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 685,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Several lines of evidence suggest a relationship between the occurrence of meningiomas and that of breast carcinomas: Both occur more frequently in women than in men, and a higher incidence of meningiomas has been observed in patients with a history of breast carcinoma. Both tumor types also express receptors that are associated with a proliferative response to progesterone, estrogen, and androgen hormones. Despite this clinical evidence, no genetic links between the two tumor types have been found. The breast carcinoma genes BRCA1 and BRCA2 have been linked to familial and sporadic forms of breast cancer and ovarian cancer, providing an opportunity to test this clinical observation. We conducted studies to detect alterations of the BRCA genes in meningiomas. Evaluation of 60 sporadic meningiomas with a panel of eight microsatellite and two restriction fragment length polymorphism markers at the locations of BRCA1 and BRCA2 demonstrated no loss of heterozygosity. Microsatellite instability was detected for one meningioma at two markers close to the BRCA2 locus. Northern blot analysis did not reveal any differences in mRNA expression of meningiomas compared to control tissues. These results suggest that alterations of the BRCA1 and BRCA2 genes are not common pathogenetic events in the development of sporadic meningiomas.
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PMID:Analysis of the BRCA1 and BRCA2 genes in sporadic meningiomas. 929 Sep 54

We performed a detailed and comprehensive study of the involvement of tumor suppressor genes in human prostate cancer. We utilized primers flanking either the restriction fragment length polymorphism (RFLP) or variable number of tandem repeat [VNTR; microsatellite or simple repeat site (SRS)] polymorphic sites to polymerase chain reaction (PCR) amplify the genomic DNA and detect loss of heterozygosity of the target genes. Quantitative reverse transcription (RT)-PCR was performed to measure the mRNA expression levels and PCR/single strand conformational polymorphism (SSCP) and DNA sequencing carried out to detect mutation of the tumor suppressor genes. We found that multiple tumor suppressor genes (e.g., p53, DCC, APC, MCC, BRCA1, and WAF1/CIP1) were inactivated at different frequencies via various mechanisms [e.g., loss of heterozygosity (LOH), loss of expression (LOE), mutation, and inactivation by cellular binding protein]. Several important and novel findings are as following: LOH and LOE of the DCC gene, LOH, LOE, and possible mutation of the APC/MCC genes, LOH of the BRCA1 locus, and mutation of the WAF1/CIP1 gene. For p53 tumor suppressor gene alone, multiple inactivation mechanisms (i.e., LOH, LOE, mutation, and amplification of the cellular inactivating protein MDM2) were identified. A possible involvement of genomic instability or mutator phenotype in human prostate cancer was investigated by microsatellite typing using PCR. A high frequency of microsatellite instability was detected and the microsatellite instability found to correlate with advanced stage and poor differentiation of prostate cancer, suggesting that genes functioning in DNA mismatch repair or general stabilization of the genome may be involved in prostate cancer. The results obtained in this study suggested that multiple tumor suppressor genes (both known and unknown genes) may share the role in prostate cancer; a pattern which has been found in a number of human malignancies such as cancers of the esophagus, colon and breast. In fact, we performed deletion studies aimed at localizing potential tumor suppressor loci on various chromosomal regions. A number of chromosomal regions (i.e., 6p12-24 and 17q21) were found to potentially harbor unidentified tumor suppressor genes. Detailed deletion mapping has localized the potential tumor suppressor loci to a < 2 Mb region centromeric to the BRCA1 gene on chromosome 17q. In addition, we identified a number of novel mechanisms of tumor suppressor gene inactivation, in prostate cancer such as loss of mRNA expression of the DCC, APC, MCC and p53 gene, and mutator phenotype. And for the very first time, we identified somatic mutations of the WAF1/CIP1 gene in primary human malignancy-human prostate cancer. This finding provides the first evidence in primary tumor that the WAF1/CIP1 gene may be a tumor suppressor gene and may be involved in prostate cancer. We identified 12-lipoxygenase (12-LOX) as a potential prognostic marker for human prostate cancer. mRNA expression levels of the 12-LOX gene was measured by quantitative reverse transcription-polymerase chain reaction (RT-PCR) and semi-quantitative in situ hybridization (ISH) in 122 pairs of matched normal and tumor tissues from prostate cancer patients. We found that 12-LOX expression levels were elevated in approximately half of the patients analyzed and the 12-LOX elevation correlates with advanced stage, poor differentiation, and surgical margin positivity. Our data suggest that 12-LOX may serve as a correlative marker for a more aggressive phenotype of prostate cancer and therefore for poor prognosis. We are currently refining our assays for possible clinical applicability. Since not all patients with loss of expression of the DCC gene showed LOH of the DCC locus, there must be other mechanism(s) responsible for loss of expression of the DCC gene. When we analyzed the relationship between DCC loss of expression and 12-LOX elevation in prostate cancer pati
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PMID:Involvement of the multiple tumor suppressor genes and 12-lipoxygenase in human prostate cancer. Therapeutic implications. 932 30

Epidemiologic studies have shown that the risk of cancer in the ovarian surface epithelium is decreased by factors that suppress ovulation, whereas uninterrupted ovulation has been associated with increased risk. This suggests that ovulation may play a critical role in ovarian carcinogenesis. More recently, molecular studies have demonstrated alterations in specific oncogenes and tumor suppressor genes in ovarian cancers. Overexpression of the HER-2/neu oncogene occurs in approximately 30% of ovarian cancers and correlates with poor survival. Although mutation of the K-ras oncogene has been found in some mucinous ovarian cancers, mutations in this gene appear to be more common in borderline ovarian tumors. Amplification of c-myc occurs in approximately 30% of ovarian cancers and is more frequently seen in serous cancers. Mutation of the p53 tumor suppressor gene, with resultant overexpression of mutant p53 protein, occurs in 50% of stage III/IV and 15% of stage I/II ovarian cancers. Most p53 mutations in ovarian cancers are transitions, which suggests that they arise spontaneously rather than due to exogenous carcinogens. In contrast to the acquired genetic alterations described above that are a feature of sporadic ovarian cancers, 5-10% of ovarian cancers probably arise due to inherited genetic defects. Recently, the BRCA1 tumor suppressor gene has heen identified and shown to be responsible for most cases of hereditary ovarian cancer. Further studies are needed to augment our understanding of the molecular pathogenesis of ovarian cancer.
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PMID:Human ovarian cancer of the surface epithelium. 933 69

Germ-line mutations of the BRCA1 gene predispose women to early-onset breast and ovarian cancer by compromising the gene's presumptive function as a tumor suppressor. Although the biochemical properties of BRCA1 polypeptides are not understood, their expression pattern and subcellular localization suggest a role in cell-cycle regulation. When resting cells are induced to proliferate, the steady-state levels of BRCA1 increase in late G1 and reach a maximum during S phase. Moreover, in S phase cells, BRCA1 polypeptides are hyperphosphorylated and accumulate into discrete subnuclear foci termed "BRCA1 nuclear dots." BRCA1 associates in vivo with a structurally related protein termed BARD1. Here we show that the steady-state levels of BARD1, unlike those of BRCA1, remain relatively constant during cell cycle progression. However, immunostaining revealed that BARD1 resides within BRCA1 nuclear dots during S phase of the cell cycle, but not during the G1 phase. Nevertheless, BARD1 polypeptides are found exclusively in the nuclear fractions of both G1- and S-phase cells. Therefore, progression to S phase is accompanied by the aggregation of nuclear BARD1 polypeptides into BRCA1 nuclear dots. This cell cycle-dependent colocalization of BARD1 and BRCA1 indicates a role for BARD1 in BRCA1-mediated tumor suppression.
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PMID:Cell cycle-dependent colocalization of BARD1 and BRCA1 proteins in discrete nuclear domains. 934 65

The ability to identify individuals who are predisposed to specific malignant tumors is a promising molecular diagnostic by-product of over two decades of intensive research into the genetic pathogenesis of human cancer. Approximately 2% of Ashkenazi Jews carry recurrent germline mutations in either the BRCA1 or BRCA2 genes that may predispose these individuals to the development of breast and ovarian cancer. We have developed a nonisotopic method, based on the formation of heteroduplexes between polymerase chain reaction (PCR) amplified wild-type and mutant alleles, which can be used to identify the BRCA1 185delAG and the BRCA2 6174delT mutations. The same assay can also be used to verify the loss of heterozygosity in a tumor sample arising in an individual with a germline mutation. The four steps described in this report (PCR amplification, heteroduplex formation, acrylamide gel electrophoresis, and ethidium bromide staining/UV-fluorescence photography) can be readily and reproducibly performed in the course of a single day, making this a useful method for the routine identification of these mutations.
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PMID:Convenient, nonradioactive, heteroduplex-based methods for identifying recurrent mutations in the BRCA1 and BRCA2 genes. 936 Aug 44

Factors affecting the penetrance and expression of BRCA1 are not understood. Breast cancer risk and ovarian cancer risk, in general, are known to be associated with non-Mendelian factors. However, whether and how these various factors influence tumor development in BRCA1 mutation carriers is not known. Here we report the breast and ovarian cancer syndrome in an identical twin pair. These female identical twins had remarkably similar clinical histories. Both twins developed histologically similar ovarian cancer in their mid-fifties. One twin was diagnosed with stage III disease and died of refractory metastatic disease. The other twin was diagnosed with stage I disease but ultimately died of recurrent disease. Neither twin developed breast or colon cancer. The twins have both similarities and differences in terms of nongenetic cancer-related risk factors. Results of BRCA1 analysis of DNA from both twins revealed a novel mutation, 2711delA, which resulted in a premature termination at codon 892. This report has intriguing implications concerning the role of genotype in the ultimate penetrance and expression of disease among BRCA1 mutation carriers.
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PMID:A novel BRCA1 mutation in an identical twin pair with similar clinical histories. 940 79

Women carrying a germ-line mutation in the BRCA1 or BRCA2 genes have a high risk of developing breast cancer, and loss of the wild-type allele in tumors suggests that these genes function as tumor suppressor genes. The BRCA2 gene encodes a 3418-amino acid protein with no significant sequence similarity to any known protein. To begin to elucidate the cellular role of BRCA2, we have raised antibodies to the BRCA2 protein and used these to study its subcellular localization and expression. We show that BRCA2 is a nuclear protein expressed in response to cell proliferation and that BRCA2 expression is initiated before DNA synthesis.
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PMID:Nuclear location and cell cycle regulation of the BRCA2 protein. 940 55

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


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