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Query: UMLS:C0027651 (tumor)
 685,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A review of chromosomal analyses of human lung carcinomas is presented. Karyotypic studies have revealed multiple cytogenetic changes in most small cell lung carcinomas (SCLCs) and non-small cell lung carcinomas (NSCLCs). In SCLCs, losses from 3p, 5q, 13q, and 17p predominate; double minutes associated with amplification of members of the MYC oncogene family may be common late in disease. In NSCLCs, deletions of 3p, 9p, and 17p, +7, i(5)(p10), and i(8)(q10) often are reported. The recurrent deletions encompass sites of tumor suppressor genes commonly inactivated in lung carcinomas, such as CDKN2 (9p21), RB1 (13q14), and TP53 (17p13). Despite technical advances in cell culture, the rate of successful karyotypic analysis of lung carcinomas has remained low. Alternative molecular cytogenetic methods to assess chromosome changes in lung cancer, particularly comparative genomic hybridization (CGH) analysis, are discussed. Initial CGH studies confirm the existence of many of the karyotypic imbalances identified earlier in lung cancer and have revealed several recurrent abnormalities, such as 10q- in SCLC, that had not been recognized previously. The further application of such molecular cytogenetic approaches should enable investigators to define more precisely the spectrum and clinical implications of chromosome alterations in lung cancer.
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PMID:Advances in the analysis of chromosome alterations in human lung carcinomas. 914 Apr 50

BIN1 is a putative tumor suppressor that was identified in a genetic screen for polypeptides that interact with the MYC oncoprotein. Using a set of six monoclonal antibodies, we identified and examined biochemical features and localization of cellular BIN1. Epitope mapping indicated that a putative nuclear localization motif and the MYC-binding domain were among the regions recognized by five antibodies. In immunoprecipitation and Western analyses, cellular BIN1 was identified in human and rodent cells as a monomeric phosphoprotein of M(r) approximately 70,000. Pulse-chase experiments showed that BIN1 was short-lived, with a half-life of approximately 2 h. Cell immunofluorescence experiments revealed overlapping but unique nuclear localization patterns distinguished by two different antibodies. In normal cells, BIN1 was predominantly nucleoplasmic but was also present in a subnuclear compartment. Conversely, in a panel of tumor cells that expressed BIN1, the predominant localization was the subnuclear compartment. Taken together, the results suggested that the antibodies recognized different isoforms or conformations of BIN1, the localization of which varied between normal and tumor cells. This study will facilitate further analysis of the structure and regulation of BIN1 in normal and malignant cells.
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PMID:The putative tumor suppressor BIN1 is a short-lived nuclear phosphoprotein, the localization of which is altered in malignant cells. 924 58

DNA amplification is frequent in breast cancer and has been associated with specific clinicopathological parameters and/or worsened course of the disease. In the present work, we were interested in further defining the association linking the occurrence of DNA amplification to the emergence of specific breast tumor phenotype. To this aim, we studied by Southern blotting a total of 1875 breast tumor DNAs with 26 probes mapping at 15 distinct chromosomal localizations. Of the 26 loci tested, 11 loci showed elevated levels of amplification, 9 loci showed occasional and/or low level of DNA copy number increase, and 6 loci showed very rare or no variation. This allowed us to define six amplified domains mapping at 8p12, 8q24, 11q13, 12q13, 17q12, and 20q13.2, respectively. Over 60% of the tumors analyzed presented at least one amplification at one of these localizations. Amplifications often covered large regions of DNA and bore complex patterns involving coamplification of several colocalized markers. Statistical analysis revealed correlations associating DNA amplification with breast tumor phenotype, as well as sets of preferential coamplifications. Based on these correlations, we defined three subsets of breast cancer according to their patterns of DNA amplification. The first subset (group A) was organized around the amplifications at 11q13 and/or 8p12 and was predominantly composed of estrogen receptor-positive tumors and presented a large proportion of lobular cancers. The second subset (group B) was organized around the amplifications of ERBB2 and/or MYC. These tumors were mostly estrogen receptor-negative and of the ductal invasive type. The third subset (group C) corresponded to tumors in which no amplification was detected in the present screen. Tumors in this group were largely diploid and of low histopathological grading.
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PMID:Mapping of DNA amplifications at 15 chromosomal localizations in 1875 breast tumors: definition of phenotypic groups. 933 Oct 99

In a separate study (F. Courjal et al., Cancer Res., 57: 4360-4367, 1997), we have analyzed by Southern blotting the relationship between DNA amplification and clinicopathological features of breast cancer. Six regions of recurrent amplifications were tested (8p12, 8q24, 11q13, 12q13, 17q12, and 20q13), and the results suggested that there was a relationship between DNA amplification profiles and breast tumor phenotype. We had delineated three subgroups of tumors showing distinct DNA amplification profiles and clinicopathological characteristics: group A, tumors showing amplification at 11q13 and/or 8p12 and/or 20q13; group B, tumors amplified at ERBB2 and/or MYC and/or MDM2/SAS; and group C, tumors with no detectable amplification. The aim of the present work was to characterize extensively the amplification profiles in the different subgroups of tumors. Sixty-one breast tumors distributed in all three subgroups were studied by comparative genomic hybridization (CGH). There was an overall good agreement between Southern blotting results and CGH data. As expected, CGH revealed gains undetected by Southern blotting. Most of these gains occurred in regions for which no adapted probes were available but also revealed nondetected amplifications at 8q24 or 20q13. Tumors showed multiple aberrations with a medium number of 5.6 copy number variations/tumor, whereas, according to Southern blotting results, 38% of the tumors analyzed were devoid of any amplification. This proportion fell to 6.5% after CGH analysis. Recurrent gains were observed in tumors from all three subgroups, albeit at varying incidences, and involved 1q, 8q, 17q23-q24, and 20q13. Gains covered large regions of DNA and could possibly include several cores of amplification. Some events, such as gains at 16p11-p12 and 14q or losses at 22q, showed more restricted distributions, suggesting the existence of additional sets of preferential coamplifications. The complexity of genetic profiles revealed by CGH indicates that breast cancer development depends on a large (yet undetermined) number of genetic events. The description of molecular phenotypes in breast cancer may therefore prove to be complex, and it should be interesting to see how many breast tumor subtypes will be defined in the end.
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PMID:Comparative genomic hybridization analysis of breast tumors with predetermined profiles of DNA amplification. 933 Nov

Twenty primary central nervous system lymphomas (PCNSL) from immunocompetent patients (nineteen B-cell lymphomas and one T-cell lymphoma) were investigated for genetic alterations and/or expression of the genes BCL2, CCND1, CDK4, CDKN1A, CDKN2A, MDM2, MYC, RB1, REL, and TP53. The gene found to be altered most frequently was CDKN2A. Eight tumors (40%) showed homozygous and two tumors (10%) hemizygous CDKN2A deletions. Furthermore, methylation analysis of six PCNSL without homozygous CDKN2A loss revealed methylation of the CpG island within exon 1 of CDKN2A in three instances. Reverse transcription PCR analysis of CDKN2A mRNA expression was performed for 11 tumors and showed either no or weak signals. Similarly, immunocytochemistry for the CDKN2A gene product (p16) remained either completely negative or showed expression restricted to single tumor cells. None of the PCNSL showed amplification of CDK4. Similarly, investigation of CCND1 revealed no amplification, rearrangement or overexpression. The retinoblastoma protein was strongly expressed in all tumors. Only one PCNSL showed a mutation of the TP53 gene, i.e., a missense mutation at codon 248 (CGG to TGG:Arg to Trp). No evidence of BCL2 gene rearrangement was found in 11 tumors investigated. The bcl-2 protein, however, was strongly expressed in most tumors. None of the 20 PCNSL demonstrated gene amplification of MDM2, MYC or REL. In summary, inactivation of CDKN2A by either homozygous deletion or DNA methylation represents an important molecular mechanism in PCNSL. Mutation of the TP53 gene and alterations of the other genes investigated appear to be of minor significance in these tumors.
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PMID:Frequent inactivation of CDKN2A and rare mutation of TP53 in PCNSL. 954 85

Race is widely believed to be a factor in the relationship between S allele of L-MYC oncogene and disseminated lung cancer. In particular, the clinical significance of L-MYC genotype was demonstrated in the Japanese while the results for the white US, Australian and Norwegian cohorts were negative. The present study was concerned with distribution of L-MYC oncogene alleles in 43 patients with lung cancer and 77 healthy subjects in Moldova. L and S allele frequency in both groups were nearly identical. However, the SS genotype was registered much more frequently in patients with metastasis (10/28; 36%)(p < 0.05) than in those with localized tumor (0/12). Moreover, overall frequency of S allele was significantly higher in lung cancer patients with node involvement (35/56; 63%)(p < 0.02) than in those with localized tumors (8/24; 33%)(p < 0.02). Finally, a significant correlation was found between S allele occurrence and distant metastases (M1: 19/28; 68%; M0:26/58; 45%)(p < 0.05). Similar data were reported in Russia. (ABSTRACT TRUNCATED)
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PMID:[S allele of the L-myc oncogene is associated with lung cancer metastases in patients from Moldova]. 957 28

The cellular protooncogene MYC encodes a nuclear transcription factor that is involved in regulating important cellular functions, including cell cycle progression, differentiation, and apoptosis. Dysregulated MYC expression appears critical to the development of various types of malignancies, and thus factors involved in regulating MYC expression may also play a key role in the pathogenesis of certain cancers. We have cloned one such MYC regulatory factor, termed CTCF, which is a highly evolutionarily conserved-11-zinc finger transcriptional factor possessing multiple DNA sequence specificity. CTCF binds to a number of important regulatory regions within the 5' noncoding sequence of the human MYC oncogene, and it can regulate its transcription in several experimental systems. CTCF mRNA is expressed in cells of multiple different lineages. Enforced ectopic expression of CTCF inhibits cell growth in culture. Southern blot analyses and fluorescence in situ hybridization (FISH) with normal human metaphase chromosomes showed that the human CTCF is a single-copy gene situated at chromosome locus 16q22. Cytogenetic studies have pointed out that chromosome abnormalities (deletions) at this locus frequently occur in many different human malignancies, suggesting the presence of one or more tumor suppressor genes in the region. To narrow down their localization, several loss of heterozygosity (LOH) studies of chromosome arm 16q in sporadic breast and prostate cancers have been carried out to define the most recurrent and smallest region(s) of overlap (SRO) for commonly deleted chromosome arm 16q material. For CTCF to be considered as a candidate tumor suppressor gene associated with tumorigenesis, it should localize within one of the SROs at 16q. Fine-mapping of CTCF has enabled us to assign the CTCF gene to about a 2 centiMorgan (cM) interval of 16q22.1 between the somatic cell hybrid breakpoints CY130(D) and CY4, which is between markers D16S186 (16AC16-101) and D16S496 (AFM214zg5). This relatively small region, containing the CTCF gene, overlaps the most frequently observed SROs for common chromosomal deletions found in sporadic breast and prostate tumors. In one of four analyzed paired DNA samples from primary breast cancer patients, we have detected a tumor-specific rearrangement of CTCF exons encoding the 11-zinc-finger domain. Therefore, taken together with other CTCF properties, localization of CTCF to a narrow cancer-associated chromosome region suggests that CTCF is a novel candidate tumor suppressor gene at 16q22.1.
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PMID:A widely expressed transcription factor with multiple DNA sequence specificity, CTCF, is localized at chromosome segment 16q22.1 within one of the smallest regions of overlap for common deletions in breast and prostate cancers. 959 31

In contrast to low-grade B-cell lymphomas originating in the gastrointestinal (GI) tract, only few cytogenetic data are available for the large cell, highly malignant variants. We studied 31 large B-cell lymphomas of the GI tract by comparative genomic hybridization (CGH) and fluorescence in situ hybridization using specific DNA probes (FISH). The most frequent aberrations were gains of all or of parts of chromosomes 11 (11 cases), 12 (9 cases), 1q (4 cases), and 3q (4 cases). Losses of parts of chromosome 6q and of parts of the short arm of chromosome 17 (6 cases each) were found most frequently. In four cases a total of seven high-level DNA amplifications was detected. In two of these cases, involvement of specific protooncogenes (REL and MYC) was shown. Some genetic aberrations seemed to be associated with an inferior clinical course: patients with >/=2 aberrations had a significantly shorter median survival. Furthermore, all patients with gains of all or parts of chromosome arm 1q and with high-level DNA amplifications as well as seven of nine patients with gains of all or parts of chromosome 12 died of lymphoma. In conclusion, the pattern of chromosomal gains and losses in large B-cell lymphomas was different from data reported for low-grade (MALT) lymphomas of the stomach and bowel, especially with respect to the high incidence of partial gains of chromosome arm 11q and of all or parts of chromosome 12 and the low frequency of polysomy 3. In addition, our data suggest that chromosomal gains and losses detected by CGH and FISH may predict for the outcome of patients with this tumor entity.
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PMID:Characteristic pattern of chromosomal gains and losses in primary large B-cell lymphomas of the gastrointestinal tract. 959 81

Twenty-one patients with T-prolymphocytic leukemia (T-PLL) were studied by FISH to characterize abnormalities of chromosomes 8, 11, 14, and X. A higher percentage of abnormalities of these chromosomes was detected by FISH than by cytogenetics. Seventy-one percent had inv(14) (q11q32)/t(14;14)(q11;q32). Four patients had abnormalities involving Xq28 (MTCP-1 locus) resulting from t(X;14)(q28;q11) or t(X;7)(q28;q35). These abnormalities have also been described in persistent expanding pre-malignant T-cell clones in patients with ataxia telangiectasia (AT). We have previously reported that in T-PLL and AT developing T-cell leukemia, the above abnormalities occur with additional abnormalities, mainly trisomy for 8q resulting predominantly from an i(8)(q10) and an increased expression of MYC. In this series, 81% of cases had chromosome 8 abnormalities including i(8)(q10)[43%]/t(8;8)(p12;q11)[14%], + 8[14%], and 8p + [14%]. The use of probes for MYC (8q24) and chromosome 8 centromere on metaphase chromosomes revealed that cases with i(8)(q10) were dicentric and t(8;8) monocentric. These abnormalities are not only associated with increase in dosage of 8q and the MYC gene, but also involved 8p. 8p is known to have several suppressor genes associated with solid tumors. Our findings suggest that the possible loss of a tumor suppressor gene plus the increased dosage of the q arm and/or the high expression of TCL-1/MTCP-1, which results from inv(14)/t(14;14), allows the malignant phenotype to emerge.
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PMID:Abnormalities of chromosomes 8, 11, 14, and X in T-prolymphocytic leukemia studied by fluorescence in situ hybridization. 961 8

One of the most common chromosomal abnormalities in prostate cancer involves loss of 10q22-qter. Rarely, a smaller deletion, involving 10q24-q25, has been observed, suggesting the presence of a tumor suppressor gene at this site. We previously demonstrated that the MXI1 gene maps to 10q24-q25 and is mutated in some tumors with cytogenetically detectable deletions of this locus. MXI1 encodes a basic-helix-loop-helix protein that suppresses the transcriptional activity of the MYC oncoprotein by competing for the common dimerization partner, MAX, and binding to identical DNA sites. Because more than 90% of prostate tumors contain no cytogenetic abnormality of 10q, the relevance of MXI1 loss and/or mutation to the vast majority of cases remains unclear. We prospectively evaluated prostate tumors for loss of MXI1 by fluorescence in situ hybridization (FISH) and cytogenetic techniques. Twenty-one of 40 tumors (53%) demonstrated loss of a single MXI1 allele as determined by FISH. Ten cases with cytogenetically normal 10qs, but with FISH-documented deletion of MXI1, were examined at the molecular level, and eight mutations were identified, albeit at low frequency. Five of the mutant proteins were unable to bind DNA in association with MAX. We conclude that MXI1 gene loss in prostate cancer is common and most frequently involves a cytogenetically undetectable deletion.
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PMID:Commonly occurring loss and mutation of the MXI1 gene in prostate cancer. 966 67


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