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)

The high-mobility-group, HMGA1 (formerly HMGI(Y)) chromosomal proteins are known to be involved in gene regulation and their high expression is associated with neoplastic transformation of cells and metastatic tumor progression. Here, we present our results on the expression of HMGA1 in murine skin carcinoma as detected by acid-urea electrophoresis, reverse-phase high-performance liquid chromatography and Western blot. The enhanced expression of HMGA1 proteins directly correlates with the extent of cellular atypia and neoplastic changes noticed in the histopathology of tumor and suggest a potential use of these proteins as marker for determining the grade of skin tumor.
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PMID:Elevated levels of high-mobility-group chromosomal proteins, HMGA1, in murine skin carcinoma. 1157 14

Activation of the transcription factor AP-1 (activator protein-1) is required for tumor promotion and maintenance of malignant phenotype. A number of AP-1-regulated genes that play a role in tumor progression have been identified. However, AP-1-regulated genes driving tumor induction are yet to be defined. Previous studies have established that expression of a dominant-negative c-Jun (TAM67) inhibits phorbol 12-tetradecanoyl-13-acetate (TPA)-induced AP-1 transactivation as well as transformation in mouse epidermal JB6/P+ cells and tumor promotion in mouse skin carcinogenesis. In this study, we utilized the tumor promotion-sensitive JB6/P+ cells to identify AP-1-regulated TAM67 target genes and to establish causal significance in transformation for one target gene. A 2700 cDNA microarray was queried with RNA from TPA-treated P+ cells with or without TAM67 expression. Under conditions in which TAM expression inhibited TPA-induced transformation, microarray analysis identified a subset of six genes induced by TPA and suppressed by TAM67. One of the identified genes, the high-mobility group protein A1 (Hmga1) is induced by TPA in P+, but not in transformation-resistant P cells. We show that TPA induction of the architectural transcription factor HMGA1 is inhibited by TAM67, is extracellular-signal-regulated kinase (ERK)-activation dependent, and is mediated by AP-1. HMGA1 antisense construct transfected into P+ cells blocked HMGA1 protein expression and inhibited TPA-induced transformation indicating that HMGA1 is required for transformation. HMGA1 is not however sufficient as HMGA1a or HMGA1b overexpression did not confer transformation sensitivity on P- cells. Although HMGA1 expression is ERK dependent, it is not the only ERK-dependent event required for transformation because it does not suffice to rescue ERK-deficient P- cells. Our study shows (a) TAM 67 when it inhibits AP-1 and transformation, targets a relatively small number of genes; (b) HMGA1, a TAM67 target gene, is causally related to transformation and therefore a potentially important target for cancer prevention.
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PMID:Dominant-negative c-Jun (TAM67) target genes: HMGA1 is required for tumor promoter-induced transformation. 1506 52

The high mobility group A (HMGA) proteins are thought to work as ancillary transcription factors and to regulate the expression of a growing number of genes through direct binding to DNA or via protein-protein interactions. Both HMGA1 and HMGA2 are important regulators of basic biological processes, including cell growth, differentiation and transformation. Their qualitatively or quantitatively altered expression has been described in a number of human tumors. We studied and review here their expression in neuroblastic tumors. HMGA2 is expressed only in a subset of ex vivo neuroblastoma (NB) tumors and in the embryonic adrenal gland, but it is undetectable in the adult adrenal gland, suggesting that its anomalous expression might be associated with NB tumorigenesis and/or tumor progression. In vitro, its expression is easily detectable in retinoic acid (RA)-resistant cell lines. The exogenous expression of HMGA2 is sufficient to convert RA-sensitive SY5Y NB cells into RA-resistant cells, thus suggesting that HMGA2 might be a relevant player in determining NB cell responses to endogenous or therapeutically important growth inhibitory substances. In contrast, HMGA1 expression is readily detectable in all NB cell lines and tumors, but its expression is consistently higher in less differentiated NBs compared with ganglioneuromas and ganglioneuroblastomas. Interestingly, RA increases HMGA1 expression in RA-resistant NB cells but inhibits it in cells undergoing RA-induced growth inhibition and neuronal differentiation. Our studies indicate that HMGA molecules might be biologically and pathologically relevant factors in neuroblastic tumor development and progression.
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PMID:HMGA molecules in neuroblastic tumors. 1565 Feb 38

HMGA1 is an architectural transcription factor expressed at high levels in transformed cells and tumors. Several lines of evidence indicate that HMGA1 up-regulation is involved in the malignant transformation of thyroid epithelial cells. However, the mechanisms underlying the effect of HMGA1 on thyroid cancer cell phenotype are not fully understood. We now show that in thyroid cancer cells, HMGA1 down-regulation by small interfering RNA and antisense techniques results in enhanced transcriptional activity of p53, TAp63alpha, TAp73alpha, and, consequently, increased apoptosis. Coimmunoprecipitation and pull-down experiments with deletion mutants showed that the COOH-terminal oligomerization domain of p53 family members is required for direct interaction with HMGA1. Moreover, inhibition of HMGA1 expression in thyroid cancer cells resulted in increased p53 oligomerization in response to the DNA-damaging agent doxorubicin. Finally, electrophoretic mobility shift assay experiments showed that the p53-HMGA1 interaction results in reduced DNA-binding activity. These results indicate a new function of HMGA1 in the regulation of p53 family members, thus providing new mechanistic insights in tumor progression.
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PMID:HMGA1 inhibits the function of p53 family members in thyroid cancer cells. 1654 Jun 46

We have previously demonstrated that HMGA1 proteins translocate from the nucleus to mitochondria and bind to mitochondrial DNA (mtDNA) at the D-loop control region [G.A. Dement, N.R. Treff, N.S. Magnuson, V. Franceschi, R. Reeves, Dynamic mitochondrial localization of nuclear transcription factor HMGA1, Exp. Cell Res. 307 (2005) 388-401.] [11]. To elucidate possible physiological roles for such binding, we employed methods to analyze mtDNA transcription, mitochondrial maintenance, and other organelle functions in transgenic human MCF-7 cells (HA7C) induced to over-express an HA-tagged HMGA1 protein and control (parental) MCF-7 cells. Quantitative real-time (RT) PCR analyses demonstrated that mtDNA levels were reduced approximately 2-fold in HMGA1 over-expressing HA7C cells and flow cytometric analyses further revealed that mitochondrial mass was significantly reduced in these cells. Cellular ATP levels were also reduced in HA7C cells and survival studies showed an increased sensitivity to killing by 2-deoxy-D-glucose, a glycolysis-specific inhibitor. Flow cytometric analyses revealed additional mitochondrial abnormalities in HA7C cells that are consistent with a cancerous phenotype: namely, increased reactive oxygen species (ROS) and increased mitochondrial membrane potential (Delta Psi(m)). Additional RT-PCR analyses demonstrated that gene transcripts from both the heavy (ND2, COXI, ATP6) and light (ND6) strands of mtDNA were up-regulated approximately 3-fold in HA7C cells. Together, these mitochondrial changes are consistent with many previous reports and reveal several possible mechanisms by which HMGA1 over-expression, a common feature of naturally occurring cancers, may affect tumor progression.
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PMID:Nuclear HMGA1 nonhistone chromatin proteins directly influence mitochondrial transcription, maintenance, and function. 1704 86

HMGA1 proteins exert their major physiological function during embryonic development and play a critical role in neoplastic transformation. Here, we show that Hand1 gene, which codes for a transcription factor crucial for differentiation of trophoblast giant cells and heart development, is upregulated in hmga1 minus embryonic stem cells. We demonstrate that HMGA1 proteins bind directly to Hand1 promoter both in vitro and in vivo and inhibit Hand1 promoter activity. We have also investigated HAND1 expression in human thyroid carcinoma cell lines and tissues, in which HMGA proteins are overexpressed, with respect to normal thyroid; an inverse correlation between HMGA1 and HAND1 expression was found in all thyroid tumor histotypes. A correlation between HAND1 gene repression and promoter hypermethylation was found in anaplastic carcinomas but not in other thyroid tumor histotypes. Therefore, we can hypothesize that HMGA1 overexpression plays a key role on HAND1 silencing in differentiated thyroid carcinomas and that promoter hypermethylation occurs in later stages of thyroid tumor progression. Finally, the restoration of the HAND1 gene expression reduces the clonogenic ability of two human thyroid carcinoma-derived cell lines, suggesting that HAND1 downregulation may have a role in the process of thyroid carcinogenesis.
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PMID:HAND1 gene expression is negatively regulated by the High Mobility Group A1 proteins and is drastically reduced in human thyroid carcinomas. 2734 8

The High Mobility Group A1 (HMGA1, formerly HMG-I/Y) gene is highly expressed during embryogenesis and in virtually all aggressive human cancers studied to date, although its role in these settings is only beginning to emerge. Moreover, high levels of expression portend a poor prognosis in some tumors. Increasing evidence suggests that the HMGA1 protein functions as a master regulator with a critical role in normal development and tumor progression in diverse malignancies. These proteins contain AT-hook DNA binding domains that mediate binding to AT-rich regions of chromatin. After binding to DNA, HMGA1 alters DNA structure, and orchestrates the assembly of a transcriptional complex or "enhanceosome" to regulate gene expression. Previous studies indicate that HMGA1 participates in regulating fundamental cellular processes, including transcription, cell cycle progression, embryonic development, neoplastic transformation, differentiation, senescence, viral integration, and DNA repair by virtue of its ability to interact with other proteins, bind to DNA, and modulate gene expression. Recent studies also link HMGA1 expression to poor differentiation status and a refractory, stem cell-like state in aggressive cancers. Together, these findings suggest that HMGA1 could serve as a useful biomarker and therapeutic target in advanced malignancies. Here, we focus on prior studies implicating HMGA1 in the pathogenesis of refractory human tumors arising from diverse tissues and its potential role as a biomarker. We also review previous attempts to target HMGA1 pathways in cancer. Further study of HMGA1 promises to have a major impact on our ability to understand and treat cancer.
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PMID:High mobility group A1 and cancer: potential biomarker and therapeutic target. 2241 21

Caveolin-1 (CAV1) acts as a growth suppressor in various human malignancies, but its expression is elevated in many advanced cancers, suggesting the oncogenic switch of its role during tumor progression. To understand the molecular basis for the growth-promoting function of CAV1, we characterized its expression status, differential roles for tumor growth, and effect on glucose metabolism in colorectal cancers. Abnormal elevation of CAV1 was detected in a substantial fraction of primary tumors and cell lines and tightly correlated with promoter CpG sites hypomethylation. Depletion of elevated CAV1 led to AMPK activation followed by a p53-dependent G1 cell-cycle arrest and autophagy, suggesting that elevated CAV1 may contribute to ATP generation. Furthermore, CAV1 depletion downregulated glucose uptake, lactate accumulation, and intracellular ATP level, supporting that aerobic glycolysis is enhanced by CAV1. Consistently, CAV1 was shown to stimulate GLUT3 transcription via an HMGA1-binding site within the GLUT3 promoter. HMGA1 was found to interact with and activate the GLUT3 promoter and CAV1 increased the HMGA1 activity by enhancing its nuclear localization. Ectopic expression of HMGA1 increased glucose uptake, whereas its knockdown caused AMPK activation. In addition, GLUT3 expression was strongly induced by cotransfection of CAV1 and HMGA1, and its overexpression was observed predominantly in tumors harboring high levels of CAV1 and HMGA1. Together, these data show that elevated CAV1 upregulates glucose uptake and ATP production through HMGA1-mediated GLUT3 transcription, suggesting that CAV1 may render tumor cells growth advantages by enhancing aerobic glycolysis.
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PMID:Caveolin-1 increases aerobic glycolysis in colorectal cancers by stimulating HMGA1-mediated GLUT3 transcription. 2270 2

Although elevated expression of CAV1/caveolin 1 is associated with the malignant progression of various human cancers, the molecular mechanism underlying its oncogenic functions is largely unknown. We found that CAV1 is frequently overexpressed in advanced colorectal tumors due to aberrant promoter CpG site hypomethylation, and its elevation is implicated in enhanced aerobic glycolysis of tumor cells. Depletion of elevated CAV1 downregulates glucose uptake, intracellular ATP level and lactate accumulation, and triggers autophagy through activation of AMPK-TP53/p53 signaling. CAV1 elevation increases glucose uptake and ATP production by stimulating transcription of the glucose transporter SLC2A3/GLUT3 via an HMGA1-binding site within the promoter. Collectively, our study suggests that elevated CAV1 expression may contribute to colorectal tumor progression by providing tumor cells growth and survival advantages under nutritional stress conditions.
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PMID:CAV1/caveolin 1 enhances aerobic glycolysis in colon cancer cells via activation of SLC2A3/GLUT3 transcription. 2287 59

The High Mobility Group A (HMGA) are nuclear proteins that participate in the organization of nucleoprotein complexes involved in chromatin structure, replication and gene transcription. HMGA overexpression is a feature of human cancer and plays a causal role in cell transformation. Since non-coding RNAs and pseudogenes are now recognized to be important in physiology and disease, we investigated HMGA1 pseudogenes in cancer settings using bioinformatics analysis. Here we report the identification and characterization of two HMGA1 non-coding pseudogenes, HMGA1P6 and HMGA1P7. We show that their overexpression increases the levels of HMGA1 and other cancer-related proteins by inhibiting the suppression of their synthesis mediated by microRNAs. Consistently, embryonic fibroblasts from HMGA1P7-overexpressing transgenic mice displayed a higher growth rate and reduced susceptibility to senescence. Moreover, HMGA1P6 and HMGA1P7 were overexpressed in human anaplastic thyroid carcinomas, which are highly aggressive, but not in differentiated papillary carcinomas, which are less aggressive. Lastly, the expression of the HMGA1 pseudogenes was significantly correlated with HMGA1 protein levels thereby implicating HMGA1P overexpression in cancer progression. In conclusion, HMGA1P6 and HMGA1P7 are potential proto-oncogenic competitive endogenous RNAs.
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PMID:HMGA1 pseudogenes as candidate proto-oncogenic competitive endogenous RNAs. 2526 43


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