Repressor roles for TCF-4 and Sfrp1 in Wnt signaling in breast cancer.

Mutations in Wnt pathway genes are rare in human breast cancer, yet activation of the pathway is evident from the misolocalization of beta-catenin. We searched for relationships in the expression of Wnt pathway genes and found that both secreted frizzled related protein 1 (Sfrp1) and TCF-4 transcripts were all highly downregulated in a common subset of breast cancers relative to normal breast tissue. Sfrp1 has been previously characterized as a Wnt inhibitor, and we found that interfering with its expression in the human mammary epithelial cell line MCF10A activated Wnt signaling. Reduction of TCF-4 levels in breast cancer was surprising as it is a transcription factor that is responsive to Wnt signaling. Therefore, we investigated a possible inhibitory role for TCF-4 in human breast cells as well as further characterizing Sfrp1. We identified CD24 as a Wnt target in MCF10A cells and used its expression a marker of Wnt signaling. Interfering with either Sfrp1 or TCF-4 in this cell line enhanced CD24 expression. Furthermore, removal of TCF/LEF binding sites in a CD24-luciferase reporter resulted in elevated reporter gene expression. Our results indicate that both Sfrp1 and TCF-4 repress Wnt signaling in breast tissue and their downregulation contributes to the activation of Wnt signaling.

Axin-dependent phosphorylation of the adenomatous polyposis coli protein mediated by casein kinase 1epsilon.

Axin and the adenomatous polyposis coli protein (APC) interact to down-regulate the proto-oncogene beta-catenin. We show that transposition of an axin-binding site can confer beta-catenin regulatory activity to a fragment of APC normally lacking this activity. The fragment containing the axin-binding site also underwent hyperphosphorylation when coexpressed with axin. The phosphorylation did not require glycogen synthase kinase 3beta but instead required casein kinase 1epsilon, which bound directly to axin. Mutation of conserved serine residues in the beta-catenin regulatory motifs of APC interfered with both axin-dependent phosphorylation and phosphorylation by CKIepsilon and impaired the ability of APC to regulate beta-catenin. These results suggest that the axin-dependent phosphorylation of APC is mediated in part by CKIepsilon and is involved in the regulation of APC function.

Overexpression of the retinoic acid-responsive gene Stra6 in human cancers and its synergistic induction by Wnt-1 and retinoic acid.

Genetic defects in the Wnt-1 signaling pathway contribute to human tumor progression and are especially prevalent in colorectal cancer. We screened mouse C57MG cells to isolate mRNAs induced by Wnt-1 and identified Stra6, an mRNA known to be up-regulated by retinoic acid. Up-regulation of Stra6 mRNA was also observed in hyperplastic mammary tissue and mammary gland tumors from transgenic mice expressing Wnt-1 and in human tumors that frequently harbor defects in Wnt-1 signaling. Stimulation of C57MG cells with retinoic acid plus Wnt-1 resulted in expression of Stra6 transcript to levels greatly exceeding that observed with either stimulus alone. This synergy could be explained in part by the up-regulation of retinoic acid receptor-gamma that was observed in response to Wnt-1 signaling. Accordingly, treatment of human colorectal cancer cell lines with retinoic acid resulted in the up-regulation of Stra6 mRNA and accumulation of Stra6 protein at the cell membrane. The data support a model in which Wnt-1 signaling synergizes with retinoids to activate retinoic acid receptor-gamma-responsive genes in human cancers.

Structural basis of the Axin-adenomatous polyposis coli interaction.

Axin and the adenomatous polyposis coli (APC) tumor suppressor protein are components of the Wnt/Wingless growth factor signaling pathway. In the absence of Wnt signal, Axin and APC regulate cytoplasmic levels of the proto-oncogene beta-catenin through the formation of a large complex containing these three proteins, glycogen synthase kinase 3beta (GSK3beta) and several other proteins. Both Axin and APC are known to be critical for beta-catenin regulation, and truncations in APC that eliminate the Axin-binding site result in human cancers. A protease-resistant domain of Axin that contains the APC-binding site is a member of the regulators of G-protein signaling (RGS) superfamily. The crystal structures of this domain alone and in complex with an Axin-binding sequence from APC reveal that the Axin-APC interaction occurs at a conserved groove on a face of the protein that is distinct from the G-protein interface of classical RGS proteins. The molecular interactions observed in the Axin-APC complex provide a rationale for the evolutionary conservation seen in both proteins.

Functional interaction between Galpha(z) and Rap1GAP suggests a novel form of cellular cross-talk.

G(z) is a member of the G(i) family of trimeric G proteins whose primary role in cell physiology is still unknown. In an ongoing effort to elucidate the cellular functions of G(z), the yeast two-hybrid system was employed to identify proteins that specifically interact with a mutationally activated form of Galpha(z). One of the molecules uncovered in this screen was Rap1GAP, a previously identified protein that specifically stimulates GTP hydrolytic activity of the monomeric G protein Rap1 and thus is believed to function as a down-regulator of Rap1 signaling. Like G(z), the precise role of Rap1 in cell physiology is poorly understood. Biochemical analysis using purified recombinant proteins revealed that the physical interaction between Galpha(z) and Rap1GAP blocks the ability of RGSs (regulators of G protein signaling) to stimulate GTP hydrolysis of the alpha subunit, and also attenuates the ability of activated Galpha(z) to inhibit adenylyl cyclase. Structure-function analyses indicate that the first 74 amino-terminal residues of Rap1GAP, a region distinct from the catalytic core domain responsible for the GAP activity toward Rap1, is required for this interaction. Co-precipitation assays revealed that Galpha(z), Rap1GAP, and Rap1 can form a stable complex. These data suggest that Rap1GAP acts as a signal integrator to somehow coordinate and/or integrate G(z) signaling and Rap1 signaling in cells.

Evidence for SH3 domain directed binding and phosphorylation of Sam68 by Src.

Sam68 is a 68 kDa protein that associates with and is phosphorylated by the c-Src kinase at mitosis. It contains a KH domain implicated in RNA binding and several proline-rich motifs that resemble known SH3 binding sites. The SH3 domains of c-Src, phosphatidylinositol 3-OH kinase, phospholipase C-gamma and Grb2 protein (containing two SH3 domains), but not other SH3 domains tested, were capable of binding Sam68 in vitro. Synthetic peptides corresponding to the proline motifs of Sam68 inhibited with different efficiencies the binding of SH3 domains to Sam68 suggesting that the proline motifs of Sam68 function as specific SH3 domain binding sites. Mutation of Sam68 SH3 binding sites further indicated that the SRC SH3 domain mediates binding of Src to unphosphorylated Sam68. Phosphorylation of Sam68 by Src kinase was inhibited when the Src SH3 binding site of Sam68 was mutated or when corresponding peptides were added to in vitro kinase reactions indicating that binding of the Src SH3 domain to a specific site near the amino-terminus of Sam68 (including residues 38 - 45: PPLPHRSR) facilitates phosphorylation of Sam68 by the Src kinase domain. Sam68-based proline peptides had no effect on the phosphorylation of another in vitro substrate of Src, enolase. These results suggest that Src effectively mounts Sam68 through its SH3 domain, possibly as a mechanism to position the kinase domain close to substrate tyrosine residues in the carboxyl-half of the protein.

A GSK3-binding peptide from FRAT1 selectively inhibits the GSK3-catalysed phosphorylation of axin and beta-catenin.

The Axin-dependent phosphorylation of beta-catenin catalysed by glycogen synthase kinase-3 (GSK3) is inhibited during embryogenesis. This protects beta-catenin against ubiquitin-dependent proteolysis, leading to its accumulation in the nucleus, where it controls the expression of genes important for development. Frequently rearranged in advanced T-cell lymphomas 1 (FRAT1) is a mammalian homologue of a GSK3-binding protein (GBP), which appears to play a key role in the correct establishment of the dorsal-ventral axis in Xenopus laevis. Here, we demonstrate that FRATtide (a peptide corresponding to residues 188-226 of FRAT1) binds to GSK3 and prevents GSK3 from interacting with Axin. FRATtide also blocks the GSK3-catalysed phosphorylation of Axin and beta-catenin, suggesting a potential mechanism by which GBP could trigger axis formation. In contrast, FRATtide does not suppress GSK3 activity towards other substrates, such as glycogen synthase and eIF2B, whose phosphorylation is independent of Axin but dependent on a 'priming' phosphorylation. This may explain how the essential cellular functions of GSK3 can continue, despite the suppression of beta-catenin phosphorylation.

The metalloproteinase matrilysin is a target of beta-catenin transactivation in intestinal tumors.

Matrilysin is a matrix metalloproteinase expressed in the tumor cells of greater than 80% of intestinal adenomas. The majority of these intestinal tumors are associated with the accumulation of beta-catenin, a component of the cadherin adhesion complex and, through its association with the T Cell Factor (Tcf) DNA binding proteins, a regulator in the Wnt signal transduction pathway. In murine intestinal tumors, matrilysin transcripts show striking overlap with the accumulation of beta-catenin protein. The matrilysin promoter is upregulated as much as 12-fold by beta-catenin in colon tumor cell lines in a manner inversely proportional to the endogenous levels of beta-catenin/Tcf complex and is dependent upon a single optimal Tcf-4 recognition site. Coexpression of the E-cadherin cytoplasmic domain blocked this induction and reduced basal promoter activity in every colon cancer cell line tested. Inactivation of the Tcf binding site increased promoter activity and overexpression of the Tcf factor, LEF-1, significantly downregulated matrilysin promoter activity, suggesting that beta-catenin transactivates the matrilysin promoter by virtue of its ability to abrogate Tcf-mediated repression. Because genetic ablation of matrilysin decreases tumor formation in multiple intestinal neoplasia (Min) mice, we propose that regulation of matrilysin production by beta-catenin accumulation is a contributing factor to intestinal tumorigenesis.

The ubiquitin-proteasome pathway and serine kinase activity modulate adenomatous polyposis coli protein-mediated regulation of beta-catenin-lymphocyte enhancer-binding factor signaling.

The tumor suppressor function of the adenomatous polyposis coli protein (APC) depends, in part, on its ability to bind and regulate the multifunctional protein, beta-catenin. beta-Catenin binds the high mobility group box transcription factors, lymphocyte enhancer-binding factor (LEF) and T-cell factor, to directly regulate gene transcription. Using LEF reporter assays we find that APC-mediated down-regulation of beta-catenin-LEF signaling is reversed by proteasomal inhibitors in a dose-dependent manner. APC down-regulates signaling induced by wild type beta-catenin but not by the non-ubiquitinatable S37A mutant, beta-catenin. Bisindoylmaleimide-type protein kinase C inhibitors, which prevent beta-catenin ubiquitination, decrease the ability of APC to down-regulate beta-catenin-LEF signaling. All these effects on LEF signaling are paralleled by changes in beta-catenin protein levels. Lithium, an inhibitor of glycogen synthase kinase-3beta, does not alter the ability of APC to down-regulate beta-catenin protein and beta-catenin-LEF signaling in the colon cancer cells that were tested. These results point to a role for beta-catenin ubiquitination, proteasomal degradation, and potentially a serine kinase other than glycogen synthase kinase-3beta in the tumor-suppressive actions of APC.

The oncogenic activation of beta-catenin.

The activation of beta-catenin to an oncogenic state can result from the inactivation of the tumor suppressor adenomatous polyposis coli (APC), by direct mutation in the beta-catenin gene, or by the activation of wnt receptors. Once activated, beta-catenin most likely promotes tumor progression through its persistent interaction with one or more of its numerous downstream targets.

The F-box protein beta-TrCP associates with phosphorylated beta-catenin and regulates its activity in the cell.

Defects in beta-catenin regulation contribute to the neoplastic transformation of mammalian cells. Dysregulation of beta-catenin can result from missense mutations that affect critical sites of phosphorylation by glycogen synthase kinase 3beta (GSK3beta). Given that phosphorylation can regulate targeted degradation of beta-catenin by the proteasome, beta-catenin might interact with an E3 ubiquitin ligase complex containing an F-box protein, as is the case for certain cell cycle regulators. Accordingly, disruption of the Drosophila F-box protein Slimb upregulates the beta-catenin homolog Armadillo. We reasoned that the human homologs of Slimb - beta-TrCP and its isoform beta-TrCP2 (KIAA0696) - might interact with beta-catenin. We found that the binding of beta-TrCP to beta-catenin was direct and dependent upon the WD40 repeat sequences in beta-TrCP and on phosphorylation of the GSK3beta sites in beta-catenin. Endogenous beta-catenin and beta-TrCP could be coimmunoprecipitated from mammalian cells. Overexpression of wild-type beta-TrCP in mammalian cells promoted the downregulation of beta-catenin, whereas overexpression of a dominant-negative deletion mutant upregulated beta-catenin protein levels and activated signaling dependent on the transcription factor Tcf. In contrast, beta-TrCP2 did not associate with beta-catenin. We conclude that beta-TrCP is a component of an E3 ubiquitin ligase that is responsible for the targeted degradation of phosphorylated beta-catenin.

Defects in the regulation of beta-catenin in colorectal cancer.

The molecular events that contribute to the progression of colon cancer are beginning to unravel. An initiating and probably obligatory event is the oncogenic activation of beta-catenin. This can come about by the loss of its negative regulator the adenomatous polyposis coli (APC) protein, or by mutations in the beta-catenin gene that result in a more stable protein product. The interaction between APC and beta-catenin, and additional proteins that affect assembly and signaling along this pathway, are discussed.

Downregulation of beta-catenin by human Axin and its association with the APC tumor suppressor, beta-catenin and GSK3 beta.

BACKGROUND: Inactivation of the adenomatous polyposis coli (APC) tumor suppressor protein is responsible for both inherited and sporadic forms of colon cancer. Growth control by APC may relate to its ability to downregulate beta-catenin post-translationally. In cancer, mutations in APC ablate its ability to regulate beta-catenin, and mutations in beta-catenin prevent its downregulation by wild-type APC. Moreover, signaling by the protein product of the wnt-1 proto-oncogene upregulates beta-catenin and promotes tumorigenesis in mice. In a Xenopus developmental system, Wnt-1 signaling was inhibited by Axin, the product of the murine fused gene. This suggests a possible link between Axin, the Wnt-1 signaling components beta-catenin and glycogen synthase kinase 3 beta (GSK3 beta), and APC. RESULTS: Human Axin (hAxin) binds directly to beta-catenin, GSK3 beta, and APC in vitro, and the endogenous proteins are found in a complex in cells. Binding sites for Axin were mapped to a region of APC that is typically deleted due to cancer-associated mutations in the APC gene. Overexpression of hAxin strongly promoted the downregulation of wild-type beta-catenin in colon cancer cells, whereas mutant oncogenic beta-catenin was unaffected. The downregulation was increased by deletion of the APC-binding domain from Axin, suggesting that APC may function to derepress Axin activity. In addition, hAxin dramatically facilitated the phosphorylation of APC and beta-catenin by GSK3 beta in vitro. CONCLUSIONS: Axin acts as a scaffold upon which APC, beta-catenin and GSK3 beta assemble to coordinate the regulation of beta-catenin signaling.

Loss of beta-catenin regulation by the APC tumor suppressor protein correlates with loss of structure due to common somatic mutations of the gene.

The mutation cluster region in the APC gene defines a region of approximately 660 bp, in which the vast majority of its somatic mutations are found. These mutations disrupt the polypeptide chain, typically eliminating five of the seven repeated sequences of 20 amino acids (aa) each in the central region of the APC protein. To examine the relationship between loss of this structure and loss of function, we constructed APC deletion mutants that progressively truncated the protein across the mutation cluster region. The mutants were tested for their association with beta-catenin and their ability to down-regulate it in SW480 cells. The binding of beta-catenin to APC fragments required the inclusion of only a single 20-aa repeat sequence, whereas down-regulation required the presence of at least three of these repeat sequences, and those including the second repeat exhibited the highest activity. The mutation of three conserved serine residues in the second repeat greatly reduced the activity of an otherwise highly active APC fragment. Thus, the repeated 20-aa sequence is directly implicated in beta-catenin turnover. The elimination of at least five of these seven repeats due to somatic mutations suggests that loss of beta-catenin regulation by APC is selected for during tumor progression.

Induction of phosphorylation on BRCA1 during the cell cycle and after DNA damage.

BRCA1, the familial breast cancer susceptibility gene product, is a 220-kDA phosphorylated protein. BRCA1 immunoprecipitated from MCF7 cells blocked in G1-S phase or progressing through S-phase of the cell cycle migrated more slowly through SDS polyacrylamide gels than BRCA1 from cells maintained in serum-supplemented media, serum-free media for 24 h, or delayed in G2-M phase by treatment with colchicine. Restoration of BRCA1 to the faster-migrating form, which occurred on release of cells from the G1-S-phase block, was prevented by the phosphatase inhibitor okadaic acid. Phosphatase treatment of immunoprecipitated BRCA1 resulted in the conversion of the slower-migrating form to the faster-migrating form. Although these results suggested that BRCA1 was preferentially hyperphosphorylated near the G1-S-phase boundary of the cell cycle, exposure of cells to DNA-damaging agents including UV light or treatment with hydrogen peroxide (H2O2) also promoted BRCA1 hyperphosphorylation. These same stimuli also eliminated the punctate nuclear staining pattern normally observed for BRCA1 in control cells. These results indicate that BRCA1 undergoes cyclic hyperphosphorylation during the cell cycle; however, this modification, as well as changes in BRCA1 nuclear staining, also occurs in response to DNA damage.

The adenomatous polyposis coli (APC) tumor suppressor.

Defects in the APC gene are inarguably linked to the progression of colon cancers that arise both sporadically and through the transmission of germline mutations. Genetic evidence from humans and mouse models suggest that APC is a classic tumor suppressor in that both alleles likely require inactivation for tumor growth to ensue. Nearly all of the mutations, germline and somatic, result in premature termination of the single polypeptide chain, normally consisting of 2843 amino acids. Several definable motifs have now been mapped to the linear amino acid sequence of the APC polypeptide. These include an oligomerization domain, armadillo repeats, binding sites for beta-catenin, the human discs large protein, microtubules, and other proteins of unknown function. Inactivation of APC in cancer is likely due to loss of function(s) normally associated with the deleted protein structure.

Stabilization of beta-catenin by genetic defects in melanoma cell lines.

Signal transduction by beta-catenin involves its posttranslational stabilization and downstream coupling to the Lef and Tcf transcription factors. Abnormally high amounts of beta-catenin were detected in 7 of 26 human melanoma cell lines. Unusual messenger RNA splicing and missense mutations in the beta-catenin gene (CTNNB1) that result in stabilization of the protein were identified in six of the lines, and the adenomatous polyposis coli tumor suppressor protein (APC) was altered or missing in two others. In the APC-deficient cells, ectopic expression of wild-type APC eliminated the excess beta-catenin. Cells with stabilized beta-catenin contained a constitutive beta-catenin-Lef-1 complex. Thus, genetic defects that result in up-regulation of beta-catenin may play a role in melanoma progression.