UMLS:C0027651 - FACTA Search

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

The MDM2 oncogene product is a regulator of the p53 tumor suppressor. MDM2 is cleaved by Caspase 3 (CPP32) during apoptosis after aspartic acid-361, generating a 60 kd fragment. Here we report that human tumor cell lines often express high levels of a 60 kd MDM2 isoform (p60) in the absence of apoptosis. We demonstrate that p60 is a product of caspase cleavage of full length MDM2 after residue 361. The protease that cleaves MDM2 in non-apoptotic cells appears to be distinct from the apoptosis-specific Caspase 3, since Caspase 3 substrate poly(ADP-ribose) polymerase (PARP) is not cleaved in cells producing p60. The p60 form of MDM2 is a significant fraction of the p53-bound MDM2 protein in certain tumor cells, suggesting that it functions in the regulation of p53. p60 is also detected in breast tumors overexpressing MDM2. These observations suggest that MDM2 is regulated by caspase processing in non-apoptotic cells, and may account for the MDM2 proteins of similar mobility seen in tumors and other cell lines.
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PMID:A 60 kd MDM2 isoform is produced by caspase cleavage in non-apoptotic tumor cells. 984 Sep 26

The p16-pRb and p53-MDM2 pathways represent vital cell cycle checkpoints. Recent studies provide evidence that these pathways are directly linked via MDM2-pRb interaction and p53 suppression of the RB1 gene. In the present study we investigated the alterations of this G1 phase protein network using immunohistochemical and molecular methods in a series of 68 non-small-cell lung carcinomas (NSCLCs) and correlated the findings with clinicopathological features and prognosis of the patients. Aberrant expression (Ab) of p16 and pRb was observed in 33 (49%) and 27 (40%) of the carcinomas, respectively. Analysis of the region that encodes for p16 by deletion mapping, a polymerase chain reaction (PCR)-based methylation assay and PCR single-strand conformation polymorphism (SSCP) analysis revealed that deletions and transcriptional silencing by methylation might represent the main mechanisms of CDKN2/p16ink4a inactivation in NSCLCs. The results of deletion mapping also suggest that other tumor suppressor genes may reside at the 9p21-22 region, which encodes for CDKN2/MTS1/p16ink4a, p14ARF, and MTS2/p15ink4b. In addition, microsatellite instability was observed with a frequency of 16% in the 9p21-22 chromosome area. Overexpression (P) of p53 and MDM2 proteins was found in 39 (58%) and 47 (70%) of the cases, respectively. A highly significant association was observed between p53 overexpression and p53 mutations (P = 0.006). Statistical analysis of the expression patterns of the biologically relevant molecules (p16/pRb, p53/MDM2, MDM2/pRb, and p53/pRb) showed coincident overexpression of p53 and MDM2 (P = 0.04) and that abnormal pRb was correlated with elevated levels of MDM2 (P = 0.013) and p53 (P = 0.01), respectively. We suggest that deregulated expression of these molecules may act synergistically. An important finding of the study was that multiple impairments (three and four molecules affected) of the p16/pRb/p53/MDM2 network occurred in a large proportion (43%) of the carcinomas. This finding in addition to the absence of correlation with clinical stage of the tumors suggests that multiple hits of this network may be a relatively early event in the development of a subset of NSCLCs. The relationship between the factors examined in the present study, clinicopathological features, and survival of the patients did not reveal any significant correlations with the exception of smoking, which was associated with microsatellite alterations (loss of heterozygosity and microsatellite instability) at the 9p21-22 locus (P = 0.04) and the immunophenotypes p53(P)/MDM2(P) (P = 0.04) and p16(Ab)/pRb(Ab)/p53(P)/MDM2(P) (P = 0.03), respectively. We suggest that in a subset of NSCLCs, simultaneous deregulation of the members of this network may represent one way of initiating the oncogenic procedure whereas in other NSCLC subgroups alternative pathways may play this role.
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PMID:Alterations of the p16-pRb pathway and the chromosome locus 9p21-22 in non-small-cell lung carcinomas: relationship with p53 and MDM2 protein expression. 984 66

Transforming growth factor-beta (TGF-beta) inhibits cell proliferation, and acquisition of TGF-beta resistance has been linked to tumorigenesis. A genetic screen was performed to identify complementary DNAs that abrogated TGF-beta sensitivity in mink lung epithelial cells. Ectopic expression of murine double minute 2 rescued TGF-beta-induced growth arrest in a p53-independent manner by interference with retinoblastoma susceptibility gene product (Rb)/E2F function. In human breast tumor cells, increased MDM2 expression levels correlated with TGF-beta resistance. Thus, MDM2 may confer TGF-beta resistance in a subset of tumors and may promote tumorigenesis by interference with two independent tumor suppressors, p53 and Rb.
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PMID:p53-independent role of MDM2 in TGF-beta1 resistance. 985 53

The AIB1 gene was isolated upon microdissection of the homogeneously staining regions observed in breast cancer cell lines. It was subsequently shown to map at a region at 20q12 that is frequently amplified in breast tumors. In a screen of breast tumor cell lines, of all the genes mapping to the region, AIB1 appeared to be the most consistently amplified and overexpressed. AIB1 shares homology with the SRC-1 family of nuclear receptor coactivators. It was found to interact in a ligand-dependent manner with the estrogen receptor (ER) and to result in increased levels of estrogen-dependent transcription. These properties could be of important biological significance in breast and ovarian cancerigenesis, and we were, therefore, interested in determining whether the amplification of the AIB1 gene was associated with a particular phenotype or subgroup in these tumors. We tested a population of 1157 breast and 122 ovarian tumors in which DNA amplification had been determined previously at 15 chromosomal locations. Amplification of the AIB1 gene was observed in 4.8% of breast cancers and 7.4% of ovarian cancers. In breast tumors, AIB1 was correlated with ER and progesterone receptor positivity, as well as with tumor size. Correlation was also observed with the amplification of MDM2 and FGFR1 genes, but interestingly, no correlation was found with the amplification of CCND1, which is known to be strongly associated with ER. Furthermore, analyzing at 20q12-q13 range, we show the existence of three amplification cores, represented by AIB3/AIB4, AIB1, and RMC20C001. AIB1 and CCND1 amplifications may, thus, represent two different subsets of ER-positive breast tumors.
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PMID:In breast cancer, amplification of the steroid receptor coactivator gene AIB1 is correlated with estrogen and progesterone receptor positivity. 986 2

The key role of p53 and Rb alterations in human osteosarcoma is clear. For example, osteosarcoma is common in individuals inheriting mutant p53 or Rb genes. Osteosarcoma in dogs is similar to humans by histology, site, gender ratio and several other biological parameters. To study whether this similarity extends to the molecular level, 21 canine osteosarcomas were analyzed for alterations of p53, Rb and MDM2. MDM2 is a normal cell protein which antagonizes p53, amplification is seen in some human sarcomas. The gross structure of the p53, Rb and MDM2 genes was examined by Southern blotting. No deletions or rearrangements of the p53 or Rb genes were detected. The absence of gross gene alterations affecting these tumor suppressor genes is a significant difference between the disease in dogs and humans, since rearrangements or deletions of the p53 or Rb genes occur in 20-30 per cent of human osteosarcomas. The MDM2 gene appeared to be duplicated in one canine tumor but no cases of significant amplification were detected. Expression of normal Rb was detected in all cases. Mutations of the p53 gene were found in 38 percent of canine osteosarcomas. Analysis of mutations revealed a predominance of spontaneous mutation. These finding emphasize the key role that alterations of p53 have in the development of osteosarcoma in dogs and humans.
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PMID:Status of the p53, Rb and MDM2 genes in canine osteosarcoma. 989 8

Cell cycle checkpoint controls play a major role in preventing the development of cancer [see Sherr, 1994, for a more detailed discussion]. Major checkpoints occur at the G1 to S phase transition and at the G2 to M phase transitions. Cancer is a genetic disease that arises from defects in growth-promoting oncogenes and growth-suppressing tumor suppressor genes. The p53 tumor suppressor protein plays a role in both the G1/S phase and G2/M phase checkpoints. The mechanism for this activity at the G1/S phase checkpoint is well understood, but its mechanism of action at the G2/M phase checkpoint remains to be elucidated. The p53 protein is thought to prevent chromosomal replication specifically during the cell cycle if DNA damage is present. In addition, p53 can induce a type of programmed cell death, or apoptosis, under certain circumstances. The general goal of p53 appears to be the prevention of cell propagation if mutations are present. The p53 protein acts as a transcription factor by binding to certain specific genes and regulating their expression. One of these, WAF1 or Cip1, is activated by p53 and is an essential downstream mediator of p53-dependent G1/S phase checkpoint control. The function of p53 can be suppressed by another gene, MDM2, which is overexpressed in certain tumorigenic mouse cells and binds to p53 protein, thus inhibiting its transcriptional activation function. Other cellular proteins have been found to bind to p53, but the significance of the associations is not completely understood in all cases. The large number of human cancers in which the p53 gene is altered makes this gene a good candidate for cancer screening approaches.
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PMID:Checking on the cell cycle. 989 55

The transcription of MDR1 gene may be increased by mutation or loss of function of p53 gene. In this study, we investigated whether in osteosarcoma, the p53 status is correlated with overexpression of the MDR1 gene product P-glycoprotein. The relationship between P-glycoprotein expression and p53 status was analyzed by immunohistochemistry in 64 primary and 11 metastatic high-grade osteosarcomas. In the same series, we also assessed the nuclear accumulation of MDM2 protein, whose binding to p53 protein provides an alternative mechanism of p53 inactivation. No association was found between mutant-p53 and MDM2 nuclear accumulation either with P-glycoprotein expression or with clinical course. Only increased expression of P-glycoprotein in tumor cells was significantly associated with a poor outcome, further supporting the adverse prognostic value of this marker in osteosarcoma.
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PMID:Relationship between P-glycoprotein expression and p53 status in high-grade osteosarcoma. 991 6

The INK4A gene, localized to human chromosome 9p21, encodes p16INK4A, a tumor suppressor that functions at least in part through the inhibition of CDK4, a cyclin-dependent kinase encoded by a gene at 12q13. To examine INK4A gene alterations in uncultured samples of osteosarcoma and the relationship between INK4A and CDK4 alterations, we analyzed the INK4A and CDK4 genes in 87 specimens from 79 patients. INK4A deletion and CDK4 gene amplification were determined by quantitative Southern blot analysis. INK4A exon 2 was screened for mutation by polymerase chain reaction and single-strand conformational polymorphism analysis. Methylation at the CpG island in INK4A, associated with loss of p16INK4A expression, was assessed by Southern blot analysis using methylation-sensitive restriction enzymes. INK4A deletion (4/55) or rearrangement (1/55) was found in 5 of 55 cases. No INK4A exon 2 point mutations and methylation were detected. CDK4 gene amplification was found in 6 of 67 samples, but not in tumors with INK4A alteration. Amplification analysis of other genes at 12q13 (GLI, CHOP, HMGI-C and MDM2) in these 6 cases supports the view that CDK4 and MDM2 are independent targets for amplification, with variable amplification of the intervening region containing HMGI-C. Of 46 patients studied for both INK4A alterations and CDK4 amplification, the tumors in 22% contained one or the other. The prevalence of these alterations, in conjunction with the reported inactivation of RB in up to 80% of cases, suggests that genetic lesions deregulating the G1 to S cell cycle checkpoint may be an almost constant feature in the pathogenesis of osteosarcoma.
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PMID:CDK4 gene amplification in osteosarcoma: reciprocal relationship with INK4A gene alterations and mapping of 12q13 amplicons. 993

Central giant cell granuloma (CGCG) is a reactive bone lesion that occurs mainly in the jaws. The giant cell tumour (GCT) is a benign locally aggressive neoplasm located near the articular end of tubular bones. Both lesions are characterised histologically by multinucleated giant cells in a background of ovoid to spindle-shaped mesenchymal cells. There is a basic question whether both lesions are separate entities or variants of the same disease. The study of cell cycle-associated proteins may give insights into clarifying such question. The expression of these proteins is also important to determine the cell cycle regulation in both tumours. The purpose of this study was to evaluate the immunohistochemical expression of p53, MDM2, Ki-67 and PCNA in CGCG and GCT. The results demonstrated that, despite the lack of p53 immunoreactivity, all the samples showed wide expression of MDM2. The percentage of Ki-67- and PCNA-positive cells in CGCG was statistically higher than that of GCT Our findings show that CGCG has a higher proliferative activity compared with that of the GCT. Our results also suggest that p53 inactivation by MDM2 expression may be involved in the pathogenesis of giant cell lesions of the jaws and long bones.
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PMID:Immunohistochemical expression of p53, MDM2, Ki-67 and PCNA in central giant cell granuloma and giant cell tumor. 995 Feb 50

Amplification of genes in the 12q13-15 region occurs frequently in several malignancies including osteosarcoma. The products of these amplified genes are thought to provide cancer cells with a selective growth advantage; however, the specific gene(s) driving this amplicon is unknown. We have previously shown that the SAS gene is amplified in most parosteal osteosarcomas. In this study we analysed additional putative growth regulatory genes in this chromosomal region in 24 primary osteosarcoma specimens. CDK4 and SAS were coamplified in 6/6 parosteal tumors, and MDM2 was also amplified in 4/5 parosteal cases. In comparison, amplification occurred in only 2/16 classical intramedullary osteosarcomas and involved the SAS gene. Each amplified gene had a correspondingly elevated mRNA level. Four high grade intramedullary tumors had elevated mRNA expression of SAS, but did not exhibit gene amplification. Gene amplification/overexpression was not associated with metastatic disease and did not change markedly with tumor progression, as evidenced by analysis of sequential tumor specimens from eight patients. Three other genes in the 12q13-15 region (CDK2, WNT1 and WNT10b) were not amplified in any of the tumors. The different patterns of gene amplification and overexpression of CDK4, SAS and MDM2 in parosteal and intramedullary osteosarcomas may help explain the disparity in the biological behaviour of these two types of osteosarcoma.
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PMID:Co-amplification and overexpression of CDK4, SAS and MDM2 occurs frequently in human parosteal osteosarcomas. 998 29

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