Membrane-anchored Plakoglobins Have Multiple Mechanisms of Action in Wnt Signaling

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Vol. 10, Issue 10, 3151-3169, October 1999

Membrane-anchored Plakoglobins Have Multiple Mechanisms of Action in Wnt Signaling

Michael W. Klymkowsky,^* Bart O. Williams,^§ Grant D. Barish,^§ Harold E. Varmus,^§ and Yanni E. Vourgourakis^*

^*Molecular, Cellular, and Developmental Biology, University of Colorado, Boulder, Boulder, Colorado, 80309-0347; and ^§Division of Basic Sciences, National Cancer Institute, National Institutes of Health, Bethesda, Maryland 20892

Submitted March 1, 1999; Accepted July 13, 1999
Monitoring Editor: John C. Gerhart

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

In Wnt signaling, $beta$ -catenin and plakoglobin transduce signals to the nucleus through interactions with TCF-type transcriptionfactors. However, when plakoglobin is artificially engineeredto restrict it to the cytoplasm by fusion with the transmembranedomain of connexin (cnxPg), it efficiently induces a Wnt-likeaxis duplication phenotype in Xenopus. In Xenopus embryos, maternalXTCF3 normally represses ventral expression of the dorsalizinggene Siamois. Two models have been proposed to explain the Wnt-likeactivity of cnxPg: 1) that cnxPg inhibits the machinery involvedin the turnover of cytosolic $beta$ -catenin, which then accumulatesand inhibits maternal XTCF3, and 2) that cnxPg directly acts toinhibit XTCF3 activity. To distinguish between these models, wecreated a series of N-terminal deletion mutations of cnxPg andexamined their ability to induce an ectopic axis in Xenopus, activatea TCF-responsive reporter (OT), stabilize $beta$ -catenin, and colocalizewith components of the Wnt signaling pathway. cnxPg does not colocalizewith the Wnt pathway component Dishevelled, but it does lead tothe redistribution of APC and Axin, two proteins involved in theregulation of $beta$ -catenin turnover. Expression of cnxPg increaseslevels of cytosolic $beta$ -catenin; however, this effect does not completelyexplain its signaling activity. Although cnxPg and Wnt-1 stabilize $beta$ -catenin to similar extents, cnxPg activates OT to 10- to 20-foldhigher levels than Wnt-1. Moreover, although LEF1 and TCF4 synergizewith $beta$ -catenin and plakoglobin to activate OT, both suppress thesignaling activity of cnxPg. In contrast, XTCF3 suppresses thesignaling activity of both $beta$ -catenin and cnxPg. Both exogenousXLEF1 and XTCF3 are sequestered in the cytoplasm of Xenopus cellsby cnxPg. Based on these data, we conclude that, in addition toits effects on $beta$ -catenin, cnxPg interacts with other componentsof the Wnt pathway, perhaps TCFs, and that these interactionscontribute to its signalingactivity.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Wnts are secreted glycoproteins that are thought to act locally (see Nusse and Varmus, 1992; Cadigan and Nusse, 1997). A combinationof genetic, biochemical, and cell biological studies have ledto a consensus model for the Wnt signaling pathway. Binding ofa secreted Wnt to Frizzled/Frizzled-2-type receptors (Bhanot etal., 1996; Bhat, 1998; Kennerdell and Carthew, 1998; Muller etal., 1999) activates the protein Dishevelled (Dvl) (Yanagawa etal., 1995), which in turn leads to the inactivation of glycogensynthase kinase-3 $beta$ (Gsk3 $beta$ ). Gsk3 $beta$ , a ubiquitous enzyme (see Yostet al., 1997), regulates levels of $beta$ -catenin (Siegfried et al.,1992) by phosphorylating serine and threonine residues in theN terminus of cytosolic $beta$ -catenin (Yost et al., 1996) and targeting $beta$ -catenin for proteolytic degradation. Thus, in response to aWnt signal, Gsk3 $beta$ activity is inhibited and cytosolic $beta$ -cateninaccumulates and is available to interact with TCF-type transcriptionfactors (Behrens et al., 1996; Huber et al., 1996; Molenaar etal., 1996; Brunner et al., 1997; van de Wetering et al., 1997),which alter the expression of targetgenes.

The proteolytic degradation of cytosolic $beta$ -catenin and its closely related vertebrate paralogue plakoglobin/ $gamma$ -catenin appearsto involve the product of the adenomatous polyposis coli (APC)gene (Munemitsu et al., 1995). $beta$ -Catenin and plakoglobin formcomplexes with APC and Gsk3 $beta$ (Rubinfeld et al., 1993, 1995, 1996;Hulsken et al., 1994) to target these proteins for ubiquitinationand degradation via the proteosome (Aberle et al., 1997). Axinand the related protein Conductin/Axil, which negatively regulatethe Wnt pathway, link Gsk3 $beta$ , $beta$ -catenin, and APC into a singlecomplex (Yamamoto et al., 1988; Zeng et al., 1997; Behrens etal., 1998; Ikeda et al., 1998; Kishida et al., 1998; Sakanakaet al., 1998). Mutations in APC, responsible for most cases offamilial colon cancer, act, at least in part, by increasing thestability of $beta$ -catenin (Korinek et al., 1997). A substantial numberof colon cancers without apparent mutations in APC have mutationsin $beta$ -catenin that stabilize the cytosolic form of the protein(Morin et al., 1997; Sparks et al., 1998). Similar mutations in $beta$ -catenin have been found in cultured melanoma cell lines (Rubinfeldet al., 1997), medulloblastomas (Zurawel et al., 1998), pilocytomas(Chan et al., 1999), and carcinomas of the liver (de La Costeet al., 1998; Miyoshi et al., 1998), prostate (Voeller et al.,1998), and endometrium (Fukuchi et al., 1998; Palacios and Gamallo,1998).

In addition to its role in Wnt signaling, $beta$ -catenin plays a critical role in cadherin-mediated cell-cell adhesion, in whichit links the classic cadherins of adherens junctions to actinfilaments through $alpha$ -catenin (see Yap et al., 1997). Plakoglobinhas a similar role at the adherens junction, and expression ofeither vertebrate plakoglobin or $beta$ -catenin in Drosophila can rescuethe adhesion defects associated with armadillo mutants (Whiteet al., 1998). $beta$ -Catenin and plakoglobin have also been foundto be associated with the tight junction protein ZO-1 (Rajasekaranet al., 1996), the EGF receptor (Hoschuetzky et al., 1994; Kanaiet al., 1995), tyrosine phosphatases (Kypta et al., 1996), theactin-bundling protein fascin (Tao et al., 1996), the integralmembrane protein Presenilin-1 (Zhou et al., 1997; Murayama etal., 1998; Yu et al., 1998), the TATA box-binding protein pontin-52(Bauer et al., 1998), SOX-type transcription factors (Zorn etal., 1999) and APC, Axin, and Conductin/Axil (see above). $beta$ -Cateninand plakoglobin differ most dramatically in the ability of plakoglobin,but not $beta$ -catenin, to bind to desmosomal cadherins (see Gelderlooset al., 1997; however, also see Bierkamp et al., 1999). Differencesin their interactions with adhesion complexes have been observedin vivo (see Nathke et al., 1994; Lampugnani et al., 1995). Inparticular, tissues, $beta$ -catenin, and plakoglobin can be presentat different levels and in different complexes (see Simcha etal., 1998).

The HMG-type transcription factors known as lymphoid enhancer factor-1 (LEF1) and T-cell enhancer factors (TCFs), which werefer to generically as TCFs, mediate the final steps in Wnt signalingthrough their interactions with $beta$ -catenin and plakoglobin. Theprevailing model for Wnt signaling states that in response toa Wnt stimulus, hypophosphorylated forms of $beta$ -catenin or plakoglobinaccumulate and form complexes with TCFs. These heterodimeric complexesare then thought to activate transcription at TCF target genepromoters. Alternatively, several lines of evidence suggest thatcertain TCFs may act as constitutive repressors at target promoters,whose repression is relieved by binding to $beta$ -catenin or plakoglobin(see Klymkowsky, 1997, and below). In Drosophila, mutation ofthe TCF-binding site in the Ultrabithorax midgut enhancer augmentsexpression of Ubx in cells not exposed to the Wingless protein(Riese et al., 1997). A similar derepression is observed uponmutation of TCF sites in the Siamois enhancer, increasing ventralproduction of Siamois; such mutations have no effect on dorsalexpression (Brannon et al., 1997). More recent work has solidifiedthe notion of TCFs as transcriptional repressors (see Bienz, 1998),e.g., Groucho family members can bind TCFs and mediate constitutivetranscriptional repression at TCF-binding sites (Roose et al.,1998; see also Cavallo et al., 1998; Levanon et al., 1998).

We originally constructed membrane-anchored forms of plakoglobin to study whether plakoglobin's nuclear localization was requiredto induce axis duplication in Xenopus. When RNAs encoding thesepolypeptides were injected into fertilized Xenopus eggs, theywere effective at inducing axis duplication and did not appearto alter nuclear $beta$ -catenin levels (Merriam et al., 1997). Basedon this result and the inhibitory effects of mutated XTCF3 onaxis formation (Molenaar et al., 1996), we argued that plakoglobin(and $beta$ -catenin) inhibited the repressive activity of maternalXTCF3, allowing the ventral expression of Siamois and other dorsalizinggenes (see Klymkowsky, 1997; Merriam et al., 1997). Subsequently,Miller and Moon (1997) and Hsu et al. (1998) reported that analogousanchored forms of $beta$ -catenin inhibit $beta$ -catenin degradation andthereby stabilized endogenous $beta$ -catenin, arguing that the effectsof "anchored catenins" are indirect and dependent on endogenous $beta$ -catenin. Most recently, Cox et al. (1999) reported that a "membrane-tethered"form of armadillo did not modulate gene expression in the absenceof wild-type armadillo, arguing for an indirect mode ofaction.

To resolve these apparent discrepancies, we examined further the signaling activities of membrane-anchored plakoglobins usinga panel of deletion mutants. Our studies in human 293T and XenopusA6 cell lines confirm that anchored plakoglobins do act to increaselevels of cytosolic $beta$ -catenin. However, several lines of evidenceindicate that the signaling activity of anchored plakoglobin isnot simply due to its effects on cytosolic $beta$ -catenin. We showthat XTCF3 acts negatively, suppressing the ability of $beta$ -cateninto activate a TCF-responsive promoter, and that connexin-plakoglobins(cnxPgs) can sequester TCF family members in the cytoplasm. Theresults obtained with these admittedly artificial polypeptidesraise the intriguing possibility that cytoplasmic forms of cateninsmay modulate the nuclear availability of TCFs and other negativelyactingfactors.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Plasmids

For expression of proteins in Xenopus A6 and human 293T cells, we used the pCS2mt plasmid developed by Rupp and Turner (Ruppet al., 1994) or the pCDNA3 plasmid (Invitrogen, Carlsbad, CA).For synthesis of cnxPg RNAs for embryo injection, we used thepT7 plasmid described previously (Karnovsky and Klymkowsky, 1995;Merriam et al., 1997). The pT7cnx-human plakoglobin-myc (pT7cnxPg-myc),pT7cnx-human plakoglobin-green fluorescent protein (pT7cnxPg-GFP),pT7N2 $Delta$ Pg-myc, and pT7N5 $Delta$ Pg-myc plasmids have been described previously(Merriam et al., 1997; Rubenstein et al., 1997). The GFP in theseplasmids contains a S65 $right-arrow$ T mutation that enhances its fluorescence(Heim et al., 1995). The N2 $Delta$ Pg sequence was subcloned into pCS2mt-GFPusing EcoRI and XbaI sites to form pCS2mt-N2 $Delta$ Pg-GFP. To subclonecnxPg into pCS2 plasmids, pT7cnxPg-myc was digested with HindIIIand XbaI and the released fragment was subcloned into pCS2mt-GFP.The resulting plasmid has the original SP6 RNA polymerase promoter,5' untranslated region, and 6-myc tag region of the pCS2mt plasmidreplaced with the T7 RNA polymerase promoter and 5' $beta$ -globin untranslatedregion of the pT7 plasmid. We refer to these plasmids as pCsCnxPg-GFP.PCR was used to amplify the N3 $Delta$ Pg and N4 $Delta$ Pg sequences (5' N3 $Delta$ oligonucleotide CCCGAATTCgcacaacctctcccaccac and 5' N4 $Delta$ oligonucleotideCCCGAATTCgctgcacaacctgctcctg, together with the 3' full-lengthhuman plakoglobin primer CCCCTCTAGAggccagcatgtggtctgc). To createuntagged forms of the cnxN $Delta$ 2Pg, cnxN3 $Delta$ Pg, cnxN4 $Delta$ Pg, and cnxN $Delta$ 5Pgpolypeptides, the pCsCnx plasmids were digested with XbaI andthe DNA ends filled in T4 DNA polymerase and religated, creatingan in-frame stop codon between the plakoglobin and GFP sequences.Because of the presence of a second, downstream T7 RNA polymerasepromoter in the pCsCnx plasmids, we subcloned the cnxN3 $Delta$ Pg andcnxN4 $Delta$ Pg sequences from pCsCnx into the pT7-GFP plasmid usingHindIII and XbaI to form pT7cnxN3 $Delta$ Pg-GFP and pT7cnxN4 $Delta$ Pg-GFP,which were used for in vitro RNA synthesis (seebelow).

Plasmids encoding an single HA-epitope-tagged form of Xenopus TCF3 (HA-XTCF3), a single myc-tagged Xenopus LEF-1 (myc-XLEF-1)(Molenaar et al., 1996, 1998), human TCF4 (Korinek et al., 1997),mouse and human LEF1 (Travis et al., 1991; Waterman et al., 1991),a myc-tagged mouse Axin (mtAxin) (Zeng et al., 1997), XenopusNotch (Xotch) (Coffman et al., 1990), and a myc-tagged form ofXenopus Dishevelled (mtXDvl) (Sokol, 1996) were generously suppliedby Hans Clevers and Miranda Molenaar (University of Nijmegen,Nijmegen, The Netherlands), Rudolf Grosschedl (University of California,San Francisco, CA), Katherine Jones (Salk Institute, La Jolla,CA), Michael Sargent (National Institute for Medical Research,Mill Hill, United Kingdom), Frank Costantini (Columbia University,New York, NY), Clark Coffman (University of Colorado, Boulder,CO), and Sergei Sokol (Harvard Medical School, Cambridge, MA),respectively. A myc-GFP-tagged form of the Xenopus zinc-fingertranscription factor XSlug has been described elsewhere (Carlet al., 1999). The full nucleotide coding regions of XTCF3 andhLEF1 were amplified using PCR (oligonucleotides for XTCF3: 5'-CCCGAATTCGcctcaactaaacagcggcgand 3'-CCCTCTAGAgtcactggatttggtcacc; oligonucleotides for hLEF1:5'-CCCGAATTCGccccaactttccggagg and 3'-CCCCTCTAGAtcagatgtaggcagctgtcattc).In the case of Xotch, we isolated the cytoplasmic tail domain(5'-CCCGAATTCcaagaagcgtcgccgtgaac and 3'-CCCTCTAGAttacttgaaagcttcagg).The amplified DNAs were digested with EcoRI and XbaI and weresubcloned into pCS2mt-GFP (pCS2mtXTCF3-GFP) and pCS2mycGFP (pCS2mGXTCF3,pCS2mGLEF1, and pCS2mGXotchTail) (Figure 1). In addition, a formof XTCF3 missing the N-terminal 166 amino acids (pCS2mt- $Delta$ N166-XTCF3-GFP)was generated in a similar manner (oligonucleotides 5' CCCGAATTCCcacccacttacgcctctcatcaccand the 3' XTCF3 above). Plasmids expressing an S37 $right-arrow$ F mutatedform of human $beta$ -catenin were obtained from Paul Robbins (SurgeryBranch, National Cancer Institute, Bethesda, MD). The coding sequencewas amplified and subcloned into pCDNA3. Sequence analysis revealedthe presence of an additional point mutation in this construct(D32 $right-arrow$ V). We have subsequently shown that a version of $beta$ -catenincontaining only a mutation in S37 (S37 $right-arrow$ A) acts identically inall assays to the D32 $right-arrow$ V/S37 $right-arrow$ F (referred to as S37 $right-arrow$ F) mutant describedhere (our unpublished results). We have also used the stabilized"pt-mutant" form of Xenopus $beta$ -catenin, which was described byYost et al. (1996) and supplied to us by Aaron Zorn (Wellcome/CRCInstitute, Cambridge, United Kingdom). A mutated version of humanplakoglobin (S28 $right-arrow$ A), derived from a human plakoglobin cDNA (Frankeet al., 1989), was also constructed. The wild-type plasmid wasmutagenized using the Stratagene (La Jolla, CA) QuikChange mutagenesissystem with primers that placed a silent NgoMI site in the "mutator"oligonucleotide together with the addition of a S $right-arrow$ A mutation inthe 28th residue. Sequencing confirmed the presence of the expectedmutation.

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Figure 1. Constructs. (Top) Cartoon of cnxPg, based on the crystal structure of the closely related protein $beta$ -catenin (Huber et al., 1997

), that illustrates the cnxPg constructs used in this work. The positions of the first plakoglobin-derived amino acid in the various deletions are indicated. N2 $Delta$ fuses the connexin transmembrane domain to Asn-167 of plakoglobin, N3 $Delta$ fuses the connexin domain to His-210 of plakoglobin, N4 $Delta$ fuses the connexin domain to Leu-250 of plakoglobin, and N5 $Delta$ fuses the connexin domain to Gln-292 of plakoglobin. Each deletion removes the bulk of the N-terminal Arm repeat, leaving five to eight amino acids upstream of the start of the next Arm repeat, as defined structurally. (Bottom) myc- and GFP-tagged forms of TCFs used in this work.

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Figure 2. The axis-inducing activities of the cnxPg-GFPs. (A) Fertilized Xenopus eggs, injected with various amounts of capped RNA (20 nl injected), were allowed to develop to stages 15-18 and then assayed for dorsal axis duplication. Only embryos that were fluorescent as a result of the expression of exogenous protein were counted; the numbers above each point indicate the total number of embryos scored. (B) Expression of TCFs in 293T cells. Reverse transcriptase-PCR analysis was used to analyze TCF expression. Human Jurkat cells express TCF1 and LEF1 RNAs. 293T cells express detectable levels of all four TCF RNAs, i.e., TCF1, LEF1, TCF3, and TCF4. Reactions in which ribonuclease was added showed no DNA amplification (our unpublished results). (C) cnxPg induction of the OT reporter. Human 293T cells were transfected with plasmids (2 µg of DNA) that express S37 $right-arrow$ F- $beta$ -catenin, N2 $Delta$ Pg, or various forms of cnxPg, together with the OT reporter and a plasmid driving the expression of $beta$ -galactosidase. Luciferase activity was measured after 36 h and was normalized to $beta$ -galactosidase activity levels. All transfections used a total of 4.0 µg of DNA. Activity of the "empty vector" was normalized to 1. In each case, the pattern of reporter activation shown was reproduced in at least three independent experiments. (D) Accumulation of cnxPgs. 293T cells were transfected with 4 µg of plasmid DNA; 36 h later, the cells were homogenized and extracts were analyzed by immunoblot (lanes 1 and 6, empty vector; lane 2, cnxPg-GFP; lane 3, cnxN2 $Delta$ Pg-GFP; lane 4, cnxN4 $Delta$ Pg-GFP; lanes 5 and 8, cnxN5 $Delta$ Pg-GFP; lane 7, cnxN3 $Delta$ Pg) using either an anti-GFP antibody (lanes 1-5) or an anti-plakoglobin antibody (lanes 6-8). The cnxPg polypeptides consistently run with an apparent molecular weight lower than their calculated size. The positions of molecular weight markers are noted. (E) Stabilization of soluble $beta$ -catenin by cnxPgs. 293T cells were transfected with plasmids (2 µg of DNA) driving the expression of various cnxPgs or N2 $Delta$ Pg; 36 h later, the cells were harvested, homogenized, and centrifuged to remove membrane-associated proteins, and soluble $beta$ -catenin was analyzed by immunoblot using an anti- $beta$ -catenin antibody. Two different exposures of the blot (5 s and 1 min) are shown. Very low levels of soluble $beta$ -catenin were seen in cultures transfected with the pCDNA3 plasmid (empty vector) alone. (F) A comparison of the stabilization of soluble $beta$ -catenin by Wnt-1 and cnxPg. 293T cells were cotransfected with plasmids that drove the expression of Wnt-1 (4 µg), S37 $right-arrow$ F- $beta$ -catenin (2 µg), cnxPg-GFP (2 µg), or cnxN4 $Delta$ Pg-GFP (2 µg) and assayed 36 h later for soluble $beta$ -catenin, as in D (exposures of 1 and 5 min are shown). (G) The ability of cnxPg, Wnt-1, and S37 $right-arrow$ F- $beta$ -catenin plasmids to activate OT. 293T cells were transfected with cnxPgs or Wnt-1-expressing plasmids, and their ability to activate OT was measured. In a large number of experiments (>10), Wnt-1 produced only a modest increase in reporter activity, ranging from 2- to 10-fold.

Embryo Experiments

To assay the biological activity of various cnxPg constructs, RNA was synthesized from the T7 promoter of the pT7cnx-GFP plasmidsas described previously (Merriam et al., 1997). Fertilized eggswere injected with 10-20 nl of RNA (0.01-0.8 ng/nl). Injectedembryos were examined using a Leitz (Midland, Ontario, Canada)M5 stereo dissecting microscope equipped with epifluorescenceoptics to identify those expressing the exogenous protein. Theeffects of the injected RNAs on axis formation were assayed atstages 15-20; axis duplication was based on the presence of twodistinct neural axes (see Merriam et al., 1997).

Cell Culture, Transfection, and Plasmid Injection

Xenopus A6 cells were cultured on glass coverslips in 85% Leibowitz L15 medium supplemented with 10% FCS and antibiotics andgrown at room temperature. Injection of plasmid DNAs (1-10 µg/ml)was carried out as described previously (Klymkowsky, 1999). Greenfluorescence was first visible within 2-4 h of injection. Livingcells were examined using a Zeiss (Thornwood, NY) IM35 microscopeequipped with appropriate filter sets; images were captured onslide film (Ektachrome 400, Kodak, Rochester, NY) or on an Apple(Cupertino, CA) Power Macintosh 6500/275 computer using a Microimage(Boyertown, PA) i308 video camera and the Minimonitor 1.2program.

Immunofluorescence Microscopy

Cells were fixed with 70% acetone/30% ethanol for 5 min, rehydrated in Tris-buffered saline (TBS), and stained with appropriateantibodies. GFP autofluorescence were visualized directly usingfluorescein optics. The mouse anti-plakoglobin ( $gamma$ -catenin) (TransductionLaboratories, Lexington, KY) mAb was used to visualize untaggedplakoglobin-containing polypeptides; its epitope is located inthe C-terminal region of plakoglobin and is present in all versionsof plakoglobin used here. A rabbit anti-Xenopus plakoglobin antibody,obtained from Thomas Kurth and Peter Hausen (Max Planck Institute,Tubingen, Germany), was used in some studies. myc-tagged polypeptideswere visualized using the mouse anti-myc mAb 9E10 (Evan et al.,1985). APC was visualized using a rabbit antiserum directed againstthe C-terminal region of APC (Santa Cruz Biotech, Santa Cruz,CA). Western immunoblot studies, carried out by Richard Nelsonand Barry Gumbiner (Sloan-Kettering Memorial Cancer Center, NewYork, NY) with baculovirus-synthesized Xenopus APC, indicate thatthis anti-APC antiserum reacts specifically with Xenopus APC (R.Nelson and B. Gumbiner, personal communication; and our unpublishedresults). A mouse anti-E-cadherin antibody (Transduction Laboratories)was used to visualize E-cadherin. $beta$ -Catenin was visualized usinga rabbit anti- $beta$ -catenin antibody (supplied by Pierre McCrea, Universityof Texas, Houston, TX; see McCrea et al., 1993; Fagotto and Gumbiner,1994). Bound antibodies were recognized using either fluorescein-,Texas Red- (Southwestern Biotechnology, Birmingham, AL), Alexa488-, or Alexa 495- (Molecular Probes, Eugene, OR) conjugatedspecies-specific secondary antibody conjugates. Cells were mountedin airvol/glycerol and viewed using a Zeiss IM35 microscope andphotographed onto Kodak Ektachrome 400 film, as described by Carland Klymkowsky (1999). Slides were digitized using a Polaroid(Cambridge, MA) SprintScan 35plus slide scanner. Alternatively,cells were visualized using a Nikon (Tokyo, Japan) upright epifluorescencemicroscope with a ×100 lens, and the images were captured usinga Cooke (Auburn Hills, MI) Sensicam video camera on a PowerMacintosh8500/150MHz computer using the SlideBook 2.1 program (IntelligentImaging Innovations, Denver, CO). Images were deconvoluted usingthe SlideBook program and exported as TIFF files. Images weremanipulated using Photoshop 4.0 (Adobe, Mountain View, CA) software,and final figures were prepared using Illustrator 7.0(Adobe).

Reporter Studies

To measure the ability of various forms of cnxPg to activate a TCF-dependent reporter construct, human 293T cells were cotransfectedwith the plasmid to be tested, an optimized version of the TOPFLASHreporter plasmid (OT) (Korinek et al., 1997) (supplied by BertVogelstein, Johns Hopkins University, Baltimore, MD), and thepCDNA3.1-lacZ plasmid. Transfections were performed in duplicate.For each experiment, 60-mm plates were seeded with equal numbersof cells on the night before transfection. A CaPO₄-based transfectionmethod was used for all transfections with Stratagene Stable MammalianTransfection Kits. Cells were 30-50% confluent at the time oftransfection. Cells were harvested 36 h after transfection bylysing in 1× reporter lysis buffer (Promega, Madison, WI). Lysateswere pelleted and 10 µl of each supernatant was added to 100 µlof luciferase assay substrate (Promega). Luciferase activity wasmeasured (with duplicate readings for each sample) using a Berthold(Bad Wildbad, Germany) Lumat LB9507 luminometer. Readings werenormalized for transfection efficiency by measuring $beta$ -galactosidaseactivity. To monitor the accumulation of cnxPgs, cell lysateswere analyzed by immunoblot (see below) using mouse mAbs directedagainst either plakoglobin (Transduction Laboratories) or GFP(Boehringer-Mannheim, Indianapolis,IN).

Reverse Transcriptase-PCR Analysis of TCFs in 293T Cells

Total RNA was extracted from human 293T cells and Jurkat lymphoma cells using a Qiagen (Valencia, CA) RNeasy kit. The RNAwas reverse transcribed into cDNA using a Life Technologies/BRL(Bethesda, MD) one-step reverse transcriptase-PCR kit using 1µl of RNA at 1 µg/ml, according to the manufacturer's protocol.PCR was carried out under the following cycling conditions: 1time at 50°C for 3 min, 30 times at 94°C for 2 min, 94°C for 25s, 56°C for 30 s, and 72°C for 2 min, and 1 time at 72°C for 15min. PCR products were resolved on a 2% NuSieve FMC (Rockland,ME) agarose gel. The oligonucleotides used for the PCR analysiswere: TCF1 5', 5' TCA AGA AGC CCC TCA ATG CC 3'; TCF1 3', 5' TTGGTG CTT TTC CCT CGA CC 3'; LEF1 5', 5' CAG AAG GAA AAG ATC TTCGC 3'; LEF1 3', 5' GTA GGA GGG TCC CTT GTT GTA 3'; TCF3 5', 5'CAG TCA CAG CAG CAA GTT TAG GAG 3'; TCF3 3', 5' GGG TTT CTG GTTTGG TGG TGA AG 3'; TCF4 5', 5' TCC AGA GAA GAG CAA GCG AAA TAC3'; and TCF4 3', 5' TGA GGT CTG TAA TCG GAG GAA GTG 3 '.

Examination of Cytoplasmic $beta$ -Catenin Levels

To examine the effects of cnxPgs on cytosolic $beta$ -catenin levels, samples were prepared as described by Shimizu et al. (1997).Cultures of 293T cells were transfected with 4 µg of plasmid DNA.Thirty-six hours after transfection, cells were harvested in 10mM Tris (pH 7.5), 140 mM NaCl, and 2 mM DTT supplemented withprotease inhibitors. The samples were then scraped from the plates,lysed in a Dounce homogenizer, and centrifuged for 1 h at 100,000× g at 4°C. Supernatants were removed and diluted in SDS-samplebuffer. The diluted sample was then separated on a 10% SDS-PAGEgel and transferred to nitrocellulose. After confirming even transferby staining with Ponceau S, the blot was incubated for 30 minat room temperature in blocking solution (0.1% Tween-20 in TBSwith 5% BSA). Blots were incubated for 12-16 h at 4°C with primaryantibody against anti- $beta$ -catenin (Transduction Laboratories) diluted1:1,000 in blocking solution. Blots were washed three times (5-10min per wash) in 0.1% Tween-20 in TBS, incubated in secondaryantibody (goat anti-mouse immunoglobulin G-peroxidase), diluted1:15,000 in blocking solution for 30 min at room temperature,washed three times for 10-15 min in Tween-20 in TBS, exposed toECL substrate (Amersham, Arlington Heights, IL), and exposed tofilm.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Three assays are commonly used to study the Wnt signaling activity of a polypeptide: its ability to induce an ectopic dorsalaxis in Xenopus, to activate a TCF-responsive reporter plasmid,and to stabilize soluble $beta$ -catenin. Previously, we found thatinjection of RNAs encoding membrane-anchored forms of plakoglobinled to the synthesis of cytoplasmic proteins that induced an ectopicdorsal axis in Xenopus embryos but had no apparent effect on nuclear $beta$ -catenin levels (Merriam et al., 1997). To study further themechanism of cnxPg action, we created a panel of GFP-tagged (anduntagged) cnxPg deletion mutants (Figure 1). The mutations removedthe entire N-terminal domain of plakoglobin together with thefirst (cnxN2 $Delta$ Pg, starts at Asn-167 of plakoglobin), second (cnxN3 $Delta$ Pg,starts at His-210), third (cnxN4 $Delta$ Pg, starts at Leu-250), or fourth(cnxN5 $Delta$ Pg, starts at Gln-292) Arm repeats (Figure 1). Based onthe original definition of the Arm repeats, these deletions leavethe last five to eight amino acids of the N-terminal deleted Armrepeat, as defined structurally in $beta$ -catenin (Huber et al., 1997).

To compare the signaling activity of cnxPg with that of plakoglobin and $beta$ -catenin, we used full-length and deleted versionsof plakoglobin (Karnovsky and Klymkowsky, 1995; Rubenstein etal., 1997) and a mutated version (S28 $right-arrow$ A) of plakoglobin analogousto the S37 $right-arrow$ A oncogenic mutation described for $beta$ -catenin. In addition,the pt-mutant version of Xenopus $beta$ -catenin (Yost et al., 1996)was also tested. Oncogenic mutations in $beta$ -catenin lead to thestabilization of the cytoplasmic form of the protein and greatlyenhance its ability in Wnt-signaling assays (see Yost et al.,1996; Morin et al., 1997).

Wnt-like Signaling Activity of cnxPg Requires the N-Terminal Arm Repeat Region

Previously, we found that a unanchored N5 $Delta$ version of plakoglobin induced axis duplication in Xenopus (Rubenstein et al.,1997). To determine whether the same N-terminal region was requiredfor the signaling activities of anchored plakoglobin, we testedthe ability of RNAs encoding the various cnxPg deletion mutationsto induce the formation of an ectopic axis when injected intofertilized Xenopus eggs. As previously reported, injection ofcnxPg-GFP mRNA induced axis duplication (Merriam et al., 1997)(Figure 2A). Injection of cnxN3 $Delta$ Pg-GFP RNA also induced axis duplication,whereas injection of cnxN4 $Delta$ Pg-GFP RNA did not (Figure 2A). Basedon the intensity of green fluorescence, the products of all testedconstructs appeared to accumulate to roughly equal extents. Todetermine if the N3 $Delta$ deletion decreased the efficiency of axisinduction, embryos were injected with various amounts of cnxPg-GFPand cnxN3 $Delta$ Pg-GFP RNAs; cnxN3 $Delta$ Pg-GFP RNA was less efficient thanequivalent amounts of cnxPg-GFP RNA at inducing axis duplication(Figure 2A).

cnxPg Activates a TCF-responsive Reporter and Stabilizes Soluble $beta$ -Catenin

We next examined the ability of the cnxPg deletion constructs to transactivate a TCF-responsive reporter, OT, when cotransfectedinto 293T cells. The OT plasmid contains three copies of a TCF-bindingmotif (CCTTTGATC) upstream of a minimal c-fos promoter. All transfectionsalso included a plasmid encoding LacZ (pCDNA3.1- $beta$ gal) to normalizefor transfection efficiency by measurement of $beta$ -galactosidaseactivity. Reverse transcriptase-PCR analysis of 293T cells indicatedthat they expressed detectable levels of all four TCF RNAs, i.e.,TCF1, LEF1, TCF3, and TCF4; in contrast, human Jurkat cells expresseddetectable levels of TCF1 and LEF1 only (Figure 2B). The OT reporterwas efficiently activated by a S37 $right-arrow$ F "stabilized" (oncogenic)mutant form of $beta$ -catenin (Figure 2C). cnxPg and cnxN2 $Delta$ Pg wereequally effective, and typically as or more effective than oncogenic $beta$ -catenin, at activating the OT reporter (Figure 2C and Table1). cnxN3 $Delta$ Pg was significantly less effective, although it stillconsistently activated OT 5- to 10-fold above background. cnxN4 $Delta$ Pgand cnxN5 $Delta$ Pg did not activate the OT reporter. Interestingly,the N2 $Delta$ form of plakoglobin (Figure 2C) activated the reporteronly weakly, even though it induced axis duplication in Xenopus(Rubenstein et al., 1997). A variant of OT containing point mutationsthat prevent TCF binding to the three TCF-binding motifs was notactivated above basal levels by any of the constructs describedhere (our unpublished results).

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Table 1. Variation in $beta$ -catenin/cnxPg activation of OT

Western blot analysis of extracts from cells transfected with these constructs indicated that similar amounts of each polypeptidewere produced (Figure 2D). We also assayed the effects of transfectionof the various cnxPgs into 293T cells on the levels of soluble $beta$ -catenin (Figure 2E). cnxPg and cnxN2 $Delta$ Pg were equally effectiveat increasing the concentration of soluble $beta$ -catenin, whereascnxN3 $Delta$ Pg was less effective and cnxN4 $Delta$ Pg stabilized soluble $beta$ -cateninonly very weakly. As reported previously by Miller and Moon (1997)and Simcha et al. (1998), expression of wild-type plakoglobinincreased soluble $beta$ -catenin (our unpublished results); in contrast,expression of N2 $Delta$ Pg failed to induce a detectable increase insoluble $beta$ -catenin (Figure 2E). The ability of cnxPg to stabilizecytosolic $beta$ -catenin was similar to that seen in cells transfectedwith plasmid encoding Wnt-1 (Figure 2F); however, the abilityof cnxPg to activate the OT reporter was much greater than thatseen with Wnt-1 (Figure 2G). Transfection with the Wnt-1 plasmidincreased reporter activity 2- to 10-fold, compared with the 50-to 150-fold activation seen with cnxPg. Therefore, it seems likelythat the stabilization of $beta$ -catenin is not the only factor thatdetermines the level of signaling induced by cnxPg.

Different TCFs Differ in Their Ability to Activate OT Alone and in Combination with $beta$ -Catenin

The response of the OT reporter to $beta$ -catenin is presumably mediated by TCFs. TCFs are reported not to activate TCF-dependentreporters on their own, but coexpression of TCFs and $beta$ -cateninenhances reporter activation over the levels seen with eitheralone (see Korinek et al., 1997; Hsu et al., 1998, and referencestherein). Therefore, if activation of OT by cnxPg were due solelyto cnxPg's effects on $beta$ -catenin levels, increasing TCF levelsshould enhance OT activation by cnxPg. To test this hypothesis,we examined the effects of expressing various TCFs on the abilityof $beta$ -catenin and cnxPg to activate the OT reporter. These studiesled to several surprising observations. First, it is clear thatdifferent TCFs behaved quite differently in this assay system(Figure 3). Transfection of 293T cells with mLEF1 alone consistentlyactivated OT activity 10- to 20-fold above baseline (Figure 3,A and C), whereas transfection of either hTCF4 (Figure 3E) orXTCF3 (Figure 3G) alone failed to activate OT. Cotransfectionof LEF1 or hTCF4 with oncogenic forms of $beta$ -catenin resulted ina large increase in OT reporter activation (Figure 3, A and E)well beyond the strong activation induced by oncogenic $beta$ -cateninalone. A similar synergistic activation of OT was observed whencells were transfected with the S28 $right-arrow$ A mutant form of plakoglobinand LEF1 (Figure 3B).

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Figure 3. (A-C) Interactions between $beta$ -catenin, cnxPg, and TCFs. (A) 293T cells were transfected with plasmids driving the expression of either mouse LEF1 (2 µg), S37 $right-arrow$ F- $beta$ -catenin (2 µg), or both plasmids together, and their ability to activate the OT reporter was measured. A strong synergy between LEF1 and S37 $right-arrow$ F- $beta$ -catenin was seen. (B) A similar synergy in the activation of the OT reporter was observed when S28 $right-arrow$ A plakoglobin (S28A Pg) (1 µg) was coexpressed with mouse LEF1 (1 µg). (C) In contrast, cotransfection of 293T cells with mouse LEF1 plasmid DNA (1 or 2 µg) suppressed the activation of OT by cnxPg-GFP plasmid (1 µg). This pattern of reporter activity was seen reproducibly in at least three independent experiments. (D) Effect of TCF and cnxPg coexpression on soluble $beta$ -catenin levels. 293T cells were transfected with S37 $right-arrow$ F- $beta$ -catenin, cnxPg-GFP plasmid DNA, or both cnxPg-GFP and LEF1 or XTCF3 plasmid DNAs. After 36 h, the cells were homogenized and soluble $beta$ -catenin was assayed by immunoblot. Two exposures (1 and 4 min) of the blot are shown. (E-H) Differences in the activities of TCFs. (E) On its own, hTCF4 (1 µg) did not activate the OT reporter but did produce a strong enhancement of the activity of S37 $right-arrow$ F- $beta$ -catenin (2 µg). (F) Coexpression of hTCF4 and cnxPg-GFP suppressed cnxPg's ability to activate the OT reporter. (G) XTCF3 (2 µg) suppressed the ability of both the pt-mutant form of Xenopus $beta$ -catenin (2 µg) (described by Yost et al., 1996

) and the oncogenic mutant form of human $beta$ -catenin (2 µg) to activate the reporter. (H) XTCF3 (1 µg) did activate OT on its own, and coexpression of XTCF3 (1 µg) suppressed cnxPg-GFP's ability to activate OT. In E and H, the effects of transfecting mLEF1 (1 µg) are included for the purpose of comparing the various experiments. The patterns of reporter activity illustrated here were seen reproducibly in at least three independent experiments.

Previously, Molenaar et al. (1996) reported that XTCF3 enhanced the ability of $beta$ -catenin to activate a TCF-dependent reporter.In contrast, we found that cotransfection of XTCF3 and eitherthe human or Xenopus $beta$ -catenin suppressed $beta$ -catenin's abilityto activate OT by approximately twofold (Figure 3G). DNA-bindingstudies indicate that XTCF3 binds to $beta$ -catenin and that the XTCF3/ $beta$ -catenincomplex binds to a TCF-DNA consensus sequence (our unpublishedresults). The reason behind the discrepancy between our resultsand those of Molenaar et al. (1996) is unclear, but the abilityof XTCF3 to suppress $beta$ -catenin signaling is consistent with itsactivity in the Xenopus embryo (seebelow).

cnxPg Does Not Activate OT Simply by Stabilizing $beta$ -Catenin

Contrary to what would have been expected if cnxPg activated OT solely by increasing the level of cytosolic $beta$ -catenin, coexpressionof cnxPg with either mLEF1 (Figure 3C) or hTCF4 (Figure 3F) suppressedcnxPg's ability to activate OT. XTCF3's effect on cnxPg was similarto its effect on $beta$ -catenin, i.e., coexpression of XTCF3 suppressedactivation of the OT reporter by cnxPg (Figure 3H). The inhibitoryeffects of TCFs on cnxPg reporter activity were not due to effectson cytosolic levels of $beta$ -catenin, because cotransfection withmLEF1 or XTCF3 did not affect the levels of cytosolic $beta$ -catenininduced by cnxPg (Figure 3D).

cnxPg Alters the Intracellular Distribution of $beta$ -Catenin, Axin, and APC

To gain more insight into the actions of cnxPgs on signaling, we tested their abilities to alter the localization of variousWnt signaling components in Xenopus A6 cells. Because transfectionefficiencies are low in Xenopus cells by conventional methods,we injected DNAs encoding cnxPgs directly into nuclei (see Klymkowsky,1999). The encoded cnxPgs tended to form irregular cytoplasmicaggregates and did not appear to enter the plasma membrane efficiently(Figures 4A and 5, G and J). Occasionally, cnxPgs were seen ina reticular pattern (see Figure 8, E and I, for examples) likelyto represent the endoplasmic reticulum (our unpublished results).In contrast, unanchored forms of plakoglobin accumulate largelyin the nuclei in living and fixed cells (Karnovsky and Klymkowsky,1995; Merriam et al., 1997; Rubenstein et al., 1997) (Figure 5D).

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Figure 4. Localization of $beta$ -catenin in cells expressing cnxPgs. Xenopus A6 cells were injected intranuclearly with DNAs encoding cnxPg (A and B), cnxN3 $Delta$ Pg (C and D), or cnxN4 $Delta$ Pg (E and F); 20 h later, the cells were fixed and stained for plakoglobin with a mouse anti-plakoglobin mAb and an Alexa 596-conjugated secondary antibody (A, C, and E) and for $beta$ -catenin with a rabbit anti- $beta$ -catenin antiserum and an Alexa 488-conjugated secondary antibody (B, D, and F). A clear increase in nuclear $beta$ -catenin was seen in many cells expressing cnxPg (arrow 2 in B); however, there was variability in the effects observed. For example, a cell expressing high levels of cnxPg (arrow 1) could show little apparent increase in nuclear $beta$ -catenin compared with a neighboring cell expressing lower levels (arrow 2) or compared with an uninjected cell (arrow 3). In cells expressing cnxN3 $Delta$ Pg (C), there was often an apparent increase in nuclear $beta$ -catenin (D, arrow 1; an uninjected cell is marked by arrow 2); no such increase in nuclear $beta$ -catenin (F) was seen in cells expressing cnxN4 $Delta$ Pg (E) (arrows in F indicate the level of nuclear $beta$ -catenin in uninjected cells). All images have been deconvoluted.

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Figure 5. cnxPg colocalizes with exogenous Axin. To examine the colocalization between cnxPgs and Axin, Xenopus A6 cells were injected with plasmid DNAs encoding mtAxin either alone (A-C) or together with N2 $Delta$ -plakoglobin (D-F), cnxPg-GFP (G-I), cnxN3 $Delta$ Pg-GFP (J-L), or cnxN4 $Delta$ Pg-GFP (M-O); 20 h later, the cells were fixed and stained with the anti-myc antibody 9E10. In cells injected with mtAxin DNA alone, the protein accumulated in irregular cytoplasmic aggregates (A, phase image; B, staining with anti-myc antibody; C, staining with a rabbit anti-plakoglobin antibody to reveal cell boundaries). In cells coinjected with N2 $Delta$ -plakoglobin-GFP and mtAxin-encoding plasmids, theN2 $Delta$ -plakoglobin-associated green fluorescence (D) was localized to nuclei; mtAxin (E) was partially localized to nuclei and to the nuclear periphery (F shows an overlap of D and E). In contrast, when mtAxin was coinjected with cnxPg-GFP (G-I), cnxN2 $Delta$ Pg-GFP (our unpublished results), or cnxN3 $Delta$ Pg-GFP (J-L) plasmid DNAs, there was extensive colocalization of cnxPg-associated green fluorescence (G and J) and mtAxin (H and K) (I shows an overlap of G and H, and L shows an overlap of J and K). In contrast, when mtAxin and cnxN4 $Delta$ Pg DNAs were coinjected (M-O), no overlap was observed between cnxN4 $Delta$ Pg-GFP-associated green fluorescence (M) and the pattern of anti-myc staining (N) (O shows an overlap of M and N). All images except A-C were deconvoluted, and areas of yellow in F, I, L, and O correspond to regions of overlapping fluorescence.

Consistent with our biochemical studies of soluble $beta$ -catenin (see above) and the observations of Miller and Moon (1997; seealso Hsu et al., 1998), A6 cells injected with cnxPg DNA oftendisplayed increased levels of nuclear $beta$ -catenin (Figure 4). However,this effect was quite variable between cells and did not alwayscorrelate with the level of cnxPg expression (Figure 4, A-C).It is perhaps this variability that obscured an increase in nuclear $beta$ -catenin in embryonic cells expressing cnxPg (see Merriam etal., 1997). Injection of the cnxN3 $Delta$ Pg plasmid increased nuclear $beta$ -catenin in some cells (Figure 4, C and D), whereas expressionof the cnxN4 $Delta$ Pg-GFP polypeptide had no apparent effect on $beta$ -catenin'sintracellular localization (Figure 4, E andF).

Axin and the related protein Conductin/Axil bind to $beta$ -catenin in a complex with APC and Gsk3 $beta$ (see above). To determine whetherAxin could colocalize with cnxPgs, we coinjected DNAs encodingwild-type mtAxin (Zeng et al., 1997) into A6 cells either alone(Figure 5, A-C) or together with DNA encoding either N2 $Delta$ Pg-GFP(Figure 5, D-F) or cnxPgs (Figure 5, G-O). After injection ofmtAxin DNA alone, mtAxin was found in irregular aggregates scatteredthroughout the cytoplasm and excluded from the nucleus (Figure5, A-C). When DNAs encoding mtAxin and N2 $Delta$ Pg-GFP were coinjected,green fluorescence from the N2 $Delta$ Pg-GFP polypeptide was almost entirelynuclear, whereas mtAxin was found in aggregates scattered throughoutthe cytoplasm and within the nuclei (Figure 5, D-F). When mtAxinand cnxPg-GFP DNAs were coinjected, the two polypeptides colocalized(Figure 5, G-I). Deletion of plakoglobin's N-terminal head andfirst two Arm repeats (cnxN3 $Delta$ Pg-GFP) did not disrupt the colocalizationof mtAxin with cnxPg (Figure 5, J-L), whereas deletion of thethird Arm repeat (cnxN4 $Delta$ Pg-GFP) abolished colocalization (Figure5, M-O). In human 293T cells, coexpression of mtAxin with cnxPgsuppressed cnxPg's ability to activate the OT reporter by 40-60%(our unpublishedresults).

APC forms a complex with $beta$ -catenin or plakoglobin (see above), targeting these catenins for proteolytic degradation. In XenopusA6 cells, anti-APC antibody stained both nuclei and cytoplasmdiffusely, and staining of the cell boundary was sometimes visible(Figure 6, H and I) (see Neufeld and White, 1997; Senda et al.,1998). In cells expressing cnxPg-GFP (Figure 6, A-C), anti-APCstaining colocalized with cnxPg-GFP. APC colocalized with cnxN3 $Delta$ Pg(Figure 6, D-F) but not with cnxN4 $Delta$ Pg (Figure 6, G-I) or cnxN5 $Delta$ Pg(our unpublished results).

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Figure 6. cnxPg colocalization with APC. The nuclei of Xenopus A6 cells were injected with DNAs encoding various cnxPgs. After ~16-18 h, the cells were fixed and stained for APC using an Alexa 596-conjugated secondary antibody. cnxPg-GFP (A), visualized through its green fluorescence, was found to induce the reorganization of endogenous APC (B) (C shows an overlap of A and B). Endogenous APC was found to colocalize with cnxN3 $Delta$ Pg-GFP (D, green fluorescence; E, APC staining; F, overlap) but not with cnxN4 $Delta$ Pg-GFP (G, green fluorescence; H, APC staining; I, overlap). Staining for APC was also found within nuclei of some cells (I, arrow). Punctate anti-APC staining at cell boundaries can be seen in some images (H, arrows). All images were deconvoluted, and areas of yellow in C, F, and I correspond to regions of overlap.

cnxPg Does Not Induce the Redistribution of Either E-Cadherin or Dishevelled

Chitaev et al. (1996) showed that membrane-anchored forms of plakoglobin were capable of interacting with desmosomal cadherins,whereas Cox et al. (1999) reported that anchored forms of Armadillolocalized to the plasma membrane and coimmunoprecipitated withDE-cadherin. However, cnxPgs do not efficiently reach the plasmamembrane in A6 cells (see above), and double-label immunofluorescencemicroscopy revealed little overlap between cnxPgs and E-cadherin(Figure 7, A and B).

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Figure 7. Analysis of colocalization between cnxPg, E-cadherin, Dishevelled, and XLEF-1. Xenopus A6 cell nuclei were injected with DNAs encoding cnxPg (A and B), mtXDvl (C), mycXLEF1 (D), cnxPg-GFP and mtXDvl (E-G), or cnxPg-GFP and mycXLef1 (H-J); 20 h later, the cells were fixed and stained. Cells injected with cnxPg DNA were stained with an anti-E-cadherin mAb (A) and a rabbit anti-plakoglobin antibody (B). Cytoplasmic aggregates of cnxPg (B, arrows) did not overlap with intracellular E-cadherin staining (A). mtXDvl (C) was exclusively cytoplasmic, whereas mycXLEF1 was found exclusively in the nucleus (D) (arrows in C and D point to nuclei). When cnxPg-GFP and mtXDvl DNAs were coinjected, the cnxPg-GFP (E, visualized through its autofluorescence) showed no tendency to colocalize with the mtXDvl (F; G shows an overlap of E and F). In contrast, when cnxPg-GFP and mycXLEF1 DNAs were coinjected, the cnxPg-GFP (H, visualized through its autofluorescence) appeared to overlap with the mycXLEF staining (I; J shows an overlap of H and I). In the most extreme examples, such as that illustrated here, the redistribution of XLEF1 was dramatic, such that the nuclear localization of mycXLEF1 was significantly reduced (arrows point to the position of the nucleus). Images in A and B are standard photomicrographs, whereas images in C-J were deconvoluted.

Genetic studies indicate that Dishevelled is activated in response to Wnt signaling and plays a role in the inhibition ofGsk3 $beta$ . To determine if the expression of cnxPg altered the distributionof Dishevelled, we coexpressed cnxPg-GFP with a myc-tagged formof Xenopus Dishevelled (Sokol, 1996) in A6 cells. Exogenous Dishevelledwas distributed throughout the cytoplasm and excluded from thenucleus (Figure 7C). The presence of cnxPg had no apparent effecton the distribution of Dishevelled (Figure 7, E-G).

cnxPgs Can Sequester TCFs in the Cytoplasm of A6 Cells

We have previously proposed that cnxPgs act, at least partially, by sequestering and inhibiting negatively acting factorsin the cytoplasm. The ability of cnxPgs to sequester Axin andAPC supports such a model. To determine whether cnxPgs could alsosequester TCFs in Xenopus cells, we coexpressed them with eithera myc-tagged form of XLEF1 or myc- and GFP-tagged forms of XTCF3and hLEF1 (Figure 1). When expressed on their own, XLEF1 (Figure7D) and XTCF3 (Figure 8C) were exclusively nuclear. When DNAsencoding XLEF and cnxPg (Figure 7, H-J) or XTCF3 and cnxPg (ourunpublished results) were coinjected, a significant amount offluorescent signal was observed in the cytoplasm. Cytoplasmiclocalization of exogenous TCFs was observed in cells expressingcnxN2 $Delta$ Pg (Figure 8, A and B) or cnxN3 $Delta$ Pg (Figure 8D) but not incells expressing cnxN4 $Delta$ Pg (Figure 8, E and F) or cnxN5 $Delta$ Pg (ourunpublished results). This cytoplasmic localization of exogenousTCFs was not an artifact of fixation, because it could be readilyobserved in living cells (Figure 8D).

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Figure 8. Cytoplasmic localization of XTCF3 associated with the coexpression of cnxPg. Cells were injected with DNA encoding GFP-tagged XTCF3 either alone (C) or together with cnxN2 $Delta$ Pg (A and B), cnxN3 $Delta$ Pg (D), or cnxN4 $Delta$ Pg (E and F); 20 h later, cells were examined while living (C and D) or were fixed and stained with an anti-plakoglobin antibody to visualize the cnxPg polypeptide (A and E). When coexpressed in A6 cells with full-length cnxPg (our unpublished results), cnxN2 $Delta$ Pg (A and B) or cnxN3 $Delta$ Pg (D), GFP-XTCF3-derived green fluorescence was observed in the cytoplasm. Cytoplasmic localization of GFP-tagged XTCF3 was not observed in cells expressing XTCF3 alone (C) or in cells coexpressing cnxN4 $Delta$ Pg (E and F). Removal of the N-terminal 166 amino acids of XTCF3 abolished its interaction with cnxPg (G, stained for plakoglobin; H, green fluorescence). The images in this figure were not deconvoluted.

The colocalization of XTCF3 and $beta$ -catenin requires the presence of the "catenin-binding domain" located at the N terminusof XTCF3 and LEF1 (Molenaar et al., 1996). A version of XTCF3with this domain deleted (mt $Delta$ N₁₆₆XTCF3-GFP) failed to colocalizewith cnxPg (Figure 7, G and H). Similarly, we found no apparentcolocalization between cnxPg and tagged forms of the cytoplasmictail domain of Xenopus Notch, the zinc-finger transcription factorXSlug, or the bHLH transcription factor NeuroD (our unpublishedresults), all of which localized to nuclei. This finding suggeststhat the colocalization between cnxPg and TCFs is not due to nonspecificinteractions between highly expressed proteins in thesecells.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Recently, our understanding of the mechanisms underlying Wnt signaling has deepened considerably. After the discovery of theinteraction between $beta$ -catenin or plakoglobin and TCFs, it wascommonly held that $beta$ -catenin and plakoglobin acted exclusivelyas transcriptional coactivators. It was already clear, however,that such a model did not accurately describe one important modelsystem of Wnt-like signaling, i.e., dorsal axis formation in Xenopus(see Klymkowsky, 1997). XTCF3, the only TCF so far detected inthe early embryo at the time of dorsal determination (see Molenaaret al., 1998), does not by itself induce axis duplication. Infact, overexpression of XTCF3 partially suppresses dorsal axisformation (Zorn et al., unpublished observations), and a mutatedform of XTCF3, missing its catenin-binding domain, blocks dorsaldifferentiation (Molenaar et al., 1996). Analysis of the promoterregion of the homeobox gene Siamois, a target of Wnt/ $beta$ -catenintranscriptional regulation in the early Xenopus embryo (Carnacet al., 1996), indicates that XTCF3 represses expression ventrallybut does not appear to stimulate expression dorsally (Brannonet al., 1997; see also Fan et al., 1998). In contrast to Molenaaret al. (1996), we found that XTCF3 fails to enhance activationof the TCF-responsive OT reporter by $beta$ -catenin, but rather suppressesit (Figure 3G). The origin of this discrepancy is unclear. Wehave confirmed the sequence of the XTCF3 construct used in ourstudies and shown that XTCF3 binds to a TCF DNA consensus sequenceand that the XTCF3/DNA complex binds to $beta$ -catenin (our unpublishedresults). Perhaps differences in the TCF-responsive reportersand cell lines used are responsible, although the repressive effectsof XTCF3 on OT activity are more consistent with the effects ofXTCF3 overexpression observed in the Xenopus embryo (see Molenaaret al., 1996; Klymkowsky, 1997). In any case, the negative effectsof XTCF3 are consistent with a model in which anchored forms ofplakoglobin induce Wnt-like axis duplication in Xenopus, at leastin part, by repressing XTCF3 activity, thereby allowing the ectopicexpression of Siamois and other directly dorsalizing genes (Figure9) (see Klymkowsky, 1997).

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Figure 9. A model of cnxPg action. (A) In the early Xenopus embryo, XTCF3 appears to repress the ventral expression of dorsalizing genes (e.g., Siamois); on the dorsal side of the embryo, increased levels of $beta$ -catenin act to suppress the repressive action of XTCF3. cnxPgs stabilize $beta$ -catenin through interactions with components of the $beta$ -catenin turnover system, i.e., APC and Axin. They can also act directly on TCFs by sequestering them in the cytoplasm. (B) In Drosophila, tethered armadillo inhibits the armadillo turnover system, leading to increased levels of armadillo, interactions with pangolin/dTCF (Pan/dTCF), and altered gene expression. Tethered armadillo has been shown to interact strongly with DE-cadherin (Cox et al., 1999

). In the absence of wild-type armadillo, the interaction between tethered armadillo and cadherins would be expected to increase, thereby suppressing the ability of tethered armadillo to interact with Pan/dTCF. In contrast, cnxPg does not appear to interact significantly with E-cadherin in A6 cells (see Figure 7, A and B). The idea that cnxPg could sequester TCFs in the cytoplasm of vertebrate cells is similar to the pathway (C) proposed for Wnt signaling in the early C. elegans embryo by Thorpe et al. (1997)

and Rocheleau et al. (1997)

. Based on the data presented here, we suggest that cnxPg can contribute to the induction of dorsal mesoderm by stabilizing $beta$ -catenin and sequestering XTCFs or other negatively acting factors.

cnxPg Stabilizes Endogenous $beta$ -Catenin

The proposal that membrane-anchored forms of plakoglobin or $beta$ -catenin act solely by inhibiting the activity of XTCF3 has beenchallenged. Miller and Moon (1997) provided clear evidence thatexpression of a membrane-anchored $beta$ -catenin leads to the accumulationof soluble $beta$ -catenin, presumably by inhibiting the $beta$ -catenin turnoversystem (see also Hsu et al., 1998; Simcha et al., 1998). Althoughwe previously did not detect an increase in nuclear $beta$ -cateninlevels in embryonic cells expressing anchored plakoglobins (Merriamet al., 1997), it now seems likely that the methodologies usedwere not sensitive enough to detect the small changes in $beta$ -cateninlevels involved (see Figure 4 for example), particularly in thepresence of the high basal levels of nuclear $beta$ -catenin presentat the embryonic stage examined. Our own subsequent studies, presentedhere, confirm that anchored plakoglobins do stabilize cytosolic $beta$ -catenin in both Xenopus A6 (Figure 4) and human 293T cells (Figure2D), presumably by interacting with negative factors, i.e., APC(Miller and Moon, 1997) (Figure 6) and Axin (Figure 5). Thus,the idea that anchored plakoglobins or $beta$ -catenins act, at leastin part, by stabilizing soluble $beta$ -catenin is wellestablished.

Our analysis indicates that the N-terminal head and the first Arm repeat of plakoglobin can be removed from cnxPg withoutabolishing the ability to colocalize with Axin and APC (Figures5 and 6). Removal of the second Arm repeat (cnxN3 $Delta$ Pg), however,impaired the ability of the polypeptide to induce axis duplication(Figure 2A), activate the OT reporter (Figure 2C), and stabilize $beta$ -catenin (Figure 2E). Removal of the third Arm repeat (cnxN4 $Delta$ Pg)completely abolished axis duplication activity and the abilityto activate the OT reporter and greatly reduced, although it didnot eliminate, the stabilizing effect on $beta$ -catenin (Figure 2,A, C, and E). The cnxN4 $Delta$ Pg and cnxN5 $Delta$ Pg polypeptides also failedto colocalize with either Axin or APC (Figures 5, M-O, and 6,G-I). Interestingly, a N5 $Delta$ version of plakoglobin induces axisduplication in Xenopus (Rubenstein et al., 1997), arguing fordifferences in the Wnt-signaling mechanisms of the "free" andanchored forms of theprotein.

cnxPg Does More Than Stabilize $beta$ -Catenin

Our analysis of cnxPg in vertebrate cells suggests that cnxPgs do not act exclusively through effects on $beta$ -catenin. First,expression of either cnxPg or Wnt-1 in 293T cells results in similarlevels of soluble $beta$ -catenin (Figure 2F). A comparable stabilizationof $beta$ -catenin in NIH 3T3 cells by membrane-tethered $beta$ -catenin orWnt-1 was observed by Hsu et al. (1998). Despite similar effectson cytosolic $beta$ -catenin levels, anchored plakoglobins transactivatedthe OT reporter to levels 10- to 20-fold greater than did Wnt-1(Figure 2G and Table 1).

Second, work from several laboratories has shown that $beta$ -catenin and LEF1 or TCF4 act synergistically to transactivate OT andother similar reporters when cotransfected into a number of celltypes (see Korinek et al., 1997; Hsu et al., 1998). We confirmedthese observations by showing that an oncogenic form of $beta$ -catenin,when coexpressed with LEF1 or hTCF4, strongly induced reporteractivity (at least 4-fold above the levels induced by $beta$ -cateninalone and up to 300-fold over baseline activity) (Figure 3, AandE).

Miller and Moon (1997) suggested that plakoglobin acts to induce axis duplication indirectly through effects on $beta$ -cateninstability. In cultured cells, expression of plakoglobin stabilizesendogenous $beta$ -catenin (Simcha et al., 1998), and coexpression ofplakoglobin with LEF1 produces a similar synergistic activationof the OT promoter (Figure 3B). Although this may be true forfull-length plakoglobin, it does not seem to be the case for deletedforms of the protein, because the N2 $Delta$ form of plakoglobin inducesaxis duplication (Rubenstein et al., 1997) but does not appearto alter cytoplasmic $beta$ -catenin levels (Figure 2E).

If cnxPg's signaling activity were due solely to its ability to increase $beta$ -catenin levels, we would predict a similar synergismin OT activation between cnxPg and TCFs. Instead, coexpressionof cnxPg and LEF1 or hTCF4 inhibited cnxPg-induced OT transactivation(Figure 3, C and F). One possible mechanism to explain such aninhibition is that the binding of TCFs to cnxPg blocks the interactionbetween cnxPg, Axin, and APC, leading to a decrease in cytoplasmic $beta$ -catenin. This does not appear to be the case, however. Coexpressionof LEF1 or XTCF3 and cnxPg does not appear to decrease the cnxPg-inducedstabilization of $beta$ -catenin (Figure 3D).

Cytoplasmic Sequestration of TCFs by cnxPg

One potential explanation for the behavior of cnxPg emerges from the model we originally proposed, namely, that cnxPg altersgene expression, at least in part, by sequestering in the cytoplasma molecule that normally represses relevant target genes involvedin Xenopus axis induction (Figure 9). A growing body of evidencesupports the idea that TCFs, and XTCF3 (Figure 2G) in particular,have the characteristics of such a molecule (see above; Klymkowsky,1997; Bienz, 1998). Mutation of TCF sites in the Ultrabithoraxand Siamois promoters of Drosophila and Xenopus, respectively(Brannon et al., 1997; Riese et al., 1997; Fan et al., 1998),derepresses expression of these genes in cells not exposed toWingless/Wnt signals. Furthermore, Groucho-like corepressor proteinsbind to XTCF3 and, as a complex, XTCF3 and Groucho can constitutivelyrepress transcription at promoters with TCF-binding sites (Rooseet al., 1998).

To examine the possibility that cnxPgs can bind to and sequester TCF-type transcription factors in the cytoplasm, we examinedthe behavior of myc- and GFP-tagged forms of XLEF1 and XTCF3.Nuclear when expressed on their own (Figures 7D and 8C), bothXLEF1 (Figure 7, H-J) and XTCF3 (Figure 8, B and D) were foundto accumulate to readily detectable levels in the cytoplasm ofcells expressing cnxPg. The cytoplasmic localization of GFP-taggedTCFs could be observed in living cells (Figure 8D), ruling outany artifactual redistribution of the protein during fixation.Staining of fixed cells showed a close association between exogenousTCFs and cnxPgs (Figures 7, H-J, and 8, A andB).

The specificity of the colocalization between cnxPg and TCFs was demonstrated in two ways. The colocalization of TCFs and $beta$ -catenin involves the N-terminal region of these DNA-bindingproteins (Behrens et al., 1996; Molenaar et al., 1996). When amutated version of XTCF3 lacking the N-terminal 166 amino acidswas tested, it did not colocalize with cnxPg (Figure 8, E andF). We have tested a number of other identically tagged transcriptionfactors and nuclear proteins, including the Xenopus zinc-fingertranscription factor XSlug, the cytoplasmic domain of the XenopusNotch homologue Xotch, and the mouse HLH transcription factorNeuroD. None of these polypeptides showed any tendency to colocalizewith cnxPg (our unpublished results). Based on these data, weconclude that cnxPg specifically interacts with, and can sequester,exogenous TCFs in the cytoplasm of Xenopus cells. Because Wnt-1and cnxPg induce similar increases in $beta$ -catenin levels (Figure2F) but differ significantly in their signaling activity (as measuredby OT activation) (Figure 2G), we suggest that inhibition of therepressive activities of TCF family members may, at least in part,account for this difference. Alternatively, cnxPg may either activatesome other activator or inhibit some other repressor of TCF signaling,distinct from $beta$ -catenin, APC, Axin, orTCF.

How does the ability of cnxPg to sequester a portion of exogenous TCFs in somatic cells relate to its effects in the Xenopusembryo? This question clearly requires an analysis of the effectsof cnxPg on endogenous TCFs; we are currently generating anti-XTCF3antibodies to directly examine this issue. However, it is clearthat in somatic cells cnxPgs can sequester at least a portionof total exogenous TCFs in the cytoplasm. In the early Xenopusembryo, which breaks down its nuclei every 30-40 min during theperiod of axis determination (Newport and Kirschner, 1982), thelikelihood that cnxPgs can significantly affect the intracellulardistribution of endogenous XTCF3 seems even morelikely.

The Dual Mechanism of cnxPg Action

Based on all of the data presented here, we propose that cnxPg acts by two distinct mechanisms to affect Wnt signaling (Figure9A). It inhibits the negatively acting cytoplasmic proteins Axinand APC (Figures 5 and 6), thereby stabilizing $beta$ -catenin (Figures2 and 4). This is the mechanism originally proposed by Millerand Moon (1997). On the other hand, cnxPg can also clearly sequesterexogenous TCFs to the cytoplasm of Xenopus A6 cells (Figures 7and 8), and its ability to activate the OT reporter is inhibited,rather than activated, by TCF coexpression (Figure 3), suggestingthat TCFs may compete for binding sites on cnxPg for negativelyacting factors. Clearly, it is the relative levels of specificTCFs expressed in a specific cell type, combined with their relativeaffinities for $beta$ -catenin, plakoglobin, and other accessory factors(e.g., Groucho-like proteins, pontin-52, ALY, etc.), that is criticalfor determining the outcome of cnxPgexpression.

Differences between Anchored Forms of Plakoglobin and Armadillo

To further study the signaling activities of cytoplasmic catenins, it is necessary to uncouple cnxPg's ability to increasecytoplasmic levels of $beta$ -catenin from its ability to bind TCFsand other regulatory proteins. Cox et al. (1999) performed suchan analysis in Drosophila using a membrane-tethered form of Armadillo.Drosophila appears to have a single TCF-type protein, pangolin/dTCF,which can act both positively, in conjunction with Armadillo (Brunneret al., 1997; van de Wetering et al., 1997), and negatively, incombination with dCBP (Waltzer and Bienz, 1998) and Groucho (Cavalloet al., 1998). In the presence of the "nearly null" allele ofarmadillo, arm^XP33, Cox et al. (1999) found no evidence that anchored Armadilloaltered target gene expression. However, there is an importantcaveat to this conclusion: tethered armadillo rescues the adhesiondefects associated with armadillo mutations and interacts withDE-cadherin, as demonstrated by coimmunoprecipitation analyses(Cox et al., 1999). It is known from studies in Xenopus (see Heasmanet al., 1994; Karnovsky and Klymkowsky, 1995; Fagotto et al.,1996) and Drosophila (Sanson et al., 1996) that binding to cadherinblocks the signaling activities of armadillo, $beta$ -catenin, and plakoglobin.Therefore, it is likely that the signaling function of tetheredarmadillo is inhibited by interactions with DE-cadherin (see Figure9B). Moreover, the absence of wild-type armadillo would be expectedto enhance the interaction between tethered armadillo and endogenouscadherins. In contrast, cnxPg does not efficiently reach the plasmamembrane in (Figure 7, A and B; see also Merriam et al., 1997),and there appears to be no substantial colocalization of cnxPgwith endogenous cadherins (Figure 7, A and B). It is likely, therefore,that differences in the abilities of different anchored cateninsto interact with cadherins may underlie the observed differencesin their ability to activate gene expression in differentsystems.

It is already clear that different TCF-regulated promoters differ in their requirements for catenin cofactors. For example,the T-cell receptor $alpha$ -enhancer is regulated by LEF-1 in a $beta$ -catenin-independent,ALY-dependent manner (Hsu et al., 1998), whereas other TCF-regulatedpromoters, such as that in the cyclin D1 gene, appear to require $beta$ -catenin as a coactivator (Tetsu and McCormick, 1999) and mayrespond to cnxPg differently than does the OTpromoter.

Although cnxPgs are artificial proteins expressed from exogenous DNAs, it is known that endogenous $beta$ -catenin and plakoglobincan form complexes with several cytoplasmic proteins. Indeed,interactions of $beta$ -catenin and plakoglobin with APC, Axin, Conductin/Axil,Presenilin, cadherins, EGFR, fascin, pontin-52, and phosphataseshave all been described (see above). Binding to cadherins clearlyblocks the signaling activity of plakoglobin and $beta$ -catenin (seeabove). It is not known, however, whether interactions between $beta$ -catenin (or plakoglobin) and other proteins inhibit the abilityof the complex to bind to TCF proteins. If such interference doesnot occur, cytoplasmic sequestration of TCFs could play a physiologicalrole in the regulation of Wnt signaling. In fact, studies of endodermformation in Caenorhabditis elegans indicate that nuclear levelsof the TCF-like transcription factor pop-1 are reduced in responseto Wnt signaling (Rocheleau et al., 1997; Thorpe et al., 1997)(Figure 9C). This result supports our premise that regulationof the intracellular distribution of TCFs may be involved in vertebrateWnt signaling aswell.

	ACKNOWLEDGMENTS

We thank Amy Hopkins for technical assistance with cell culture and plasmid growth, Aaron Zorn for stimulating discussionsof Wnt signaling, and Rudolf Grosschedl, Pierre McCrea, KathyJones, Hans Clevers, Miranda Molenaar, Barry Gumbiner, SergieSokol, Michael Sargent, Thomas Kurth, Peter Hausen, Paul Robbins,Werner Franke, Jacqueline Lee, and Randy Moon for supplying cDNAsand antibodies. In particular, we thank Richard Nelson and BarryGumbiner for examining the specificity of the anti-APC antibodiesused in this study and Mark Peifer for discussion of work beforepublication. This work was supported by a grant from the NationalInstitutes of Health (GM54001) to M.W.K. B.O.W. is a Fellow ofthe Cancer Research Fund of the Damon Runyon-Walter Winchell Foundation.G.D.B. is a Howard Hughes Medical Institute-National Institutesof Health ResearchScholar.

	FOOTNOTES

These two authors contributed equally to thismanuscript.

Corresponding author. E-mail address: klym{at}spot.colorado.edu.

Present address: Van Andel Research Institute, 201 Monroe Avenue NW, Suite 400, Grand Rapids, MI49503.

ABBREVIATIONS

Abbreviations used: APC, adenomatous polyposis coli; cnxPg, connexin-plakoglobin; Dvl, dishevelled; GFP, green fluorescent protein; Gsk3 $beta$ , glycogen synthase kinase 3 $beta$ ; mt, myc tag; TBS, Tris-buffered saline; TCFs, LEF/TCF proteins.

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