Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UNIPROT:B0FTZ7 (catenin)
18,795 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We showed that the YMB-1-derived breast cancer cell line YMB-S, which proliferates in suspension without aggregation, exhibits complete loss of cell-cell adhesion despite the presence of E-cadherin-catenin complex and expression of free beta-catenin in the cytoplasm. Here, we describe beta-catenin gene regulation, interaction with E-cadherin, immunocytochemical localization, and their relation to growth rate in the YMB-1-derived cell line YMB-A, which forms tight junctions and displays anchorage-dependent growth. YMB-A cells proliferated more slowly than YMB-S cells. E-cadherin and APC gene product expression in YMB-A cells was significantly higher than that in YMB-S cells, whereas expression of beta-catenin, MUC1, and c-myc was lower in YMB-A cells than in YMB-S cells. According to immunocytochemical analysis, beta-catenin in YMB-A cells displayed membranous or submembranous localization, indicating that beta-catenin is mostly tethered to E-cadherin. Inhibition of E-cadherin expression in YMB-A cells by an antisense oligonucleotide did not change expression of whole cell beta-catenin protein, but increased nuclear beta-catenin protein level, c-myc expression, and cell growth rate. These results suggest that decreased expression of E-cadherin and APC and increased amount of beta-catenin in YMB-S cells lead to accumulation of beta-catenin in the nucleus, activate beta-catenin-LEF/TCF signaling pathway, and trigger c-myc proto-oncogene expression. c-Myc overexpression in breast cancer may be related to activated Wnt independent beta-catenin-LEF/TCF signaling.
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PMID:Decreased E-cadherin augments beta-catenin nuclear localization: studies in breast cancer cell lines. 1117 84

PTPmu, an Ig superfamily receptor protein-tyrosine phosphatase, promotes cell-cell adhesion and interacts with the cadherin-catenin complex. The signaling pathway downstream of PTPmu is unknown; therefore, we used a yeast two-hybrid screen to identify additional PTPmu interacting proteins. The membrane-proximal catalytic domain of PTPmu was used as bait. Sequencing of two positive clones identified the scaffolding protein RACK1 (receptor for activated protein C kinase) as a PTPmu interacting protein. We demonstrate that RACK1 interacts with PTPmu when co-expressed in a recombinant baculovirus expression system. RACK1 is known to bind to the src protein-tyrosine kinase. This study demonstrates that PTPmu association with RACK1 is disrupted by the presence of constituitively active src. RACK1 is thought to be a scaffolding protein that recruits proteins to the plasma membrane via an unknown mechanism. We have shown that the association of endogenous PTPmu and RACK1 in a lung cell line is increased at high cell density. We also demonstrate that the recruitment of RACK1 to both the plasma membrane and cell-cell contact sites is dependent upon the presence of the PTP mu protein in these cells. Therefore, PTPmu may be one of the proteins that recruits RACK1 to points of cell-cell contact, which may be important for PTPmu-dependent signaling in response to cell-cell adhesion.
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PMID:The PTPmu protein-tyrosine phosphatase binds and recruits the scaffolding protein RACK1 to cell-cell contacts. 1127 57

Recently it has been shown that the VHL tumor suppressor targets the hypoxia-inducible transcription factor (HIF-1) for ubiquitin-dependent degradation by the proteasome. Past mysteries of the p53 tumor suppressor help to solve the present puzzles of the VHL tumor suppressor. Thus, Mdm-2 targets the p53 tumor suppressor for ubiquitin-dependent degradation by the proteasome, but, in addition, the p53 transcription factor induces Mdm-2, thus, establishing a feedback loop. Hypoxia or DNA damage by abrogating binding of HIF-1 with VHL and p53 with Mdm-2, respectively, leads to stabilization and accumulation transcriptionally active HIF-1 and p53. More detailed analysis depicts the VHL/HIF-1 pair as the p53/mdm-2 pair that is turned upside down, suggesting that VHL may be a HIF-1-inducible gene of the feedback loop. The extended model proposes that an oncoprotein and a tumor suppressor due to transactivation coupled with feedback protein degradation might form functional pairs (Rb/E7, E2F/Rb, E2F/Mdm-2, catenin/APC, p27, cyclin D1, Rb/gankyrin), thus, predicting missing links.
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PMID:Do VHL and HIF-1 mirror p53 and Mdm-2? Degradation-transactivation loops of oncoproteins and tumor suppressors. 1131 69

Among the hallmarks of cancer are defective cell-cell and cell-matrix adhesion. Alterations in cadherin-catenin complexes likely have a major contributing role in cell-adhesion defects in carcinomas arising in many different tissues. E-cadherin, the prototypic member of the cadherin transmembrane protein family, regulates cell adhesion by interacting with E-cadherin molecules on opposing cell surfaces. E-cadherin's function in cell adhesion is also critically dependent on its ability to interact through its cytoplasmic domain with catenin proteins. A diverse collection of defects alter cadherin-catenin function in cancer cells, including loss-of-function mutations and defects in the expression of E-cadherin and certain catenins, such as alpha-catenin. Although there is much evidence that beta-catenin is deregulated in cancer as a result of inactivating mutations in the APC and AXIN tumor-suppressor proteins and gain-of-function mutations in beta-catenin itself, the principal consequences of beta-catenin deregulation in cancer appear to be largely distinct from the effects attributable to inactivation of E-cadherin or alpha-catenin. In this review, we highlight some of the specific genetic and epigenetic defects responsible for altered cadherin and catenin function in cancer, as well as potential contributions of cadherin-catenin alterations to the cancer process.
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PMID:Cadherin and catenin alterations in human cancer. 1200 86

OBJECTIVES: Characterization of breast cancers by various tumour markers which are appropriate for the identification of high risk groups. Markers related to the metastasis cascade and tumour recurrence have been investigated. MATERIALS AND METHODS: RT-PCR was used to determine the expression of cytokeratin 20 in the bone marrow and sentinel lymph node of breast cancer patients (n=45). The expression of HER2, Cadherin E, Cyclin D, Bcl2 and Bax has been evaluated by Western blot (n=744 invasive ductal carcinomas and 117 invasive lobular carcinomas, 124 recurrent breast cancers). Mutations of p53, APC and beta Catenin genes were detected by PCR-SSCP method. RESULTS: Expression of cytokeratin 20 was found in 30% of the bone marrow samples indicating the presence of micrometastasis. The level of Cyclin D, HER2 and Bcl2 is elevated four-fold in the recurrent breast cancers. The metastasis of invasive ductal carcinomas is accompained by high frequency of p53 mutations (24%) and APC mutations (18%). The invasive lobular carcinomas could be characterized with low frequency of p53 mutation (3%), low level of Cadherin E and high level of catenin beta. CONCLUSIONS: Identification of micrometastasis can promote the development of therapeutic strategy. Evaluation of HER2 level and determination of p53 mutations contribute to the identification of high risk patients. Our results suggest that the progression of invasive ductal carcinomas depends on the APC mutations, while metastasis of invasive lobular carcinomas depends on beta catenin mutations.
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PMID:[Prognostic factors of breast cancer] 1205 Jul 67

A novel phosphorylation-specific antibody (alphapbeta-catenin) was generated against a peptide corresponding to amino acids 33-45 of human beta-catenin, which contained phosphorylated serines at positions 33 and 37. This antibody is specific to phosphorylated beta-catenin and reacts neither with the non-phosphorylated protein nor with phosphorylated or non-phosphorylated plakoglobin. It weakly interacts with S33Y beta-catenin but not with the S37A mutant. pbeta-catenin is hardly detectable in normal cultured cells and accumulates (up to 55% of total beta-catenin) upon overexpression of the protein or after blocking its degradation by the proteasome. Inhibition of both GSK-3beta and the proteasome resulted in a rapid (t1/2=10 minutes) and reversible reduction in pbeta-catenin levels, suggesting that the protein can undergo dephosphorylation in live cells, at a rate comparable to its phosphorylation by GSK-3beta. pbeta-catenin interacts with LEF-1, but fails to form a ternary complex with DNA, suggesting that it is transcriptionally inactive. Immunofluorescence microscopy indicated that pbeta-catenin accumulates in the nuclei of MDCK and BCAP cells when overexpressed and is transiently associated with adherens junctions shortly after their formation. pbeta-catenin only weakly interacts with co-transfected N-cadherin, although it forms a complex with the ubiquitin ligase component beta-TrCP. SW480 colon cancer cells that express a truncated APC, at position 1338, contain high levels of pbeta-catenin, whereas HT29 cells, expressing APC truncated at position 1555, accumulate non-phosphorylated beta-catenin, suggesting that the 1338-1555 amino acid region of APC is involved in the differential regulation of the dephosphorylation and degradation of pbeta-catenin.
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PMID:Regulation of S33/S37 phosphorylated beta-catenin in normal and transformed cells. 1207 67

Molecular biology studies have led to the identification of two different types of colorectal carcinomas. The first group, called LOH (for loss of heterozygosity), represents 80% of colorectal cancers and is characterised by aneuploidy, allelic losses and a location in the distal colon. The second group displays phenotypic microsatellite instability (MSI-positive tumours), has a near-diploid karyotype and a relatively low frequency of allelic losses. It accounts for 15% of all colorectal cancers and for about 30% of right-sided cancers. Four different pathways have been identified as responsible for tumour progression: the WNT/Wingless, the K-ras, the Transforming growth factor (TGF) and the P53 pathways. The involvement of these pathways depends on the tumour type. In LOH-positive tumours, the WNT/Wingless pathway is activated through an APC mutation, whereas MSI+ tumours do so through a catenin stabilising mutation. The TGFb growth inhibitory pathway is altered either by mutations in the signal transduction molecules SMAD2 and SMAD4 in LOH positive tumours or by mutations of TGFbRII in MSI+ tumours. In the p53 pathway, mutations in BAX may contribute to the adenoma-carcinoma transition just as p53 mutations may do in LOH positive tumours. Until now, cancer phenotype determination has had no clinical implications. However, the predictive value of the MSI status was recently stressed as a predictive factor for response to chemotherapy. Immunohistochemistry could represent a complementary strategy to molecular biology in assessing MSI status. This simple test would allow to screen all colorectal carcinomas for MSI status, which would provide valuable management information in addition to the histological assessment for tumour stage and grade.
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PMID:[Genetic pathways in colorectal cancer: interest for the pathologist]. 1241 Jan 50

beta-catenin is involved in both cell-cell interactions and wnt pathway-dependent cell fate determination through its interactions with E-cadherin and TCF/LEF transcription factors, respectively. Cytoplasmic/nuclear levels of beta-catenin are important in regulated transcriptional activation of TCF/LEF target genes. Normally, these levels are kept low by proteosomal degradation of beta-catenin through Axin1- and APC-dependent phosphorylation by CKI and GSK-3beta. Deregulation of beta-catenin degradation results in its aberrant accumulation, often leading to cancer. Accordingly, aberrant accumulation of beta-catenin is observed at high frequency in many cancers. This accumulation correlates with either mutational activation of CTNNB1 (beta-catenin) or mutational inactivation of APC and Axin1 genes in some tumors. However, there are many tumors that display beta-catenin accumulation in the absence of a mutation in these genes. Thus, there must be additional sources for aberrant beta-catenin accumulation in cancer cells. Here, we provide experimental evidence that wild-type beta-catenin accumulates in hepatocellular carcinoma (HCC) cells in association with mutational inactivation of p53 gene. We also show that worldwide p53 and beta-catenin mutation rates are inversely correlated in HCC. These data suggest that inactivation of p53 is an important cause of aberrant accumulation of beta-catenin in cancer cells.
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PMID:P53 mutation as a source of aberrant beta-catenin accumulation in cancer cells. 1243 47

The activation of the APC/beta-catenin signalling pathway due to beta-catenin mutations has been implicated in the development of a subset of endometrial carcinomas (ECs). However, up to 25% of ECs have beta-catenin nuclear accumulation without evidence of beta-catenin mutations, suggesting alterations of other molecules that can modulate the Wnt pathway, such as APC, gamma-catenin, AXIN1 and AXIN2. We investigated the expression pattern of beta- and gamma-catenin in a group of 128 endometrial carcinomas, including 95 endometrioid endometrial carcinomas (EECs) and 33 non-endometrioid endometrial carcinomas (NEECs). In addition, we evaluated the presence of loss of heterozygosity and promoter hypermethylation of the APC gene and mutations in the APC, beta- and gamma-catenin, AXIN1, AXIN2, and RAS genes, and phospho-Akt expression. No APC mutations were detected but LOH at the APC locus was found in 24.3% of informative cases. APC promoter 1A hypermethylation was observed in 46.6% of ECs, and was associated with the endometrioid phenotype (P=0.034) and microsatellite instability (P=0.008). Neither LOH nor promoter hypermethylation of APC was associated with nuclear catenin expression. Nuclear beta-catenin expression was found in 31.2% of EECs and 3% of NEECs (P=0.002), and was significantly associated with beta-catenin gene exon 3 mutations (P<0.0001). beta-catenin gene exon 3 mutations were associated with the endometrioid phenotype, and were detected in 14 (14.9%) EECs, but in none of the NEECs (P=0.02). gamma-catenin nuclear expression was found in 10 ECs; it was not associated with the histological type but was associated with more advanced stages (P=0.042). No mutations in gamma-catenin, AXIN1 and 2 genes were detected in this series. Neither RAS mutations nor phospho-Akt expression, which were found in 16 and 27.6% of the cases, respectively, were associated with beta-catenin nuclear expression. Our results demonstrated a high prevalence of alterations in molecules of the APC/beta-catenin pathway, but only mutations in beta-catenin gene are associated with aberrant nuclear localization of beta-catenin.
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PMID:Abnormalities of the APC/beta-catenin pathway in endometrial cancer. 1243 48

Beta-catenin is a glicoprotein which has an important role in cell-cell adhesion, as well as in cell signal transmission, in u regulation of gen expression and in interaction with axin and APC (adenomatous poliposis coli). Its oncogenic role in several types of carcinomas in human population is well known. It is very likely that beta-catenin as an protooncogen plays an important role in genesis of Wilms tumor. It is well known that in 15% Wilms tumors there are beta-catenin mutations, which indicates that there is a disorder in Wnt signal path that plays an important role in Wilms tumor genesis. The aim of our study was to investigate b-catenin expression in Wilms tumor, to compare it with the expression in normal renal tissue as well as to see if there is a positive correlation between b-catenin expression in Wilms tumor with tumor stage, histologic type and/or prognostic group.
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PMID:[Adhesion molecules in Wilm's tumor: expression and significance of beta-catenin (part II)]. 1460 68


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