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First published online 13 September 2006
doi: 10.1242/dev.02583
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Departments of Zoology and Anatomy and Neuroscience Training Program, University of Wisconsin, Madison, WI 53706, USA.
* Author for correspondence (e-mail: mchalloran{at}wisc.edu)
Accepted 11 August 2006
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SUMMARY |
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 TOP SUMMARY INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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TCF) reduces hindbrain cell
proliferation and leads to a disruption of migratory NCC markers. Moreover,
expression of TCF downregulates sema3d RNA expression.
Finally, Sema3d overexpression rescues reduced proliferation caused by
TCF expression, suggesting that Sema3d lies downstream of Wnt/TCF
signaling in the molecular pathway thought to control cell cycle in NCC
precursors.
Key words: Neural crest, Zebrafish, Semaphorin, TCF, Cell cycle, Cyclin
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INTRODUCTION |
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TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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). To begin migration, NCCs delaminate
from the neuroepithelium, which requires an EMT. During EMT, cells
downregulate epithelial cell adhesions in favor of adhesion to the
extracellular matrix and undergo changes in cell morphology that allow them to
migrate (Duband et al., 1995;
Hay, 1995). NCCs undergo cell
division before and throughout their migration and differentiation
(Kalcheim and Burstyn-Cohen,
2005). Precise regulation of the proliferation of NCCs and their
precursors is probably crucial for their development. Wnt signaling plays a
role in controlling the G1- to S-phase transition of trunk NCCs, and this is
thought to be required for the onset of NCC migration
(Burstyn-Cohen et al., 2004).
However, little is known about what other factors may control NCC
proliferation or the role of the cell cycle in subsequent NCC development.
We have investigated the role of a semaphorin, Sema3d, in hindbrain NCC
development in the zebrafish. Semaphorins constitute a large family of
signaling molecules originally identified as axon guidance cues
(Kolodkin, 1998). Semaphorins
also guide migrating cells (Tamagnone and
Comoglio, 2004). Class 3 semaphorins are secreted and bind to
heteromeric receptors containing members of the plexin and neuropilin protein
families (Yu and Kolodkin,
1999). Signaling through these receptors is thought to regulate
the cytoskeleton of axonal growth cones and migratory cells, in part, through
the activity of Rho GTPases (Tamagnone and
Comoglio, 2000; Liu and
Strittmatter, 2001; Pasterkamp
and Kolodkin, 2003; Negishi et
al., 2005).
Semaphorins have been implicated previously in the control of NCC
migration. Sema3a inhibits the migration of chick NCCs in vitro and is
expressed in regions bordering NCC migration pathways in vivo
(Eickholt et al., 1999).
Disruption of Sema3a or Sema3f signaling in vivo causes NCCs to invade
normally NCC-free zones, suggesting that these semaphorins act to inhibit NCCs
from straying outside their pathway
(Osborne et al., 2005).
Similarly, class 3 semaphorins are proposed to maintain appropriate separation
of hindbrain migratory NCC streams in zebrafish
(Yu and Moens, 2005). In other
contexts, semaphorins may also attract NCCs. In mice, Sema3c is expressed in
the cardiac outflow tract, a target to which NCCs fail to migrate in Sema3c
knockout mice (Brown et al.,
2001; Feiner et al.,
2001). Semaphorin receptors are also implicated in NCC migration.
When neuropilin 1 expression is inhibited in chick, NCCs destined to form
sympathetic neurons are unable to complete their migration
(Bron et al., 2004). A similar
phenotype is seen in neuropilin 1-null mice
(Kawasaki et al., 2002). Thus,
semaphorins and their receptors play an important role in the migration of
NCCs across species. Here, we show a different role for a semaphorin in
controlling proliferation of NCC precursors.
In zebrafish, Sema3d and neuropilins are expressed in subsets of cranial
NCCs prior to the onset of migration
(Halloran et al., 1999;
Yu et al., 2004), suggesting a
potential role in NCC development. We show that Sema3d loss of function leads
to a decrease in the number of migratory NCCs and a disruption in the
development of NCC derivatives. Furthermore, we unexpectedly found that Sema3d
knockdown leads to reduced proliferation of hindbrain neuroepithelial cells at
the time of NCC production. Cell proliferation in NCC precursors has been
linked to Wnt signaling (Burstyn-Cohen et
al., 2004). We also show that the inhibition of Wnt/TCF signaling
via expression of TCF leads to the inhibition of hindbrain cell
proliferation and migratory NCC markers. Moreover, sema3d expression
is eliminated by expression of TCF. Finally, overexpression of Sema3d
partially rescues the reduced cell proliferation, suggesting that Sema3d lies
downstream of Wnt/TCF signaling in this pathway.
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MATERIALS AND METHODS |
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TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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) embryos
were obtained from homozygote incrosses. For TCF inhibition studies,
Tg(hsp70:TCFgfp)
(Lewis et al., 2004) embryos
were obtained from hemizygous outcrosses to leopard strain. Double
transgenic embryos were obtained from Tg(hsp70:sema3dmyc)
homozygote crosses to Tg(hsp70:TCFgfp) hemizygotes
and screened by GFP fluoresence. Embryos were reared at 25-29.5°C in E3
embryo medium and staged according to Kimmel et al.
(Kimmel et al., 1995). Hours
or days post fertilization (hpf and dpf) were defined as time reared at
28.5°C. Heatinduction of transgenes was performed by transferring embryos
in 100 ml E3 in glass beakers from 28.5°C to 39.5°C for 1 hour.
Embryos were then returned to 28.5°C for recovery until BrdU treatment
and/or fixation.
Morpholino design and injection
Morpholino oligonucleotides were synthesized by Gene Tools (Corvalis, OR).
Lyophilized morpholinos were resuspended in sterile water at a concentration
of 2 mM. Morpholinos were further diluted in 1x Danieau solution
(Nasevicius and Ekker, 2000)
with 0.1% Phenol Red to the working concentration. Optimal doses, defined as
the highest dose that did not significantly increase mortality or cause overt
non-specific necrosis, were determined empirically. Approximately 1 nl was
injected into the yolks of embryos at the one- to four-cell stage. In some
cases, morpholinos conjugated to FITC were used. This tag did not affect the
efficacy of the morpholino (not shown).
Sema3d translation inhibition morpholino (3DMO,
5'-catgatggacgaggagatttctgca-3') and four-base mismatch control
morpholino
(5'-catcatgcacgaggagatatctcca-3')
were used at 100 or 250 µM (Liu et al.,
2004; Wolman et al.,
2004). Additionally, either of two Sema3d splice blocking
morpholinos was injected at 500 µM. These were designed to complement the
boundaries of the fourth intron/fifth exon (3DI4E5MO,
5'-cacattcagtctgcagcaagagaaa-3') and fourth exon/fourth intron
(3DE4I4MO, 5'-ctgactgatacttacaagagggttt-3'). In some experiments,
we also used a random sequence control morpholino
(5'-cctcttacctcagttacaatttata-3') at 500 µM. Sema3d splice
morpholinos were tested by RT-PCR on total RNA isolated from embryos with
Trizol (Invitrogen) using the following primers: RT, 5'-tgg aac tgg tag
tgg tga ac-3'; forward, 5'-cca gac aac atc aat aaa cac
ccc-3'; reverse, 5'-ttg ccc agg aaa tca gac gc-3'.
Sequencing of individual, gel-purified bands was performed by the
UW-Biotechnology Center (Madison, WI). Sequence analysis was conducted using
MacVector (Accelrys, San Diego, CA).
In situ hybridization
In situ hybridization was performed at 67°C with digoxigenin or
FITC-labeled riboprobes as in Halloran et al.
(Halloran et al., 1999).
Digoxigenin or FITC was localized immunohistochemically with an antibody
conjugated to alkaline phosphatase (Roche, Indianapolis, IN) and with NBT/BCIP
as a substrate.
crestin and dlx2 double-labeling experiments were
performed according to Jowett (Jowett,
1999). Quantification was performed by outlining the rhombomere 4
migratory stream in images collected by epifluoresence and automated
calculation of the integrated area by Metamorph (Universal Imaging, Dowington,
PA).
Phosphohistone-H3 and BrdU labeling
Phosphorylated histone H3 was recognized by a rabbit polyclonal antibody
(Upstate Bio, NY) and detected with the Vector ABC kit (Vector Labs, CA) or
Alexa 568 secondary antibodies. PH3-positive nuclei were counted by eye on a
Nikon TE3000 inverted microscope at 600x magnification. Nuclei were
counted in rhombomeres 3, 4 and 5 throughout the entire dorsal ventral extent
of the neuroepithelium.
S-phase nuclei were identified by 5-bromo-2-deoxyuridine (BrdU)
incorporation as described (Shepard et
al., 2004). Immunohistochemistry for BrdU (mouse anti-BrdU, Roche,
Indianapolis, IN) was performed using Alexa 488- or Alexa 568-conjugated
secondary antibodies (Molecular Probes, Eugene, OR). Embryos were flat-mounted
dorsal side towards the coverslip in an anti-fade solution
(Hjorth and Key, 2001). Images
were collected every 1 µm to a depth of 40 µm from the dorsal surface
with a BioRad MRC 1024 laser-scanning confocal microscope. Experimental and
control embryos were always imaged during the same session using the same
settings on the microscope and software. Nuclei were counted in rhombomeres 3,
4 and 5 on one side of the neural tube in a single optical plane at the level
of the dorsal otocyst.
Alcian blue
Cartilage was labeled with 0.1% (w/v) Alcian Blue (Sigma) essentially as
described (Schilling et al.,
1996), except that the dilution buffer consisted of 0.37% HCl and
70% ethanol, and trypsinization was not performed. Lower jaws were dissected
and flat-mounted.
FITC-uncaging
One cell stage embryos were injected with 2% DMNB-caged FITC-dextran
(10x103 Mr, Molecular Probes, Eugene,
OR). At 15 hpf, embryos were dechorionated, arrayed in depression wells, and
bathed in E3. The fluorophore was uncaged via illumination at 360 nm with a
60x dipping objective. Exposure for 1 second through a pinhole aperture
was controlled by an automated shutter. Embryos were fixed 2 hours later,
counter-stained with 0.2% TOPRO3 (Molecular Probes, Eugene, OR), and flat
mounted for confocal imaging. The number of uncaged cells adjacent to the
neuroepithelium was quantified.
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RESULTS |
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TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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).
Subsequently, NCCs also arise from the neuroepithelium proper (J.D.B. and
M.C.H., unpublished). NCCs begin migration around 14-15 hpf and segregate into
three distinct streams lateral to rhombomeres 2, 4 and 6. We have reported
previously that sema3d is expressed in rhombomeres 3, 4 and 5, and in
migratory NCCs (Halloran et al.,
1999). A more detailed analysis of sema3d expression
confirms this initial expression pattern and reveals additional expression in
other premigratory NCCs. As early as 11-12 hpf, sema3d expression is
initiated in the hindbrain and premigratory NCCs (not shown). By 15 hpf,
sema3d is expressed strongly in rhombomeres 3, 4 and 5 and in
rhombomere 2 (Fig. 1A).
Transverse sections through rhomobomere 4 at this stage reveal that expression
is restricted to the dorsal neuroepithelium
(Fig. 1B). Expression is also
apparent in premigratory and early migratory NCCs adjacent to rhombomere 4
(Fig. 1A,B). Despite this
initial restriction, sema3d is eventually expressed in all three
migratory streams, i.e. adjacent to rhombomeres 2, 4 and 6
(Halloran et al., 1999).
Ultimately, sema3d is expressed in the mandibular, hyoid and gill
pharyngeal arches (Halloran et al.,
1999) (Fig. 1C).
Thus, sema3d is expressed in a dynamic pattern during premigratory
and migratory NCC stages, suggesting that it may play a role in NCC
development.
Sema3d knockdown causes abnormalities in a subset of NCC derivatives
In order to investigate the role of Sema3d in NCC development, we examined
the effects of Sema3d knockdown on NCC derivatives in the head. We injected
newly fertilized embryos with a Sema3d translation blocking morpholino (3DMO)
(Liu et al., 2004;
Wolman et al., 2004), or one
of two control morpholinos (CONMO): a random sequence control morpholino or
one containing four mispaired bases relative to 3DMO. To control for potential
non-specific effects of the morpholino, we also used two Sema3d spliceblocking
morpholinos (3DI4E5MO and 3DE4I4MO). RT-PCR and sequencing of Sema3d cDNA from
morpholino injected embryos showed that 3DI4E5MO caused an 118 nucleotide
in-frame deletion corresponding to nucleotides 656-775 of Sema3d (GenBank
Accession Number, NM_131048, Fig.
1J). This deletion removed a region of the Sema domain, including
a predicted N-glycosylation site. 3DE4I4MO caused a small variable deletion
(15-20 nucleotides within the Sema domain)
(Fig. 1J, deletion begins at
nucleotide 656 and has a variable 3' end). Embryos in this and
subsequent experiments were stage-matched to correct for delay caused by
morpholino injection.
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Sema3d knockdown does not alter NCC induction or hindbrain patterning
To understand the function of Sema3d and determine the stage of NCC
development at which it is required, we analyzed each step of NCC development.
To test whether defects in NCC derivatives were due to a failure of initial
NCC induction, we analyzed markers of premigratory NCCs. Prior to the onset of
migration, NCCs are found in two bands lateral to the neuroepithelium. In
addition, NCCs arise from a region overlying and within the neuroepithelium.
We found no difference in the expression of two premigratory NCC markers,
crestin (Rubinstein et al.,
2000; Luo et al.,
2001) and snail1b (previously snail2)
(Thisse et al., 1995), in
these regions between 3DMO and CONMO-injected embryos at 13 hpf
(Fig. 1K,L and not shown). We
also examined premigratory NCC markers at later stages of development. At 17
hpf we saw no reduction in foxd3
(Odenthal and Nusslein-Volhard,
1998; Kelsh et al.,
2000), sox9a/sox9b
(Chiang et al., 2001),
sox10 (Dutton et al.,
2001) or snail1b expression (not shown). Because NCCs are
formed from dorsal ectoderm, the absence of changes in the expression of
premigratory NCC markers suggests that Sema3d knockdown does not alter
dorsoventral patterning in the hindbrain. In addition, we examined the
anteroposterior patterning of the hindbrain because different numbers of NCCs
are generated from different rhombomeres
(Lumsden et al., 1991). Thus,
anteroposterior fate transformations could conceivably alter the number of
migratory NCCs and NCC derivatives. We labeled 3DMO and CONMO-injected embryos
at 17 hpf for hoxb1a, hoxb2a, hoxb3a or hoxa2b
(Prince et al., 1998), or for
krox20 (Oxtoby and Jowett,
1993), each of which is expressed with specific anteroposterior
boundaries. We did not detect differences in the placement, size or
compartmentalization of rhombomeres between 3DMO and CONMO-injected embryos
(Fig. 1M,N; not shown).
Collectively, these data show that the defects in NCC derivatives caused by
Sema3d knockdown are not due to large scale changes in NCC induction or
hindbrain patterning.
Sema3d does not affect the NCC EMT
Following their induction, NCCs undergo an EMT to begin migration;
inhibition of EMT could lead to defects in NCC derivatives. In order to test
whether Sema3d is required for EMT, we counted the number of NCCs that
underwent the EMT during a 2-hour time period in Sema3d knockdown embryos. We
co-injected embryos with either 3DMO or CONMO and caged-FITC dextran at the
one-cell stage. To label a subset of NCC precursors in the neuroepithelium, we
photo-uncaged the fluorophore in a small region of rhombomeres 4 and 6 at 15
hpf. Embryos were fixed 2 hours later, counterstained with TOPRO3 to label all
nuclei, and imaged on a confocal microscope
(Fig. 2A,B). We found no
difference in the number of FITC-labeled migratory NCCs adjacent to
rhombomeres 4 or 6 between CONMO and 3DMO-injected embryos
(Table 1) (rhombomere 4,
P=0.20; rhombomere 6, P=0.39; t-test). These data
suggest that the EMT of NCCs from the hindbrain neuroepithelium at 15-17 hpf
is not dependent on Sema3d.
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). Wild-type and CONMO-injected embryos expressed
crestin normally in the three migratory streams of hindbrain NCCs
(Fig. 2C; not shown). By
contrast, 3DMO-injected embryos showed a strong reduction in crestin
labeling (Fig. 2D). 3DE4I4MO
and 3DI4E5MO-injected embryos also showed reduced crestin expression
in hindbrain NCCs (Fig. 2E; not
shown). We counted the number of embryos showing reduced crestin
labeling. We found that 13% and 17% of uninjected and CONMO-injected embryos,
respectively, showed a reduction; whereas, 72%, 68% and 56% of 3DMO, 3DI4E5MO
and 3DE4I4MO-injected embryos, respectively, showed a reduction. The
reductions in Sema3d knockdown embryos were statistically significant compared
to controls (P<10-7 for all comparisons,
z-test, n=272 uninjected, n=214 CONMO,
n=118 3DMO, n=122 3DI4E5MO, n=55 3DE4I4MO).
Dlx2 is expressed in NCCs migrating to the pharyngeal arches.
Following Sema3d knockdown by 3DMO or 3DI4E5MO, dlx2 expression was
also reduced, although not as severely as crestin
(Fig. 2C-E). To quantify the
reduction, we used double-fluorescent in situ hybridization to label
crestin and dlx2 in the same embryos. In whole mounts and
sections of wild-type embryos, we found that the expression regions of
dlx2 and crestin largely overlap (not shown). We measured
the area of labeling of both genes in the rhombomere 4 migratory stream. We
found a significant reduction in the area of labeling with both genes in
3DMO-injected embryos relative to CONMO-injected
(Fig. 2F). The area of
crestin expression was reduced by 27%, and the area of dlx2
expression was reduced by 23%. This suggests that 3DMO-injected embryos have
fewer migratory NCCs or that NCCs are less dispersed compared with
CONMO-injected embryos. Nevertheless, the intensity of crestin
labeling was more drastically reduced than that of dlx2, suggesting
that Sema3d knockdown may affect the expression of crestin in
addition to affecting the migration of NCCs.
Sema3d knockdown reduces cell proliferation in the hindbrain
Because the gross pattern of NCC migration was intact in Sema3d knockdown
embryos, we explored an alternative mechanism for the defects in migratory
NCCs and NCC derivatives described above. NCCs undergo extensive proliferation
before and after migration. Furthermore, progression from the G1 to S phase of
the cell cycle is required for the onset of migration in chicken trunk NCCs
(Burstyn-Cohen and Kalcheim,
2002; Burstyn-Cohen et al.,
2004). Although semaphorins have not been implicated in cell cycle
regulation, we analyzed the effect of Sema3d knockdown on the numbers of
neuroepithelial cells in G2/M phase or S phase by immunolabeling for PH3 and
incorporated BrdU, respectively. We found a reduction in the number of
proliferating hindbrain neuroepithelial cells at 17 hpf in 3DMO-injected
embryos compared with CONMO-injected embryos
(Fig. 3A-D). The number of
BrdU-positive nuclei in the dorsal neuroepithelial regions that strongly
expresses sema3d, i.e. rhombomeres 3, 4 and 5, was significantly
reduced in 3DMO (27% reduction, P<10-8) and
3DI4E5MO-injected embryos (18% reduction, P<10-7) when
compared with CONMO (Fig. 3E).
Likewise, the number of PH3-positive nuclei in the same region was also
significantly reduced in 3DMO (29% reduction, P<10-7)
and 3DI4E5MO-injected embryos (24% reduction, P<10-4)
compared with CONMO-injected embryos (Fig.
3F). Thus, Sema3d knockdown leads to a reduction in the
proliferation of NCC precursors.
In order to address the temporal and spatial specificity of the reduction in cell proliferation, we analyzed PH3 expression at other times and in other tissues of 3DMO and CONMO-injected embryos. As described above, we found that PH3 labeling was reduced in the hindbrain at 18 hpf (Table 2). By contrast, at a time before the onset of Sema3d expression (10 hpf), the number of PH3 labeled nuclei in the future neuroepithelium was unaffected by 3DMO injection (Table 2). Similarly, when we counted PH3 labeled nuclei in the hindbrain at later times of development (24 and 36 hpf), we did not find a difference between 3DMO and CONMO-injected embryos (Table 2). Furthermore, PH3 labeling in other regions of the embryo where Sema3d is not expressed, e.g. the eye, was not affected. Interestingly, in two regions that express Sema3d, the spinal cord and pharyngeal arches, Sema3d knockdown increased the number of PH3-positive nuclei (Table 2). Collectively, these data suggest that Sema3d regulates cell proliferation in a specific spatiotemporal pattern and that hindbrain neuroepithelial cell proliferation is selectively reduced during the time of NCC production.
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12 hpf) is about 4-5 hours
(Kimmel et al., 1994). As the
inhibition of Sema3d protein by morpholino injection is constitutive, the
analysis of PH3 and BrdU at 17 hpf in Sema3d knockdown embryos reflects the
cumulative effects of more than one round of cell cycle. To discern which
phase of the cell cycle is affected, we examined the expression of several
cyclins and cyclin-dependent kinase inhibitor proteins (KIPs). Cyclin D1
transcript and protein levels increase during the G1 phase of the cell cycle.
In the above studies, a low concentration (100 µM) of 3DMO was sufficient
to decrease cell proliferation (Fig.
3) (Table 2). At
this dose, we did not detect differences in cyclin D1 transcript
levels. However, when we injected the same morpholino at a higher
concentration (250 µM), the expression of cyclin D1 was increased
in 3DMO-injected embryos relative to CONMO
(Fig. 4A,B). Similarly,
3DI4E5MO injection increased cyclin D1 expression relative to
CONMO-injected and uninjected embryos (Fig.
4C). We next examined two cyclins expressed in the G2 phase of the
cell cycle, cyclin A2 and cyclin B1. Both cyclin A2
and cyclin B1 were decreased in 3DMO and 3DI4E5MO-injected embryos
relative to controls (Fig.
4D-F; not shown). Cyclin E2 mRNA, another G1 cyclin, was not
affected by Sema3d knockdown (not shown). Finally, we examined the expression
of two kinase inhibitor proteins, p27kip1 (cdkn1b -
Zebrafish Information Network) and p57kip2 (cdkn1c -
Zebrafish Information Network), which are expressed in G1 and direct cells
toward cell cycle exit (G0). Notably, both p27kip1 and
p57kip2 were increased in rhombomere 4 in 3DMO-injected embryos
relative to CONMO-injected embryos (Fig.
4G-I; not shown). Collectively, these data suggest that Sema3d
knockdown causes G1/G0 cell cycle arrest.
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Sema3d overexpression rescues aspects of Sema3d knockdown
We investigated whether Sema3d overexpression could rescue the NCC and
proliferation defects caused by Sema3d knockdown. We overexpressed Sema3d
using a stable transgenic line containing myc-tagged sema3d
(Sema3dmyc) controlled by the hsp70 promoter
(Liu et al., 2004;
Sakai and Halloran, 2006).
First, we asked whether Sema3d overexpression affected cyclin D1
expression. We overexpressed Sema3dmyc by heat-shocking
Sema3dmyc transgenic embryos for 1 hour at 14 hpf and analyzed
cyclin D1 transcript levels at 17 hpf. We found that heat-shock
induced overexpression of Sema3dmyc decreased cyclin D1
expression relative to non-heat-shocked Sema3dmyc transgenic and
heat-shock wild-type controls (see Fig. S2A,B in the supplementary material
and not shown). Furthermore, Sema3dmyc overexpression restored
normal cyclin D1 levels in 3DI4E5MO-injected transgenic embryos (see
Fig. S2C,D in the supplementary material), whereas heat-shock alone in
wild-type embryos did not (see Fig. S2E,F in the supplementary material).
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Finally, we asked whether Sema3d overexpression could rescue defects in crestin expression or NCC derivatives. We overexpressed Sema3dmyc by heat-shocking transgenic embryos for 1 hour at 14 hpf and analyzed crestin at 18 hpf. Sema3dmyc overexpression alone did not change crestin expression and failed to rescue the reduction in crestin following Sema3d knockdown by 3DI4E5MO (not shown). Moreover, Sema3dmyc overexpression induced by heat-shock for 1 hour at 14 hpf or for 1 hour at 14, 24, 36, 48, 60, 72 and 84 hpf, did not cause aberrant cartilage or pigment phenotypes at 5 dpf and did not rescue the cartilage or pigment phenotypes produced by 3DI4E5MO injection (not shown).
Sema3d overexpression rescues decreased proliferation caused by TCF inhibition
Because cell cycle was disrupted by Sema3d knockdown, we examined the
possibility that Sema3d is in the molecular pathway thought to control cell
cycle in NCCs. Canonical Wnt signaling, which activates TCF-dependent
transcription, is crucial for the G1/S transition in NCCs
(Burstyn-Cohen et al., 2004)
as in other systems (Tetsu and McCormick,
1999). Therefore, we asked whether this is also true for hindbrain
NCCs in zebrafish embryos. We employed a transgenic line containing a
dominant-repressor form of TCF (TCFgfp) driven by the
hsp70 promoter (Lewis et al.,
2004). Using this line, Lewis et al.
(Lewis et al., 2004) found
that the induction of TCFgfp before the six-somite stage (12
hpf) leads to a failure of NCC specification. Therefore, we activated the
transgene after this period. Induction of TCFgfp by heat
shock for 1 hour at 14 hpf resulted in a significant reduction in the number
of BrdU-labeled nuclei at 17 hpf (Fig.
5A,B,J, 43% reduction, P<10-13,
t-test). As expected, TCFgfp expression also
reduced crestin expression (Fig.
5C,D) and eliminated cyclin D1
(Fig. 5E,F). Notably,
expression of TCFgfp resulted in the elimination of
sema3d expression (Fig.
5G,H). Analysis of the genomic sequence revealed at least three
potential TCF-binding sites in the 5' sequence proximal to the
sema3d-coding region (not shown), suggesting the potential for direct
transcriptional regulation by TCF. Thus, we tested whether
Sema3dmyc overexpression could rescue the TCFgfp
phenotype. We crossed Sema3dmyc to TCFgfp fish to
produce double transgenic embryos. We heat induced expression of both
transgenes and analyzed BrdU incorporation and crestin expression.
Sema3dmyc overexpression significantly increased the number of
BrdU-labeled nuclei in TCFgfp-expressing embryos
(Fig. 5I,J, 40% increase,
P<10-4, t-test). crestin expression
was not restored by overexpression of Sema3dmyc in
TCFgfp expressing embryos (not shown). These data suggest
that Sema3d acts downstream of TCF and upstream of the cell cycle but in
parallel with other Wnt/TCF downstream factors necessary for NCC
development.
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|
DISCUSSION |
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TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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). Although
Sema3d is a secreted protein, there is evidence that class 3 semaphorins
associate with the extracellular matrix and neuropilins on the surface of
cells secreting them (De Wit et al.,
2005). Thus, Sema3d could act via autocrine or paracrine signaling
on NCCs or their precursors. We found that knockdown of Sema3d caused a
reduction in migratory NCC markers and defects in a subset of NCC derivatives
(Figs 1,
2). These effects occurred in
the absence of effects on premigratory NCCs or patterning of the hindbrain
neuroepithelium (Fig. 1).
Sema3d knockdown also inhibited cell proliferation in the hindbrain
(Fig. 3). A reduction in
proliferation of NCC precursors alone could cause reduced numbers of migratory
cells and subsequent defects in NCC derivatives. In addition, because cell
cycle has been linked to the NCC EMT, it is also possible that Sema3d could
affect the EMT. However, our results suggest that Sema3d knockdown does not
negatively regulate the NCC EMT. In our photo-uncaging experiments, we
examined the number of NCCs undergoing the EMT during a period less than the
length of one cell cycle. This allowed us to minimize the contribution of
differences in cell number caused by cell proliferation changes and to
emphasize potential differences in cell motility. Thus, we were able to test
the EMT largely independently of changes in cell cycle. Because we did not
exhaustively test all times during NCC production or all regions of the
hindbrain, we cannot rule out the possibility that Sema3d regulates the EMT.
However, taken together our results are consistent with a mechanism in which
the primary role of Sema3d is to regulate the cell cycle of NCCs with the
potential to affect the NCC EMT.
Interestingly, a separate class of ligands, vascular endothelial growth
factors (VEGFs), can bind to the semaphorin receptor neuropilin, and are known
to regulate cell proliferation and migration in tissues with invasive
migratory behavior similar to NCCs, e.g. endothelial cells and carcinomas
(Ferrara et al., 2003;
Tammela et al., 2005). There
is evidence that VEGFs compete with class 3 semaphorins for neuropilin binding
(Miao et al., 1999;
Bagnard et al., 2001).
Furthermore, zebrafish VEGF165 is expressed by NCCs
(Yu et al., 2004), which
suggests that this competition may be relevant to NCC proliferation and
EMT.
Previous work has shown that Wnt/TCF signaling controls cell cycle in NCCs
as well as the induction and EMT of NCCs
(Chang and Hemmati-Brivanlou,
1998; LaBonne and
Bronner-Fraser, 1998;
Burstyn-Cohen et al., 2004;
Lewis et al., 2004). We show
that sema3d expression can be regulated by TCF and that
Sema3dmyc overexpression can rescue cell cycle inhibition caused by
the inhibition of Wnt/TCF (Fig.
5). The simplest model for these data is a linear relationship
whereby Sema3d is an effector of the Wnt/TCF pathway
(Fig. 6A). However, although
Sema3dmyc rescued the reduced BrdU incorporation caused by
TCF, it did not rescue the reduction caused by Sema3d knockdown (see
Fig. S2A in the supplementary material). Moreover, TCF inhibition leads to
decreases in cyclin D1, while Sema3d knockdown leads to increases in
cyclin D1 (Figs 4,
5). These findings argue
against a direct linear relationship. Thus, we propose an alternative model
that could explain our data (Fig.
6B). According to this model, Wnt/TCF and Sema3d interact in a
more complex feedback loop. Wnt/TCF is the primary regulator of the molecular
machinery controlling the G1/S transition, Sema3d has the capacity to modulate
this pathway, and Wnt/TCF can feedback onto Sema3d. We propose that this
feedback is both positive, through the activation of sema3d
transcription, and negative, through the activation of an unknown inhibitor of
Sema3d. Thus, TCF repression would inhibit both Sema3d and the unknown
inhibitor. In this scenario, we expect Sema3d to play a modulatory role on the
timing of the cell cycle, and its activity and/or expression could be required
in a specific temporal or spatial pattern, perhaps regulated by Wnt/TCF. This
model suggests several predictions that are supported by our data. First, the
expression of the dominant repressor, TCF, would downregulate Sema3d.
Second, Sema3d overexpression would rescue TCF because of the
downregulation of the inhibitor. Finally, when TCF is not expressed,
Sema3d overexpression would not rescue Sema3d knockdown because of the
presence of the inhibitor.
|
). The two
pathways also share the ability to affect both the cell cycle and cell
adhesions, and thus there are multiple points where the pathways might
converge. For example, integrins are known to be important for NCC EMT and
migration (Perris and Perissinotto,
2000). Two semaphorins, Sema3a and Sema4d, have been shown to
modulate integrin signaling (Serini et
al., 2003; Barberis et al.,
2004; Toyofuku et al.,
2005). Furthermore, integrin-linked kinase is able to regulate
Cyclin D1 protein and mRNA through GSK3ß in cancers and mammary
epithelial cells (D'Amico et al.,
2000; Tan et al.,
2001). Cells in culture require attachment to the substratum in
order to progress from G1 to S phase of the cell cycle
(Aplin et al., 1999;
Danen and Yamada, 2001). Thus,
loss of attachment of NCCs to the extracellular matrix and the resulting loss
of integrin activation could result in aberrant cell cycle. Interestingly, we
found that membrane blebbing, which can be regulated by attachment to the
extracellular matrix (Sugrue and Hay,
1981), is increased following Sema3d knockdown (J.D.B. and M.C.H.,
unpublished).
Exciting recent studies show that the cell cycle and cell migration are
intimately connected. In addition to its role in cell cycle control, p27(KIP1)
inhibits the activation of the small GTPase RhoA in cultured mammalian cells
(Besson et al., 2004). The Rho
GTPases are known regulators of cytoskeletal dynamics and cell motility, and
in fact RhoB is required for the NCC EMT
(Liu and Jessell, 1998).
Moreover, RhoGTPases are known to regulate multiple steps in the G1/S
transition including Cyclin D1 protein accumulation
(Tatsuno et al., 2000;
Welsh et al., 2001). We found
that p27kip1 was upregulated by Sema3d knockdown, and there is
considerable evidence that RhoGTPases are modulated by semaphorin signaling
(Liu and Strittmatter, 2001;
Pasterkamp and Kolodkin, 2003;
Negishi et al., 2005).
However, a specific role for Sema3d in modulating Rho GTPases remains to be
tested.
Finally, our data do not rule out the possibility that Sema3d could
regulate NCC migration independently of its effects on cell cycle. Semaphorins
are well known for their role in directing migration of various cell types and
may also regulate EMT and cell scattering. For example, semaphorins are
upregulated in metastatic versus nonmetastatic carcinoma cells
(Christensen et al., 1998;
Martin-Satue and Blanco, 1999;
Brambilla et al., 2000). In
addition, the plexin family of semaphorin receptors has significant homology
to Met, the proto-oncogene and receptor for hepatocyte growth factor/scatter
factor (Trusolino and Comoglio,
2002). Hepatocyte growth factor (HGF) can promote
autocrine/paracrine-mediated cell dispersal
(Stoker et al., 1987;
Stella and Comoglio, 1999).
Moreover, plexins can directly interact with Met
(Giordano et al., 2002),
suggesting crosstalk between these signaling pathways.
Supplementary material
Supplementary material for this article is available at
http://dev.biologists.org/cgi/content/full/133/20/3983/DC1
|
ACKNOWLEDGMENTS |
|---|
TCFgfp) transgenic fish, and P.
Henion, V. Prince and D. Raible for cDNAs. We thank the Zebrafish Information
Resource Center for providing cDNAs and fish lines. This research was
supported by NINDS grant NS42228 (M.C.H.) and NIGMS NRSA T32 GM07507 (J.D.B.).
The NSF supported acquisition of the confocal microscope (NSF 9724515 to James
Pawley, Department of Zoology, University of Wisconsin). |
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