Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0178874 (tumor progression)
 40,807 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

To clarify the genetic aberrations involved in the development and progression of hepatitis C virus-associated hepatocellular carcinoma (HCV-HCC), we investigated DNA copy number aberrations (DCNAs) in 19 surgically resected HCCs by conventional CGH and array CGH. Conventional CGH revealed that increases of DNA copy number were frequent at 1q (79% of the cases), 8q (37%), 6p (32%), and 10p (32%) and that decreases were frequent at 17p (79%), 16q (58%), 4q (53%), 13q (42%), 10q (37%), 1p (32%), and 8p (32%). In general, genes that showed DCNAs by array CGH were usually located in chromosomal regions with DCNAs detected by conventional CGH analysis. Increases in copy numbers of the LAMC2, TGFB2, and AKT3 genes (located on 1q) and decreases in copy numbers of FGR/SRC2 and CYLD (located on 1p and 16q, respectively) were observed in more than 30% of tumors, including small, well-differentiated carcinomas. These findings suggest that these genes are associated with the development of HCV-HCC. Increases of MOS, MYC, EXT1, and PTK2 (located on 8q) were detected exclusively in moderately and poorly differentiated tumors, suggesting that these alterations contribute to tumor progression. In conclusion, chromosomal and array CGH technologies allow identification of genes involved in the development and progression of HCV-HCC.
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PMID:Analysis of DNA copy number aberrations in hepatitis C virus-associated hepatocellular carcinomas by conventional CGH and array CGH. 1513 72

Breast cancer risk is greatly increased in women who carry mutations in the BRCA1 or BRCA2 genes. Because breast cancer initiation is different between BRCA1/2 mutation carriers and women who do not carry mutations, it is possible that the mechanism of breast cancer progression is also different. Histopathologic and genetic studies have supported this hypothesis. To test this hypothesis further, we utilized a large cohort of women who underwent therapeutic mastectomy (TM) and contralateral prophylactic mastectomy (PM). From this cohort, we developed case groups of women with a family history of breast cancer with BRCA1/2 deleterious mutations, with unclassified variant alterations, and with no detected mutation and matched these cases with sporadic controls from the same TM and PM cohort. Fluorescence in situ hybridization was performed on paraffin sections by use of dual-color probes for ERBB2/CEP17, MYC/CEP8, TBX2/CEP17, and RPS6KB1/CEP17. All malignant and benign lesions, including putative precursor lesions, were studied. The invasive cancers from deleterious mutation carriers had a higher prevalence of duplication of MYC (P = 0.006) and TBX2 (P = 0.0008) compared to controls and a lower prevalence of ERBB2 amplification (P = 0.011). Coduplication of MYC and TBX2 was common in the in situ and invasive lesions from the deleterious mutation carriers. The odds ratio of having a BRCA1/2 mutation is 31.4 (95% CI = 1.7-569) when MYC and TBX2 are coduplicated but ERBB2 is normal. Unclassified variant carriers/no mutation detected and sporadic controls had a similar prevalence of alterations, suggesting that hereditary patients with no deleterious mutations follow a progression pathway similar to that of sporadic cases. With the exception of one atypical ductal hyperplasia lesion, no putative precursor lesion showed any detectable alteration of the probes tested. There was no significant intratumoral heterogeneity of genetic alterations. Our data confirm that a specific pattern of genomic instability characterizes BRCA1/2-related cancers and that this pattern has implications for the biology of these cancers. Moreover, our current and previous results emphasize the interaction between phenotype and genotype in BRCA1/2-related breast cancers and that a combination of morphologic features and alterations of ERBB2, MYC, and TBX2 may better define mechanisms of tumor progression, as well as determine which patients are more likely to carry BRCA1/2 mutations.
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PMID:ERBB2, TBX2, RPS6KB1, and MYC alterations in breast tissues of BRCA1 and BRCA2 mutation carriers. 1554 18

Thrombospondin-1 (THBS1) is a large extracellular matrix glycoprotein that affects vasculature systems such as platelet activation, angiogenesis, and wound healing. Increases in THBS1 expression have been liked to disease states including tumor progression, atherosclerosis, and arthritis. The present study focuses on the effects of thrombin activation of the G-protein-coupled, protease-activated receptor-1 (PAR-1) on THBS1 gene expression in the microvascular endothelium. Thrombin-induced changes in gene expression were characterized by microarray analysis of approximately 11,000 different human genes in human microvascular endothelial cells (HMEC-1). Thrombin induced the expression of a set of at least 65 genes including THBS1. Changes in THBS1 mRNA correlated with an increase in the extracellular THBS1 protein concentration. The PAR-1-specific agonist peptide (TFLLRNK-PDK) mimicked thrombin stimulation of THBS1 expression, suggesting that thrombin signaling is through PAR-1. Further studies showed THBS1 expression was sensitive to pertussis toxin and protein kinase C inhibition indicating G(i/o)- and G(q)-mediated pathways. THBS1 up-regulation was also confirmed in human umbilical vein endothelial cells stimulated with thrombin. Analysis of the promoter region of THBS1 and other genes of similar expression profile identified from the microarray predicted an EBOX/EGRF transcription model. Expression of members of each family, MYC and EGR1, respectively, correlated with THBS1 expression. These results suggest thrombin formed at sites of vascular injury increases THBS1 expression into the extracellular matrix via activation of a PAR-1, G(i/o), G(q), EBOX/EGRF-signaling cascade, elucidating regulatory points that may play a role in increased THBS1 expression in disease states.
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PMID:Thrombin modulates the expression of a set of genes including thrombospondin-1 in human microvascular endothelial cells. 1581 47

Mitochondrial dysfunction has crucial importance in carcinogenesis. Due to several reasons, it may lead to insufficiency in the electron transport chain, which activates a series of cytosolic proteins. These proteins are transported to the nucleus and promote the activation of genes leading to intracellular diverse metabolic, regulatory, signalization and stress-related pathways. Retrograde regulation is the general term for mitochondrial signaling, and is broadly defined as cellular responses to alterations in functional state of mitochondria. This signaling pathway is triggered by mitochondrial dysfunction. The retrograde response is not a simple On-Off switch, but rather it responds in a continuous manner to the changing metabolic needs of the cell. Communication between mitochondria and the nucleus is important for a variety of cellular processes such as carbohydrate and nitrogen metabolism, cell cycle and proliferation, and cell growth and morphogenesis. As a result of retrograde regulation, the cell, actually a component of the multicellular organism, transforms to a unicellular lifestyle and initiates a developing course, independent of the systemic structure. This transformed cell runs metabolic regulations effectively in order to utilize all energy depots, mainly the adipose tissue of the multicellular organism. The most important one is the active utilization of glyoxylate cycle, through which the malign cells supply glucose from fats. Continuously acting glycolysis and gluconeogenesis, fatty acid oxidation and de novo lipogenesis constitute futile cycles. This in turn causes cachexia by maintaining the organism in constant negative energy balance. Mitochondria-to-nucleus stress signaling activates some of the genes implicated in tumor progression and tumor cell metastasis. Retrograde regulation also renders the cell more resistant to apoptosis. It is becoming clearer which genes control the retrograde response in human cells. Most probably, MYC is one of the transcription factors necessary for this response.
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PMID:Retrograde regulation due to mitochondrial dysfunction may be an important mechanism for carcinogenesis. 1590 43

This study characterizes the frequency of exon 3 CTNNB1 mutations and compares the expression of CTNNB1 transcript variants and downstream targets MYC and WAF1 (p21) across the neoplastic progression of esophageal squamous cell carcinomas (ESCCs). Mutational analysis was performed on 56 tumors and corresponding germline DNA, using primers to exon 3 of CTNNB1 and SSCP DNA sequencing gels. Quantitative Real Time RT-PCR was performed on 45 foci representing the histological spectrum from normal to invasive cancer, using specific primer sets for alternative splice variants that differ by the presence (16A) or absence (16B) of a 159-bp noncoding segment of exon 16 of CTNNB1, in conjunction with downstream targets MYC and WAF1. Two unique mutations were identified, S37F in the SxxxS repeat region, and a germline polymorphism, T59A. Thus, mutation of CTNNB1 exon 3 is a rare event in this population. RT-PCR analysis successfully confirmed the presence of both beta-catenin splice variants in histologically normal and preneoplastic squamous epithelium, and invasive tumors of the esophagus, and identified a significant reduction in the 16A/16B ratio (P = 0.014) and an accompanying significant increase in the MYC/WAF1 expression ratio (P = 0.001) with progression from normal mucosa to dysplasia. This represents the first identification of two CTNNB1 transcripts in histologically "normal" esophageal squamous cells, squamous dysplasia, and invasive ESCC. These results show an increase in the minor mRNA (16B) isoform and changes in the expression of downstream markers consistent with increased transcription during the histological progression from normal to squamous dysplasia.
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PMID:beta-Catenin splice variants and downstream targets as markers for neoplastic progression of esophageal cancer. 1611 33

One hypothesis for breast cancer development suggests that breast carcinogenesis involves a progression of events leading from benign epithelium to hyperplasia (with or without atypia) to carcinoma in situ and then invasive carcinoma. The MYC gene (alias c-Myc) is a transcriptional regulator whose expression is strongly associated with cell proliferation and cell differentiation. The present study is a descriptive analysis of MYC status throughout the hypothesized stages of invasive ductal carcinoma progression. A tissue microarray (TMA) was constructed including representative selected areas (normal cells, hyperplasia, in situ carcinoma, and invasive carcinoma) from each of 15 patients. Fluorescence in situ hybridization (FISH) with the LSI c-MYC/CEN8/IgH probe was performed. Two cases displayed MYC amplification (13%), showing this amplification only in the invasive carcinoma zones selected. Five cases displayed polysomy of chromosome 8 (33%), detected only in ductal in situ and invasive zones selected. Benign lesions and normal adjacent cells were classified as normal. None of the hyperplasia specimens and normal specimens analyzed showed any alterations in MYC status or any aneusomies of chromosome 8. The presence of MYC amplification only in invasive cells suggests that the finding of MYC amplification could reflect an advanced tumor progression.
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PMID:The MYC oncogene in breast cancer progression: from benign epithelium to invasive carcinoma. 1652 9

The proteins of the MYC family are key regulators of cell behavior. MYC, originally identified as an oncoprotein, affects growth, proliferation, differentiation, and apoptosis of cells through its ability to regulate a significant number of genes. In addition MYC governs events associated with tumor progression, including genetic stability, migration, and angiogenesis. The pleiotropic activities attributed to MYC and their balanced control requires that the expression and function of MYC is tightly controlled. Indeed many different pathways and factors have been identified that impinge on MYC gene expression and protein function. In particular the protein is subject to different posttranslational modifications, including phosphorylation, ubiquitinylation, and acetylation. Here we discuss the latest developments regarding these modifications that control various aspects of MYC function, including its stability, the interaction with partner proteins, and the transcriptional potential.
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PMID:The ins and outs of MYC regulation by posttranslational mechanisms. 1698 7

Most human lymphomas originate from transformed germinal center (GC) B lymphocytes. While activating mutations and translocations of MYC, BCL2 and BCL6 promote specific GC lymphoma subtypes, other genetic and epigenetic modifications that contribute to malignant progression in the GC remain poorly defined. Recently, aberrant expression of the TCL1 proto-oncogene was identified in major GC lymphoma subtypes. TCL1 transgenic mice offer unique models of both aggressive GC and marginal zone B-cell lymphomas, further supporting a role for TCL1 in B-cell transformation. Here, restriction landmark genomic scanning was employed to discover tumor-associated epigenetic alterations in malignant GC and marginal zone B-cells in TCL1 transgenic mice. Multiple genes were identified that underwent DNA hypermethylation and decreased expression in TCL1 transgenic tumors. Further, we identified a secreted isoform of EPHA7, a member of the Eph family of receptor tyrosine kinases that are able to influence tumor invasiveness, metastasis and neovascularization. EPHA7 was hypermethylated and repressed in both mouse and human GC B-cell non-Hodgkin lymphomas, with the potential to influence tumor progression and spread. These data provide the first set of hypermethylated genes with the potential to complement TCL1-mediated GC B-cell transformation and spread.
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PMID:Global DNA methylation profiling reveals silencing of a secreted form of Epha7 in mouse and human germinal center B-cell lymphomas. 1726 20

The MYC family oncogenes cause transformation and tumor progression by corrupting multiple cellular pathways, altering cell cycle progression, apoptosis, and genomic instability. Several recent studies show that MYCC (c-Myc) expression alters DNA repair mechanisms, cell cycle checkpoints, and karyotypic stability, and this is likely partially due to alterations in centrosome replication control. In neuroblastoma cell lines, MYCN (N-Myc) expression induces centrosome amplification in response to ionizing radiation. Centrosomes are cytoplasmic domains that critically regulate cytokinesis, and aberrations in their number or structure are linked to mitotic defects and karyotypic instability. Whereas centrosome replication is linked to p53 and Rb/E2F-mediated cell cycle progression, the mechanisms downstream of MYCN that generate centrosome amplification are incompletely characterized. We hypothesized that MDM2, a direct transcriptional target of MYCN with central inhibitory effects on p53, plays a role in MYC-mediated genomic instability by altering p53 responses to DNA damage, facilitating centrosome amplification. Herein we show that MYCN mediates centrosome amplification in a p53-dependent manner. Accordingly, inhibition of the p53-MDM2 interaction with Nutlin 3A (which activates p53) completely ablates the MYCN-dependent contribution to centrosome amplification after ionizing radiation. We further show that modulating MDM2 expression levels by overexpression or RNA interference-mediated posttranscriptional inhibition dramatically affects centrosome amplification in MYCN-induced cells, indicating that MDM2 is a necessary and sufficient mediator of MYCN-mediated centrosome amplification. Finally, we show a significant correlation between centrosome amplification and MYCN amplification in primary neuroblastoma tumors. These data support the hypothesis that elevated MDM2 levels contribute to MYCN-induced genomic instability through altered regulation of centrosome replication in neuroblastoma.
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PMID:MYCN-directed centrosome amplification requires MDM2-mediated suppression of p53 activity in neuroblastoma cells. 1736 62

In this study, we have exploited the power of insertional mutagenesis to elucidate tumor progression pathways in mice carrying two oncogenes (MYC/Runx2) that collaborate to drive early lymphoma development. Neonatal infection of these mice with Moloney murine leukemia virus resulted in accelerated tumor onset with associated increases in clonal complexity and lymphoid dissemination. Large-scale analysis of retroviral integration sites in these tumors revealed a profound bias towards a narrow range of target genes, including Jdp2 (Jundm2), D cyclin, and Pim family genes. Remarkably, direct PCR analysis of integration hotspots revealed that every progressing tumor consisted of multiple clones harboring hits at these loci, giving access to large numbers of independent insertion events and uncovering the contrasting mutagenic mechanisms operating at each target gene. Direct PCR analysis showed that high-frequency targeting occurs only in the tumor environment in vivo and is specific for the progression gene set. These results indicate that early lymphomas in MYC/Runx2 mice remain dependent on exogenous growth signals, and that progression can be achieved by constitutive activation of pathways converging on a cell cycle checkpoint that acts as the major rate-limiting step for lymphoma outgrowth.
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PMID:Insertional mutagenesis reveals progression genes and checkpoints in MYC/Runx2 lymphomas. 1754 90


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