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)

Extensive research has led to accumulation of common hereditary evidence concerning ovarian and breast cancer, suggesting that these two cancers can be considered as one type. Subsequently, women with breast cancer are susceptible to the risk of developing ovarian cancer. Highly expressed oncogenes such as bcl-2, HER2/neu and others or mutated suppressor genes such as p53 or BRCA1 have been characterised as hereditary susceptibility genes leading to syndromes such as breast/ovarian cancer syndrome, Li-Fraumeni and others. Furthermore, these genetic alterations can cause potent chemoresistance by inhibiting induction of apoptosis after DNA damage caused by chemotherapy and/or radiotherapy. Presently, molecular onco-biology has enabled us not only to detect susceptibility to ovarian and breast cancer but also ways to inhibit their further progression or even circumventing chemoresistance mechanisms after their development by gene therapy using delivery vectors such as liposomes or viruses, by which we can replace wild-type tumour suppressor genes or by using antigene, antisense oligonucleotides and antisense RNA leading to reduced oncogene expression, enabling induction of apoptosis after DNA damage into chemoresistant tumour cells. Furthermore efflux-genes such as MDR-1 or MRP can be circumvented, suicide-genes can be employed which can facilitate sensitivity by encoding enzymes capable of converting inactive forms of a drug into toxic antimetabolites and immunotherapy can be achieved, by transfection of tumour cells with adenoviral vectors encoding immunomodulators such as IL-2 or MHC molecules. Thus, molecular biology appears to be a very strong element for the screening, diagnosis, therapy and prognosis of ovarian and breast cancer. However, consistent future research is greatly needed because many points concerning ovarian and breast cancer genetics are still unknown. Finally, we strongly believe that gene therapy could be extremely useful when is combined with conventional therapy against ovarian and breast tumours.
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PMID:Molecular aspects of breast and ovarian cancer. 937 59

The CDKN2A gene encodes p16 (CDKN2A), a cell-cycle inhibitor protein which prevents inappropriate cell cycling and, hence, proliferation. Germ-line mutations in CDKN2A predispose to the familial atypical multiple-mole melanoma (FAMMM) syndrome but also have been seen in rare families in which only 1 or 2 individuals are affected by cutaneous malignant melanoma (CMM). We therefore sequenced exons 1alpha and 2 of CDKN2A using lymphocyte DNA isolated from index cases from 67 families with cancers at multiple sites, where the patterns of cancer did not resemble those attributable to known genes such as hMLH1, hMLH2, BRCA1, BRCA2, TP53 or other cancer susceptibility genes. We found one mutation, a mis-sense mutation resulting in a methionine to isoleucine change at codon 53 (M531) of exon 2. The individual tested had developed 2 CMMs but had no dysplastic nevi and lacked a family history of dysplastic nevi or CMM. Other family members had been diagnosed with oral cancer (2 persons), bladder cancer (1 person) and possibly gall-bladder cancer. While this mutation has been reported in Australian and North American melanoma kindreds, we did not observe it in 618 chromosomes from Scottish and Canadian controls. Functional studies revealed that the CDKN2A variant carrying the M531 change was unable to bind effectively to CDK4, showing that this mutation is of pathological significance. Our results have confirmed that CDKN2A mutations are not limited to FAMMM kindreds but also demonstrate that multi-site cancer families without melanoma are very unlikely to contain CDKN2A mutations.
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PMID:CDKN2A mutation in a non-FAMMM kindred with cancers at multiple sites results in a functionally abnormal protein. 938 68

Rearrangements or loss of chromosome 17 are frequent events in breast tumors. Chromosome 17 contains at least four genes implicated in breast cancer (TP53, ERBB2 (Her2/neu), BRCA1, and NM23), as well as other putative tumor suppressor genes and oncogenes implicated in loss of heterozygosity or allelic imbalance studies. Allelic imbalance represents the addition or loss of genetic material in tumor samples, providing circumstantial evidence for the location of cancer related genes. We have analyzed a panel of 85 breast tumor/normal tissue pairs with 21 PCR-based short tandem repeat (STR) markers located at 17q12-qter to more precisely define regions of allelic imbalance and to determine their relation to clinical parameters. Our analysis revealed at least four common regions of allelic imbalance: proximal to BRCA1, including D17S800 (17q12); distal to NM23 around D17S787 (17q22); near the growth hormone (GH) locus, at D17S948 (17q23-24); and between markers D17S937 and D17S802 (17q25). These data also reveal that loss (or gain) of 17q genetic material correlates with poorly differentiated (grade III) tumors (P = < 0.001), high S phase fraction (P = 0.034), and positive TP53 immunohistochemical staining (P = 0.011). However steroid receptor status, ERBB2 (Her2/neu) staining, and aneuploidy do not correlate with allelic imbalance at 17q.
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PMID:Four regions of allelic imbalance on 17q12-qter associated with high-grade breast tumors. 940 51

Cells with abnormal TP53 lose cell cycle checkpoints, resulting in genomic instability and neoplastic transformation. However, the evidence linking the tumor-specific targets of genomic alteration to an abnormal TP53 is limited. The present study tested the hypothesis that TP53 abnormalities are correlated with an increased frequency of deletion of breast cancer susceptibility loci (17q and 13q) in breast carcinomas. Tumors from 90 patients were examined for TP53 abnormality and loss of heterozygosity (LOH) at 11 loci on 17q (17q11.2-21) and 13q (13q12-14), including the loci for BRCA1 and BRCA2. A higher frequency of LOH was consistently found at 17q or 13q loci in tumors with an abnormal TP53. The increased LOH in relation to TP53 abnormality was statistically significant at the BRCA1, D17S588, and D13S267 loci (P < 0.05) but not at the locus for BRCA2 (P = 0.64). These observations imply a possible link between an abnormal TP53 and specific genomic deletions of breast cancer susceptibility loci, which may provide clues to the role of TP53 during breast tumorigenesis.
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PMID:Allelic loss at BRCA1, BRCA2, and adjacent loci in relation to TP53 abnormality in breast cancer. 940 54

A decade of advances in understanding of the molecular basis of sporadic and familial cancers has combined with developments in mammalian gene transfer technology to stimulate intensive research into the potential applications of somatic gene therapy for cancer. Somatic gene immunotherapy is already in progress to stimulate and direct the natural targeting capabilities of the immune system against the threat of disseminated residual disease. The association of a plethora of mutated tumor suppressor genes (p53, p16 BRCA1, BRCA2) with diverse cancers has also highlighted the potential of somatic gene therapy with wild-type versions of suppressor genes as an anti-cancer therapeutic modality either in its own right or in synergistic association with traditional anti-cancer therapies. The methodologies for gene transfer technology range from direct intravenous injection of naked modified DNAs to intravenous injection of liposome-encapsulated DNAs or microsphere-bound DNAs. Recombinant retroviral and adenoviral vectors have natural transfection capabilities and display tropism for particular tissues that are of selective advantage against particular cancers. Liposomes display very high efficiencies of gene transfer with the advantages of successful transfer to a wide range of tissue types but their widespread systemic distribution offers problems in relation to selective targeting of tumor cells. The challenges to current gene transfer processes are much the same as that of other anti-cancer therapies: achieving selective targeting of cancer cells whilst optimizing dosages and minimizing the risk of collateral damage to healthy tissues.
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PMID:The basis for somatic gene therapy of cancer. 941 90

Despite nearly six decades of epidemiological studies, meta-analyses, and reviews, there is still considerable controversy in the literature about the question, does postmenopausal estrogen administration increase the risk of breast cancer? In an effort to resolve the controversy, a number of animal, biochemical, and clinical investigative studies in this field have been reviewed. The following summary formulation is proposed: 1. Administration of estrogen is inherently capable of promoting the growth of breast cancer, and therefore of increasing the incidence of clinical breast cancer. 2. Human response to estrogen is like that of the low-cancer-incidence strains of mice studied by Lacassagne, in that large doses and prolonged administration are required to induce clinical breast cancer. 3. The blood levels of estradiol produced by the usual doses of postmenopausal estrogen are relatively low, equivalent to those of the follicular phase of the menstrual cycle. These levels may be near the threshold for producing breast-cancer-promoting effects; therefore, the tumor response will vary greatly in different populations, depending on genetic susceptibility factors: a. The prevalence of a family history of premenopausal breast cancer in a first-degree relative. b. The prevalence of abnormal BRCA1, BRCA2, and p53 genes. c. The prevalence of increased 16 alpha-hydroxylation of estradiol. d. The prevalence of smokers who are slow acetylators. 4. Consumption of alcohol (5 grams or more daily) along with the postmenopausal estrogen administration results in elevation of blood estradiol levels to values equivalent to those of the periovulatory peak of the menstrual cycle, which may be well above the threshold for producing breast-cancer-promoting effects in all women. The risk for cancer will therefore be uniformly increased in women who use alcohol and take estrogen. 5. Increased risk of breast cancer from postmenopausal estrogen administration can be eliminated by taking two synergistic steps: a. Eliminating alcohol consumption, or at least keeping it well below an average of 5 grams daily (equivalent to 2/3 ounce of whiskey or 3 ounces of wine). b. Diminishing the capacity to 16 alpha-hydroxylate estradiol, either through pharmacological agents such as indole-3-carbinol or through increased consumption of cruciferous vegetables. It is concluded that despite the inherent ability of postmenopausal estrogen therapy to increase the risk of breast cancer in theory, the increased risk can be eliminated in practice by minimizing or eliminating consumption of alcohol and ingesting pharmacological or dietary agents that reduce the 16 alpha-hydroxylation of estradiol.
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PMID:Does postmenopausal estrogen administration increase the risk of breast cancer? Contributions of animal, biochemical, and clinical investigative studies to a resolution of the controversy. 942 Dec 4

During the last years, homologues of E coli RecA have been cloned in numerous species including man. These Rad51 proteins share sequence as well as functional homologies with the bacterial protein. Human Rad51 (HsRad51) is able to catalyze strand exchange in vitro between homologous DNAs, but with a lower efficiency compared to that of RecA. This suggests the requirement of additional factors. A very interesting feature of Rad51 is its essential role in mouse which could mean that it has gained an essential function in cell growth. The interaction of HsRad51 with several tumor suppressor genes namely p53, BRCA1 and BRCA2 implies possible role(s) of this protein in tumorigenesis. Thus, the continued study of Rad51 should bring important insights not only into homologous recombination mechanisms but also into cell proliferation regulation.
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PMID:Mammalian Rad51 protein: a RecA homologue with pleiotropic functions. 946 96

Breast tumours from BRCA1 and BRCA2 mutation carriers are genetically instable and display specific patterns of chromosomal aberrations, suggestive of distinct genetic pathways in tumour progression. The frequency of abnormalities affecting chromosome 17p and the TP53 gene was determined in 27 breast tumours from 26 female patients carrying the Icelandic BRCA2 founder mutation (999del5). Loss of heterozygosity (LOH) was detected in 23 of the 27 tumours (85%). The majority of tumours manifesting LOH had lost a large region on 17p, although a more restricted loss, including the TP53 locus was seen in a few tumours. Positive p53 immunostaining was observed in 18 of 26 tumours (69%). However, mutations in the TP53 gene were detected in only three tumours (11%), including a missense (codon 139) and a nonsense mutation (codon 306) in two tumours with moderate p53 expression and a frameshift deletion (codon 182) in a tumour with no detectable p53 expression. Positive p53 immunostaining, mainly weak, was observed in 16 of the 24 tumours (66%) without TP53 mutation. The high frequency of LOH at chromosome 17p13 suggests that one or more genes from this region are involved in the development of BRCA2-induced breast cancer. The frequent finding of weak overexpression of, presumably wild type p53 protein, suggests an alternative mechanism of TP53 involvement specific to these tumours.
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PMID:High incidence of loss of heterozygosity at chromosome 17p13 in breast tumours from BRCA2 mutation carriers. 946 39

Mutations in BRCA1 are present in 45% of families that segregate with susceptibility for breast cancer and in 80-90% of families with both breast and ovarian cancer. Here we report that BRCA1 stimulates artificial and genomic promoter constructs containing p53-responsive elements. This activity of BRCA1 depends on the presence of wild-type p53, which was shown by using mouse fibroblasts expressing temperature-sensitive forms of p53, or p53(+/+) and p53(-/-) fibroblasts obtained from p53 knockout mice. Furthermore, mutant forms of BRCA1 lacking the C-terminal second BRCA1 C-terminal (BRCT) domain showed reduced p53-mediated transcriptional activation. Finally, we found that BRCA1 coimmunoprecipitates with p53, in vitro and in vivo. These findings suggest a function of BRCA1 as a p53 coactivator.
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PMID:BRCA1 regulates p53-dependent gene expression. 948 80

We compared molecular alterations in histologically homologous ovarian and uterine carcinomas, including the prevalence of allelic loss of markers on 17q (within and distal to the familial breast-ovarian cancer gene BRCA1), mutations of codon 12 of Ki-ras and immunohistochemical expression of the p53 and c-erbB2 gene products in endometrioid and papillary serous carcinomas occurring in the uterus and ovary. A total of 86 uterine and 28 ovarian endometrioid carcinomas, as well as 8 uterine and 26 ovarian papillary serous carcinomas, were evaluated. The prevalence of p53 gene product immunoreactivity was similar in papillary serous carcinomas occurring in the uterus (6 of 8, 75%) and ovary (16 of 26, 62%). Allelic loss on 17q also was seen in similarly high proportions of uterine (3 of 7, 43%) and ovarian (16 of 25, 64%) papillary serous carcinomas. In contrast, expression of the p53 gene product was seen in significantly more endometrioid tumors of the ovary (14 of 28, 50%) than in those occurring in the uterus (4 of 86, 5%) (p < 0.0001). Allelic loss on 17q also was present in significantly more ovarian (19 or 27, 70% than in uterine (2 of 72, 3%) endometrioid carcinomas (p < 0.0001). Immunohistochemical expression of c-erbB2 and mutations of codon 12 of Ki-ras were present in a minority of carcinomas. Endometrioid tumors of the ovary and endometrium, although histologically similar, may arise from different genetic events, whereas uterine papillary serous carcinoma shares with its ovarian counterpart several molecular alterations that may account for its aggressive clinical behavior.
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PMID:Comparative analysis of histologic homologues of endometrial and ovarian carcinoma. 950 Jul 73

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