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Molecular and Cellular Biology, March 2000, p. 2228-2238, Vol. 20, No. 6
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Interaction of Dishevelled and Xenopus
Axin-Related Protein Is Required for Wnt Signal Transduction
Keiji
Itoh,
Alena
Antipova,
Marianne J.
Ratcliffe, and
Sergei
Sokol*
Department of Microbiology and Molecular
Genetics, Harvard Medical School, and Molecular Medicine Unit, Beth
Israel Deaconess Medical Center, Boston, Massachusetts 02215
Received 13 September 1999/Returned for modification 18 October
1999/Accepted 21 December 1999
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ABSTRACT |
Signaling by the Wnt family of secreted proteins plays an important
role in animal development and is often misregulated in carcinogenesis.
Wnt signal transduction is controlled by the rate of degradation of
-catenin by a complex of proteins including glycogen synthase kinase
3 (GSK3), adenomatous polyposis coli, and Axin. Dishevelled is required
for Wnt signal transduction, and its activation results in
stabilization of -catenin. However, the biochemical events
underlying this process remain largely unclear. Here we show that
Xenopus Dishevelled (Xdsh) interacts with a
Xenopus Axin-related protein (XARP). This interaction
depends on the presence of the Dishevelled-Axin (DIX) domains in both XARP and Xdsh. Moreover, the same domains are essential for signal transduction through Xdsh. Finally, our data point to a possible mechanism for signal transduction, in which Xdsh prevents -catenin degradation by displacing GSK3 from its complex with XARP.
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INTRODUCTION |
A central problem of molecular and
cell biology is to understand how an extracellular signal is
transmitted from the cell surface to the nucleus. One essential
signaling pathway is the Wnt pathway, which controls cell fate and cell
proliferation in embryonic development and is frequently activated
during carcinogenesis (6, 41, 43). In vertebrate embryos,
the Wnt signaling pathway is involved in specification of the
dorsoventral axis (15, 35, 56). Ectopic Wnt signaling in
Xenopus laevis leads to the activation of genes that are
normally expressed in the dorsal signaling center, known as the Spemann
organizer, resulting in the formation of a complete secondary body axis
(32, 52, 53). Inhibition of this pathway at different levels
abolishes the response to Wnt ligands and leads to deficient dorsal
development (ventralization), providing a unique model system for
signal transduction studies (2, 17, 34, 67, 68).
The canonical Wnt pathway is initiated by the interaction of Wnts with
the Frizzled family of seven-transmembrane-domain receptors (6). The cytoplasmic protein Dishevelled (Dsh) is necessary to relay the signal further downstream, leading to an increase in the
cytoplasmic level of -catenin. In the absence of Wnt signaling, -catenin is degraded by the complex of glycogen synthase kinase 3 (GSK3) (42, 66), the adenomatous polyposis coli (APC) gene product (43), PP2A (20, 50), and Axin (14,
61, 68). Wnt signaling leads to stabilization of -catenin and
its translocation to the nucleus (6, 8). In the nucleus,
-catenin forms a complex with transcription factors of the T-cell
factor family and activates target gene expression (2, 5, 21, 34, 58).
Although Dsh is required for the cellular response to Wnt signals, the
mechanism by which Dsh stabilizes -catenin has not been elucidated.
Dsh has three conserved protein domains. The DIX (Dishevelled-Axin)
domain of Dsh is similar to the C-terminal domain of Axin (6,
68). Another conserved domain of Dsh belongs to the family of PDZ
domains, which are found in many proteins interacting with
transmembrane receptors and/or the cytoskeleton (45). The
DEP domain of Dsh is also found in several proteins regulating
G-protein signaling (44) and was recently proposed to be
responsible for Jun kinase activation and for establishment of planar
cell polarity (1, 4, 29). Thus, Dsh is a multidomain protein
that is likely to function in different signal transduction pathways.
Dsh may operate by inhibiting the function of Axin, a negative
regulator of the pathway. Mice with a mutation in the Fused locus that
encodes Axin often develop duplicated embryonic axes, indicating that
Axin is an inhibitor of dorsal development in vertebrates (11, 24,
68). Axin contains two conserved protein domains: the RGS domain,
found in some regulators of G-protein signaling, and the C-terminal DIX
domain with similarity to Dsh (68). When overexpressed in
frog embryos, Axin inhibits dorsal development and blocks the ability
of Xwnt8 to induce a secondary body axis. In contrast, a putative
dominant-negative form of Axin, lacking the RGS domain, mimics Wnt
signaling and dorsalizes the embryo, consistent with the proposed
suppressive role for Axin in dorsal development (68).
Biochemical studies have shown that Axin and a related protein,
Axil/Conductin, occupy a central position in Wnt signal transduction and form a complex with GSK3 and -catenin in tissue culture cells (3, 16, 22, 38, 47, 62) and in Xenopus embryos
(23). GSK3 is an essential negative regulator of the pathway
(66). When the GSK3-binding domain of Axin is deleted, it is
no longer able to inhibit axial development (23).
Furthermore, the RGS domain of Axin was shown previously to interact
with APC (3, 16, 25, 38). In the absence of the RGS domain,
Axin behaves as a dominant-negative mutant (68) and fails to
bind -catenin in the embryo (23). These results suggest
that Axin operates by allowing GSK3 to phosphorylate its putative
substrate, -catenin. Thus, a large protein complex of Axin, APC, and
GSK3 functions to promote the phosphorylation and degradation of
-catenin.
In a Saccharomyces cerevisiae two-hybrid screen for proteins
interacting with Xenopus Dishevelled (Xdsh), we identified a cDNA encoding a novel maternally encoded Xenopus
Axin-related protein (XARP). Here we establish the biochemical
association of XARP and Xdsh and define their interacting domains. We
propose that the DIX domain of XARP is subject to regulation by Dsh and is essential for Wnt signal transduction. Our data suggest that, upon
binding to XARP, Xdsh causes the release of GSK3 from the complex with
XARP, thus providing a possible mechanism for Wnt signal transduction.
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MATERIALS AND METHODS |
Isolation of the XARP cDNA.
Proteins interacting with Xdsh
were isolated in a yeast two-hybrid screen, according to the method of
Gyuris et al. (13). In brief, a Xenopus gastrula
cDNA expression library was constructed in the yeast pJG4-5 vector that
is inducible by galactose and contains a transcriptional activation
domain. The bait contained the fusion of the LexA DNA-binding domain
and full-length Xdsh in the pEG202 vector. The bait and the library
were transformed into the EGY48 yeast strain, which requires leucine
for growth. Positive colonies were selected by growth in a leucine-free
medium and on X-Gal
(5-bromo-4-chloro-3-indolyl--D-galactopyranoside)-containing plates as described previously (13). Plasmid DNA was
recovered from positive yeast colonies and sequenced. Two positive
colonies contained inserts encoding 212 amino acids with similarity to the C terminus of the Axin protein. A full-length XARP cDNA was isolated by probing a Xenopus ovary cDNA 
ZAP library
(27) with a short fragment of the XARP cDNA using standard
procedures (49). pBluescript plasmids with the XARP cDNA
inserts were rescued from the positive phage by an in vivo excision
protocol (Stratagene). Both DNA strands of the XARP cDNA were sequenced
using a 373A DNA sequencer (Applied Biosystems, Inc.).
DNA constructs.
To construct Myc-XARP and
XARP-cyanfluorescent protein (XARP-CFP), the 2.5-kb XARP cDNA insert,
encoding amino acids 40 to 706 of XARP, was isolated from XARP-pBSSK
digested with NcoI and XhoI and ligated in frame
into pCS2-MT (57) or pECFP-C1 (Clontech). Other fragments of
XARP cDNA were subcloned in frame into pXT7-Myc and pXT7-HA vectors (S. Sokol, unpublished data) to generate XARP
DIX, encoding amino acids
40 to 584 of XARP, XARPRGS (amino acids 266 to 706), XARPRGSC
(amino acids 266 to 394), and XARP-C (amino acids 506 to 706), using
available restriction enzyme sites. Myc-Xdsh-pCS2 and Myc-Xdd1-pCS2
were described previously (55). Hemagglutinin (HA)-tagged
Xdsh constructs were obtained by in-frame subcloning of full-length
Xdsh cDNA into the pXT7-HA vectors. Truncated Xdsh variants were
constructed using PstI (for Xdsh-A), SmaI (for
Xdsh-Ab), BglII (for Xdsh-BC), and XhoI (for
Xdsh-C and Xdsh-AB) sites. Xdsh-yellow fluorescent protein (Xdsh-YFP)
was constructed by fusing the YFP insert (Clontech) to the 3' terminus
of the Xdsh cDNA by using the NcoI site next to the start
codon of YFP and the third NcoI site in Xdsh (obtained by
partial digestion). This construct lacks the C-terminal 12 amino acids
of wild-type Xdsh. Further details of plasmid construction are
available on request.
Embryo culture and analysis, RNA microinjections, and
localization studies.
Capped synthetic RNAs were generated by in
vitro transcription with Sp6, T7, and T3 RNA polymerases
(28), using the mMessage mMachine kit (Ambion). Eggs and
embryos were obtained from Xenopus females and cultured in
0.1× Marc's modified Ringer's medium (MMR) as described previously
(39). Embryonic stages were determined according to the work
of Nieuwkoop and Faber (40). For microinjection, embryos
were transferred to 3% Ficoll in 0.5× MMR and injected at the four-
to eight-cell stage with 10 nl of a solution containing 0.5 to 1 ng of
RNA, unless specified otherwise. Injections were carried out in one
ventral blastomere for secondary axis induction, two dorsal blastomeres
for assaying the ventralizing activity of XARP, and all four
blastomeres for protein analysis. Embryonic phenotypes were scored
morphologically at the equivalent of stage 36. The results are combined
for at least three independent experiments.
For subcellular localization studies, mRNAs encoding XARP-CFP and/or
Xdsh-YFP (1 ng each) were injected into the animal pole of two-cell
embryos. At stage 9 to 10.5, animal caps were dissected, fixed in 4%
paraformaldehyde in phosphate-buffered saline (PBS) for 30 min, washed
three times in PBS, and mounted in 70% glycerol-PBS supplemented with
25 mg of DABCO [diazabicyclo(2,2,2)-octane; Sigma] per ml.
Fluorescence was visualized using a Zeiss Axiophot microscope with an
Omega XF102 filter for CFP, an XF22 filter for GFP, and an XF30 filter
for YFP visualization.
Immunoprecipitations and Western blot analysis.
Injected
embryos were lysed in 500 µl of lysis buffer (1% Triton X-100, 50 mM
Tris-HCl at pH 7.5, 50 mM NaCl, 1 mM EDTA, 0.1 mM phenylmethylsulfonyl
fluoride, 10 mM NaF, 1 mM Na3VO4) when sibling
embryos had developed to late blastula to early gastrula stages (stage
9+ to stage 10+). Immunoprecipitation and
Western blot analysis were carried out as described previously
(23). For immunoprecipitations, 20 µl of 9E10 (anti-Myc)
or 12CA5 (anti-HA) hybridoma supernatants was used per each sample. The
equivalent of 0.14 embryo was loaded per lane for analysis of embryo
lysates, and the equivalent of 4 to 24 embryos was used for analysis of
immunoprecipitated proteins. GSK3 was detected by monoclonal antibodies
from Transduction Labs, and APC was detected with antibodies from
Oncogene Research Products. Peroxidase activity was visualized by
enhanced chemiluminescence as described previously (10).
When necessary, membranes were stripped for 15 min in 7 M
guanidine-HCl-50 mM Tris-HCl (pH 8.0)-20 mM dithiothreitol-2 mM EDTA
and reprobed with different antibodies. Each experiment was repeated at
least three times.
Nucleotide sequence accession number.
The sequence of the
XARP cDNA was deposited in GenBank (accession no. AF140243).
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RESULTS |
Dsh associates with XARP, a novel maternal Xenopus
homologue of Axin.
In a yeast two-hybrid screen for proteins
interacting with Xdsh, we isolated a short cDNA fragment encoding a
novel XARP. Repeated screening of a Xenopus ovary cDNA
library with the XARP cDNA probe resulted in the isolation of a 3.0-kb
XARP cDNA, which contained an open reading frame of 706 amino acids. At
the amino acid level, XARP is 45% similar to mouse Axin
(68) and 50% similar to rat Axil (62). Sequence
alignment of XARP and other Axin homologues (Fig.
1) reveals the conserved RGS domain and
the DIX domain, as well as the regions required for binding of GSK3 and -catenin (3, 22, 38, 62). A Drosophila
melanogaster Axin homologue is approximately 25% similar to both
XARP and mAxin (14). XARP has only 43% similarity to the
recently cloned Xenopus Axin (18). Thus, based on
the analysis of their amino acid sequences, XARP, Axin, and
Axil/Conductin are not orthologues but clearly belong to the same
protein family.
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FIG. 1.
Sequence alignment of XARP, mouse Axin, and rat Axil.
(A) Deduced amino acid sequences for XARP, mouse Axin (68),
and rat Axil (62) were compared using the PILEUP program of
the GCG software package. The RGS domain, the DIX domain, and the GSK3-
and -catenin-binding domains are indicated. (B) Conservation of
different protein domains in XARP. A bar at the C terminus of XARP
indicates the position of the XARP fragment that associated with Xdsh
in the two-hybrid screen.
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Since the XARP cDNA was isolated from an ovary cDNA library, XARP may
be present maternally. Both maternal and zygotic XARP
transcripts of
approximately 3.5 kb in size were detected by Northern
analysis (data
not shown), consistent with the idea that XARP
plays a role in early
dorsoventral axis specification. Functional
activity of XARP was
evaluated by microinjecting XARP mRNA into
Xenopus early
embryos. Similar to mouse Axin (
68), XARP inhibited
axial
development when overexpressed in dorsal blastomeres (Fig.
2A). Furthermore, a truncated form of
XARP, lacking the RGS domain
(XARP
RGS), induced a complete secondary
body axis in the embryo
(Fig.
2B). XARP
RGS thus appears to have a
dominant-negative effect
that is opposite to the ventralizing activity
of the wild-type
XARP. These findings suggest that XARP and Axin
function similarly
in dorsoventral axis determination.
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FIG. 2.
Functional activities of XARP constructs. (A) Inhibition
of dorsal axial development by XARP. Both dorsovegetal blastomeres of
four- to eight-cell embryos were injected with 2 ng of XARP mRNA and
allowed to develop until control siblings reached stage 36. An
uninjected embryo is shown at the bottom. (B) Axis duplication caused
by a truncated form of XARP lacking the RGS domain. Two nanograms of
Myc-XARPRGS mRNA was injected into a ventrovegetal blastomere of
four- to eight-cell embryos.
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Biochemical interactions of XARP and Xdsh.
To confirm the
biochemical association of Xdsh and XARP that was inferred from the
yeast system, we tagged both proteins with different peptide epitopes
(36) for immunoprecipitation analysis. Xenopus
embryos were coinjected with mRNAs encoding HA-tagged Xdsh and
Myc-tagged XARP (Fig. 3). At the early
gastrula stage, protein complexes were precipitated from embryo lysates
with anti-HA monoclonal antibodies. Western blot analysis with anti-Myc
antibodies revealed the presence of Myc-XARP in the complex. In the
absence of HA-Xdsh, Myc-XARP was not detected, illustrating the
specificity of interactions between Xdsh and XARP (Fig. 3). Moreover,
the association of XARP with Xdsh was dose dependent, and the complex was detected only weakly at lower doses of HA-Xdsh RNA (data not shown). These experiments reveal that Xdsh and XARP interact
biochemically and form a complex in gastrula lysates.
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FIG. 3.
Coprecipitation of Xdsh and XARP. Each blastomere of
four-cell embryos was injected with 2 to 4 ng of mRNAs, encoding
Myc-XARP, Myc-XARPDIX, and HA-Xdsh, as indicated. (A) Association of
Xdsh and XARP was revealed by immunoprecipitation of Xdsh with anti-HA
antibodies followed by Western analysis with anti-Myc antibodies.
Myc-XARP, but not Myc-XARPDIX, coprecipitated with HA-Xdsh. The same
membrane was stripped and probed with anti-HA antibodies. (B) Levels of
protein expression are shown in corresponding embryo lysates.
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The DIX domains mediate the association of XARP and Xdsh.
Initially, our two-hybrid screen resulted in the isolation of a small
C-terminal fragment of XARP that can bind Xdsh in yeast. Since the DIX
domain was the major conserved domain in the isolated fragment, we
suspected that it might be essential for XARP-Xdsh interactions. The
removal of the DIX domain in XARP impaired its ability to associate
with Xdsh (Fig. 3 and 4A), demonstrating that this domain is required for the association of XARP and Xdsh. Moreover, the XARP-C construct encoding the DIX domain of XARP with the
adjacent sequences was able to bind Xdsh on its own (Fig. 4B),
consistent with the ability of a similar construct to interact with
Xdsh in a two-hybrid assay (data not shown).
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FIG. 4.
The association of Xdsh and XARP is mediated by the DIX
domains. (A) Constructs of XARP and Xdsh used in this study. (B to D)
Each blastomere of four-cell embryos was injected with mRNAs, encoding
different tagged XARP and Xdsh constructs, as indicated.
Immunoprecipitation (IP) with tag-specific antibodies was followed by
Western analysis. Middle panels of each figure show relative protein
expression levels in embryo lysates. Bottom panels show equal
efficiency of immunoprecipitation with anti-HA antibodies. (B) The DIX
domain of XARP binds Xdsh. Myc-Xdsh coprecipitated with HA-XARP-C but
not with HA-XARPRGSC. A weak band of Xdsh was occasionally
observed due to nonspecific binding of Xdsh to protein A-Sepharose. (C)
The DIX domain of Xdsh is required for binding of XARP. Myc-XARP
coprecipitated with HA-Xdsh, but not with HA-Xdsh-C, or HA-Xdsh-BC,
lacking the DIX domain. (D) A truncated Xdsh (Xdsh-Ab) that lacks the
DEP domain and the C-terminal half of the PDZ domain can bind XARP.
HA-XARPRGS coprecipitates with Myc-Xdsh-Ab, whereas the binding of
Xdsh-A and Xdsh-C is not detectable.
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To determine which domain of Xdsh is involved in binding of XARP, a
Myc-tagged XARP was overexpressed in frog embryos together
with
truncated HA-tagged Xdsh constructs (Fig.
4A). Protein complexes
containing Xdsh were immunoprecipitated with anti-HA antibodies,
and
the presence of Myc-XARP was assessed with anti-Myc antibodies.
We
detected XARP in complex with the wild-type Xdsh, but not with
Xdsh
lacking the DIX domain, indicating that the DIX domain of
Xdsh is
required for its association with XARP (Fig.
4C). Moreover,
in a
similar experiment, the N-terminal part of Xdsh (Xdsh-Ab),
containing
the DIX domain and a part of the PDZ domain, was sufficient
for this
interaction to occur (Fig.
4D). No significant binding
of XARP was
detected for Xdsh-A, despite the presence of the DIX
domain, suggesting
that adjacent sequences are also required for
efficient binding (Fig.
4D). Together, these findings show that
the DIX domains play an
essential role in the association of Xdsh
and
XARP.
Dsh and XARP colocalize to a punctate cytoplasmic compartment.
Although we demonstrated biochemical association of XARP and Xdsh in
Xenopus embryos, as well as in the yeast system, the physiological relevance of this interaction for Wnt signal transduction was unclear. To assess whether Xdsh interacts with XARP in embryonic cells in vivo, we investigated the subcellular localization of these
proteins (Fig. 5). XARP was tagged with
the CFP, and Xdsh was tagged with the YFP. Embryos were injected with
XARP-CFP mRNA, Xdsh-YFP mRNA, or both mRNAs together at the four-cell
stage, and animal cap explants were analyzed at the late blastula
stage. XARP-CFP was present in bright vesicular structures in the
cytoplasm (Fig. 5C). This was reminiscent of the distribution pattern
reported for Dsh (1, 65), suggesting that Wnt signal
transduction may depend on the localization of some pathway
component(s) in a specific cell compartment. In agreement with this, we
found that Xdsh-YFP showed a similar punctate distribution (Fig. 5B). When expressed together, XARP-CFP and Xdsh-YFP colocalize to the same
vesicular structures (Fig. 5E to G). In contrast, wild-type GFP was
present in both the cytoplasm and the nucleus in a diffuse pattern
(Fig. 5H). These data support our biochemical data showing that Xdsh
and XARP associate in embryonic cells.
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FIG. 5.
XARP colocalizes with Xdsh in Xenopus animal
caps. Embryos were injected into the animal hemisphere with mRNAs
encoding XARP and Xdsh that contain a fluorescent protein tag. The
subcellular protein distribution was assessed by fluorescence in fixed
animal pole cells. Xdsh-YFP is localized in a punctate pattern
throughout the cell (B). This signal is not detectable through the CFP
channel (A). XARP-CFP shows a similar distribution when monitored on
the CFP channel (C) but not on the YFP channel (D). Coinjection of
Xdsh-YFP and XARP-CFP RNAs results in colocalization of YFP (E and G)
and CFP (F and G) fluorescence. Panel G shows a double exposure of
panels E and F. Arrows point to three clear instances of
colocalization. GFP alone is distributed evenly throughout the
cytoplasm and nucleus (H). Bar, 40 µm.
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We have also observed that the DIX domain of XARP is essential for its
localization to the vesicular structures, since removal
of the DIX
domain from GFP-XARP eliminated the punctate staining
(data not shown).
Moreover, overexpression of Xdsh mRNA at higher
doses (2 to 4 ng)
disrupted the punctate distribution of GFP-XARP,
and this effect
depended on the presence of the DIX domain in
Xdsh (data not shown).
These studies provide independent evidence
for functional interactions
of Xdsh and XARP in
vivo.
The DIX domain of Xdsh is required for its functional
activity.
Since our experiments indicated that the association of
XARP and Xdsh requires intact DIX domains, we wanted to test whether these domains are functionally involved in transduction of Wnt signals.
If the DIX domain of Dsh is involved in Wnt signal transduction, Xdsh
lacking this domain should not be able to induce a secondary axis when
injected into a ventral blastomere, as was reported for the wild-type
Xdsh (54). Consistent with this prediction, all embryos
injected with Xdsh-BC, in which the DIX domain was deleted, developed
normally (n = 84), whereas the wild-type Xdsh induced a
complete secondary axis in 76% of injected embryos (n = 86) (Fig. 4A and 6A and B). Western
analysis of embryo lysates with anti-HA antibodies confirmed equal
protein expression levels for Xdsh and Xdsh-BC (data not shown). Thus,
the DIX domain of Xdsh is essential for the functional activity of the
protein. Although both Xdd1 and Xdsh-Ab can bind XARP (Fig. 4A and D;
see also Fig. 7B and C), they are unable to induce secondary axes (reference 55 and data not shown), suggesting that
the association of Xdsh and XARP is not sufficient for signal
transduction and that sequences outside of the DIX domain are necessary
for Xdsh to function.
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FIG. 6.
The requirement for the DIX domains of Xdsh and XARP in
signal transduction. Four- to eight-cell embryos were injected into a
single ventrovegetal blastomere with 1 ng of HA-Xdsh mRNA (A) or
HA-Xdsh-BC mRNA (B), 1 pg of Xwnt8 mRNA (C), or 1 pg of Xwnt8 mRNA with
2 ng of XARP-C mRNA (D). Secondary axes and other morphological
abnormalities were scored when uninjected sibling embryos (E) reached
stages 36 to 39. The results show that the DIX domain of Xdsh is
required for its functional activity (A and B), whereas the DIX domain
of XARP blocks Wnt signaling (C to E). Dorsal injections of XARP-C mRNA
(2 ng) do not eliminate the primary axis but suppress morphogenetic
movements in the trunk-tail region (F).
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The DIX domain of XARP blocks Wnt signaling.
Whereas the DIX
domain of Dsh is required for its ability to transduce a signal, the
removal of the DIX domain of Axin or XARP does not impair its ability
to inhibit dorsal development (reference 23 and data
not shown). We therefore hypothesized that this domain of Axin-XARP
functions to receive a signal from Xdsh, a more upstream component of
the Wnt pathway. If the DIX domain of XARP is involved in this process,
it would compete with endogenous XARP for binding to Xdsh, resulting in
inhibition of Wnt signal transduction.
To test this prediction, we evaluated whether a short form of XARP,
containing the DIX domain with adjacent sequences (XARP-C
[Fig.
4A]),
can suppress the ability of ventrally injected Xwnt8
mRNA to induce a
complete secondary axis (
53). Consistent with
our
expectations, we found that XARP-C blocked the axis-inducing
activity
of Xwnt8 (Fig.
6C and D). Whereas Xwnt8 mRNA induced
complete secondary
axes in 90% of injected embryos (
n = 60), the
majority
of embryos coinjected with XARP-C mRNA developed a single
axis, and
only 14.5% of injected embryos were similar to embryos
overexpressing
Xwnt8 (
n = 62). In contrast, Xdsh-A, containing
the DIX
domain of Xdsh, did not inhibit Wnt signaling (data not
shown), in
agreement with our observation that this domain does
not bind XARP on
its own (Fig.
4D) and arguing that the effect
of XARP-C is specific.
These findings suggest that the DIX domain
of XARP is required for Wnt
signal
transduction.
To test the possibility that Wnt signaling upstream of XARP is involved
in dorsoventral axis specification, XARP-C mRNA was
injected into both
dorsal blastomeres of four-cell embryos. We
found that XARP-C did not
inhibit axis development even at the
highest dose of RNA tested (2 to 4 ng) but resulted in embryos
with shortened trunks (Fig.
6F). This
activity is similar to the
effect of a dominant-negative form of Xdsh
that failed to block
dorsal development and yet interfered with
morphogenetic movements
during gastrulation and neurulation
(
55). These data suggest
that XARP is unlikely to be
regulated by Xdsh during initial specification
of the dorsoventral axis
in
Xenopus.
Xdsh displaces GSK3 from the XARP-GSK3--catenin complex.
Whereas the complex of Axin, APC, and GSK3 serves to degrade
cytoplasmic -catenin (43, 56), activation of Dsh by Wnt signaling leads to accumulation of -catenin (6). Our
results suggest that Xdsh may affect interactions of XARP with other
proteins that are present in the same complex and mediate -catenin degradation.
Since the association of GSK3 with Axin appears to be critical for the
ability of Axin to inhibit axial development (
23),
we
evaluated whether Xdsh and GSK3 are present in the same complex
with
XARP or form alternative complexes. Embryos were injected
with Myc-XARP
and HA-Xdsh mRNAs, and protein complexes containing
Xdsh were
precipitated with anti-HA antibodies (Fig.
7). Subsequently,
anti-Myc antibodies
were applied to the same lysates to immunoprecipitate
Myc-XARP protein
complexes not containing Xdsh. Western analysis
of immunoprecipitates
with anti-GSK3 antibodies revealed endogenous
GSK3 in complex with XARP
(Fig.
7A). Thus, XARP, similar to Axin,
associates with GSK3. At the
same time, GSK3 was barely detectable
in the Xdsh-XARP complex,
indicating that Xdsh may function by
displacing GSK3 from the complex
with XARP (Fig.
7A). This finding
is consistent with the hypothesis
that Wnt signaling prevents
-catenin degradation through the
formation of alternative protein
complexes.
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FIG. 7.
GSK3 is not retained in the Xdsh-XARP complex. Embryos
overexpressing HA-Xdsh, HA-Xdd1, HA-Xdsh-Ab, Myc-XARP, and
Flag--catenin, as indicated, were cultured until early gastrula
stages for protein analysis. Each lysate was subjected to two
sequential precipitations, first with anti-HA antibodies and then with
anti-Myc antibodies. Protein complexes were analyzed by immunoblotting
with anti-HA, anti-Myc, anti-GSK3, and anti-Flag antibodies, as
indicated. (A) Protein complexes containing XARP in association with
Xdsh did not significantly bind GSK3, whereas the pool of XARP that is
not bound to Xdsh retained GSK3. (B) The complex of XARP with Xdd1 and
Xdsh-Ab, but not with Xdsh, retained GSK3. Protein levels in
corresponding embryo lysates are shown (A and B). (C) The Xdsh-XARP
complex retains -catenin. The panel on the right shows that the Xdsh
and XARP proteins are not fully depleted from embryo lysates. IP,
immunoprecipitation.
|
|
We next wanted to determine whether this effect of Xdsh on the
association of XARP and GSK3 is causally connected to the ability
of
Xdsh to transduce a signal and stimulate secondary axis formation
in
the embryo. We tested whether Xdd1 and Xdsh-Ab (Fig.
4A), which
do not
induce an axis, form a complex with XARP and GSK3. In contrast
to the
wild-type Xdsh, Xdd1 and Xdsh-Ab failed to release GSK3
from its
complex with XARP, although they retained the ability
to bind XARP
(Fig.
7B). Together, these findings strongly suggest
that the
regulation of GSK3 binding to XARP by Xdsh is essential
for signal
transduction.
The Xdsh-Axin and Xdsh-XARP complexes contain -catenin but not
APC.
We further asked whether -catenin and APC, which can also
bind Axin, were present in the Xdsh-XARP protein complex. In a similar
experimental setup, Flag--catenin (31) was detected at
approximately equal levels both in the Xdsh-XARP complex and in the
complex of XARP with Xdd1 or Xdsh-Ab (Fig. 7C). This finding suggests
that Xdsh does not eliminate the binding of -catenin to XARP.
Similarly, the complex of Xdsh with mouse Axin also contained decreased
amounts of GSK3, but not -catenin (Fig.
8A and data not shown).
View larger version (33K):
[in this window]
[in a new window]
|
FIG. 8.
The comparative analysis of mouse Axin and XARP
properties. (A and C) GSK3 (A) and APC (C) are not well retained in the
Xdsh-mAxin complex in comparison with the Xdd1-mAxin and Xdsh-Ab-mAxin
complexes. The experimental design is similar to the one described in
the Fig. 7 legend. (B) Overexpressed Myc-XARP or Myc-mAxin was
immunoprecipitated with anti-Myc antibodies followed by Western
analysis with anti-APC and anti-Myc antibodies. Xdsh does not
significantly alter the amount of Axin or APC in the complex. In
contrast to mAxin, XARP does not appear to bind endogenous APC. (D)
Axin and XARP can form heterodimers. Myc-mAxin and HA-XARP were
coexpressed in early embryos, and HA-XARP was precipitated with anti-HA
antibodies followed by Western analysis with anti-Myc antibodies.
Binding of GSK3 to XARP is not affected by overexpressed Axin. IP,
immunoprecipitation.
|
|
We also wanted to examine if the association of APC with XARP or Axin
is affected by Xdsh. Unexpectedly, endogenous APC did
not appear to
bind XARP (Fig.
8B), indicating that despite the
structural similarity,
the biochemical properties of XARP and
Axin are different. APC was not
detectable in the Xdsh-mAxin complex
but was retained in the complex of
mAxin with Xdd1 or Xdsh-Ab
(Fig.
8C). These data show that the negative
regulators of Wnt
signaling, GSK3 and APC, are selectively eliminated
from the Xdsh-XARP
and Xdsh-Axin complexes, whereas
-catenin remains
associated
with both XARP and Axin, suggesting a possible mechanism for
Wnt
signal
transduction.
Association of XARP and Axin.
Axin has been reported to
dimerize via its C-terminal region, which includes the DIX domain
(19, 20, 48). Since the C terminus of XARP bears a
significant similarity to Axin, we tested if XARP and Axin can form
heterodimers. Following microinjection of embryos with Myc-mAxin and
HA-XARP mRNAs, HA-XARP-containing protein complexes were precipitated
with anti-HA antibodies for analysis with anti-Myc antibodies. Clear
association of HA-XARP with Myc-mAxin was observed (Fig. 8D).
Since Axin is known to bind GSK3, it is possible that GSK3 associates
with XARP only indirectly, through Axin. Overexpression
of mAxin did
not significantly alter the amount of GSK3 bound
to XARP (Fig.
8D),
indicating that GSK3 binding to XARP is not
likely to be mediated by
Axin. Moreover, the presence of a conserved
GSK3-binding domain in XARP
suggests that XARP can bind GSK3 directly.
In support of this view, a
short construct of XARP, XARP
RGS
C,
encompassing the putative
GSK3-binding domain, was still capable
of binding GSK3 (data not
shown).
| |
DISCUSSION |
In this study, we have found that Dsh associates with
XARP, a Xenopus Axin-related protein, which is not an
orthologue of Axin and yet functions similarly. This interaction,
initially discovered in a yeast two-hybrid system, was confirmed
biochemically in embryonic lysates. In addition, we have demonstrated
colocalization of Xdsh and XARP in embryonic cells in vivo. The
interaction of Xdsh and XARP is mediated predominantly by their DIX
domains, because their removal eliminates binding. Whereas the DIX
domain of Xdsh is required for the ability of Xdsh to transduce a
signal, the DIX domain of XARP is not essential for the activity of
XARP but appears to be important for the regulation of XARP by Xdsh. Finally, our data point to a possible mechanism of signal transduction, in which Xdsh operates by displacing GSK3 from its complex with XARP.
The role of the DIX domains in Wnt signaling.
Our findings
reveal the importance of the DIX domains in Wnt signal transduction. We
have found that the DIX domain of XARP is essential for its
interactions with Xdsh. Furthermore, the DIX domain of Xdsh is also
required for the association of the two proteins, indicating that the
two DIX domains bind each other. Interestingly, recent studies reported
that the C terminus of Axin is capable of homophilic interactions
(19, 20, 48). Furthermore, we observed that XARP can
heterodimerize with Axin (Fig. 8D), although the significance of these
findings is not fully clear. The physiological relevance of
interactions of Xdsh and XARP is supported by our observation that Xdsh
disrupts cytoplasmic localization of GFP-XARP depending on the
expression levels, and this property of Xdsh correlated with the
presence of the Xdsh-DIX domain (data not shown).
The removal of the DIX domain of Xdsh resulted in a complete loss of
the axis-inducing activity of Xdsh (Fig.
6A and B), indicating
that
this domain is required for the ability of Xdsh to transduce
a signal.
This finding corroborates earlier studies in
Drosophila,
in
which Dsh lacking the DIX domain does not elevate the cytoplasmic
levels of Armadillo in tissue culture cells and fails to rescue
dsh embryos (
1,
64). On the other hand, the DIX
domains of
Xdsh and Xdsh-Ab (Fig.
4A) do not have significant
axis-inducing
activity (data not shown), indicating that other regions
of Xdsh
must contribute to the effector function of the
protein.
Since the deletion of the DIX domain of XARP or Axin does not affect
its ability to ventralize frog embryos (reference
23 and data not shown), we hypothesized that this domain is subject
to
regulation by the upstream components of the pathway such as
Dsh. This
hypothesis is strongly supported by our observation
that XARP-C, which
contains the DIX domain with adjacent sequences,
blocked the ability of
Xwnt8 to induce a secondary axis (Fig.
6C and D). Thus, the DIX domain
is not required for functional
activity of XARP but is likely to be
involved in the reception
of a
signal.
In contrast to Xwnt8-induced secondary axis, XARP-C failed to suppress
the primary axis (Fig.
6F), suggesting that endogenous
axis does not
depend on signaling from Xdsh to XARP. Since overexpression
of a
dominant-negative Xdsh resulted in similar embryonic phenotypes
(
55), these observations are consistent with the view that
the
endogenous pathway leading to dorsal development does not seem
to
involve Xdsh. Although maternal Xdsh was reported to be enriched
at the
dorsal side of the embryo (
33), our data fail to provide
additional support for a role of Xdsh in primary axis
specification.
Signal transduction by Dsh and XARP-Axin.
-Catenin appears
to be a central target of Wnt signal transduction (12, 43).
In the absence of Wnt signals, -catenin is degraded by the complex
of Axin, GSK3, and APC. The binding of GSK3 to Axin is essential for
the ability of Axin to ventralize Xenopus embryos
(23). Wnt signaling prevents degradation of -catenin,
which then enters the nucleus and activates target gene expression.
Although Wnt signaling has been shown to require the function of Dsh,
the mechanism by which Dsh regulates signaling was not
clear. Our
findings suggest that Xdsh may function by displacing
GSK3 from the
XARP-GSK3 complex, thereby allowing
-catenin to
escape degradation.
The alternative explanation of these data
is that Xdsh preferentially
associates with the pool of XARP that
is not bound to GSK3. This
possibility seems unlikely, because
other Xdsh constructs, such as Xdd1
and Xdsh-Ab, are able to associate
with the XARP-GSK3 complex,
indicating that the Xdsh-interacting
domain of XARP is accessible even
in the presence of GSK3 (Fig.
7B and
C).
Since Xdd1 lacks the C-terminal half of the PDZ domain (
55),
the PDZ domain may be involved in the regulation of XARP-GSK3
interactions. Consistent with this idea, the removal of the PDZ
domain
abolishes the ability of Dsh to stabilize Armadillo in
Drosophila cells (
64). However, Dsh lacking the
PDZ domain can
suppress the segment polarity phenotype of
dsh flies (
1), indicating
that the PDZ domain may
not be absolutely required for the downstream
function of Dsh and that
other regions of the protein may suffice
in some experimental
situations.
XARP and Axin are indistinguishable in our functional assays,
consistent with the significant conservation of their structural
domains. Despite this similarity, there is a clear difference
in the
biochemical properties, since only Axin, not XARP, binds
endogenous APC
(Fig.
8B). It is thus possible that APC is not
an essential component
of Wnt signal transduction. Alternatively,
since several APC gene
products are known to exist in
Drosophila and mammals
(
37,
59), they may be engaged in specific interactions
with
different Axin homologues. At present, it remains unclear
whether there
is a direct homologue of XARP in mammals. Although
there are multiple
Axin homologues in the human and mouse genome,
the database search did
not reveal a gene that is more closely
related to XARP than to Axin or
Axil/Conductin (data not
shown).
Since Wnt signaling was shown to inhibit the enzymatic activity of GSK3
(
7,
23,
46), it is possible that the association
of Dsh and
Axin inactivates GSK3 and, as a result, lowers the
affinity of GSK3 for
Axin. Consistent with the possible displacement
of GSK3 from the
Axin-XARP-GSK3 complex, Ikeda et al. (
22) observed
that
inactive forms of GSK3 do not bind Axin. Thus, downregulation
of GSK3
activity and the removal of GSK3 from the complex with
Axin-XARP and
-catenin may be coupled. Moreover, the study of
Willert et al.
suggested that phosphorylation of Axin by GSK3
is decreased in response
to Wnt3a (
60). Although Dsh was reported
to stimulate
degradation of Axin in tissue culture (
63), our
experiments
did not reveal significant changes in the amount of
XARP or Axin in
embryos overexpressing
Xdsh.
Our model predicts that the formation of the complex between Xdsh and
XARP-Axin is essential for Wnt signal transduction.
This notion is
supported by recent independent reports of functional
interactions and
colocalization of Dsh and Axin (
9,
26,
30,
51). At present,
we have not detected a significant change in
the amount of Xdsh-XARP or
GSK3-XARP complexes in embryos injected
with Xwnt8 RNA (data not
shown). It is possible that such change
cannot be detected in our
assays, because only a small proportion
of the total pool of Xdsh is
associated with XARP. Moreover, since
Axin-XARP blocks Wnt signaling
(reference
68 and data not shown),
it is likely that
overexpressed XARP easily overcomes the effects
of limiting endogenous
upstream regulators. The analysis of endogenous
proteins will be
necessary to investigate how XARP is controlled
by Wnt signaling and to
clarify a role for XARP in dorsoventral
axis
determination.
| |
ACKNOWLEDGMENTS |
We thank K.-M. Yao and G. Wong for help in the yeast two-hybrid
screen, R. Brent for yeast strains and plasmid vectors, F. Costantini
and X. He for plasmids, and T. Komiya for the Xenopus ovary
cDNA ZAP library. We also thank A. Lugovskoy for help with Fig. 1
and V. Krupnik, J. Weber, M. Fan, and T. Schultheiss for comments on
the manuscript.
This work was supported by the grants from the March of Dimes Birth
Defects Foundation and NIH to S.S.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Microbiology and Molecular Genetics, Harvard Medical School, and
Molecular Medicine Unit, Beth Israel Deaconess Medical Center, 330 Brookline Ave., Boston, MA 02215. Phone: (617) 667-3894. Fax: (617)
667-2913. E-mail: ssokol{at}caregroup.harvard.edu.
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Molecular and Cellular Biology, March 2000, p. 2228-2238, Vol. 20, No. 6
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Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
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