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First published online 3 May 2006
doi: 10.1242/dev.02387
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1 National Institute for Medical Research, Division of Developmental Biology,
The Ridgeway, Mill Hill, London NW7 1AA, UK.
2 Institut de Génétique et Biologie Moléculaire et
Cellulaire, CNRS/INSERM/ULP, BP 163, 67404 Illkirch cedex, CU de Strasbourg,
France.
3 UMR 7009 CNRS, Université de Paris VI, Observatoire
Océanologique de Villefranche sur Mer, 06230 Villefranche-sur-Mer,
France.
Author for correspondence (e-mail:
lepage{at}obs-vlfr.fr)
Accepted 31 March 2006
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SUMMARY |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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Key words: Endoderm, Zebrafish, FGF, BMP, MAP kinase, Mesoderm, Casanova, Bon, ERK
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INTRODUCTION |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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; Warga and
Nusslein-Volhard, 1999). The endodermal progenitors arise from the
first four rows of marginal cells, while mesodermal precursors arise from the
entire marginal region (Kikuchi et al.,
2004). Fate-mapping experiments have shown that when single cells
located near the margin are labelled at the late blastula stage, their progeny
frequently populate both germ layers
(Warga and Nusslein-Volhard,
1999). Therefore, in the most vegetal rows of cells, mesodermal
and endodermal fates are intermingled and both germ layers share common
mesendodermal precursors. The molecular mechanisms that allow segregation of
these two germ layers are poorly understood.
In zebrafish, as in other vertebrates, signalling by secreted TGFß
factors of the Nodal family is crucial for the formation of the mesoderm and
endoderm (Schier, 2003). The
nodal-related genes cyclops and squint are
expressed in the first two rows of cells and are potent inducers of endoderm
and mesoderm when overexpressed (Erter et
al., 1998; Feldman et al.,
1998; Gritsman et al.,
2000; Peyrieras et al.,
1998; Rebagliati et al.,
1998; Sampath et al.,
1998). cyclop;squint double mutants or mutants lacking
the maternal and zygotic contribution of oep (MZoep), which
encodes a Nodal co-receptor, lack all endoderm and have little or no mesoderm
(Agathon et al., 2003;
Gritsman et al., 1999;
Zhang et al., 1998).
Several lines of evidence suggest that in addition to being required for
endoderm and mesoderm formation, differential Nodal signalling may also be
involved in the separation of these two germ layers. First, many studies have
documented that high levels of Nodal signalling promote endoderm formation and
expression of endodermal determination genes, while lower levels of Nodal
signalling promote mesoderm formation and expression of mesodermal genes such
as brachyury (Alexander et al.,
1999; Alexander and Stainier,
1999; Clements et al.,
1999; Erter et al.,
1998; Faucourt et al.,
2001; Gritsman et al.,
2000; Henry et al.,
1996; Jones et al.,
1995; Piccolo et al.,
1999; Rodaway et al.,
1999; Sun et al.,
1999; Yasuo and Lemaire,
1999). Second, overexpression of low doses of lefty1,
which encodes a potent endogenous antagonist of Nodal, suppresses endoderm
formation while higher doses also affect the mesoderm
(Thisse et al., 2000;
Thisse and Thisse, 1999).
Similarly, in zygotic oep mutants that have reduced Nodal signalling,
the endoderm is absent while the mesoderm is modestly affected
(Schier et al., 1997;
Strahle et al., 1997). By
contrast, MZoep embryos resemble cyclops;squint double
mutants and lack all endoderm and most mesoderm
(Agathon et al., 2003;
Gritsman et al., 1999;
Zhang et al., 1998). Finally,
it has been demonstrated that Squint acts as a morphogen capable of inducing
different cell fates and that it does not require a relay mechanism
(Chen and Schier, 2001;
Le Good et al., 2005).
The endodermal determination program initiated by Nodal signalling requires
the maternally expressed Smad2 factor
(Dick et al., 2000;
Gaio et al., 1999) and
eomesodermin (Bjornson et al.,
2005) as well as several zygotic transcription factors such as the
Mix-like homeobox proteins Bon; the product of the bonnie and clyde
gene (bon) (Alexander et al.,
1999; Trinh et al.,
2003) and Mezzo (Poulain and
Lepage, 2002). Mix-like proteins act in parallel with the
zinc-finger-containing factor Gata5, which is encoded by the faust
gene to induce the sox-related gene casanova/sox32
(Kikuchi et al., 2004;
Reiter et al., 1999).
casanova/sox32 mutants do not express the endodermal marker
sox17, and lack endodermal precursors and organs derived from the gut
tube (Alexander et al., 1999;
Alexander and Stainier, 1999;
Aoki et al., 2002a;
Dickmeis et al., 2001;
Kikuchi et al., 2001;
Kikuchi et al., 2004;
Reiter et al., 1999;
Reiter et al., 2001;
Sakaguchi et al., 2001). In
the absence of Casanova activity, cells that normally contribute to the
endoderm change their fate and differentiate into mesodermal cells. Therefore,
Casanova is a key transcription factor in the endoderm determination network
and is required for the expression of sox17.
In addition to Nodal, the FGF and BMP signalling pathways have been shown
to play crucial roles in formation and patterning of mesoderm and endoderm in
vertebrates. Basic FGF was first identified as a mesoderm-inducing factor that
promotes ventral mesoderm formation
(Kimelman, 1991). Then,
studies in Xenopus and zebrafish demonstrated that FGF is required
for posterior mesoderm formation through the maintenance of the expression of
Tbox transcription factors such as No Tail and Tbx-16
(Bottcher and Niehrs, 2005;
Griffin et al., 1995a;
Griffin and Kimelman, 2003;
Schulte-Merker and Smith,
1995). Because overexpression of a dominant-negative FGF receptor
blocks the dorsal mesoderm inducing activity of Activin, FGF ligands have been
proposed to act as competence factors needed by presumptive mesodermal cells
to respond to TGF-ß signals (Cornell
et al., 1995; Zhao et al.,
2003). In zebrafish, FGF signals may relay the action of TGFß
ligands over long distances, allowing activation of the pan-mesodermal marker
brachyury in cells distant from the Nodal source
(Reiter et al., 1999).
Consistent with these observations, FGF is required downstream of Nodal
signalling to induce the co-receptor Oep in cells distant from the source of
Nodal, a mechanism that contributes to the amplification and propagation of
Nodal signals (Mathieu et al.,
2004). Thus, the FGF pathway might be involved in the initiation
of, as well as in the maintenance of, mesodermal populations. Finally, studies
in zebrafish have shown in addition to its effects on anteroposterior
patterning of the mesoderm, FGF signalling controls patterning along the DV
axis by repressing the expression of BMPs
(Fürthauer et al., 2004).
Although a large body of evidence supports the role of FGF in mesoderm
formation and patterning, the implication of FGF signalling in formation of
the endoderm has received considerably less attention and the results obtained
are unclear. In Xenopus, studies with vegetal pole explants by Henry
et al. showed that FGF is required for expression of the pancreatic marker
pdx1 but not for expression of the intestinal marker intestinal fatty
acid binding protein (IFABP) (Henry et
al., 1996). By contrast, Gamer and Wright
(Gamer and Wright, 1995) found
that bFGF is a potent inhibitor of pdx1 expression in vegetal pole
explants. A third study concluded that overexpression of eFGF inhibits
expression of mixer, while inhibition of FGF signalling in animal
caps induces the ectopic expression of the key endodermal regulator
mixer and of the gene marker endodermin
(Cha et al., 2004). These
observations suggest that in Xenopus, FGF signalling may antagonize
endoderm specification. However, nothing is known about the role of FGF
signalling in endoderm specification in other vertebrates.
Similarly, the roles of BMPs in patterning of the mesoderm and ectoderm are
well documented but only a few studies focused on the role of BMPs on endoderm
formation. Sasai et al. (Sasai et al.,
1996) reported that, in Xenopus, overexpression of
noggin or chordin induces endoderm in animal caps.
Furthermore, they showed that endoderm induction by chordin is
strongly potentiated by inhibition of FGF signalling and counteracted by
activation of FGF signalling. Taken together these observations suggest that
both BMP and FGF signalling antagonize endoderm formation in Xenopus
but the molecular mechanism responsible for this antagonism is not known and
these observations have not been extended to other vertebrates.
Here, we have attempted to unravel the interactions between the Nodal, FGF and BMP pathways during formation of the endoderm in zebrafish. We show that both the FGF/MAPK and the BMP pathways antagonize endoderm formation in response to Nodal signals. We have found that activation of the FGF/MAPK pathway by overexpression of FGF ligands or constitutively active versions of Ras or ERK caused a severe reduction in the number of endodermal precursors in the whole embryo and antagonized the ability of Tar/Acvr1b to induce endoderm at the animal pole. By contrast, the triple inhibition of Fgf8, Fgf17b and Fgf24 caused a strong increase in the number of endodermal precursors while inhibition of FGF/ERK signalling potentiated the ability of Tar*/Acvr1b to induce endoderm at the animal pole. Furthermore, we found that overexpression of BMPs also inhibits endoderm formation and that simultaneous inhibition of the FGF/Ras and BMP pathways causes formation of an excess of endoderm in the embryo. Furthermore, we provide evidence that FGF/ERK signalling results in phosphorylation of Casanova and that this phosphorylation attenuates its activity. These results suggest that the FGF and BMP pathways counteract the Nodal signalling pathway and limit formation of endoderm. Importantly, they identify Casanova as a key factor at the crossroads between signalling pathways and highlight a potential molecular mechanism that may help explain the separation of the mesoderm and endoderm.
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MATERIALS AND METHODS |
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SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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). Wild-type
embryos were collected by natural spawning from the AB strain. Mutant embryos
were obtained by inter-crossing heterozygous carrier fish identified by random
crossing. We used the bonnie and clydem425 mutant allele
(Kikuchi et al., 2000).
Embryos were genotyped following the procedure published by Kikuchi et al.
(Kikuchi et al., 2000). To
inhibit FGFR activity, embryos were treated with SU5402
(Mohammadi et al., 1997), at
15 µM after 1000 cell stage at 28.5°C in the dark. This concentration
gave the most consistent results but some variability was observed in the
effects of the drug, depending of the batch of inhibitor, the cell line and
the time of addition of the drug. SU5402 activity was monitored by its ability
to inhibit MAPK activity and sprouty4 expression (see Fig. S1 in the
supplementary material).
RNA and oligonucleotides microinjection
Constructs for microinjection of Fgf8
(Fürthauer et al., 1997),
DN-Fgfr1 and noggin1 (Furthauer
et al., 1999), DN-Ras and CA-Ras
(Whitman and Melton, 1992),
Erk2* (Emrick et al., 2001),
tar*/acvr1b (Peyrieras et al.,
1998), and BMP2b, BMP4 and BMP7 have been previously described
(Schmid et al., 2000). All
capped mRNA were synthesised from templates linearised with Asp718 using the
SP6 mMessage mMachine kit (Ambion). After synthesis, capped RNAs were purified
on Sephadex G50 columns and quantitated by spectrophotometry. Injections were
performed either in the yolk at the one-cell stage or in the animal blastomere
at the 16- to 128-cell stages. The Fgf8, Fgf17b and Fgf24 morpholino antisense
oligonucleotides were injected at respectively 0.2, 0.125 and 0.5 µM. At
these doses, the Fgf24 morpholino phenocopied the ikarus mutation
that disrupts the fgf24 gene
(Fischer et al., 2003), while
the Fgf8 morpholino phenocopied the acerebellar mutation, which
disrupts the fgf8 gene. When co-injected, these oligos caused severe
defects in the posterior region of the embryo, which is known to require FGF
signalling. The sequence of the morpholinos used are: MO Fgf8,
5'-GAGTCTCATGTTTATAGCCTCAGTA-3'; MO Fgf24:
5'-GACGGCAGAACAGACATCTTGGTCA-3'; MO Fgf17b,
5'-AGTGTTCAATATCCAGGGCTCTCCT-3'. noggin1 mRNA was
injected at 25 µg/ml.
Whole-mount in situ hybridisation
In situ hybridisation was performed following a protocol adapted from
Thisse et al. (Thisse et al.,
2004) with antisense RNA probes and staged embryos. In some cases,
the lineage tracer (FLDX) was detected after in situ hybridisation using an
anti-fluorescein antibody coupled to alkaline phosphatase and Fast Red as
substrate. The probes used in this publication have been described previously:
sox17 (Alexander and Stainier,
1999), sprouty4
(Fürthauer et al., 2001),
nkx2.5 (Chen and Fishman,
1996) and foxi1
(Fürthauer et al., 2004).
All probes were synthesized with the T7 RNA polymerase after linearization by
NotI.
To count the number of cells expressing sox17, the embryos were photographed under different angles so that the whole surface was covered. Four to six different pictures were taken by progressively rotating the embryo and landmarks were used to delimit nonoverlapping areas. Alternatively, flat preparations of the blastoderm were made after removing the yolk platelets (see Fig. S2 in the supplementary material).
Immunochemistry and western blot
Capped mRNA of FLAG-tagged casanova/sox32 (100 ng/µl) were
injected into embryos at the two-cell stage. When the embryos reached 30%
epiboly (5 hpf), the chorion was removed with pronase and the yolk was removed
using an `eye hair knife' in an agarose chamber in MBS 1x (Modified
Barth Saline Buffer) supplemented with gentamycin
(Peng, 1991;
Sagerstrom et al., 1996).
Fifteen blastoderms were pooled, allowed to recover for 20 minutes after
dissection in MBS 1x and then lysed in SDS sample buffer. Proteins were
fractioned by sodium dodecyl sulphate-polyacrylamide gel electrophoresis
(SDS-PAGE) and electrophoretically transferred to PVDF membranes. The
replicate was blocked for 1 hour in 1% BSA, BRBT (Tris-HCl 10 mM, NaCl 150 mM,
EDTA 1 mM, pH 7.5, Tween 0.01%) and incubated overnight at 4°C with a
monoclonal antibody [
-Casanova-Phospho at 1/100 or -Flag M2
(Kodak) at 1/1000]. After washing in BRBT, the membrane was incubated with the
secondary anti body at 1/10000 (anti-Rabbit HRP or anti-mouse HRP conjugated
antibodies, Amersham). Bound antibodies were revealed by ECL western blotting
detection reagent (Pierce). The -Casanova-Phospho antibody was made in
rabbit by Eurogentec and was purified by affinity chromatography using HPLC
(BioRad system). Immunostaining was performed essentially as described
(Shinya et al., 2001).
RNA extraction and reverse transcription-polymerase chain reaction
Total RNA from staged embryos was extracted by the method of Chomczynski
(Chomczynski, 1987). For RT-PCR, cDNA synthesis and PCR were performed as
described by Sagerström (Sagerström, 1996). Primers pairs for
histone H4 were synthesized according to previous published reports. Other
primer pairs used were derived from the ORF of each protein: Zsox-17 forward,
5'-ACGAGGTGGAGTTTGAGCAC; Zsox-17 reverse, 5'-GGCTGCTCTAAAAGCTGCTG
(amplified fragment 465 bp); Casanova forward, 5'-CAGCATTCTGTCCAGCAGAG;
Casanova reverse, 5'-CAAAATCAGCAGCAATCTGG (amplified fragment 480 bp).
Cycling parameters were as follows: initial denaturation at 94°C for 1
minute, annealing at 55°C for 1 minute, extension at 72°C for 1 minute
30 seconds. Thirty cycles were used for ease of comparison. Each experiment
was repeated three times using one or three whole embryos.
Site-directed mutagenesis and construction of expression plasmids
To make pCS2 cas-S47A construct, the AGC codon encoding serine in
position 47 of pCS2 cas was mutated GCC (alanine) by splicing PCR
using the following oligonucleotides: Casanova-S47A Fw,
5'-TCGGGCCCATTAGCCCCGGTGTCTGTC-3'; Casanova-S47A Rev;
5'-GACAGACACCGGGGCTAATGGGCCCGA-3'. The exchange was
verified by sequencing. pCS2 cas-WT-Flag and pCS2
cas-S47A-Flag were constructed as follows. A ClaI-EcoRI
fragment containing Casanova was PCR amplified with the following
oligonucleotides (restriction sites sequences underlined and ATG in bold):
Fw-Casanova-ClaI-ATG,
5'-CCCATCGATATGTATCTCGACCGGATG-3';
Casanova-EcoRI-Rev,
5'-CTTGAATTCCCTTTTTGCTGTGGTCCAA-3' and cloned into the
pCS2-Flag Vector digested with EcoRI and ClaI.
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RESULTS |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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).
Expression of lefty1 was not affected in the embryos overexpressing
Fgf8 (data not shown), indicating that the loss of endodermal precursors
caused by Fgf8 was not a consequence of interfering with Nodal expression.
Similarly, overexpression of an activated form of Ras (CA-RAS)
(Whitman and Melton, 1992) or
of an activated form of human ERK2*
(Emrick et al., 2001) strongly
reduced the number of sox17-expressing cells
(Fig. 1B,D). As FGFs are
expressed (Draper et al.,
2003; Fürthauer et al.,
2004) and MAPK activity is detected in the endomesodermal
territory during gastrulation (Fig. S1 in the supplementary material), FGFs
are good candidates for endogenous factors that negatively regulate formation
of the endodermal precursors. To test this hypothesis we attempted to block
FGF signalling using morpholinos. Injection of morpholinos directed against
either Fgf8 or Fgf17b or Fgf24 mRNA alone did not affect significantly the
number of endoderm precursors. By contrast, the triple knockdown of Fgf8,
Fgf17b and Fgf24 resulted in a large increase in the number of endodermal
precursors that formed (Fig.
1E,F; see Table 3).
Taken together, these results show that endogenous FGF signals restrict
endoderm formation during gastrulation.
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; Peyrieras et
al., 1998; Renucci et al.,
1996). To block FGF signalling, we used a dominant-negative form
of FGFR1 (DN-FGFR1) (Fürthauer et
al., 2004). In agreement with the known role of FGF in mesoderm
formation, injection of the dominant-negative form of FGFR1 potently inhibited
endogenous mesodermal expression (data not shown). To block FGF signalling, we
also used the pharmacological agent SU5402, a specific inhibitor of FGFR
function (Mohammadi et al.,
1997).
Injection of RNA encoding Tar*/Acvr1b at the animal pole induced ectopic
expression of the endodermal marker sox17 (55%, n=40,
Fig. 2E) and of the mesodermal
marker ZFIN CB187 (50%, n=14,
Fig. 2B) (see Thisse et al.,
2001 at
http://zfin.org).
In agreement with previous studies
(Mathieu et al., 2004), we
found that inhibition of FGF signalling reduced the ability of Tar*/Acvr1b to
induce expression of the mesodermal marker CB187 (6.9%,
n=28, Fig. 2C). By
contrast, the frequency of sox17 induction by tar*/acvr1b
was moderately enhanced (75.5%, n=49,
Fig. 2F). Similarly, whereas
injection of very low doses 1-2 pg of tar*/acvr1b caused the ectopic
expression of sox17 in about 32% of the embryos, treatment with
SU5402 following the injection increased this percentage to 54%
(Table 1). RT-PCR assays
confirmed that the level of casanova/sox32 and sox17
transcripts in response to tar*/acvr1b overexpression was increased
following treatment with SU5402 (Fig.
2G). By contrast, when mRNA encoding an activated Erk2* was
co-injected with tar*/acvr1b, the number of embryos expressing
sox17 ectopically was decreased to 23%
(Table 1) and the size of the
clones showing ectopic expression of the marker was strongly reduced
(Fig. 2H,I). Taken together,
these results show that the FGF/ERK pathway negatively regulates the ability
of ectodermal cells to be converted into endoderm in response to
tar*/acvr1b overexpression.
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), which
have a reduced expression of casanova/sox32
(Aoki et al., 2002a). Although
the average number of sox17-expressing cells in homozygous
bon mutants at 75% epiboly is around 11, this number increased more
than threefold following application of SU5402 at 15 µM at the blastula
stage (Fig. 3A-C;
Table 2) and endodermal
precursors could be detected even on the ventral side of the embryos. In
addition, treatment with SU5402 partially rescued the cardia bifida phenotype
caused by the defect in endoderm formation in this mutant
(Fig. 3D-F,
Table 2). However, in most
cases, the rescued hearts beat at a very low frequency and did not
differentiate properly into an atrium and a ventricle but remain as an
elongated tube. We found that a combination of morpholinos against Fgf8 and
Fgf24 also rescued the cardia bifida of bon mutants, while causing
only a modest increase in the number of endodermal precursors present at 80%
epiboly (Table 2). Thus,
inhibition of FGF signalling is able to compensate for the reduced activity of
the molecular cascade leading to endoderm formation. We then attempted to
rescue the lack of endoderm of embryos injected with antisense morpholino
oligonucleotides directed against casanova/sox32
(Dickmeis et al., 2001).
Treatment with SU5402, did not rescue endoderm formation in these embryos (not
shown). These results suggest that blocking the FGF-MAPK pathway cannot
compensate for the absence of Casanova but can attenuate the endodermal
deficiency of mutants with a reduced expression of
casanova/sox32.
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) did
not, result in an overall excess of endoderm (354/477, n=88/93)
(compare Fig. 5A,E with 5C,G).
The number of endodermal cells was slightly increased dorsally
(Fig. 5C), but in fact, fewer
sox17-expressing cells were present in lateral and ventral regions
(Fig. 5G). This observation
suggests that, in addition to FGF signalling, the extent of endoderm formation
is also regulated by signals emanating from the ventral side of the embryo. As
BMPs are known to be essential for the specification of ventral cell fates
(Kishimoto et al., 1997;
Schmid et al., 2000), we
investigated whether their activity modulates endoderm formation. The gene
encoding the transcription factor Foxi1
(Nissen et al., 2003) displays
a BMP-dependent expression in the prospective epidermis and can therefore be
considered as a molecular readout of ongoing BMP signalling. In the ventral
region of wild-type embryos, the expression domains of foxi1 and
sox17 are strikingly complementary
(Fig. 4A-C). Moreover, when FGF
signalling is blocked using DN-Ras, DN-FGFR1 or SU5402, the expression of the
bmp genes and their target foxi1 expands dorsally
(Fig. 4D-I)
(Fürthauer et al., 2004).
In these FGF-signalling inhibited embryos, sox17 expression becomes
restricted to the residual dorsal BMP-free zone that does not express
foxi1, consistent with a potential role of BMPs in restricting
endoderm formation. In support of this hypothesis, co-injection of the three
BMP ligands at the ventral margin created a local gap in sox17
expression (97.3%, n=38, Fig.
4K). Injection of the same molecules at the one-cell stage
produced a range of effects going from a loss of endoderm on the ventral side
(Fig. 4L, n=14/53) to
an almost complete loss of endoderm precursors all around the embryo (not
shown; n=39/53). We therefore investigated whether BMP signalling is
responsible for the inhibition of endoderm formation in the ventrolateral
region of FGF-depleted embryos. In agreement with a previous study, we found
that the number of endodermal progenitors was not increased in zebrafish
embryos mutant for bmp2b or bmp7
(Tiso et al., 2002) (data not
shown). Similarly, inhibition of BMP signalling with noggin caused
only a slight increase in the number of endodermal precursors that formed
(Fig. 5B,F, n=84/84
and Table 3). However, we found
that simultaneously inhibiting MAPK signalling and BMP signalling caused a
massive excess of endodermal precursors to form all around the embryo
(Fig. 5D-H, n=70/88,
Table 3). By counting
individual sox17-positive cells in embryos at 75% epiboly co-injected
with noggin and DN-Ras we found that the number of endodermal
precursors was increased by 50% (652/437, n=15,
Table 3). Furthermore, the
quadruple inhibition of Fgf8, Fgf17b, Fgf24 using morpholinos and of BMP
signalling with noggin mRNA resulted in an even higher number of
endodermal precursors compared with wild type (1000/437, n=6). These
data suggest that FGF signals acting all around the margin cooperate with BMP
signals that act ventrally to limit the number of endoderm precursors during
normal development.
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;
Pera et al., 2003) (reviewed
by Massagué, 2003). We
therefore examined whether the repressive effect of FGF/ERK on specification
of endoderm precursors was mediated by phosphorylation of Smad2 or Smad3. To
test this idea, we overexpressed Smad2 and Smad3 constructs with the serines
of the four putative phosphorylation sites in the Smad linker domain mutated
to alanine (Kretzschmar et al.,
1999). These mutant versions of Smads were not able to rescue the
loss of endodermal precursors following overexpression of Fgf8 (not shown).
Moreover, we found that the expression of lefty1, which is regulated
by Nodal signalling, is unchanged in Fgf8-injected embryos, indicating that
Fgf8 does not inhibit directly the Smads. Taken together, these observations
suggested that the repressive effect of FGF/ERK on endoderm formation occurred
downstream or in parallel of the Smads. Therefore, we focused on
Casanova/Sox32, which is an important factor in the endoderm determination
cascade acting downstream of Smads. We noticed that Casanova contains a single
ERK consensus phosphorylation site PLSP
(Gonzalez et al., 1991), which
is conserved in zebrafish sox17, while the mouse and human Sox17
proteins contain a related sequence SLSP
(Fig. 6A). In order to test
whether this putative site is phosphorylated in vivo, we generated antibodies
against a 15 amino acids peptide spanning the phosphorylated serine
(Fig. 6A). Antibodies
recognizing the phosphorylated peptide were purified by affinity
chromatography. We were not able to detect the endogenous Casanova protein
using these antibodies, probably because of the very low level of expression
of this gene. However, these antibodies recognized a single protein of 37 kDa,
the predicted molecular weight of Casanova, in protein extracts from embryos
overexpressing casanova/sox32
(Fig. 6B). These antibodies
were specific for the phosphorylated form of Casanova as they did not
recognize a protein band following injection of cas-S47A mRNA, which
contains a mutated phosphorylation site in which serine 47 is replaced with
alanine (Fig. 6B). As expected,
the level of exogenous phosphorylated Casanova was markedly increased
following co-injection with ERK2* (Fig.
6C). Similarly, the phosphorylated form of Casanova was no longer
detected when Casanova was co-expressed with zebrafish MKP3, which encodes a
zebrafish MAPK phosphatase (Fig.
6D). Treatment with SU5402 resulted in a reduction of the level of
phosphorylated Casanova protein in embryos injected with cas mRNA
(Fig. 6E). By contrast, the
MAPK P38 inhibitor SB205580 did not have any effect on the level of
phosphorylated Casanova protein (Fig.
6F). These results suggest that Casanova protein is a target of
ERK in vivo and that the FGF pathway is largely responsible for the
phosphorylation of Casanova protein.
Phosphorylation of Casanova/Sox32 attenuates its activity
We next examined whether phosphorylation of Casanova modifies its activity.
First, we compared the ability of low doses of cas-WT or
cas-S47A to induce ectopic sox17 expression. When 20 pg of
cas-WT RNA was injected, it caused ectopic expression of
sox17 in 35% of the embryos (n=381,
Fig. 7J,
Table 4). When the same dose of
mutated cas-S47A was injected, the percentage of embryos displaying
sox17 was slightly increased to 47% (n=214). Furthermore, in
situ hybridisation signals were consistently stronger in the cas-S47A
than in the cas-WT-injected embryos
(Fig. 7A,B, see Fig. S3A-C in
the supplementary material). These results suggest that the presence of the
ERK target site has a negative effect on the ability of Casanova to induce
sox17 expression.
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DISCUSSION |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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) found
that bFGF is a potent inhibitor of the expression of the pancreatic marker
pdx1. Bouwmeester et al.
(Bouwmeester et al., 1996)
found that co-injection of XFD, a dominant-negative version of Fgfr1,
potentiates the ability of chordin to induce expression of endodermal
markers in animal caps assays. Finally, a recent study showed that
overexpression of eFGF inhibits expression of mixer and that
inhibition of FGF signalling in animal caps induces the ectopic expression of
mixer and endodermin
(Cha et al., 2004). Taken
together, these studies suggest that in Xenopus FGF signalling
antagonizes the molecular pathways that control endoderm specification.
To investigate whether FGF and Nodal signalling interact during endoderm
formation in zebrafish, we ectopically expressed FGF signals. Overexpression
of FGFs, as well as overexpression of activated versions of the FGF receptor,
activated forms of Ras and the MAP kinase ERK, all strongly interfered with
formation of the endoderm. Reciprocally, inhibition of FGF signalling with
antisense morpholinos oligonucleotides caused a dramatic increase in the
number of endodermal precursors. By contrast, interfering with the MAPK
pathway using DN-Ras only increased the number of endoderm precursors present
on the dorsal side as well as the number of endoderm precursors induced by
ectopic activation of the Nodal pathway at the animal pole. Finally, we showed
that treatments with SU5402 or injection of morpholinos against Fgf8 and Fgf24
partially rescued the deficit of endoderm precursors and the associated cardia
bifida phenotype of the bonnie and clyde mutant, which have a reduced
expression of casanova/sox32. This finding is consistent with the
results of David and Rosa (David and Rosa,
2001), who showed that grafted wild-type endodermal cells rescue
the cardia bifida defects of casanova/sox32 mutants.
Therefore, attenuation of FGF signalling partially compensates for the lack of
a downstream effector of Nodal probably by increasing the activity of
Casanova. This provides a further indication that in the intact embryo,
endoderm formation in response to Nodal signalling is negatively regulated by
FGF.
Studies with zebrafish mutants and experiments with inhibitors had
previously shown that FGF and Nodal signalling cooperate during mesoderm
formation (Griffin and Kimelman,
2003; Griffin et al.,
1995b; Mathieu et al.,
2004). Our results show that during endoderm formation there is a
strong antagonism between the FGF and the Nodal signalling pathways.
Endoderm formation and BMP signalling
Previous studies had suggested that, in Xenopus, endoderm
formation is regulated negatively by signals emanating from the ventral side.
In particular, Sasai et al. reported that overexpression of noggin or
chordin induces endoderm in animal caps and that this effect is
strongly potentiated by inhibition of FGF signalling
(Sasai et al., 1996). However,
Tiso et al. found that, in zebrafish, the number of endoderm precursors is
neither affected by overexpression of BMP nor reduced in the swirl
mutant which has a disrupted bmp2 gene
(Tiso et al., 2002). By
contrast, we found that overexpression of a cocktail of bmp2, bmp4
and bmp7 potently affects the number of endoderm precursors and that
overexpression of noggin increases, although only slightly, the
number of endodermal precursors. More strikingly, we found that while
inhibition of the BMP signalling pathway with noggin mRNA results in
only a modest increase in the number of endodermal precursors, when
noggin and DN-Ras are co-injected, they cause formation of a massive
excess of endodermal precursors. Finally, the largest number of endodermal
precursors was observed following simultaneous inhibition of BMP signalling
with noggin and of FGF signalling with morpholinos, further
implicating BMP signals in restricting endoderm formation. Taken together,
these experiments reveal a previously unknown role for BMP signals in
repressing endoderm formation. Therefore, our results show that in addition to
being positively regulated by signals from the TGFß family, formation of
the endoderm is negatively regulated by a combination of FGF and BMP signals
(Fig. 8).
Repression of endoderm formation by FGF or BMP may not be mediated by phosphorylation or competition for Smad2/3
Phosphorylation of Smad in their inter-linker region has been implicated in
modulating the response to Tgfß signals
(Massagué, 2003;
Pera et al., 2003). In
Xenopus gastrulae, it has been shown that MAP kinase-dependent
phosphorylation of Smad2 inhibits its translocation into the nucleus. As a
consequence, animal blastomeres loose their competence to respond to Tgfß
and differentiate into ectoderm instead of mesoderm
(Grimm and Gurdon, 2002).
Consequences of Smad2 phosphorylation are not clear as different studies gave
opposite results. One report has shown that in human cells, activation of Ras
caused the exclusion of Smad2 and Smad3 from the nucleus
(Kretzschmar et al., 1999).
These data contrast with an earlier report in which Erk2-dependant
phosphorylation of Smad2 correlated with an increase in the nuclear
localisation and activity of Smad2 (de
Caestecker et al., 1998). Our finding that a Nodal target gene
such as lefty1 is expressed normally following overexpression of Fgf8
suggests that, in zebrafish, the antagonism between endoderm formation and
FGF/ERK signalling does not rely on an inhibitory phosphorylation of Smads.
The inability of a Smad2 mutant than can not be phosphorylated by ERK to
rescue endoderm formation in FGF overexpressing embryos reinforces this
conclusion.
Although the inhibitory effect of FGF signalling on endoderm formation can
be explained by an inhibitory phosphorylation of Casanova, the molecular
mechanism responsible for the inhibitory action of BMP is not presently known.
Both the Nodal signalling pathway and the BMP signalling pathway share a
common downstream component, Smad4. It is therefore tempting to speculate that
the inhibitory action of BMP on endoderm formation may be caused by a
competition between Smad1/Smad5, which are activated by BMP signalling, and
Smad2/Smad3, which are activated by Nodal signalling for binding to Smad4
(Candia et al., 1997). However,
we found that overexpression of Smad4 was not able to rescue the loss of
sox17 expression in BMP-overexpressing embryos (not shown),
therefore, a competition at the level of Smad proteins does not seem to be the
cause of the inhibitory action of BMPs on endoderm formation.
|
) (M.P. and T.L., unpublished). Phosphorylation of Smad2/3 may
affect their interaction with Mixer and Mezzo.
In zebrafish, the endodermal and mesodermal precursors originate from a
common endomesodermal territory and both require Nodal signalling. The
molecular mechanisms that allow these two cell fates to segregate during
gastrulation are not well understood. It was previously known that factors
promoting endoderm formation, such as Casanova or Mezzo repress mesoderm
formation when overexpressed (Aoki et al.,
2002a; Kikuchi et al.,
2001; Poulain and Lepage,
2002). Our finding that endogenous FGF signals strongly antagonize
endoderm formation by downregulating Casanova shows that a reciprocal negative
interaction exists between factors that promote mesoderm formation and
transcription factors required for endoderm formation. This mutual antagonism
may therefore help to understand how mesodermal- or endodermal-specific gene
regulatory networks are established in the precursors of these two germ
layers, allowing different cell fates to be segregated.
In conclusion, we have shown that the FGF and BMP signals antagonize endoderm formation by Nodal factors. Furthermore, we have shown that Casanova is subject to an inhibitory phosphorylation in response to FGF signalling and therefore stands at the intersection between the FGF and Nodal signalling pathways. This phosphorylation may represent a general mechanism whereby FGF attenuates Nodal-induced endodermal transcription factors, and therefore these results may help to understand how mesoderm and endoderm segregate from each other.
|
ACKNOWLEDGMENTS |
|---|
|
Footnotes |
|---|
Supplementary material for this article is available at http://dev.biologists.org/cgi/content/full/133/11/2189/DC1
* Present address: Max Planck Institute of Molecular Cell Biology and
Genetics, Pfotenhauerstrasse 108, D-01307 Germany 
|
REFERENCES |
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|
TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
|---|
Agathon, A., Thisse, C. and Thisse, B. (2003).
The molecular nature of the zebrafish tail organizer.
Nature 424,448
-452.[CrossRef][Medline]
Alexander, J. and Stainier, D. Y. (1999). A
molecular pathway leading to endoderm formation in zebrafish. Curr.
Biol. 9,1147
-1157.[CrossRef][Medline]
Alexander, J., Rothenberg, M., Henry, G. L. and Stainier, D.
Y. (1999). casanova plays an early and essential role in
endoderm formation in zebrafish. Dev. Biol.
215,343
-357.[CrossRef][Medline]
Aoki, T. O., David, N. B., Minchiotti, G., Saint-Etienne, L.,
Dickmeis, T., Persico, G. M., Strahle, U., Mourrain, P. and Rosa, F.
M. (2002a). Molecular integration of casanova in the Nodal
signalling pathway controlling endoderm formation.
Development 129,275
-286.[Medline]
Aoki, T. O., Mathieu, J., Saint-Etienne, L., Rebagliati, M. R.,
Peyrieras, N. and Rosa, F. M. (2002b). Regulation of
nodal signalling and mesendoderm formation by TARAM-A, a TGFbeta-related type
I receptor. Dev. Biol.
241,273
-288.[CrossRef][Medline]
Bjornson, C. R., Griffin, K. J., Farr, G. H., 3rd, Terashima,
A., Himeda, C., Kikuchi, Y. and Kimelman, D. (2005).
Eomesodermin is a localized maternal determinant required for endoderm
induction in zebrafish. Dev. Cell
9, 523-533.[CrossRef][Medline]
Bottcher, R. T. and Niehrs, C. (2005).
Fibroblast growth factor signaling during early vertebrate development.
Endocr. Rev. 26,63
-77.
Bouwmeester, T., Kim, S., Sasai, Y., Lu, B. and De Robertis, E.
M. (1996). Cerberus is a head-inducing secreted factor
expressed in the anterior endoderm of Spemann's organizer.
Nature 382,595
-601.[CrossRef][Medline]
Candia, A. F., Watabe, T., Hawley, S. H., Onichtchouk, D.,
Zhang, Y., Derynck, R., Niehrs, C. and Cho, K. W.
(1997). Cellular interpretation of multiple TGF-beta signals:
intracellular antagonism between activin/BVg1 and BMP-2/4 signaling mediated
by Smads. Development
124,4467
-4480.[Abstract]
Cha, S. W., Hwang, Y. S., Chae, J. P., Lee, S. Y., Lee, H. S.,
Daar, I., Park, M. J. and Kim, J. (2004). Inhibition of FGF
signaling causes expansion of the endoderm in Xenopus. Biochem.
Biophys. Res. Commun. 315,100
-106.[CrossRef][Medline]
Chen, J. N. and Fishman, M. C. (1996).
Zebrafish tinman homolog demarcates the heart field and initiates myocardial
differentiation. Development
122,3809
-3816.[Abstract]
Chen, Y. and Schier, A. F. (2001). The
zebrafish Nodal signal Squint functions as a morphogen.
Nature 411,607
-610.[CrossRef][Medline]
Chomczynski, P. and Sacchi, N. (1987).
Single-step method of RNA isolation by acid guanidinium
thiocyanate-phenol-chloroform extraction. Anal.
Biochem. 162,156
-159.[Medline]
Clements, D., Friday, R. V. and Woodland, H. R.
(1999). Mode of action of VegT in mesoderm and endoderm
formation. Development
126,4903
-4911.[Abstract]
Cornell, R. A., Musci, T. J. and Kimelman, D.
(1995). FGF is a prospective competence factor for early
activin-type signals in Xenopus mesoderm induction.
Development 121,2429
-2437.[Abstract]
David, N. B. and Rosa, F. M. (2001). Cell
autonomous commitment to an endodermal fate and behaviour by activation of
Nodal signalling. Development
128,3937
-3947.[Medline]
de Caestecker, M. P., Parks, W. T., Frank, C. J., Castagnino,
P., Bottaro, D. P., Roberts, A. B. and Lechleider, R. J.
(1998). Smad2 transduces common signals from receptor
serine-threonine and tyrosine kinases. Genes Dev.
12,1587
-1592.
Dick, A., Mayr, T., Bauer, H., Meier, A. and Hammerschmidt,
M. (2000). Cloning and characterization of zebrafish smad2,
smad3 and smad4. Gene
246, 69-80.[CrossRef][Medline]
Dickmeis, T., Mourrain, P., Saint-Etienne, L., Fischer, N.,
Aanstad, P., Clark, M., Strahle, U. and Rosa, F.
(2001). A crucial component of the endoderm formation pathway,
CASANOVA, is encoded by a novel sox-related gene. Genes
Dev. 15,1487
-1492.
Draper, B. W., Stock, D. W. and Kimmel, C. B.
(2003). Zebrafish fgf24 functions with fgf8 to promote posterior
mesodermal development. Development
130,4639
-4654.
Emrick, M. A., Hoofnagle, A. N., Miller, A. S., Ten Eyck, L. F.
and Ahn, N. G. (2001). Constitutive activation of
extracellular signal-regulated kinase 2 by synergistic point mutations.
J. Biol. Chem. 276,46469
-46479.
Erter, C. E., Solnica-Krezel, L. and Wright, C. V.
(1998). Zebrafish nodal-related 2 encodes an early mesendodermal
inducer signaling from the extraembryonic yolk syncytial layer.
Dev. Biol. 204,361
-372.[CrossRef][Medline]
Faucourt, M., Houliston, E., Besnardeau, L., Kimelman, D. and
Lepage, T. (2001). The pitx2 homeobox protein is required
early for endoderm formation and nodal signaling. Dev.
Biol. 229,287
-306.[CrossRef][Medline]
Feldman, B., Gates, M. A., Egan, E. S., Dougan, S. T.,
Rennebeck, G., Sirotkin, H. I., Schier, A. F. and Talbot, W. S.
(1998). Zebrafish organizer development and germ-layer formation
require nodal-related signals. Nature
395,181
-185.[CrossRef][Medline]
Fischer, S., Draper, B. W. and Neumann, C. J.
(2003). The zebrafish fgf24 mutant identifies an additional level
of Fgf signaling involved in vertebrate forelimb initiation.
Development 130,3515
-3524.
Fujii, R., Yamashita, S., Hibi, M. and Hirano, T.
(2000). Asymmetric p38 activation in zebrafish: its possible role
in symmetric and synchronous cleavage. J. Cell Biol.
150,1335
-1348.
Fürthauer, M., Thisse, C. and Thisse, B.
(1997). A role for FGF-8 in the dorsoventral patterning of the
zebrafish gastrula. Development
124,4253
-4264.[Abstract]
Furthauer, M., Thisse, B. and Thisse, C.
(1999). Three different noggin genes antagonize the activity of
bone morphogenetic proteins in the zebrafish embryo. Dev.
Biol. 214,181
-196.[CrossRef][Medline]
Fürthauer, M., Reifers, F., Brand, M., Thisse, B. and
Thisse, C. (2001). sprouty4 acts in vivo as a
feedback-induced antagonist of FGF signaling in zebrafish.
Development 128,2175
-2186.[Medline]
Fürthauer, M., Van Celst, J., Thisse, C. and Thisse, B.
(2004). Fgf signalling controls the dorsoventral patterning of
the zebrafish embryo. Development
131,2853
-2864.
Gaio, U., Schweickert, A., Fischer, A., Garratt, A. N., Muller,
T., Ozcelik, C., Lankes, W., Strehle, M., Britsch, S., Blum, M. et
al. (1999). A role of the cryptic gene in the correct
establishment of the left-right axis. Curr. Biol.
9,1339
-1342.[CrossRef][Medline]
Gamer, L. W. and Wright, C. V. (1995).
Autonomous endodermal determination in Xenopus: regulation of expression of
the pancreatic gene XlHbox 8. Dev. Biol.
171,240
-251.[CrossRef][Medline]
Germain, S., Howell, M., Esslemont, G. M. and Hill, C. S.
(2000). Homeodomain and winged-helix transcription factors
recruit activated Smads to distinct promoter elements via a common Smad
interaction motif. Genes Dev.
14,435
-451.
Gonzalez, F. A., Raden, D. L. and Davis, R. J.
(1991). Identification of substrate recognition determinants for
human ERK1 and ERK2 protein kinases. J. Biol. Chem.
266,22159
-22163.
Griffin, K. J. and Kimelman, D. (2003).
Interplay between FGF, one-eyed pinhead, and T-box transcription factors
during zebrafish posterior development. Dev. Biol.
264,456
-466.[CrossRef][Medline]
Griffin, K., Patient, R. and Holder, N.
(1995a). Analysis of FGF function in normal and no tail zebrafish
embryos reveals separate mechanisms for formation of the trunk and the tail.
Development 121,2983
-2994.[Abstract]
Griffin, K. J. P., Patient, R. K. and Holder, N. H. K.
(1995b). Analysis of FGF function in normal and no tail
zebrafish embryos reveals separate mechanisms for formation of the trunk and
tail. Development 121,2983
-2994.[Abstract]
Grimm, O. H. and Gurdon, J. B. (2002). Nuclear
exclusion of Smad2 is a mechanism leading to loss of competence.
Nat. Cell Biol. 4,519
-522.[CrossRef][Medline]
Gritsman, K., Zhang, J., Cheng, S., Heckscher, E., Talbot, W. S.
and Schier, A. F. (1999). The EGF-CFC protein one-eyed
pinhead is essential for nodal signaling. Cell
97,121
-132.[CrossRef][Medline]
Gritsman, K., Talbot, W. S. and Schier, A. F.
(2000). Nodal signaling patterns the organizer.
Development 127,921
-932.[Abstract]
Henry, G. L., Brivanlou, I. H., Kessler, D. S.,
Hemmati-Brivanlou, A. and Melton, D. A. (1996).
TGF-beta signals and a pattern in Xenopus laevis endodermal development.
Development 122,1007
-1015.[Abstract]
Jones, C. M., Kuehn, M. R., Hogan, B. L. M., Smith, J. C. and
Wright, C. V. E. (1995). Nodal-related signals induce axial
mesoderm and dorsalize mesoderm during gastrulation.
Development 121,3651
-3662.[Abstract]
Kikuchi, Y., Trinh, L. A., Reiter, J. F., Alexander, J., Yelon,
D. and Stainier, D. Y. (2000). The zebrafish bonnie
and clyde gene encodes a Mix family homeodomain protein that regulates the
generation of endodermal precursors. Genes Dev.
14,1279
-1289.
Kikuchi, Y., Agathon, A., Alexander, J., Thisse, C., Waldron,
S., Yelon, D., Thisse, B. and Stainier, D. Y. (2001).
casanova encodes a novel Sox-related protein necessary and sufficient for
early endoderm formation in zebrafish. Genes Dev.
15,1493
-1505.
Kikuchi, Y., Verkade, H., Reiter, J. F., Kim, C. H., Chitnis, A.
B., Kuroiwa, A. and Stainier, D. Y. (2004). Notch signaling
can regulate endoderm formation in zebrafish. Dev.
Dyn. 229,756
-762.[CrossRef][Medline]
Kimelman, D. (1991). The role of fibroblast
growth factor in early Xenopus development. Ann. N. Y.
Acad. Sci. 638,275
-282.[Medline]
Kimmel, C. B., Warga, R. M. and Schilling, T. F.
(1990). Origin and organization of the zebrafish fate map.
Development 108,581
-594.
Kishimoto, Y., Lee, K. H., Zon, L., Hammerschmidt, M. and
Schulte-Merker, S. (1997). The molecular nature of
zebrafish swirl: BMP2 function is essential during early dorsoventral
patterning. Development
124,4457
-4466.[Abstract]
Kretzschmar, M., Doody, J. and Massague, J.
(1997). Opposing BMP and EGF signalling pathways converge on the
TGF-beta family mediator Smad1. Nature
389,618
-622.[CrossRef][Medline]
Kretzschmar, M., Doody, J., Timokhina, I. and Massague, J.
(1999). A mechanism of repression of TGFbeta/Smad signaling by
oncogenic Ras. Genes Dev.
13,804
-816.
Le Good, J. A., Joubin, K., Giraldez, A. J., Ben-Haim, N., Beck,
S., Chen, Y., Schier, A. F. and Constam, D. B. (2005).
Nodal stability determines signaling range. Curr.
Biol. 15,31
-36.[CrossRef][Medline]
Massagué, J. (2003). Integration of Smad
and MAPK pathways: a link and a linker revisited. Genes
Dev. 17,2993
-2997.
Mathieu, J., Griffin, K., Herbomel, P., Dickmeis, T., Strahle,
U., Kimelman, D., Rosa, F. M. and Peyrieras, N.
(2004). Nodal and Fgf pathways interact through a positive
regulatory loop and synergize to maintain mesodermal cell populations.
Development 131,629
-641.
Mohammadi, M., McMahon, G., Sun, L., Tang, C., Hirth, P., Yeh,
B. K., Hubbard, S. R. and Schlessinger, J. (1997).
Structures of the tyrosine kinase domain of fibroblast growth factor receptor
in complex with inhibitors. Science
276,955
-960.
Nissen, R. M., Yan, J., Amsterdam, A., Hopkins, N. and Burgess,
S. M. (2003). Zebrafish foxi one modulates cellular responses
to Fgf signaling required for the integrity of ear and jaw patterning.
Development 130,2543
-2554.
Peng, H. B. (1991). Xenopus laevis:
practical uses in cell and molecular biology. In Methods in Cell
Biology. Vol. 36 (ed. B. K. Kay and H. B.
Peng), pp. 657-662. Santa Barbara: Harcourt Brace
Jovanovich.[Medline]
Pera, E. M., Ikeda, A., Eivers, E. and De Robertis, E. M.
(2003). Integration of IGF, FGF, and anti-BMP signals via Smad1
phosphorylation in neural induction. Genes Dev.
17,3023
-3028.
Peyrieras, N., Strahle, U. and Rosa, F. (1998).
Conversion of zebrafish blastomeres to an endodermal fate by TGF-beta-related
signaling. Curr. Biol.
8, 783-786.[CrossRef][Medline]
Piccolo, S., Agius, E., Leyns, L., Bhattacharyya, S., Grunz, H.,
Bouwmeester, T. and De Robertis, E. M. (1999). The head
inducer Cerberus is a multifunctional antagonist of Nodal, BMP and Wnt
signals. Nature 397,707
-710.[CrossRef][Medline]
Poulain, M. and Lepage, T. (2002). Mezzo, a
paired-like homeobox protein is an immediate target of Nodal signalling and
regulates endoderm specification in zebrafish.
Development 129,4901
-4914.
Rebagliati, M. R., Toyama, R., Haffter, P. and Dawid, I. B.
(1998). cyclops encodes a nodal-related factor involved in
midline signaling. Proc. Natl. Acad. Sci. USA
95,9932
-9937.
Reiter, J. F., Alexander, J., Rodaway, A., Yelon, D., Patient,
R., Holder, N. and Stainier, D. Y. (1999). Gata5 is
required for the development of the heart and endoderm in zebrafish.
Genes Dev. 13,2983
-2995.
Reiter, J. F., Kikuchi, Y. and Stainier, D. Y.
(2001). Multiple roles for Gata5 in zebrafish endoderm formation.
Development 128,125
-135.[Abstract]
Renucci, A., Lemarchandel, V. and Rosa, F.
(1996). An activated form of type I serine/threonine kinase
receptor TARAM-A reveals a specific signalling pathway involved in fish head
organiser formation. Development
122,3735
-3743.[Abstract]
Rodaway, A., Takeda, H., Koshida, S., Broadbent, J., Price, B.,
Smith, J. C., Patient, R. and Holder, N. (1999).
Induction of the mesendoderm in the zebrafish germ ring by yolk cell-derived
TGF-beta family signals and discrimination of mesoderm and endoderm by FGF.
Development 126,3067
-3078.[Abstract]
Sägerstrom, C. G., Grinbalt, Y. and Sive, H.
(1996). Anteroposterior patterning in the zebrafish, Danio rerio:
an explant assay reveals inductive and suppressive cell interactions.
Development 122,1873
-1883.[Abstract]
Sakaguchi, T., Kuroiwa, A. and Takeda, H.
(2001). A novel sox gene, 226D7, acts downstream of Nodal
signaling to specify endoderm precursors in zebrafish. Mech.
Dev. 107,25
-38.[CrossRef][Medline]
Sampath, K., Rubinstein, A. L., Cheng, A. M., Liang, J. O.,
Fekany, K., Solnica-Krezel, L., Korzh, V., Halpern, M. E. and Wright,
C. V. (1998). Induction of the zebrafish ventral brain and
floorplate requires cyclops/nodal signalling. Nature
395,185
-189.[CrossRef][Medline]
Sasai, Y., Lu, B., Piccolo, S. and De Robertis, E. M.
(1996). Endoderm induction by the organizer-secreted factors
chordin and noggin in Xenopus animal caps. EMBO J.
15,4547
-4555.[Medline]
Schier, A. F. (2003). Nodal signaling in
vertebrate development. Annu. Rev. Cell Dev. Biol.
19,589
-621.[CrossRef][Medline]
Schier, A. F. and Talbot, W. S. (2005).
Molecular genetics of axis formation in Zebrafish. Annu. Rev.
Genet. 39,561
-613.[CrossRef][Medline]
Schier, A. F., Neuhauss, S. C., Helde, K. A., Talbot, W. S. and
Driever, W. (1997). The one-eyed pinhead gene functions in
mesoderm and endoderm formation in zebrafish and interacts with no tail.
Development 124,327
-342.[Abstract]
Schmid, B., Furthauer, M., Connors, S. A., Trout, J., Thisse,
B., Thisse, C. and Mullins, M. C. (2000). Equivalent
genetic roles for bmp7/snailhouse and bmp2b/swirl in dorsoventral pattern
formation. Development
127,957
-967.[Abstract]
Schulte-Merker, S. and Smith, J. C. (1995).
Mesoderm formation in response to Brachyury requires FGF signalling.
Curr. Biol. 5,62
-67.[CrossRef][Medline]
Shinya, M., Koshida, S., Sawada, A., Kuroiwa, A. and Takeda,
H. (2001). Fgf signalling through MAPK cascade is required
for development of the subpallial telencephalon in zebrafish embryos.
Development 128,4153
-4164.
Strahle, U., Jesuthasan, S., Blader, P., Garcia-Villalba, P.,
Hatta, K. and Ingham, P. W. (1997). one-eyed pinhead
is required for development of the ventral midline of the zebrafish (Danio
rerio) neural tube. Genes Funct.
1, 131-148.[Medline]
Sun, B. I., Bush, S. M., Collins-Racie, L. A., LaVallie, E. R.,
DiBlasio-Smith, E. A., Wolfman, N. M., McCoy, J. M. and Sive, H. L.
(1999). derriere: a TGF-beta family member required for posterior
development in Xenopus. Development
126,1467
-1482.[Abstract]
Thisse, B., Wright, C. V. and Thisse, C.
(2000). Activin- and Nodal-related factors control
antero-posterior patterning of the zebrafish embryo.
Nature 403,425
-428.[CrossRef][Medline]
Thisse, B., Heyer, V., Lux, A., Alunni, V., Degrave, A.,
Seiliez, I., Kirchner, J., Parkhill, J. P. and Thisse, C.
(2004). Spatial and temporal expression of the zebrafish genome
by large-scale in situ hybridization screening. Methods Cell
Biol. 77,505
-519.[Medline]
Thisse, C. and Thisse, B. (1999). Antivin, a
novel and divergent member of the TGFbeta superfamily, negatively regulates
mesoderm induction. Development
126,229
-240.[Abstract]
Tiso, N., Filippi, A., Pauls, S., Bortolussi, M. and Argenton,
F. (2002). BMP signalling regulates anteroposterior endoderm
patterning in zebrafish. Mech. Dev.
118, 29-37.[CrossRef][Medline]
Trinh, L. A., Meyer, D. and Stainier, D. Y.
(2003). The Mix family homeodomain gene bonnie and clyde
functions with other components of the Nodal signaling pathway to regulate
neural patterning in zebrafish. Development
130,4989
-4998.
Warga, R. M. and Nusslein-Volhard, C. (1999).
Origin and development of the zebrafish endoderm.
Development 126,827
-838.[Abstract]
Westerfield, M. (1994). The
Zebrafish Book. Eugene OR: Institute of Neurosciences, University
of Oregon.
Whitman, M. and Melton, D. A. (1992).
Involvement of p21ras in Xenopus mesoderm induction.
Nature 357,252
-254.[CrossRef][Medline]
Yasuo, H. and Lemaire, P. (1999). A two-step
model for the fate determination of presumptive endodermal blastomeres in
Xenopus embryos. Curr. Biol.
9, 869-879.[CrossRef][Medline]
Zhang, J., Talbot, W. S. and Schier, A. F.
(1998). Positional cloning identifies zebrafish one-eyed pinhead
as a permissive EGF-related ligand required during gastrulation.
Cell 92,241
-251.[CrossRef][Medline]
Zhao, J., Cao, Y., Zhao, C., Postlethwait, J. and Meng, A.
(2003). An SP1-like transcription factor Spr2 acts downstream of
Fgf signaling to mediate mesoderm induction. EMBO J.
22,6078
-6088.[CrossRef][Medline]
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