain, immunodetection of
these related proteins closely reproduces what is observed following direct
labeling of each habenula with lipophilic dyes. Lov is predominantly, but not
exclusively, expressed in the left habenula and Lov+ immunoreactive
axonal endings are found along the entire extent of the IPN, as are
DiI-labeled projections from the left habenula. By contrast, more cells in the
right habenula express Ron and all Ron-immunoreactive endings terminate in the
ventral IPN, equivalent to dye-labeled efferents emanating from the right
habenula. From labeling with these antisera, we find that the D-V pattern of
target innervation is established between the third and fourth days of
development, indicative of the window when guidance cues must be
functioning.
The simplest model for generating L-R differences in neural connectivity is
the asymmetric distribution of axon-guidance signals or the receptors they
activate. However, prior reports on the expression of guidance molecules in
the developing zebrafish brain provided no evidence for L-R asymmetry, at
least at the level of transcription. We reinvestigated this issue by focusing
on expression in the habenulointerpeduncular system, specifically between 2
and 4 days of development. Because Semaphorin signaling through Neuropilin
receptors had been implicated previously in the fasciculation of the FR axon
bundle (Chen et al., 2000;
Funato et al., 2000;
Giger et al., 2000;
Sahay et al., 2003), and genes
encoding zebrafish family members were known to be expressed in discrete
forebrain and midbrain domains (Bovenkamp
et al., 2004; Yu et al.,
2004), these seemed to be logical candidates to re-examine. Only
one, nrp1a, was found to fulfil the criteria of being expressed
asymmetrically in the diencephalon during the relevant developmental
period.
|
). Southpaw
depletion also produces L-R reversals in the nrp1a habenular
expression pattern. Laser-mediated ablation of the parapineal has been
proposed to cause right isomerism, with both habenulae developing molecular
properties of the right habenula (Gamse et
al., 2005). Accordingly, following selective ablation of the
parapineal, nrp1a expression is not detected in the left habenula and
left habenular efferents fail to innervate the dorsal IPN. These results
strongly suggest that nrp1a mediates the selective innervation of the
dorsal target by habenular neurons on the left side of the brain, direct
support for which comes from the targeted disruption of Nrp1a protein
synthesis by antisense morpholinos.
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|
Further evidence for the role of the Nrp1a receptor in guiding left
habenular neurons at the target was provided by the identification of the
specific ligand that activates it. Nrp receptors bind a variety of secreted
Class III Semaphorins with various affinities, and the ligands can operate at
a considerable distance from the cells that produce and secrete them
(Feiner et al., 1997;
He et al., 2002;
Kolodkin et al., 1993;
Pasterkamp and Kolodkin, 2003;
Tamagnone and Comoglio, 2000;
Yu and Kolodkin, 1999).
Therefore, it is important to determine experimentally the Sema ligand(s) that
partners the Nrp receptor(s) in any given developmental context. Several lines
of evidence support the hypothesis that Sema3D serves to guide
Nrp1a-expressing axons from the left habenula towards the dorsal IPN. First,
sema3d transcripts are localized in cells along the
forebrain-to-midbrain trajectory of the FR, and dorsal to the IPN during the
period when habenulointerpeduncular connections are established. Second,
MO-mediated depletion of Sema3D phenocopies the loss of Nrp1a, causing a
reduction in left habenular projections to the dorsal IPN. Targeted depletion
of other Sema family members had no effect on the IPN innervation pattern.
Third, the combination of sub-effective doses of both the Nrp1a and Sema3D MOs
had a significantly more potent effect on perturbing left habenular
innervation of the dorsal target than either MO alone, indicating that the two
MOs function synergistically. Finally, abnormal projections from left
habenular axons extending beyond the dorsal IPN were observed following
overexpression of Sema3D.
On the basis of these results, we propose that Sema3D serves as an
attractant to guide Nrp1a-expressing axons to innervate the dorsal IPN
(Fig. 7). Normally, during
development of the zebrafish brain, Sema3D is distributed dorsal to the IPN
and diverts growth cones of some left habenular neurons towards the dorsal
target (Fig. 7A). Upon loss of
either Nrp1a or Sema3D, all left habenular axons project ventrally, as do
nrp1a-deficient neurons of the left and right habenula
(Fig. 7B,C). Conversely, Sema3D
overproduction attracts left habenula neuronal processes toward the endogenous
sema3D- expressing domain dorsal to the IPN
(Fig. 7D). Surprisingly, these
abnormal processes did not project randomly in all directions as expected from
global overexpression of Sema3D. This finding may be explained by the timing
of nrp1a expression. Growth cones of habenular axons have already
reached the midbrain target by day 2, the time when nrp1a transcripts
are first detected asymmetrically in the habenulae. Left habenular neurons may
only respond to Sema3D on day 3, when Nrp1a levels become high enough to
influence growing axon tips just as they innervate the target IPN. Thus, when
habenular axons are extending caudally through the diencephalon, we presume
their growth cones are unable to respond to Sema3D distributed along the FR
route to the midbrain owing to the lack of receptor. The low frequency
(9%) of larvae showing aberrant projections that extend beyond the dorsal
IPN is likely to reflect variability in protein levels and distribution from
injection of sema3D mRNA at the 1- to 2-cell stage. A more direct
approach, such as expressing ectopic Sema3D in a spatially-restricted manner
in the zebrafish brain or in cultures of habenular explants, will confirm
whether Sema3D functions as an attractive cue in the context of dorsal IPN
innervation.
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) and utilize membraneassociated Sema5A receptors as sensors
of extrinsic proteoglycans that can either inhibit or attract their growth
cones (Kantor et al., 2004).
Disruption of either the diffusible signal Sema3F, or its receptor Nrp2,
through targeted gene inactivation leads to defasciculation of the FR
(Chen et al., 2000;
Giger et al., 2000;
Sahay et al., 2003),
suggesting that this ligand-receptor pair normally repels axons to keep them
from straying from the FR bundle as proposed from in vitro studies
(Funato et al., 2000). In our
experiments, however, MO-mediated depletion of Sema3Fa did not significantly
alter the FR axonal bundles of zebrafish larvae. This apparent difference
between vertebrate species might be due to the presence of duplicate Sema3F
genes in zebrafish. The combined reduction of Sema3Fa and Sema3Fb activities
will reveal whether they play redundant and conserved roles in maintaining the
integrity of the zebrafish FR.
Although progress has been made in understanding how left-right asymmetry
develops in the zebrafish limbic system, much remains unanswered concerning
the basis of functional specialization of mammalian brain hemispheres. So far,
there is little evidence to support extensive habenular asymmetry in mammals,
nor does the habenulointerpeduncular projection appear to differ between the
left and right sides of the brain (Y.-S.K. and M.E.H., unpublished). However,
some recent reports have identified L-R differences in gene expression
programs in the rodent cortex (Sun et al.,
2006; Sun et al.,
2005) and hippocampus (Moskal
et al., 2006), and in the size of white-matter fiber tracts
associated with language regions of the human brain
(Nucifora et al., 2005). Our
study suggests that the asymmetric distribution of axon-guidance cues could be
an important mechanism to establish patterns of connectivity in the developing
embryonic CNS that underlie functional specialization.
Supplementary material
Supplementary material for this article is available at
http://dev.biologists.org/cgi/content/full/134/5/857/DC1
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TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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