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Query: UNIPROT:P04637 (p53)
 77,613 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The development of Wilms' tumor, a pediatric kidney cancer, has been linked to the inactivation of a tumor suppressor gene both by epidemiologic studies and by genetic analyses. Like retinoblastoma, Wilms' tumors can occur bilaterally in individuals with apparent genetic susceptibility to this disease. This led Knudson and Strong to propose in 1972 that two genetic events were rate limiting in tumor development and that predisposed individuals had already inherited one mutation in the germline. The observation of karyotype abnormalities in predisposed children and studies of the molecular genetics of Wilms' tumor specimens enabled the identification of chromosome band 11p13 as one genetic locus inactivated in Wilms' tumor. The recent isolation of the WT1 gene, which is the specific target within that locus, offers new insight into the etiology of Wilms' tumor. This gene has properties distinct from those of other known tumor suppressor genes. WT1 encodes a zinc finger transcription factor that is alternatively spliced and has high sequence homology to the early growth response genes (EGR). Unlike the retinoblastoma (RB1) and p53 genes that are expressed ubiquitously, WT1 is expressed in specific cells of the kidney and only during a short period in development. Thus, disruption of a gene that is active during a critical period in the development of a specific organ can lead to neoplastic growth in that organ. Future studies are aimed at exploring the link between the role of the WT1 gene in normal development and in tumorigenesis of the kidney.
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PMID:WT1: a novel tumor suppressor gene inactivated in Wilms' tumor. 131 85

A series of 34 Wilms' tumours have been analysed for abnormal expression of the tumour suppressor gene p53 using frozen section immunohistochemistry. All tumours showed immunoreactivity with at least one of the specific antibodies used (monoclonal antibody PAb240, polyclonal antibodies CM1 and JG8). Abnormalities of p53 expression are very frequent in this type of childhood tumour.
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PMID:Aberrant expression of the tumour suppressor gene p53 is very frequent in Wilms' tumours. 133 42

A predisposition to the development of certain specific and familial cancers is associated with the inheritance of a single mutated gene. In the best-characterized cases, this primary mutation is a loss of function mutation consistent with viability but resulting in neoplastic change consequent to the acquisition of a second somatic mutation at the same locus. Such genes are referred to as tumor-suppressor genes. Classical examples are the Rb-1 gene associated with the development of retinoblastoma and the p53 gene, which is associated with a wider range of neoplasms, including breast cancer. Other tumor-suppressor genes have been isolated which are associated with Wilms' tumor, neurofibromatosis, and inherited and sporadic forms of colorectal cancer. Some of these genes appear to act as negative regulators of mitotic cycle genes, and others may have different properties. The nature of these genes is discussed, as is the evidence for the involvement of tumor-suppressor genes in other inherited, and sporadic, forms of cancer. Some recent data on the Wilms' tumor gene, WT1, and on the involvement of the p53 gene in breast cancer are presented, and the importance of genomic imprinting in contributing to the excess of suppressor gene mutations in chromosomes of paternal origin is considered.
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PMID:Tumor-suppressor genes: cardinal factors in inherited predisposition to human cancers. 133 26

This article reviews the present understanding of chromosomal aberrations and specific genetic mutations in renal, bladder, and prostate cancers. In kidney tumors, specific emphasis is given to chromosome 3 deletions in renal cell carcinoma and the characterization of the WT1 gene in Wilms' tumor. In all three urological tumors, the presence of mutations in the RAS, P53, and RB genes (all of which often occur in other tumors) is analyzed. The expression and properties of the androgen receptor in prostate cancer are also summarized.
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PMID:The molecular biology of urological tumors. 157 58

Previous emphasis in cancer research has been placed on genes in which activating mutations are found in experimental systems and sometimes in human tumors, and many of these genes are the cellular homologs of retroviral oncogenes. Studies of genes whose functions are necessary for maintenance of the normal cellular state, but for which loss-of-function mutations lead to tumor development, are limited. The latter genes have been variously termed 'tumor suppressor genes', 'recessive oncogenes', and 'anti-oncogenes', and each term defines a specific aspect of their properties and may not always be applicable. The retinoblastoma (RB) gene is the first such gene to be identified, and was isolated based on its chromosome localization and on the recessive nature of the tumor phenotype. That is, both wild type RB alleles must be inactivated in a single cell for neoplastic transformation to occur, and deletions at the chromosomal locus now known to contain RB are often found in retinoblastoma cells. Candidate genes for Wilms' tumor and neurofibromatosis type I have also been identified recently, and loss of function of these genes seems to be indicated for these diseases. Allelic loss of chromosome 17p13 is frequently observed in many tumor types. The p53 gene was mapped to this chromosomal region and has been shown to be a tumor suppressor gene, and germ-line mutations of p53 recently were found to be correlated with Li-Fraumeni syndrome, a syndrome characterized by multiple neoplasms. Rapid progress in studies of tumor suppressor genes points to diverse mechanisms for their functioning in the negative regulation of cell growth. A scenario depicting cell growth control by positive and negative regulators, based on new and emerging findings, is the main focus of this review.
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PMID:Tumor suppressor genes: a new era for molecular genetic studies of cancer. 175 64

Cancers in which mutations have been identified in putative tumor suppressor genes, such as the TP53 gene, the retinoblastoma (RBI) gene, the adenomatous polyposis coli (APC) gene, and the Wilms tumor (WTI) gene, frequently show loss of the corresponding allele on the homologous chromosome. To identify locations of tumor suppressor genes involved in uterine cancer, we examined loss of heterozygosity (LOH) by using genomic probes detecting RFLPs in 35 uterine cancers at 29 loci throughout the genome, and with highly informative microsatellite markers in 21 uterine cancers at nine putative or known tumor suppressor gene loci. High frequencies of allelic loss found at loci on 3p (71%), 9q (38%), 10q (35%), and 17p (35%) suggest that tumor suppressor genes involved in uterine carcinogenesis exist in these regions. There were no significant differences in frequencies of LOH between cancers of the uterine cervix and cancers of the uterine endometrium at any of the loci tested.
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PMID:Allelotype of uterine cancer by analysis of RFLP and microsatellite polymorphisms: frequent loss of heterozygosity on chromosome arms 3p, 9q, 10q, and 17p. 751 41

The Wilms' tumor suppressor gene WT1 encodes a zinc finger transcription factor, whose expression inhibits the growth of the RM1 Wilms' tumor cell line. Transient transfection of WT1 constructs into 3T3 or 293 cells results in transcriptional repression of a number of cotransfected promoters containing the early growth response gene 1 consensus sequence. We now show that WT1 has properties of a transcriptional activator in RM1 cells, an effect that may be associated with the presence of a mutated p53 gene in these cells. Stable transfection of wild-type WT1 into RM1 cells results in induction of endogenous insulin-like growth factor 2 (IGF2) but not of other previously postulated WT1-target genes. The induction of IGF2 is dramatically enhanced by WT1 mutants encoding an altered transactivation domain. We conclude that IGF2 is a potentially physiological target gene for WT1 and that its induction may contribute to the growth-stimulating effects of WT1 variants.
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PMID:WT1 induces expression of insulin-like growth factor 2 in Wilms' tumor cells. 755 24

The Wilms tumor suppressor gene WT1 encodes a developmentally regulated transcription factor that is mutated in a subset of embryonal tumors. To test its functional properties, we developed osteosarcoma cell lines expressing WT1 under an inducible tetracycline-regulated promoter. Induction of WT1 resulted in programmed cell death. This effect, which was differentially mediated by the alternative splicing variants of WT1, was independent of p53. WT1-mediated apoptosis was associated with reduced synthesis of the epidermal growth factor receptor (EGFR), but not of other postulated WT1-target genes, and it was abrogated by constitutive expression of EGFR. WT1 repressed transcription from the EGFR promoter, binding to two TC-rich repeat sequences. In the developing kidney, EGFR expression in renal precursor cells declined with the onset of WT1 expression. Repression of EGFR and induction of apoptosis by mechanism that may contribute to its critical role in normal kidney development and to the immortalization of tumor cells with inactivated WT1 alleles.
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PMID:WT1 suppresses synthesis of the epidermal growth factor receptor and induces apoptosis. 758 96

The Wilms' tumor-suppressor gene product WT1 coimmunoprecipitates with p53 from baby rat kidney (BRK) cells and Wilms' tumor specimens, and expression of WT1 in BRK cells is associated with increased levels of endogenous wild-type p53 protein. To study the effect of WT1 on p53 function, we cotransfected expression constructs into Saos-2 cells, an osteosarcoma cell line without endogenous expression of either gene. Expression of WT1 resulted in increased steady-state levels of p53, attributable to a prolongation in protein half-life, and associated with protection against papillomavirus E6-mediated degradation of p53. This effect mapped to zinc fingers 1 and 2 of WT1 and was not observed with the closely related EGR1 protein. The stabilized p53 demonstrated enhanced binding to its target DNA sequence and increased trans-activation of a promoter containing this RGC site, but reduced transcriptional repression of a TATA-containing promoter lacking this site. Expression of WT1 inhibited p53-mediated apoptosis triggered by UV irradiation or by expression of temperature-sensitive p53 in the wild-type conformation, but did not affect p53-mediated cell cycle arrest. We conclude that WT1 protein can stabilize p53, modulate its trans-activational properties, and inhibit its ability to induce apoptosis. This effect may contribute to the elevated levels of wild-type p53 protein that are observed in Wilms' tumors.
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PMID:The WT1 gene product stabilizes p53 and inhibits p53-mediated apoptosis. 765 66

Mutations of p53 frequently occur in a wide variety of cancers including lung, breast, gastrointestinal, brain, and hematologic malignancies. These alterations apparently contributed to development of the malignant phenotype. Wilms' tumor is one of the most common solid tumors in childhood. The frequency of p53 alterations in this tumor is unknown. We analyzed 66 Wilms' tumor samples for p53 mutations by single-stand conformational polymorphism (SSCP) following polymerase chain reaction (PCR). Samples with an abnormal SSCP pattern were reamplified and analyzed by direct sequencing method. Mutations of p53 were found in three (5%) of 66 Wilms' tumors within the coding region (exons 2-11), showing that the frequency of p53 mutations was low. Two mutations substituted amino acids residues and one encoded a stop codon. Two of the mutations were located in the mutational hotspots (exons 5 and 6); the other was in exon 10. These data suggest that p53 mutations are infrequent in the development of Wilms' tumors.
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PMID:Mutations of p53 in Wilms' tumors. 767 65


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