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© The Rockefeller University Press,
0021-9525/2000//567 $5.00
The Journal of Cell Biology, Volume 148, Number 3,
, 2000 567-578
Original Article |
Requirement for β-Catenin in Anterior-Posterior Axis Formation in Mice
wbirch{at}mdc-berlin.de
The anterior-posterior axis of the mouse embryo is defined before formation of the primitive streak, and axis specification and subsequent anterior development involves signaling from both embryonic ectoderm and visceral endoderm. The Wnt signaling pathway is essential for various developmental processes, but a role in anterior-posterior axis formation in the mouse has not been previously established. β-Catenin is a central player in the Wnt pathway and in cadherin-mediated cell adhesion. We generated β-catenin–deficient mouse embryos and observed a defect in anterior-posterior axis formation at embryonic day 5.5, as visualized by the absence of Hex and Hesx1 and the mislocation of cerberus-like and Lim1 expression. Subsequently, no mesoderm and head structures are generated. Intercellular adhesion is maintained since plakoglobin substitutes for β-catenin. Our data demonstrate that β-catenin function is essential in anterior-posterior axis formation in the mouse, and experiments with chimeric embryos show that this function is required in the embryonic ectoderm.
Key Words: anterior visceral endoderm • Wnt/wingless pathway • cell adhesion • plakoglobin • armadillo
© 2000 The Rockefeller University Press
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Introduction |
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Protein stability of β-catenin is controlled through Wnt/wingless signaling. Wnt/wingless activates frizzled receptors, and through dishevelled, induces an increase in cytoplasmic β-catenin by preventing its degradation in proteasomes (for review see Cadigan and Nusse 1997). The proteins axin and/or conductin, in cooperation with the tumor suppressor gene product adenomatous polyposis coli, are involved in the control of β-catenin degradation, which depends on serine-threonine phosphorylation of β-catenin by GSK3β and subsequent ubiquitination (Rubinfeld et al. 1996; Yost et al. 1996; Aberle et al. 1997; Zeng et al. 1997; Behrens et al. 1998; Ikeda et al. 1998; Jiang and Struhl 1998). The increased levels of β-catenin allow interaction with transcription factors of the lymphoid enhancer factor (LEF)/T-cell factor (TCF) family and activation of gene expression (Behrens et al. 1996; Huber et al. 1996; Molenaar et al. 1996; He et al. 1998; Tetsu and McCormick 1999). In Xenopus, target genes of this pathway such as Siamois, Twin, and goosecoid have been identified, which play a role in axis formation (Heasman et al. 1994; Brannon et al. 1997; Fan and Sokol 1997; Laurent et al. 1997). In addition, inactivating mutations of adenomatous polyposis coli or activating mutations of β-catenin, which result in constitutive nuclear signaling and gene activation, have been identified in tumor progression (Morin et al. 1997; Rubinfeld et al. 1997; He et al. 1998; Tetsu and McCormick 1999; for review see Polakis 1999).
β-Catenin contains repeated elements, the armadillo repeats, that are flanked by unique NH2- and COOH-terminal domains (McCrea et al. 1991; Peifer 1993; Huelsken et al. 1994a). The central armadillo repeats of β-catenin bind directly to the LEF/TCF transcription factors, and the COOH-terminal domain of β-catenin largely mediates transcriptional activation (Behrens et al. 1996; van de Wetering et al. 1997; Vleminckx et al. 1999). β-Catenin is also located in adherens junctions, where it binds cadherins through the armadillo repeats and establishes a link to the cytoskeleton via NH2-terminally bound 
-catenin (Butz and Kemler 1994; Hinck et al. 1994; Huelsken et al. 1994b; Aberle et al. 1996; Nieset et al. 1997). Plakoglobin, the closest relative of β-catenin in vertebrates, can also bind cadherins and -catenin, and in addition, mediates the interaction between desmosomal cadherins and the intermediate filament system (Huelsken et al. 1994b; Troyanovsky et al. 1994; Sacco et al. 1995; Kowalczyk et al. 1997). Ablation of mouse genes that encode components of the cadherin–catenin system results in adhesion defects during embryogenesis: in E-cadherin– and -catenin–deficient embryos, the epithelium of the trophectoderm disintegrates at the blastocyst stage (Larue et al. 1994; Riethmacher et al. 1995; Torres et al. 1997). Plakoglobin-deficient embryos exhibit abnormal adhesion of myocardial cells that result in heart rupture at midgestation (Ruiz et al. 1996). At late gestation, adhesion defects are also observed in the skin of plakoglobin-deficient mice (Bierkamp et al. 1996).
We report here the effect of β-catenin–null mutations in mice. In embryos that lack β-catenin, we observe a block in anterior-posterior axis formation at E6.0. At this stage, cerberus-like and Lim1 expressing cells are mislocated in the distal visceral endoderm, and other anterior markers like Hex and Hesx1 are not induced. Subsequently, no mesoderm and head structures are formed, and the mutant embryos retain the differentiation of the early egg cylinder stage but continue to grow. Using chimeric embryos, we show that β-catenin function is required in the embryonic ectoderm. β-Catenin–deficient embryos contain well-developed adherens junctions, in which plakoglobin substitutes for β-catenin. In analogy to Xenopus and zebrafish, the observed block in axis formation of β-catenin–deficient mouse embryos appears to reflect a signaling function of β-catenin.
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Materials and Methods |
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GEM-12 129/Ola library were introduced into the pTV0 vector (Riethmacher et al. 1995). The β-catdel vector contained at the 5' arm genomic sequence from the end of the first intron to the beginning of the third exon, i.e., encodes only for the first 14 amino acids of β-catenin. The 3' arm contained exons 5 to 16. Targeting vector β-catlacZ contained a β-galactosidase cDNA with a nuclear localization signal fused to the ATG translation initiation codon of β-catenin. The 3' arm contained sequences from the end of the sixth intron to exon 16. In the vector β-catlacZ(hyg), neomycin was replaced by a hygromycin resistance cassette. Homozygous mutant embryonic stem (ES) cells were generated by the consecutive electroporation of the two targeting vector variants, β-catlacZ(neo) and β-catlacZ(hyg). Two independent, heterozygous ES cell clones (derived from E14 ES cell line) for the loci β-catdel and β-catlacZ(neo) were used to generate chimeric mice by blastocyst injection as described (Riethmacher et al. 1995). Heterozygous mutant animals were bred on a mixed 129xC57Bl6 background, and showed no developmental abnormalities. PCR genotyping was performed using the primers TGG CTT CTT CAG GTA GCA TTT TCA GTT C, CAT TCA TAA AGG ACT TGG GAG GTG T, and GCC TTC TAT CGC CTT CTT GAC G (β-catdel), or CAT GGA CAG GGG TGG CCT GA, TGT TTT TCG AGC TTC AAG GTT CAT, and AGA ATC ACG GTG ACC TGG GTT AAA (β-catlacZ).
Microscopic Analysis and In Situ Hybridization
β-Galactosidase staining of embryos, immunofluorescence analysis, and EM were performed as described (Hogan et al. 1994; Huelsken et al. 1994b; Riethmacher et al. 1995; Varlet et al. 1997). Embedding in paraffin or plastic was performed according to the manufacturer's protocols (Paraplast, Sherwood Medical; Technovit 7100, Kulzer Heraeus). Sections were stained with hematoxylin/eosin or 0.1% pyroninG (for lacZ-stained embryos). Size and proliferation of embryos between E5.5 and E7.5 were quantified by counting total numbers of embryonic cells and metaphases on consecutive 4,6-diamidino-2-phenylindole–stained sections. In situ hybridizations with digoxygenin-labeled RNA probes (Ding et al. 1998; Liu et al. 1999) were performed according to the manufacturer's protocols (Boehringer Mannheim) followed by PCR genotyping. For immunogold labeling, embryos were embedded in Unicryl (British BioCell Int.), and semithin sections were used for orientation, followed by immunocytochemical labeling of ultrathin sections with antiplakoglobin antibody and 12 nm colloidal gold goat anti–rabbit IgG (Jackson ImmunoResearch Inc.). Sections were contrasted with uranyl acetate and lead citrate.
Generation of Chimeric Embryos
Aggregation chimeras were generated from wild-type embryos and embryos obtained from crossing heterozygous β-catlacZ and β-catdel mutant mice as described (Hogan et al. 1994). Injection chimeras were produced either by injection of wild-type blastocysts with heterozygous or homozygous β-catlacZ ES cells or by injection of blastocysts obtained from crossing heterozygous β-catlacZ and β-catdel mice with wild-type ES cells (Riethmacher et al. 1995). For high or low ES cell contribution, 
20 or 5 ES cells were injected, respectively. 50 embryos were produced by either method, and three of the most advanced chimeric embryos between E8.0 and E9.5 were analyzed in detail by sectioning. Mutant cells were detected by β-galactosidase staining, followed by PCR genotyping of blue cells for the additional presence of the β-catdel allele.
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-catenin were observed in wild-type and mutant embryos at E7.0 (Fig. 7, a and b; data not shown). On an ultrastructural level, intact adherens junctions and desmosomes were detected (Fig. 7e and Fig. g; data not shown). In wild-type embryos, plakoglobin, the closest relative of β-catenin in the armadillo family, is localized preferentially in desmosomes and distributed in a spotty pattern along the membrane (Fig. 7 c; data not shown). In contrast, in homozygous mutant embryos, plakoglobin was detected in increased amounts and was distributed uniformly along the membrane (Fig. 7 d). Immunogold localization confirmed redistribution of plakoglobin to lateral membranes in the mutant embryos (Fig. 7f and Fig. h). Thus, plakoglobin appears to substitute for β-catenin in adherens junctions of mutant embryos. In vitro data had shown earlier that plakoglobin can mediate the interaction between E-cadherin and -catenin (Huelsken et al. 1994b).
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Discussion |
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In Xenopus, the role of β-catenin and the Wnt pathway in body axis formation and dorso-anterior specification has been well-established (Funayama et al. 1995; Harland and Gerhart 1997; Heasman 1997; Moon and Kimelman 1998). Axis formation precedes gastrulation as indicated by the enrichment of endogenous β-catenin in nuclei on the prospective dorso-anterior side of the blastula (Schneider et al. 1996; Larabell et al. 1997), and a block of β-catenin expression results in failure of axis development (Heasman et al. 1994). β-Catenin is required as a signaling molecule in this process, since a fusion protein consisting of the DNA-binding domain of the transcription factor LEF-1 and the COOH-terminal transcriptional activation domain of β-catenin is sufficient to induce an additional axis in the frog (Vleminckx et al. 1999). Also in zebrafish, signaling mediated by β-catenin and the Wnt pathway is essential for embryonic axis formation (Nasevicius et al. 1998; Peleari and Maischein 1998; Sumoy et al. 1999). Our ablation of the β-catenin gene in the mouse produced a defect in anterior-posterior axis formation at E6, i.e., earlier than gastrulation. Moreover, goosecoid, a target gene of β-catenin–mediated signaling in Xenopus (Laurent et al. 1997; Peleari and Maischein 1998; Roeser et al. 1999), is not expressed in β-catenin–deficient mouse embryos. Therefore, we suggest that in the mouse β-catenin is also required as a signaling molecule for anterior-posterior axis formation. Interestingly, Engrailed2 has been also characterized as a target gene of β-catenin–mediated signaling in Xenopus (McGrew et al. 1999), and we found that the related gene Engrailed1 is not expressed in β-catenin–deficient embryos. β-Catenin function at the egg cylinder stage may depend on interaction with high mobility group box transcription factors such as LEF-1 or TCF3, which are expressed at this stage (Roose 1999). A genetic analysis of the mouse TCF3 function has not been reported; other LEF/TCF family members function during later developmental stages (van Genderen et al. 1994; Verbeek et al. 1995; Korinek et al. 1998). Another mutation of the β-catenin gene in mice was reported previously (Haegel et al. 1995), but anterior-posterior axis formation was not examined in these mutants.
The phenotype of β-catenin–deficient embryos is distinct from other mutant mice that display a defective anterior-posterior axis. Mutations in Smad2, Smad4, or ActRIB, which block signaling of members of the transforming growth factor (TGF) β family, affect embryonic differentiation at the egg cylinder stage before gastrulation (Gu et al. 1998; Sirard et al. 1998; Waldrip et al. 1998; Weinstein et al. 1998). In the absence of Smad2, cerberus-like is not expressed, and the epiblast exclusively forms extraembryonic mesoderm (Waldrip et al. 1998), indicating that Smad2 is required for the initial generation of anterior-posterior organizing centers. This phenotype is more severe than the β-catenin mutant, and suggests that signaling of members of the TGFβ/BMP family may precede or cooperate with the β-catenin–dependent pathway. In cripto–/– embryos, the anterior-posterior axis is initially formed but mislocated, i.e., both Hex and cerberus-like are expressed distally, whereas Lim1 is expressed proximally. Anterior neuroectoderm forms at the distal end of the embryo, as assessed by the expression of Hesx1 (Ding et al. 1998). This is a less severe phenotype than that observed in β-catenin–deficient embryos, which also show mislocalization of anterior visceral endoderm markers but completely lack subsequent anterior or posterior differentiation. Hex and Hesx1 are not expressed in β-catenin–deficient embryos, suggesting that induction of these genes may depend on β-catenin (Zorn et al. 1999). These data indicate that β-catenin may operate earlier than or cooperate with EGF–cripto, Frl-1, and cryptic (CFC) molecules. Consistent with this, Wnt and β-catenin signaling does not rescue an oep/cripto mutant phenotype in zebrafish (Gritsman et al. 1999). Moreover, gene ablation has shown that Wnt3 is essential for formation or maintenance of the primitive streak (Liu et al. 1999). Wnt3 is not essential for the formation of the anterior organizing center, since anterior visceral endoderm markers are localized correctly in Wnt3-deficient embryos, but no further anterior or posterior differentiation was observed. Hypomorphic mutations of axin, which functions as a negative regulator in the Wnt pathway by reducing β-catenin stability (Zeng et al. 1997; Behrens et al. 1998), and overexpression of chicken Wnt8 in the mouse cause duplication of the posterior axis, i.e., a second primitive streak (Zeng et al. 1997; Poepperl et al. 1997). Taken together, these data indicate that signaling by members of the Wnt pathway plays a role for at least two different steps during axis formation in the mouse: (a) for the establishment of initial anterior-posterior polarity (as detected in our β-catenin mutants); and (b) for the formation of posterior structures such as the primitive streak (as found in the Wnt3 mutants) (Liu et al. 1999). β-Catenin and Wnt3 mutants both lack mesoderm and anterior neural ectoderm, probably due to an essential function of β-catenin in Wnt3-dependent signaling. It is not known which Wnt genes require β-catenin during the initial formation of polarity in the mouse; several Wnt genes are expressed during early stages of mouse embryogenesis (Gavin et al. 1990; McMahon et al. 1992; Bouillet et al. 1996), and might take over important, possibly partially redundant functions. However, β-catenin–mediated signaling is not required for the general specification of all embryonic axes, since markers for the proximal-distal axis like Oct4 and BMP4 are unchanged in the mutant embryos.
We have shown that high contribution of β-catenin–deficient cells to the epiblast of chimeric embryos leads to developmental arrest. In contrast, absence of β-catenin in extraembryonic tissues like the visceral endoderm allowed anterior and mesodermal differentiation. This indicates that β-catenin function is required in the embryonic ectoderm for axis formation, and that signals from the embryonic ectoderm may contribute to the patterning of the underlying endoderm. To further localize the cells that depend on β-catenin, we carried out two types of experiments. First, we used a mouse reporter strain that carries a lacZ transgene under the control of multiple LEF/TCF binding sites (Roose 1999) (a generous gift of Dr. H. Clevers, University of Utrecht, Utrecht, The Netherlands). Whereas β-galactosidase activity was detected at E6.5 (Roose 1999), we could not locate activity at E5.5 and E6.0. However, it should be noted that this promoter appears not to respond to all β-catenin–mediated signals in vivo or in cell culture. Second, we attempted to identify nuclear β-catenin at the egg cylinder stage by confocal immunofluorescence, but could not detect such a signal. Moreover, experiments with chimeric embryos that have a low contribution of β-catenin–deficient cells show that β-catenin is not required cell-autonomously for mesodermal differentiation. This is in accordance with experiments in Xenopus that demonstrate that β-catenin–deficient marginal zones can be instructed by β-catenin–overexpressing animal caps to form dorsal mesoderm (Wylie et al. 1996).
We showed that cellular adhesion of epithelial cells in the early mouse embryo is not grossly disturbed in the absence of β-catenin. Epithelia in the mutant embryos are well-developed, and the cells are connected by well-defined adherens junctions and desmosomes. Furthermore, β-catenin–deficient cells in chimeric embryos contributed to various epithelia such as head and limb bud ectoderm. -Catenin was found to be located along lateral cell membranes in mutant embryos, although β-catenin is normally required to connect -catenin to classical cadherins. Instead, the protein level of plakoglobin was found to be enhanced, and plakoglobin was redistributed to adherens junctions in β-catenin–deficient embryos. Apparently, plakoglobin can take over the function of β-catenin in cell adhesion of mutant embryos, a function which has been investigated by in vitro experiments (Huelsken et al. 1994b). This prevents the early disintegration of epithelia due to defective adhesion that is observed at the blastocyst stage in mice mutant for the E-cadherin or -catenin genes (Larue et al. 1994; Riethmacher et al. 1995; Torres et al. 1997). Cell detachment from the ectodermal cell layer at E7 was reported in the previously generated mutation of the β-catenin gene (Haegel et al. 1995). It was not rigorously shown that this earlier mutation corresponds to a null allele. Given the structure of the used targeting vector in Haegel et al. 1995, it is possible that an NH2-terminally truncated β-catenin protein is produced from the mutant allele described previously, which could bind to cadherins but not to -catenin. Such a molecule would act in a transdominant manner and disturb adhesion, in contrast to the rescue of adhesion we observe in our null-mutants. It should be noted that no β-catenin mRNA or protein is produced by both our β-catdel or β-catlacZ alleles, which therefore represent null mutations of the β-catenin gene. Thus, our data suggest that plakoglobin can substitute for the adhesive function of β-catenin at the egg cylinder stage. Apparently, plakoglobin cannot compensate for the proposed signaling function of β-catenin in axis formation. This is in accordance with previous findings in Xenopus, which indicate that plakoglobin does not significantly participate in Wnt signaling (Kofron et al. 1997; Miller and Moon 1997; Ben-Ze'ev and Geiger 1998).
The early postimplantation lethality caused by null mutations in β-catenin precludes the analysis of its function in many tissues and events at later developmental stages that depend on Wnt signaling. A function of β-catenin in hair formation and in skin tumors such as pilomatricomas has been identified by the overexpression of an activated form of β-catenin in the skin of mice (Gat et al. 1998). Conditional gene ablation will also allow to study functions of β-catenin at later developmental stage.
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Acknowledgments |
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This work was supported in part by a grant of the Volkswagen-Stiftung to J. Huelsken and W. Birchmeier.
Submitted: 9 November 1999
Revised: 23 December 1999
Accepted: 23 December 1999
Abbreviations used in this paper: BMP, bone morphogenetic protein; E, embryonic day; ES, embryonic stem; LEF, lymphoid enhancer factor; TCF, T-cell factor.
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