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First published online 16 October 2008
doi: 10.1242/dev.021899
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1 Department of Genetics, Case Western Reserve University School of Medicine,
10900 Euclid Avenue, Cleveland, OH 44106, USA.
2 Department of Pharmacology, Kyoto University, Yoshida-Konoé-cho, Sakyo,
Kyoto 606-8501, Japan.
* Author for correspondence (e-mail: cbb9{at}case.edu)
Accepted 24 September 2008
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SUMMARY |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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Key words: Canonical Wnt signaling, Activation, Mutation, Ventral patterning, Cell fate, Gli2, Gli3, Shh
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INTRODUCTION |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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).
Shh, one of the Hedgehog (Hh) family of proteins, is strongly expressed in the
notochord and later in the floor plate, and is able to mimic the ability of
the notochord in inducing different ventral spinal cord cell types. In
response to Shh signaling, neural progenitors activate or suppress the
expression of several homeobox and basic helix-loop-helix (bHLH) transcription
factors. The combinatorial expression of these transcription factors defines
the fate of the neural progenitor cells
(Briscoe et al., 2000).
Although Shh has been shown to be sufficient for the induction of distinct
ventral spinal cord neurons, recent studies have suggested an alternative
derepression mechanism whereby many neuronal cell types could be generated in
the absence of Shh signaling. For example, although most of the ventral cell
types are absent from Shh or Smo mutants because of the
ectopic production of Gli3 repressor, most of the ventral neurons are
generated in Shh;Gli3 and Smo;Gli3 double mutants
(Litingtung and Chiang, 2000;
Wijgerde et al., 2002).
Similarly, in embryos that lack all Gli transcription factors and cannot
respond to Hh signaling, many of the ventral neurons are also present
(Bai et al., 2004;
Lei et al., 2004). These
results suggest that perhaps the primary role of Hh signaling is to repress
excess Gli3 repressor in the ventral spinal cord so that progenitors can
respond to other signals. An additional role for Shh signaling is to organize
the formation of distinct progenitor domains, as different cell types intermix
in the absence of Shh signaling (Bai et
al., 2004; Fuccillo et al.,
2006).
In search of other signals that might influence the generation of ventral
neurons, we focused on the Wnt pathway, as several Wnts, their receptors and
inhibitors are expressed in the developing spinal cord
(Hoang et al., 1998;
Leimeister et al., 1998;
Parr et al., 1993). Wnts
signal through Frizzled and LRP factors, resulting in the stabilization of
β-catenin, which then interacts with TCF/LEF transcription factors to
control the expression of downstream target genes
(Logan and Nusse, 2004).
Previous studies have uncovered a prominent role for Wnt signaling in
proliferation in the spinal cord. For example, ectopic expression of
Wnt1 or stabilized β-catenin caused overproliferation in the
spinal cord, but did not cause patterning defects or ectopic expression of
dorsal neuronal markers (Chenn and Walsh,
2002; Megason and McMahon,
2002). Furthermore, when Wnt signaling was disrupted or
ectopically activated at E9.5 by Brn4-Cre (which is
expressed throughout the spinal cord), the neuronal progenitors were either
depleted or overproliferated (Zechner et
al., 2003). Recent chick electroporation studies suggest that Wnt
signaling might interact with Gli genes to regulate the expression of key
transcription factors in the spinal cord
(Alvarez-Medina et al., 2008;
Lei et al., 2006). However,
how Wnt signaling interacts with Shh signaling is a matter of controversy,
with one study showing that Wnt signaling is required for Gli-mediated
activation of Nkx2.2 (Lei et al.,
2006), whereas another study showed an antagonistic interaction
between Wnt and Shh signaling
(Alvarez-Medina et al., 2008).
Furthermore, it is unclear whether Wnt signaling normally functions in early
ventral progenitors at the time of neural tube closure to specify distinct
neural progenitors, in addition to its role in establishing domain boundaries
after neural tube closure as suggested by chick electroporation studies.
Here we use a genetic, inducible approach to perturb Wnt signaling in small domains of the mouse ventral spinal cord before and after the neural tube closes. We show that Wnt signaling activates downstream genes in a time-dependent manner, and that Wnt signaling regulates the ventral spinal cord cell fates in part through Gli3, but not Gli2. These data reveal a crucial role of Wnt signaling in regulating ventral cell fates during normal vertebrate development.
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MATERIALS AND METHODS |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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; Brault et al.,
2001; Harada et al.,
1999; Lu et al.,
2002; Maynard et al.,
2002; Mo et al.,
1997). Double heterozygous mutant mice were maintained on a CD1
background. Tamoxifen (Sigma T-5648) was dissolved in corn oil at 20 mg/ml and
was fed to pregnant females using a gavage feeding needle (FST, Foster City,
CA) to activate CreER expressed from the Gli1-CreER
allele.
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;
Bai and Joyner, 2001). RNA in
situ probes have been described (Platt et
al., 1997) with the exception of Axin2 (Open Biosystems,
clone 6827741). The primary antibodies used have been described
(Pierani et al., 1999;
Takebayashi et al., 2002),
except for mouse anti-Lim3, Msx1/2 (DSHB), N-cadherin, Mash1 (BD Biosciences);
rabbit anti-β-catenin (Sigma), Math1
(Helms and Johnson, 1998),
Gsh1/2, Foxd3, Lbx1 (Gross et al.,
2002), Pax2 (Zymed), Smad1/5/8 (Cell Signaling); and goat
anti-β-galactosidase (Biogenesis). Secondary antibodies were purchased
from Jackson ImmunoResearch or Molecular Probes. Nuclei were counterstained
with Hoechst 33258 (Molecular Probes) or with 0.005% Nuclear Fast Red
(Polyscientific).
Microscopy and statistical analysis
Pictures were taken with a Leica DMLB epifluorescence microscope fitted
with a SPOT camera (Genetics Imaging Facility, supported by NIH-NCRR,
RR-021228-01). Images were cropped and the brightness and contrast adjusted in
Adobe Photoshop. For quantification purposes, three cross-sections at the
forelimb level were examined from each embryo, and three embryos were used for
each time point. Histograms show the average number of labeled cells in the
section ± s.e.m. Student's t-test was used to calculate the
P-value. To quantify the distribution of ectopic Msx1/2+
or Pax7+ cells, ventral spinal cord was divided into five equal
domains and the number of ectopic cells within each domain was calculated.
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RESULTS |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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), in the developing spinal cord at E8.5 and E9.5.
lacZ-expressing cells were detected strongly in the mid/hindbrain
(data not shown) and in the dorsal neural hinges (between neural and
non-neural ectoderm) of the posterior hindbrain/anterior spinal cord where the
neural tube is open (Fig. 1A).
In the posterior regions of the embryo where the neural plate had not yet
closed, lacZ-expressing cells were detected throughout the neural
plate (Fig. 1C,D). In the
intermediate region where the neural tube had already closed,
lacZ-expressing cells were found both dorsally and ventrally in the
spinal cord (Fig. 1B). To
confirm that the pattern of reporter expression reflects endogenous Wnt
signaling, we examined the expression of Axin2, a known target of Wnt
signaling, using RNA in situ hybridization. We found a similar patterning of
Axin2 expression from anterior to posterior of the E8.5 embryo
(Fig. 1E-H). At E9.5,
Axin2 expression was detected throughout the posterior neural tube
(Fig. 1K), although the
expression became dorsally restricted in more-anterior levels
(Fig. 1I,J). These two lines of
evidence indicating that Wnt signaling is active in the ventral neural tube
led us to test whether Wnt signaling has a role in the determination of
ventral progenitor cell fates.
Stabilized β-catenin in the ventral spinal cord promotes dorsal and inhibits ventral cell fates
To address whether Wnt signaling specifies ventral spinal cord neural
progenitors, we created genetic mosaics of cells that express stabilized
β-catenin. In this approach, Tamoxifen (TM) was used to activate an ER
(estrogen receptor)-fused Cre recombinase expressed from the Gli1
locus (Gli1-CreER knock-in), to induce the recombination of two
conditional alleles: Ctnnb1tm1Mmt, which has two loxP
sites surrounding a β-catenin degradation signal in exon 3 and encodes
stabilized β-catenin after recombination
(Harada et al., 1999)
(hereafter referred to as the Ctnnb1gof allele); and a
Rosa26 reporter (R26R) that expresses β-galactosidase
upon recombination (Soriano,
1999). Since β-galactosidase and stabilized β-catenin
are expressed from two separate recombination events, they might not always
coexpress in the same cells (Balordi and
Fishell, 2007; Joyner and
Zervas, 2006; Zong et al.,
2005). Thus, we used β-galactosidase only to monitor the
overall extent of recombination, and not to identify cells that expressed
stabilized β-catenin.
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), was
not expressed ectopically (Fig.
2H,K). However, Mash1 (Ascl1), a marker for d3-d5 in the dorsal
spinal cord (Gross et al.,
2002) and for V2 progenitors (pV2) in the ventral spinal cord
(Parras et al., 2002)
(Fig. 2I), was ectopically
expressed in the ventral spinal cord (Fig.
2L, yellow bracket).
We next determined whether dorsal interneurons were produced as a result of
the switching of progenitor cell fates. In these experiments, we co-stained
sections with antibodies to Pax7 or Msx1/2, two dorsal progenitor markers that
were induced by stabilized β-catenin (see below), in order to identify
ventral progenitors that had switched their cell fates. We first examined the
expression of Foxd3, which marks post-mitotic dI2 dorsal neurons and pV1
progenitors (Dottori et al.,
2001) (Fig. 2N),
and of Lbx1, which marks dI4-6 interneurons
(Gross et al., 2002)
(Fig. 2O). We found a small
number of ectopic Foxd3+ cells
(Fig. 2R, asterisk, next to
green Pax7 staining) and Lbx1+ cells
(Fig. 2S, inset). The small
number of ectopic dorsal neurons suggests that other factors are needed in
addition to Wnt signaling for the generation of distinct dorsal neurons.
If stabilized β-catenin induces ventral cells to adopt dorsal fates, then a reduction in ventral cells expressing ventral fate markers would be predicted. We examined the expression of Nkx2.2 (a marker for pV3), Olig2 (a marker for pMN) and Nkx6.1 (a marker for pMN, pV2 and pV3), and found that Nkx2.2 (Fig. 2M), Olig2 (Fig. 2T) and Nkx6.1 (Fig. 2U) were all inhibited by the expression of stabilized β-catenin. In particular, Olig2 and Nkx6.1 were not expressed in cells that were Pax7+ (Fig. 2T,U, insets). These results therefore suggest that expression of stabilized β-catenin in the ventral spinal cord inhibits ventral progenitor cell fates and, at the same time, promotes different dorsal progenitor cell fates (summarized in Fig. 2G).
Wnt signaling activates the expression of different subsets of targets cell-autonomously and in a time-dependent manner
One possible mechanism by which Wnt signaling regulates different cell
fates is by activating different subsets of downstream targets in different
developmental stages. If this is the case, then we would expect that early Wnt
signaling in the ventral spinal cord induces one set of targets, whereas late
Wnt signaling induces another set of targets. Alternatively, a reduction in
the signaling strength in the ventral spinal cord might also contribute to the
activation of different target genes. To distinguish between these two
possibilities, we generated
Gli1-CreER;Ctnnb1gof;TCF/LEF-lacZ embryos and activated
Wnt signaling through stabilized β-catenin at different stages, using a
low dose of TM (50 mg/kg body weight). Since Wnt signaling should be equally
maximized, any differences in target gene expression should be due to the
activation of Wnt signaling at different stages. In control embryos, a few
β-galactosidase-positive cells were detected in the V2 progenitor region
of the ventral spinal cord at E10.5 (Fig.
3A,E, white brackets). When TM was given at E7.5 (12:00 h),
patches of progenitor cells expressing β-galactosidase were identified in
the ventral spinal cord. These cells also expressed Pax7 and Msx1/2
(Fig. 3B,F, see also insets),
suggesting a cell-autonomous activation of dorsal markers. Since these patches
of cells were located close to the floor plate, in the pV3 and pMN domains,
this result suggests that induction of stabilized β-catenin respecifies
the most ventral cells into dorsal cell fates. To quantify the distribution of
the ectopic cells, we divided the ventral spinal cord into five equal domains
that roughly correspond to the five progenitor domains
(Fig. 3I), and found ectopic
Pax7+ and Msx1/2+ cells distributed throughout these
five ventral domains (Fig.
3J,K). We then examined whether expression of stabilized
β-catenin at a later stage could activate these genes. We found that when
TM was given at late E8.5 (12:00 h), progenitors located in the most ventral
regions (domains 4 and 5) expressed Msx1/2
(Fig. 3G, inset), but not Pax7
(Fig. 3C, inset), suggesting a
partial respecification of dorsal cell fates. Indeed, quantification revealed
that Pax7+ ectopic cells rarely occupied domains 4 and 5, although
Pax7+ cells were found in domains 1-3
(Fig. 3J). By contrast,
Msx1/2+ cells were distributed almost evenly throughout the ventral
domains (Fig. 3K), similar to
when TM was injected at E7.5. Finally, when TM was given at E9 (09:00 h),
little, if any, ectopic expression of Msx1/2 or Pax7 was detected in the
ventral spinal cord (Fig.
3D,H).
To exclude the possibility that ectopic Pax7+ cells were not induced in embryos receiving TM injection at E8.5 because of a shorter exposure to Wnt signaling by the time of analysis at E10.5 (as compared with embryos receiving TM at E7.5), we let these embryos develop until E11.5. We found that, similar to when analyzed at E10.5, Msx1/2+ cells were found throughout the ventral spinal cord, whereas Pax7+ cells were detected mainly in domains 1-3 (see Fig. S1A-F in the supplementary material). These results suggest that differential activation of target genes is controlled by a time-dependent mechanism, rather than by the length of exposure to Wnt signaling.
In addition to Pax7, another dorsal marker, Gsh1/2 (Gsx1/2 - Mouse Genome
Informatics), which normally marks dI3-5 in the dorsal spinal cord
(Kriks et al., 2005), was
found to be induced in a similar time-dependent manner in the ventral spinal
cord (see Fig. S1G-J in the supplementary material). The observation that
stabilized β-catenin induces different molecular markers in the ventral
progenitors (TM7: Pax7, Gsh1/2 and Msx1/2; TM8: Msx1/2; TM9: no ectopic
induction), coupled with the reduction of Wnt signaling in the ventral spinal
cord during this period of time, raise the possibility that a gradual
reduction in Wnt signaling in the ventral spinal cord allows for the
activation of ventral-specific genes and the generation of distinct ventral
progenitors.
Stabilization of β-catenin in MN progenitors promotes the generation of V2 neurons
The genetic mosaics, although powerful, do not permit the tracing of fate
changes in a chosen population. To determine whether Wnt signaling is involved
in specifying different ventral neuronal cell fates in specific groups of
ventral progenitors, we used Olig1-Cre to induce recombination in
discrete progenitor groups (pMN and pV3) in the ventral spinal cord starting
from late E8 (Lu et al., 2002;
Wu et al., 2006;
Zhou and Anderson, 2002).
Compared with Gli1-CreER-mediated recombination, Olig1-Cre
is much stronger and can induce complete recombination of floxed alleles
within cells expressing Olig1 (Wu
et al., 2006), allowing quantitative analysis of changes in cell
fates. Furthermore, Olig1-Cre only induces a partial transformation
of cell fates, as Msx1/2, but not Pax7, was induced in pMN/pV3 domains (see
Fig. S2D-I in the supplementary material). The partially switched phenotype is
similar to that found when TM was applied at E8.5 to
Gli1-CreER;Ctnnb1gof embryos to stabilize β-catenin
(Fig. 3). We first examined the
expression of two transcription factors, Pax6 and Irx3, that respectively
define the dorsal limits of the pV3 and pMN domains. We found that the ventral
limit of the Pax6 expression domain was extended ventrally towards the floor
plate (Fig. 4A,E, arrowhead).
Similarly, the ventral limit of the Irx3 domain was extended ventrally in the
pMN domain (Fig. 4B,F, arrow)
and the Mash1 expression domain was also expanded
(Fig. 4C,G). As a result, there
was a drastic reduction in the number of Olig2+ pMNs [wild-type
(WT), 56.4±2.5 versus 8.1±1.6; P<0.01] and
Nkx2.2+ pV3 neurons (WT, 87±1.7 versus 36.7±3.6;
P<0.01) (Fig.
4D,H,M). The remaining pMNs did not form a tight cluster but were
instead scattered around in the ventral spinal cord, which is likely to
reflect disruption in the progenitor domains as a result of persistent Wnt
signaling in the ventral spinal cord.
If there was a change in progenitor cell fates, then we would expect
alterations in the number of post-mitotic neurons. In WT embryos, MN and V2
interneurons are generated from ventral progenitors expressing Nkx6.1. As
progenitor cells exit the cell cycle, Lim3 (Lhx3 - Mouse Genome Informatics)
is expressed in both differentiating MNs and V2 interneurons
(Thaler et al., 2002). When
β-catenin was stabilized using Olig1-Cre, we found a
significant reduction in the number of Isl+ (Isl1) MNs (WT,
269.9±10.1 versus 146.4±4.5; P<0.01) and a
significant increase in the number of Chx10+ (Vsx2) V2 interneurons
(WT, 38.4±1.8 versus 77.9±5.7; P<0.01)
(Fig. 4I,K,M). Consistent with
this, we also found a significant reduction in the number of Isl+
Lim3+ MNs (WT, 48±1.7 versus 21.1±2.7;
P<0.01) (Fig.
4J,L,M). Together, these results show that sustained Wnt signaling
in pMN inhibits the generation of MN while promoting V2 neurons.
Wnt signaling-mediated cell fate switching is not dependent on Gli2
Wnt signaling might act directly to specify cell fates, or it could
interact with the Hh signaling pathway, as both Wnt and Shh signaling are
active as early as E8.5 in the ventral neural tube. Indeed, a recent study
using the chick electroporation system suggests that Wnt signaling cooperates
with Gli2, the primary Gli activator, to regulate the transcriptional response
of Shh targets and cell fates (Lei et al.,
2006). To determine whether Wnt signaling-mediated cell fate
switching functions through Gli2, we removed endogenous Gli2
in embryos expressing stabilized β-catenin. Removal of Gli2
results in the loss of V3 neurons and in the appearance of MNs in the ventral
midline of the spinal cord (Fig.
5A,B) (Matise et al.,
1998). When MNs and V2 interneurons were counted in Olig1-Cre,
Ctnnb1gof;Gli2-/- embryos, we found a significant
reduction in the number of MNs (WT, 269.9±10 versus 155.8±13.2;
P<0.01) and a significant increase in the number of V2 neurons
(WT, 38.4±1.8 versus 67±8.2; P<0.01)
(Fig. 5D,K). However, compared
with Olig1-Cre, Ctnnb1gof embryos, the number of MNs
(P=0.53) or V2 interneurons (P=0.30) in Olig1-Cre,
Ctnnb1gof;Gli2-/- embryos was not significantly
different (Fig. 5K). These
results suggest that a drastic reduction in Shh signaling by removal of
Gli2 does not further alter the cell fate changes caused by
activation of Wnt signaling.
Wnt signaling promotes V2 and inhibits MN cell fate in part through the activation of Gli3
To determine whether β-catenin-mediated cell fate specification
involves activation of Gli3, we performed in situ hybridization. In
WT embryos at E10.5, Gli3 is expressed in a dorsal-to-ventral
decreasing gradient in the spinal cord
(Fig. 5E). When β-catenin
was stabilized in the ventral spinal cord with Olig1-Cre, we found
that the ventral expression domain of Gli3 was extended towards the
floor plate (Fig. 5F, red
arrowhead).
If Wnt signaling inhibits the ventral cell fate specification through transcriptional activation of Gli3, then removal of the endogenous Gli3 genes should rescue the MN defect phenotype caused by ectopic activation of Wnt signaling. Indeed, when Gli3 was removed, we found a significant increase in the number of Olig2+ pMNs (Olig1-Cre;Ctnnb1gof, 8.11±1.64; Olig1-Cre;Ctnnb1gof;Gli3-/-, 34.8±3.6; P<0.01) (Fig. 5I,J,M) and a recovery of Nkx6.1+ progenitors (see Fig. S2L-N in the supplementary material). However, the number of pMNs was still significantly lower than in the WT embryos (WT, 56.4±2.5; P<0.01) (Fig. 5M). We then examined whether removal of Gli3 increases the number of Nkx2.2+ pV3 in embryos expressing stabilized β-catenin. We found many cells expressing variable levels of Nkx2.2 (Fig. 5J). When only cells expressing high (similar to WT) levels of Nkx2.2 were counted, we found a slight, and not significant, increase in Nkx2.2+ cells (P=0.17). We also examined whether the number of post-mitotic neurons was changed. We found a significant decrease of Chx10+ V2 interneurons (Olig1-Cre;Ctnnb1gof, 77.9±5.7; Olig1-Cre;Ctnnb1gof;Gli3-/-, 55.9±5.4; P=0.013), and a slight increase of post-mitotic MNs (Olig1-Cre;Ctnnb1gof, 146.4±4.5; Olig1-Cre;Ctnnb1gof;Gli3-/-, 166.5±11.7; P=0.12) (Fig. 5G,H,L). This result suggests that Gli3 is only partially responsible for the Wnt-mediated repression of ventral cell fates.
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). Because expression of Olig1 starts at
E8.75, we examined whether the expression of β-catenin was affected
at E9.5. We found a drastic reduction in the level of β-catenin in both
pV3 (Fig. 6A,D, bracket) and
pMN (Fig. 6E, bracket) domains.
By E10.5, β-catenin was also clearly absent from ventral-lateral spinal
cord that is normally occupied by MNs and V3 cells
(Fig. 6F,I,J). Because
β-catenin interacts with N-cadherin to regulate cell-cell adhesion, we
investigated whether N-cadherin expression was affected. We found that the
overall expression of N-cadherin was not affected
(Fig. 6K,L), although in some
sections cells were found to occupy the spinal cord lumen
(Fig. 6I,J,L) and the floor
plate appeared to be less compact (Fig.
6H), suggesting that deletion of β-catenin does affect cell
adhesion at E10.5. To confirm that deletion of β-catenin does not affect
the production or reception of Shh at E9.5, a time when neural progenitors are
being specified, we examined the level of Shh protein
(Fig. 6B,C), the number of
floor plate cells expressing Shh (as estimated by mRNA in situ
hybridization) and the expression of the Shh targets Gli1 and
Ptch1 (see Fig. S3 in the supplementary material), and found no
significant differences between the β-catenin mutant and WT embryos. We next examined whether the generation of different cell types in the ventral spinal cord was affected at E10.5. We found a reduction in the ventral expression of Pax6 (Fig. 6M,P, bracket indicates the weak Pax6 expression domain) in β-catenin mutant embryos. This reduction in the ventral expression of Pax6 suggests a ventral-to-dorsal shift of the transcription codes in the ventral spinal cord, and predicts an expansion of ventral neurons. Indeed, we found a significant increase in the number of Nkx2.2+ V3 interneurons (WT, 87±1.7; mutant, 107.7±5.1; P<0.01) (Fig. 6O,R,V). Furthermore, there was a significant increase in the number of FoxA2+ cells, which include floor plate and some pV3 cells (WT, 24.2±0.5; mutant, 67.2±7.0; P<0.01) (Fig. 6O,R,V). The slight increase in floor plate cells is likely to be caused by changes in cell adhesion and is unlikely to affect neuronal specification as most of the ventral neurons have already been specified by E10.5 and, in addition, we did not detect any significant changes in the expression of Gli1 or Ptch1 (see Fig. S4 in the supplementary material). The numbers of pMNs and MNs in the β-catenin mutant and WT embryos were not significantly different (WT, 269.9±10.1; mutant, 263.9±15.7; P=0.75) (Fig. 6N,Q,V). One possibility is that the fate of pMN is partially fixed by the time β-catenin function is deleted. A second possibility is that the reduction in pMN is masked by an increase in cell proliferation, as we observed an increase in BrdU incorporation in the Olig1-Cre domain (Fig. 6V). Overall, there was no obvious change in the number of progenitors expressing Nkx6.1 (see Fig. S5A-D in the supplementary material). To exclude the possibility that dorsoventral patterning of the ventral spinal cord was affected, we examined the generation of other cell types that do not express Olig1-Cre. We found that the numbers of Chx10+ V2 interneurons and Evx1+ V0 interneurons were not affected (P=0.32 and P=0.75, respectively) (Fig. 6V).
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3 embryos)
(Fig. 6S). A similar change was
observed when TM was delivered at early E8.5 (09:00 h) (see Fig. S5 in the
supplementary material). Together, these results demonstrate that the
inhibition of canonical Wnt signaling in specific domains of the ventral
spinal cord promotes an expansion of ventral cell types. |
DISCUSSION |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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;
Dessaud et al., 2007). In this
scenario, the dorsal-most cell type, d1, is specified because these cells
receive the longest exposure to Wnt signaling (from E8.5 to E10.5), whereas
other cells adopt more-ventral cell fates because they receive shorter
exposure to Wnt signaling. However, extending the length of Wnt signaling does
not appear to alter the expression of dorsal markers. Lastly, it is possible
that different cell fates are specified depending on when Wnt signaling is
active. In this scenario, Wnt signaling is capable of activating different
genes at different time points, based on the changing competence of the cells.
Indeed, we found that early Wnt signaling (induced with TM at E7.5) activated
the expression of several dorsal markers, Pax7, Gsh1/2 and Msx1/2. By
contrast, Wnt signaling induced with TM at E8.5 could only induce the
expression of Msx1/2, and Wnt signaling induced subsequently did not activate
dorsal markers. Our results therefore strongly support the time-dependent
mechanism of Wnt signaling in the ventral spinal cord.
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70-90% of ectopic Msx1/2+ or Pax7+ cells
coexpressed TCF/LEF-lacZ (see Fig. S6C in the supplementary
material). However, this is likely to be an underestimate because the
TCF/LEF-lacZ transgenic reporter was not expressed in all E10.5
progenitors that expressed stabilized β-catenin (see Fig. S6B-B'' in
the supplementary material). The action of Wnt signaling on cell fate changes
is likely to be cell-autonomous. However, we cannot completely exclude
non-autonomous effects, particularly in light of the reduction in the Irx3
ventral expression domain, which lies outside of the Olig1-Cre
expression domain, in β-catenin mutant embryos (see Fig. S6D,E in the
supplementary material). Nevertheless, we did not observe upregulation of
phosphorylated Smad1/5/8 in embryos expressing stabilized β-catenin (see
Fig. S2J,K in the supplementary material), suggesting that BMP pathways were
not activated in response to stabilized β-catenin.
Although the removal of β-catenin using Olig1-Cre affects the
morphology of the floor plate at E10.5, the action of Wnt signaling on cell
type switching appears to be direct, based on the following observations.
First, there was no significant change in the level of Shh protein, the number
of Shh-expressing cells or in the response to Shh at E9.5, when cell fate is
being specified (see Fig. 6C;
see Fig. S3 in the supplementary material). Even at E10.5, when most of the
cells have been specified, no significant changes in the expression of
Gli2, Shh, Ptch1 or Gli1 were observed (see
Fig. 6G,H; see Fig. S4 in the
supplementary material), although the floor plate appeared to be less compact.
In fact, deletion of floor plate does not affect the generation of most
ventral neurons, except for V3 cells, as has been demonstrated in
Gli2 mutants (Ding et al.,
1998; Matise et al.,
1998). Lastly, activation of Wnt signaling in small patches of
cells using Gli1-CreER reveals that activation of Wnt
signaling directly affects cell fate (Fig.
3).
Wnt signaling has multiple roles in spinal cord development
Previous studies have suggested that Wnt signaling plays multiple roles in
neural development. For example, Wnt signaling controls the rostrocaudal
patterning of the motor column (Nordstrom
et al., 2006), the proliferation of neural progenitors
(Chenn and Walsh, 2002;
Megason and McMahon, 2002;
Zechner et al., 2003) and the
specification of dorsal spinal cord cell types, either directly or through
interactions with the BMP pathway or Olig3
(Chesnutt et al., 2004;
Ille et al., 2007;
Muroyama et al., 2002;
Zechner et al., 2007). Wnt
signaling also appears to prevent the expansion of Shh signaling into the
dorsal spinal cord, an effect that is mediated through the regulation of the
Gli3 gene (Alvarez-Medina et al.,
2008).
|
So if Wnt signaling promotes dorsal character, how can it be involved in
regulating distinct cell types in the ventral spinal cord? One likely
mechanism is through a combination of restricting the extent of Wnt signaling
and restricting the ability of Wnt signaling to regulate downstream targets in
the ventral spinal cord. The ventral-to-dorsal shift in Wnt signaling,
together with a restricted ability to regulate downstream targets, is likely
to create a permissive molecular environment that enables different ventral
cell fates to emerge. Such a release-of-inhibition mechanism has been
described in the development of other neural tissues. For example, the
attenuation of FGF signaling emanating from the posterior mesoderm is
necessary for the emergence of neuronal cell types in the ventral spinal cord
(Diez del Corral et al.,
2003). Similarly, Shh expression, which is initially detected in
the ventral hypothalamus, needs to be inhibited in those tissues in order for
different cell types to develop (Manning
et al., 2006). In all these cases, regulated inhibition of these
signaling molecules is required for the specification of normal cell
fates.
In addition to activating dorsal markers, Wnt signaling appears to interact
directly with Shh signaling through the regulation of Gli genes. We show that
removal of endogenous Gli2, which encodes the major Gli activator,
does not affect the Wnt-mediated switching of cell fates
(Fig. 5B). Furthermore, we
independently found that Wnt signaling activates the transcription of
Gli3, which encodes the primary transcriptional repressor of the Shh
signaling pathway. By activating the transcription of Gli3, the
extent of Shh signaling can be restricted. However, Gli3 is unlikely
to be the sole effector of Wnt signaling in the ventral spinal cord because
removal of endogenous Gli3 in embryos with stabilized β-catenin
only partially rescues the inhibitory effect of Wnt signaling on pV3 and pMN
(Fig. 5). Furthermore,
expression of Gli3 alone is not sufficient to activate the expression
of dorsal genes, such as Pax7 or Msx. A second likely effector of Wnt
signaling are the Msx genes, as these were ectopically induced in embryos with
stabilized β-catenin (Fig.
3) and have previously been shown to activate the expression of
dorsal spinal cord genes in response to BMP signaling
(Liu et al., 2004;
Timmer et al., 2002).
Therefore, Wnt signaling, through activating both dorsal genes and
Gli3, ensures that ventral genes are inhibited and dorsal genes are
activated, and that different ventral cell types emerge in coordination with
Shh signaling (Fig. 7).
Supplementary material
Supplementary material for this article is available at
http://dev.biologists.org/cgi/content/full/135/22/3687/DC1
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ACKNOWLEDGMENTS |
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REFERENCES |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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