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Literature DB >> 15579438

CTNNB1 mutations and overexpression of Wnt/beta-catenin target genes in WT1-mutant Wilms' tumors.

Chi-Ming Li¹, Connie E Kim, Adam A Margolin, Meirong Guo, Jimmy Zhu, Jacqueline M Mason, Terrence W Hensle, Vundavalli V V S Murty, Paul E Grundy, Eric R Fearon, Vivette D'Agati, Jonathan D Licht, Benjamin Tycko.

Abstract

Gain-of-function mutations in exon 3 of beta-catenin (CTNNB1) are specific for Wilms' tumors that have lost WT1, but 50% of WT1-mutant cases lack such "hot spot" mutations. To ask whether stabilization of beta-catenin might be essential after WT1 loss, and to identify downstream target genes, we compared expression profiles in WT1-mutant versus WT1 wild-type Wilms' tumors. Supervised and nonsupervised hierarchical clustering of the expression data separated these two classes of Wilms' tumor. The WT1-mutant tumors overexpressed genes encoding myogenic and other transcription factors (MOX2, LBX1, SIM2), signaling molecules (TGFB2, FST, BMP2A), extracellular Wnt inhibitors (WIF1, SFRP4), and known beta-catenin/TCF targets (FST, CSPG2, CMYC). Beta-Catenin/TCF target genes were overexpressed in the WT1-mutant tumors even in the absence of CTNNB1 exon 3 mutations, and complete sequencing revealed gain-of-function mutations elsewhere in the CTNNB1 gene in some of these tumors, increasing the overall mutation frequency to 75%. Lastly, we identified and validated a novel direct beta-catenin target gene, GAD1, among the WT1-mutant signature genes. These data highlight two molecular classes of Wilms' tumor, and indicate strong selection for stabilization of beta-catenin in the WT1-mutant class. Beta-Catenin stabilization can initiate tumorigenesis in other systems, and this mechanism is likely critical in tumor formation after loss of WT1.

Entities: Disease Gene

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Year: 2004 PMID： 15579438 PMCID： PMC1618727 DOI： 10.1016/s0002-9440(10)63246-4

Source DB: PubMed Journal: Am J Pathol ISSN： 0002-9440 Impact factor: 4.307

31 in total

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Journal: Cancer Res Date: 1995-11-15 Impact factor: 12.701

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Authors: Valérie Schumacher; Stefanie Schuhen; Sandra Sonner; Angela Weirich; Ivo Leuschner; Dieter Harms; Jonathan Licht; Stefan Roberts; Brigitte Royer-Pokora
Journal: Clin Cancer Res Date: 2003-06 Impact factor: 12.531

8. Upregulation of c-MYC in WT1-mutant tumors: assessment of WT1 putative transcriptional targets using cDNA microarray expression profiling of genetically defined Wilms' tumors.

Authors: Malini Udtha; Sang-Joon Lee; Rita Alam; Kevin Coombes; Vicki Huff
Journal: Oncogene Date: 2003-06-12 Impact factor: 9.867

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Authors: Jennifer Willert; Mirjam Epping; Jonathan R Pollack; Patrick O Brown; Roel Nusse
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52 in total

1. Different incidences of epigenetic but not genetic abnormalities between Wilms tumors in Japanese and Caucasian children.

Authors: Masayuki Haruta; Yasuhito Arai; Naoki Watanabe; Yuiko Fujiwara; Shohei Honda; Junjiro Ohshima; Fumio Kasai; Hisaya Nakadate; Hiroshi Horie; Hajime Okita; Jun-Ichi Hata; Masahiro Fukuzawa; Yasuhiko Kaneko
Journal: Cancer Sci Date: 2012-04-19 Impact factor: 6.716

Review 2. Candidate genes and potential targets for therapeutics in Wilms' tumour.

Authors: Christopher Blackmore; Max J Coppes; Aru Narendran
Journal: Clin Transl Oncol Date: 2010-09 Impact factor: 3.405

3. WT1 mutation and 11P15 loss of heterozygosity predict relapse in very low-risk wilms tumors treated with surgery alone: a children's oncology group study.

Authors: Elizabeth J Perlman; Paul E Grundy; James R Anderson; Lawrence J Jennings; Daniel M Green; Jeffrey S Dome; Robert C Shamberger; E Cristy Ruteshouser; Vicki Huff
Journal: J Clin Oncol Date: 2010-12-28 Impact factor: 44.544

4. Subtype-specific FBXW7 mutation and MYCN copy number gain in Wilms' tumor.

Authors: Richard D Williams; Reem Al-Saadi; Tasnim Chagtai; Sergey Popov; Boo Messahel; Neil Sebire; Manfred Gessler; Jenny Wegert; Norbert Graf; Ivo Leuschner; Mike Hubank; Chris Jones; Gordan Vujanic; Kathy Pritchard-Jones
Journal: Clin Cancer Res Date: 2010-03-23 Impact factor: 12.531