UNIPROT:P43146 - FACTA Search

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Query: UNIPROT:P43146 (tumour suppressor)
5,935 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The tumour suppressor gene WT1 encodes a transcription factor expressed in tissues of the genito-urinary system. Inactivation of this gene is associated with the development of Wilms tumour a pediatric kidney cancer. We show that WT1 is also expressed at high levels in many supportive structures of mesodermal origin in the mouse. We also describe a case of adult human mesothelioma, a tumour derived from the peritoneal lining, that contains a homozygous point mutation within WT1. This mutation, within the putative transactivation domain, converts the protein from a transcriptional repressor of its target sequence to a transcriptional activator. The role of WT1 in normal development thus extends to diverse structures derived from embryonic mesoderm and disruption of WT1 function contributes to the onset of adult, as well as pediatric, tumours.
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PMID:The Wilms tumour gene WT1 is expressed in murine mesoderm-derived tissues and mutated in a human mesothelioma. 840 92

The Wilms' tumour suppressor gene 1 (WT1) (1,2) encodes four C2H2 zinc finger-containing proteins (3) critical for normal mammalian urogenital development (4). Mutations in this gene are observed in the childhood kidney cancer, Wilms' tumour (WT) (5). WT1 can bind specific DNA targets within the promoters of many genes (6-9) and both transcriptional repression and activation domains have been identified (10). On this basis, it has been assumed that regulation of transcription is the basis of WT1 tumour suppressor activity. However, subnuclear localization studies have revealed an association between WT1 proteins and 'speckled bodies' within the nucleus. Degradation of nuclear RNA in cells expressing WT1 abolishes this speckled localization and WT1 co-immunoprecipitates with a number of spliceosomal proteins, suggesting that it may also bind to RNA (11). Using structural rather than sequence comparison, we have now identified an evolutionarily conserved N-terminal RNA recognition motif (RRM) in all known WT1 isoforms similar to that in the constitutive splicing factor U1A. Given the association between WT1 mutations and Wilms' tumours, this study, together with other recent findings, may suggest a novel tumour suppression mechanism.
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PMID:An RNA recognition motif in Wilms' tumour protein (WT1) revealed by structural modelling. 858 29

We have examined 41 cases of follicle centre cell lymphoma with fluorescent PCR of microsatellite repeats closely linked to or within six tumour suppressor gene loci (APC, DCC, P53, RB1, WT1 and NM23). These probes are highly informative with heterozygousity rates in the range of 57%-90%. In addition we have used four loci from chromosome 6 (D6S260, TNFa, D6S281 and D6S262) as control loci which are unlikely to be involved in the pathogenesis of lymphoma. Of 369 informative PCR reactions allele imbalance was identified in 38 (10%) and this was seen in 23 of the 41 cases. Looking at individual loci allele imbalance was seen in APC(1) 11%, APC(2) 12%, P53(1) 5%, P53 (2) 7%, WT1 5%, RB1 13%, DCC 18% and NM23 0%. This frequency of change was no different from that seen at the control loci D6S260 16%, TNFa 20%, D6S281 4% and D6S262 9%. In the indolent phase of germinal centre cell lymphoma there is therefore quite a high rate of allele imbalance at all loci but this is no higher in those loci linked to tumour suppressor genes.
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PMID:Allele imbalance at tumour suppressor loci during the indolent phase of follicle centre cell lymphoma. 872 37

Activation of the silent maternal IGF2 allele has recently been found in approximately half of Wilms' tumour (WTs) examined. This process of imprint relaxation leads to biallelic expression of IGF2 and it has been suggested that this is a key event in the onset of some WTs. Although it has previously been proposed that the 11p15 chromosome region contains a growth-promoting gene and a tumour suppressor gene, the simplest explanation is that increased expression of the IGF2 gene is responsible for somatic overgrowth in the BWS and predisposition to tumours. This model explains overgrowth in BWS cases with unbalanced translocations with paternal dup(11p), and cases with balanced maternal translocations which are physically close to the IGF2 gene. Maternal translocations are envisaged to disrupt the maternal IGF2 imprint by a mechanism similar to the position-effect variegation mechanism in Drosophila. Relaxation of IGF2 imprinting has also been detected in several patients with the BWS syndrome and a patient with gigantism and Wilms' tumour. Recent gene disruption experiments have shown that inactivation of the mouse h19 gene leads to biallelic lgf2 expression and extensive proportional overgrowth. This mouse model has parallels with the BWS and WT where it has been found that biallelic IGF2 expression is accompanied by an epigenetic modification of the H19 gene. From these data it is possible to speculate that an epigenetic modification of the H19 gene may be the primary event leading to the relaxation of IGF2 imprinting.
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PMID:Role of genomic imprinting in Wilms' tumour and overgrowth disorders. 882 76

Wilms' tumour (nephroblastoma) has been associated with chromosomal abnormalities at the 11p13, 11p15 and 16q regions. A study into the possibility of mutations occurring within p53, the ubiquitous adult tumour suppressor gene, in Wilms' tumour was carried out. Thirty-eight cases were studied. Of these 36 were categorised into the favourable histology group and two into the unfavourable histology group based on the National Wilms' Tumour Study criteria. Archival formalin-fixed, paraffin-embedded tissue sections from each case were stained with a polyclonal (AB565:Chemicon) and a monoclonal (DO7:Dako) antibody raised against p53 protein using a peroxidase-labelled streptavidin biotin kit (Dako). 'Cure' (disease-free survival of 60 months or longer) was documented in 39% of cases with favourable histology tumours. Eleven percent in this group succumbed to the disease. Both cases with unfavourable histology died. Four out of 36 (11%) tumours with favourable histology demonstrated weak to moderate staining with both AB565 and DO7 in more than 75% of tumour cells. In contrast, p53 protein expression in unfavourable histology tumours was significantly increased compared with the favourable histology group (P = 0.021) with both cases demonstrating immunopositivity in > 75% of tumour cells when stained with AB565 and DO7. The intensity of staining ranged from moderate to strong in both cases. It appears from this preliminary study that the immunohistochemical expression of p53 protein in Wilms' tumour, presumably a result of mutation in the p53 tumour suppressor gene, correlates with histological classification, histological categorisation being one of the useful features in the prognostic assessment of Wilms' tumours.
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PMID:Immunohistochemical expression of p53 proteins in Wilms' tumour: a possible association with the histological prognostic parameter of anaplasia. 883 20

Wilms' tumor (WT) is an embryonal renal malignancy, which overexpresses insulin-like growth factor II (IGF-II), a fetal mitogen. Relaxation of parental imprinting of IGF2, the gene encoding IGF-II, is found in Wilms' tumors, suggesting an important role for IGF2 dosage in tumorigenesis. The IGF2R gene encodes a nonmitogenic receptor which targets IGF-II to the lysosomes for degradation and, therefore, inhibits the mitogenic function of IGF-II. The human IGF2R is imprinted in a proportion of normal individuals. To test the hypothesis that IGF2R imprinting predisposes to Wilms' tumor through the effect of decreased IGF2R dosage on IGF-II inactivation, we examined IGF2R imprinting in Wilms' tumors. Two transcribed CA repeat polymorphisms were used to distinguish the two alleles in the RT-PCR product. We observed that in 7/16 of Wilms' tumor patients, the paternal IGF2R was markedly but not completely repressed in both tumor and normal kidney. In one additional case, IGF2R was likewise imprinted in the tumor but not in the normal kidney. A similar imprinting was observed in fetal tissues and placenta prior to 20 weeks fetal age but not in term placenta or postnatal blood cells, indicating abnormal persistence of a fetal pattern in the kidneys of Wilms' patients. Genetic analysis showed association of the imprinting with a cis-acting locus. The high frequency of aberrant persistence of IGF2R imprinting in the kidneys of Wilms' tumor patients, which may be an embryonic feature, suggests that it is a predisposing factor in tumorigenesis. This is in accordance with evidence that IGF2R is a tumour suppressor in other types of malignancies.
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PMID:Aberrant imprinting of the insulin-like growth factor II receptor gene in Wilms' tumor. 907 Jun 52

Mouse p57(Kip2) arrests cells in G1 by functioning as a strong inhibitor of several G1 cyclin/Cdk complexes (Lee et al., 1995; Matsuoka et al., 1995; Sherr and Roberts, 1995). Human p57(KIP2) has been suggested to be a tumour suppressor gene because of its location at 11p15.5 which frequently undergoes maternal allele LOH in several types of cancer (Matsuoka et al., 1995; Sherr and Roberts, 1995; Hatada and Mukai, 1995). This suggestion was supported by the discovery that mouse p57(Kip2) is imprinted with expression from only the maternally inherited allele (Hatada and Mukai, 1995). Interestingly, p57(KIP2) is several hundred kilobases from the imprinted H19 and IGF2 genes which are involved in growth regulation (Hoovers et al., 1995). Here we show that human p57(KIP2) is imprinted with expression from the maternal allele. However, unlike the mouse, the imprinting is incomplete with significant expression from the paternal allele depending on the tissue examined. We have also shown that the imprinting of p57(KIP2) occurs independently of the H19/IGF2 domain and thus there must be at least two imprinted domains in 11p15.5. Finally, by examining Wilms tumours we have shown that following maternal 11p LOH, p57(KIP2) was expressed from the paternal allele. Therefore, p57(KIP2) cannot function as an imprinted tumour suppressor gene, at least in Wilms tumour.
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PMID:Human p57(KIP2) defines a new imprinted domain on chromosome 11p but is not a tumour suppressor gene in Wilms tumour. 912 69

A familial Wilms' tumour susceptibility gene, known as FWT1, has recently been localised to chromosome 17q12-q21 by genetic linkage analysis. Four Wilms' tumours from a family showing strong evidence of linkage to FWT1 were examined for allele loss using polymorphic microsatellite markers on chromosome 17q. In three tumours no loss of heterozygosity was observed. In the remaining case, loss of heterozygosity was detected at all markers analysed. However, the alleles lost in this Wilms' tumour were those segregating with the disease in the family. This is in contrast to the usual pattern observed in familial cancer syndromes, where the allele lost in tumours arising in gene carriers is the wild type inherited from the non mutation carrying parent. Taken together with previous data indicating that LOH on chromosome 17q is rare in sporadic Wilms' tumour, the results suggest that FWT1 is not a tumour suppressor gene. Moreover, loss of alleles linked to the disease and the implied absence of the mutated susceptibility gene in one tumour, suggests that a mutation in FWT1 may be necessary for the initiation of some familial Wilms' tumours but subsequently the maintenance of the neoplastic phenotype becomes independent of the FWT1 mutation.
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PMID:The familial Wilms' tumour susceptibility gene, FWT1, may not be a tumour suppressor gene. 922 74

Cytomegalovirus-based mammalian expression vectors are widely used to drive the expression of transfected genes in cultured cells. Immunofluorescent staining of the WT1 protein in 3T3 and 293 cell clones, stably transfected with a cyomegalovirus (CMV) expression vector carrying a cDNA coding for the tumour suppressor protein WT1, showed extreme cell to cell variation in the amount of recombinant protein expressed, indicative of cell cycle dependence. This was investigated further by Western blot and FACS analysis which showed that WT1 protein expression was highest in S phase and almost absent in G0/G1. Northern blot analysis of cell clones expressing sense or antisense WT1 cDNAs regulated by the CMV promoter/enhancer showed that RNA expression was also cell cycle-dependent. Western blotting of cells expressing a luciferase reporter gene driven by the CMV promoter/enhancer also showed apparent cell cycle-dependent expression. We further demonstrated that the expression of these gene constructs was serum responsive with a 10-fold increase in expression occurring 2 h after the addition of serum. These results show that the CMV promoter/enhancer system varied in its response to serum and the cell cycle state. Therefore, care must be taken when interpreting any phenotypic alterations (or lack of them) produced in cells transfected with CMV-based expression vectors.
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PMID:Serum-dependent and cell cycle-dependent expression from a cytomegalovirus-based mammalian expression vector. 926 80

Chromosomal translocations resulting in chimaeric transcription factors underlie specific malignancies, but few authentic target genes regulated by these fusion proteins have been identified. Desmoplastic small round-cell tumour (DSRT) is a multiphenotypic primitive tumour characterized by massive reactive fibrosis surrounding nests of tumour cells. The t(11;22)(p13;q12) chromosomal translocation that defines DSRT produces a chimaeric protein containing the potential transactivation domain of the Ewing-sarcoma protein (EWS) fused to zinc fingers 2-4 of the Wilms tumour suppressor and transcriptional repressor WT1 (refs 2,3). By analogy with other EWS fusion products, the EWS-WT1 chimaera may encode a transcriptional activator whose target genes overlap with those repressed by WT1 (ref. 4). To characterize its functional properties, we generated osteosarcoma cell lines with tightly regulated inducible expression of EWS-WT1. Expression of EWS-WT1 induced the expression of endogenous platelet-derived growth factor-A (PDGFA), a potent secreted mitogen and chemoattractant whose promoter contains the many potential WT1-binding sites. Native PDGFA was not regulated by wild-type WT1, indicating a difference in target gene specificity between this tumour suppressor and its oncogenic derivative. PDGFA was expressed within tumour cells in primary DSRT specimens, but it was absent in Wilms tumours expressing WT1 and Ewing sarcomas with an EWS-Fli translocation. We conclude that the oncogenic fusion of EWS to WT1 in DSRT results in the induction of PDGFA, a potent fibroblast growth factor that contributes to the characteristic reactive fibrosis associated with this unique tumour.
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PMID:The EWS-WT1 translocation product induces PDGFA in desmoplastic small round-cell tumour. 935 95

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