Michael Shtutman scite author profile

ABSTRACT␤-Catenin plays a dual role in the cell: one in linking the cytoplasmic side of cadherin-mediated cell-cell contacts to the actin cytoskeleton and an additional role in signaling that involves transactivation in complex with transcription factors of the lymphoid enhancing factor (LEF-1) family. Elevated ␤-catenin levels in colorectal cancer caused by mutations in ␤-catenin or by the adenomatous polyposis coli molecule, which regulates ␤-catenin degradation, result in the binding of ␤-catenin to LEF-1 and increased transcriptional activation of mostly unknown target genes. Here, we show that the cyclin D1 gene is a direct target for transactivation by the ␤-catenin͞LEF-1 pathway through a LEF-1 binding site in the cyclin D1 promoter. Inhibitors of ␤-catenin activation, wild-type adenomatous polyposis coli, axin, and the cytoplasmic tail of cadherin suppressed cyclin D1 promoter activity in colon cancer cells. Cyclin D1 protein levels were induced by ␤-catenin overexpression and reduced in cells overexpressing the cadherin cytoplasmic domain. Increased ␤-catenin levels may thus promote neoplastic conversion by triggering cyclin D1 gene expression and, consequently, uncontrolled progression into the cell cycle.

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Differential Nuclear Translocation and Transactivation Potential of β-Catenin and Plakoglobin

Simcha

et al. 1998

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β-Catenin and plakoglobin are homologous proteins that function in cell adhesion by linking cadherins to the cytoskeleton and in signaling by transactivation together with lymphoid-enhancing binding/T cell (LEF/TCF) transcription factors. Here we compared the nuclear translocation and transactivation abilities of β-catenin and plakoglobin in mammalian cells. Overexpression of each of the two proteins in MDCK cells resulted in nuclear translocation and formation of nuclear aggregates. The β-catenin-containing nuclear structures also contained LEF-1 and vinculin, while plakoglobin was inefficient in recruiting these molecules, suggesting that its interaction with LEF-1 and vinculin is significantly weaker. Moreover, transfection of LEF-1 translocated endogenous β-catenin, but not plakoglobin to the nucleus. Chimeras consisting of Gal4 DNA-binding domain and the transactivation domains of either plakoglobin or β-catenin were equally potent in transactivating a Gal4-responsive reporter, whereas activation of LEF-1– responsive transcription was significantly higher with β-catenin. Overexpression of wild-type plakoglobin or mutant β-catenin lacking the transactivation domain induced accumulation of the endogenous β-catenin in the nucleus and LEF-1–responsive transactivation. It is further shown that the constitutive β-catenin–dependent transactivation in SW480 colon carcinoma cells and its nuclear localization can be inhibited by overexpressing N-cadherin or α-catenin. The results indicate that (a) plakoglobin and β-catenin differ in their nuclear translocation and complexing with LEF-1 and vinculin; (b) LEF-1–dependent transactivation is preferentially driven by β-catenin; and (c) the cytoplasmic partners of β-catenin, cadherin and α-catenin, can sequester it to the cytoplasm and inhibit its transcriptional activity.

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Inhibition of β-catenin-mediated transactivation by cadherin derivatives

Sadot

Simcha²,

Shtutman³

et al. 1998

Proc. Natl. Acad. Sci. U.S.A.

207

196

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We studied the effect of N-cadherin, and its free or membrane-anchored cytoplasmic domain, on the level and localization of ␤-catenin and on its ability to induce lymphocyte enhancer-binding factor 1 (LEF-1)-responsive transactivation. These cadherin derivatives formed complexes with ␤-catenin and protected it from degradation. N-cadherin directed ␤-catenin into adherens junctions, and the chimeric protein induced diffuse distribution of ␤-catenin along the membrane whereas the cytoplasmic domain of N-cadherin colocalized with ␤-catenin in the nucleus. Cotransfection of ␤-catenin and LEF-1 into Chinese hamster ovary cells induced transactivation of a LEF-1 reporter, which was blocked by the N-cadherin-derived molecules. Expression of N-cadherin and an interleukin 2 receptor͞cadherin chimera in SW480 cells relocated ␤-catenin from the nucleus to the plasma membrane and reduced transactivation. The cytoplasmic tails of N-or E-cadherin colocalized with ␤-catenin in the nucleus, and suppressed the constitutive LEF-1-mediated transactivation, by blocking ␤-catenin-LEF-1 interaction. Moreover, the 72 C-terminal amino acids of N-cadherin stabilized ␤-catenin and reduced its transactivation potential. These results indicate that ␤-catenin binding to the cadherin cytoplasmic tail either in the membrane, or in the nucleus, can inhibit ␤-catenin degradation and efficiently block its transactivation capacity.

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Expression of L1-CAM and ADAM10 in Human Colon Cancer Cells Induces Metastasis

Gavert¹,

Sheffer

Raveh³

et al. 2007

186

189

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L1-CAM, a neuronal cell adhesion receptor, is also expressed in a variety of cancer cells. Recent studies identified L1-CAM as a target gene of B-catenin-T-cell factor (TCF) signaling expressed at the invasive front of human colon cancer tissue. We found that L1-CAM expression in colon cancer cells lacking L1-CAM confers metastatic capacity, and mice injected in their spleen with such cells form liver metastases. We identified ADAM10, a metalloproteinase that cleaves the L1-CAM extracellular domain, as a novel target gene of B-catenin-TCF signaling. ADAM10 overexpression in colon cancer cells displaying endogenous L1-CAM enhanced L1-CAM cleavage and induced liver metastasis, and ADAM10 also enhanced metastasis in colon cancer cells stably transfected with L1-CAM. DNA microarray analysis of genes induced by L1-CAM in colon cancer cells identified a cluster of genes also elevated in a large set of human colon carcinoma tissue samples. Expression of these genes in normal colon epithelium was low. These results indicate that there is a gene program induced by L1-CAM in colon cancer cells that is also present in colorectal cancer tissue and suggest that L1-CAM can serve as target for colon cancer therapy. [Cancer Res 2007;67(16):7703-12]

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