UNIPROT:P04637 - FACTA Search

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

Carcinoid tumor of the kidney is a rare neoplasm of uncertain histogenesis. Attempts to elucidate its cell of origin have been made, but there is a lack of experimental proof. We present a case of primary renal carcinoid tumor with a characteristic molecular abnormality and discuss its histogenetic implications. Histologic, immunohistochemical, and electron microscopic analyses revealed features typical of carcinoid tumor, and DNA flow cytometric analysis showed diploid pattern. Molecular genetic studies of informative WT1, p53, and 3p21 loci revealed loss of heterozygosity only at the D3F15S2 locus (3p21 telomeric). The similarity between the molecular abnormality in the present case and that in most renal cell carcinomas suggests a possible common genetic event in the genesis of these neoplasms.
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PMID:Primary renal carcinoid tumor with molecular abnormality characteristic of conventional renal cell neoplasms. 773 56

Wilms' tumor, or nephroblastoma, is a developmental malignancy of the kidney that affects approximately 1 in 10,000 children between 1 and 6 years of age. Typically, the histology of nephroblastoma reveals a disorganized renal developmental process showing blastema and epithelia randomly interspersed in varying amounts of stroma. This developmental disruption is associated with the loss of function of the tumor suppressor gene WT-1. This gene, located on chromosome 11 at band p13, codes for a zinc finger protein that may act as a transcriptional repressor. Familial cases of Wilms' tumor fit Knudson's "two hit" model, according to which a germ line mutation of one WT-1 allele predisposes to the tumor while an additional somatic mutation of the other allele causes malignant transformation. Originally proposed for retinoblastoma, this model defines the nature of the tumor suppressor gene as a gene that is tumorigenic when inactivated. However, not all Wilms' tumor cases fit this model because the majority of Wilms' tumors do not show a mutation of WT-1. For Wilms' tumor, the loss of tumor suppression appears to be more complex than for retinoblastoma. Some of the mechanisms recognized to date involve dominant negative WT-1 mutations, interaction of the WT-1 gene product with other mutated transcription factors such as p53, loss of imprinting, and mutations of other tumor suppressor genes at 11p15 or other loci. Although classic Wilms' tumor is associated with good prognosis (85% survival), its anaplastic form is often fatal. Despite the plethora of knowledge gained in recent years, Wilms' tumor remains the center of attention for further investigation because it offers opportunities for studying normal kidney development, for understanding the molecular basis for clinically important anaplastic forms, as well as for elucidating the molecular mechanisms of tumor suppressor genes. To facilitate this task, Wilms' tumor heterotransplants have been established in nude mice. This provides an indefinite source of tumor tissue and a means to test their growth properties in response to drug treatments or molecular genetic manipulations. Furthermore, the establishment of stable Wilms' tumor cell lines is essential to investigating further the molecular basis of tumorigenesis using recombinant DNA technology.
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PMID:Nephroblastoma (Wilms' tumor): a model system of aberrant renal development. 780 6

The p53 gene product is required for activation of an apoptotic pathway triggered by oncogenes and cytotoxic agents. Wilms' tumor, a pediatric renal malignancy, provides a paradigm for evaluating genetic events involved in tumor progression. This malignancy is generally not associated with p53 mutations, and even in advanced disease states is quite responsive to current treatment regimens. The anaplastic histological variant of Wilms' tumor, however, is frequently associated with p53 gene mutations and shows poor prognosis. We analyzed seven Wilms' tumors for which we had paired samples from nonanaplastic and anaplastic regions. p53 mutations were detected in six of these tumors, five of which demonstrated mutations restricted to anaplastic regions. Nonanaplastic cells of the sixth sample were heterozygous for a p53 mutation, whereas the anaplastic area of this tumor showed reduction to homozygosity. These results indicate that progression to anaplasia is associated with clonal expansion of cells which have acquired a p53 mutation. We demonstrated that tumor cells with p53 mutations show attenuated apoptosis, suggesting that such lesions may provide a selective advantage in vivo by decreasing cell death.
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PMID:Clonal expansion and attenuated apoptosis in Wilms' tumors are associated with p53 gene mutations. 781 46

The cases of two young male siblings independently developing unilateral Wilms' tumors and brain tumors are reported. The renal tumors were resected; the first child was treated with chemotherapy and the second child was given additional radiotherapy. Five years after treatment, both children developed a second primary neuroectodermal tumor. All four tumors showed a high proliferative activity, and rapidly progressing disease led to the death of the first child. Histopathological and molecular studies were carried out on all four neoplasms. No functionally relevant mutation was found in selected exons of the p53, K-ras and WT1 gene loci of tumor and germ line DNA. Since additional family members had developed brain tumors and carcinomas, this peculiar association of neoplasms may be due to germ line mutation of a hitherto unidentified oncogene acting in a recessive or weakly dominant fashion.
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PMID:Association of Wilms' tumor with primary brain tumor in siblings. 787 89

The frequent allelic deletions observed on the short arm of chromosome 11 in ovarian tumors suggest that the WT1 gene, a proposed tumor-suppressor gene located on chromosome 11p13 and expressed in the human fetal genitourinary system, may contribute to the development of ovarian neoplasms. Structural and sequence analysis of the entire coding portions of the WT1 gene did not reveal any abnormalities in the 20 ovarian tumor specimens (13 of which showed 11p13 allelic deletions) and 5 cell lines which we analyzed. These findings invalidate the hypothesis that the WT1 gene functions as a classical tumor-suppressor gene in ovarian tumorigenesis and suggest that a different recessive oncogene may be "exposed" by the observed 11p13 allelic deletions. Expression analysis showed that the WT1 gene was transcriptionally active in all the tumors tested, but considerable variations in the mRNA levels were found. This apparent variability, which should be confirmed at the cellular level in the tumor specimens, was also observed in the ovarian tumor-cell lines. Finally, WT1 expression data were evaluated in conjunction with immunohistochemical data on p53. The possible functional effects of altered WT1 mRNA expression in ovarian tumors are discussed, taking into account the potential WT1/p53 protein interaction.
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PMID:Molecular mechanisms possibly affecting WT1 function in human ovarian tumors. 791 Jan 52

Although it is widely accepted that tumor suppressor genes play an important role in the genesis and progression of human cancer, little is known about genetic events that accumulate during multistage lung carcinogenesis. Thus, to determine a subset of tumor suppressor genes that are involved in the genesis and progression of non-small cell lung carcinoma (NSCLC), 22 brain metastases and 23 stage I primary lung tumors were examined for allelic losses at 40 loci on 10 chromosomes including the loci of 5 tumor suppressor genes, APC, WT1, RB, p53, and DCC. The incidence of allelic losses on chromosomes 3p, 13q, and 17p was high (> 60%) in both primary tumors and brain metastases. In brain metastases, a high incidence of allelic losses (> 60%) was also observed at loci on chromosomes 2q, 18q, and 22q, and the incidence of allelic losses on these chromosomes in brain metastases was significantly higher than that in primary tumors (P < 0.05). In two cases of brain metastases with corresponding primary lung tumors, sequential accumulation of allelic losses during progression of primary lung tumors was observed on several chromosomes including chromosomes 2q and 18q. These results indicate that, besides loss of heterozygosity for chromosomes 3p, 13q, and 17p, loss of heterozygosity for chromosomes 2q, 18q, and 22q also occurs frequently in advanced NSCLCS. Thus, it is possible that loss of heterozygosity on chromosomes 2q, 18q, and 22q occurs late in the progression of NSCLC and/or causes phenotypic alterations of NSCLC cells into more aggressive ones.
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PMID:Frequent allelic losses on chromosomes 2q, 18q, and 22q in advanced non-small cell lung carcinoma. 792 10

We report expression of the wt1 (Wilms' tumor) gene by cultured human melanoma cells. Using RNA polymerase chain reaction analysis, wt1 transcripts were detected in 7 of 9 melanoma cell lines but not in 5 normal melanocyte strains. In Northern blot analysis, steady-state wt1 mRNA levels were found in 2 of 4 melanoma lines but not in normal melanocytes. Sequence analysis of the wt1 cDNA expressed by melanoma cell line WM 902-B revealed the presence of 4 previously published splice variants but no evidence for mutations in the coding region. Previous work has shown that WT1 modulates transcription after binding to the early growth response (EGR)-1 sites present in the platelet-derived growth factor (PDGF)-A chain promoter; the PDGF-A chain gene is known to be expressed by various melanoma cell lines. Based on these findings, we studied the relationship of wt1 and PDGF-A chain gene expression in melanoma cell lines. Co-expression of the wt1 and the PDGF-A chain genes was observed in 2 melanoma cell lines with mutated p53 but not in 2 melanoma cell lines with wild-type p53; this result is consistent with a previous report showing that, in the context of absent or mutated p53, WT1 acts as a transcriptional activator, whereas in the presence of wild-type p53 it acts as a repressor.
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PMID:Expression of the wt1 Wilms' tumor gene by normal and malignant human melanocytes. 792 8

The tumor suppressor/developmental regulator protein WT1 encoded by the Wilms' tumor gene is a zinc finger-containing transcription factor which binds to the G+C-rich motif 5'-GCGGGGGCG-3' and represses transcription. Alternatively spliced variants of WT1 (termed+KTS) having an insertion in the zinc finger region are defective for binding to and hence for repression of transcription from promoters containing this motif. Due to the known interactions of two other tumor suppressor proteins with the simian virus 40 (SV40) oncoprotein large tumor antigen (TAg) [which in one case (p53) results in inhibition of the replication initiation activity of TAg], and because of the presence of G+C-rich sequences in the SV40 origin region, we tested the effect of WT1 on TAg- and SV40 origin-dependent DNA replication. WT1 and its alternatively spliced variants were found to be potent inhibitors of replication. Inhibition of replication by WT1 required portions of the N-terminal transcription repression domain and the C-terminal DNA binding domain, while other WT1 sequences needed for transcriptional regulation were dispensable. WT1 neither inhibited the synthesis of TAg nor formed a stable complex with it. Studies of the requirement of cis-active origin sequences in vivo and protein-DNA interactions in vitro indicated that WT1 and its alternatively spliced variants might inhibit replication by their novel binding to the GC box promoter motifs of the SV40 21 bp repeat replication-auxiliary sequence.
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PMID:Novel replication inhibitory function of the developmental regulator/transcription repressor protein WT1 encoded by the Wilms' tumor gene. 793 34

Although pediatric solid tumors are cytogenetically less well characterized than childhood leukemias, an understanding of the role of chromosomal changes in the development of these neoplasms is emerging. The major clinical importance of chromosome analysis today is diagnostic. Especially in small cell round cell tumors of childhood, the unique karyotypic patterns that characterize some of the differential diagnostic entities make it possible to determine with a high degree of certainty which type of cancer the child has. Molecular studies have revealed that almost all retinoblastomas show homozygous loss of function of the RB1 gene in 13q14. At the cytogenetic level, however, aberrations of 13q are seen in less than 25% of retinoblastomas; instead, the presumably progression-related i(6p) and aberrations leading to gain of 1q predominate, each being present in one-third of the tumors. Twenty percent of cytogenetically aberrant Wilms' tumors show structural rearrangements, often deletions, of 11p13 and 11p15, where the WT1 and WT2 genes map. Other frequent changes are trisomy 12 and duplication of 1q. The most common (80%) cytogenetic abnormality in neuroblastoma is loss of distal 1p, a chromosome segment thought to harbor at least two tumor-suppressor genes of importance in tumorigenesis. Double minute chromosomes or homogeneously staining regions are present in one-third of all neuroblastomas and are associated with MYCN amplification. Loss of 1p material or MYCN amplification predicts a poor outcome. The most common (30%) chromosomal aberration in primitive neuroectodermal tumors of the central nervous system is i(17q). The formation of this isochromosome may help inactivate a tumor-suppressor gene located distal to the TP53 locus on 17p. No specific chromosome abnormality has been detected in gliomas, but monosomy 22 and rearrangements leading to loss of 1p and gain of 1q are recurrent. Few hepatoblastomas with chromosomal changes have been reported, but several potential primary aberrations have been described, including +2, +20, and duplication 8q. In Ewing's sarcoma, t(11;22)(q24;q12) is the primary aberration, with trisomy 8 and gain of 1q being frequent secondary changes. Fibrosarcomas in children often carry only numeric aberrations, especially trisomy for chromosomes 11, 20, 17, and 8. Most osteosarcomas are cytogenetically complex, and no specific abnormality has been detected; the single most common change is loss of chromosome 13, which is observed in half the tumors. In contrast, the low-malignancy parosteal osteosarcomas often display supernumerary ring chromosomes as the sole karyotypic deviation. The cytogenetic profiles of rhabdomyosarcomas differ among the various morphologic subtypes.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Cytogenetic analysis in the examination of solid tumors in children. 794 9

We report here the use of multiplex fluorescent polymerase chain reaction (PCR) for quantitative allele loss detection using microsatellites with 2-5 base pair repeat motifs. Allele loss of APC, DCC, p53 and RB1 in colorectal tumours has been reported previously using a variety of methods. However, not all workers used intragenic markers. We have used microsatellite polymorphisms which map within, or are closely linked to, these tumour-suppressor gene loci in order to determine whether these loci are indeed the targets for alteration in colorectal cancer. In addition, we have assayed two other tumour-suppressor genes, WT1 and NF1, to see whether they play a role in colorectal carcinogenesis. The putative metastasis-suppressor gene, NM23, was also investigated since there have been conflicting reports about its involvement in colorectal carcinogenesis. Allele loss was detected at the DCC (29%), p53 (66%), RB1 (50%) and NF1 (14%) loci and in the APC/MCC region (50%), but not at the WT1 or NM23 loci. These rapid, and mostly gene-specific, fluorescent multiplex PCR assays for allele loss detection could be modified to devise a single molecular diagnostic test for the important lesions in colorectal cancer.
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PMID:Frequency of allele loss of DCC, p53, RBI, WT1, NF1, NM23 and APC/MCC in colorectal cancer assayed by fluorescent multiplex polymerase chain reaction. 794 85

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