Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0345904 (liver cancer)
 15,188 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

For isolation of novel cellular transforming genes that potentially participated in hepatocarcinogenesis, we conducted anchorage-independent growth (AIG) assays on 10 human liver cancer cell lines and observed strong AIG capabilities in PLC5 and Huh7 but negligible in Tong cells. After cloning of genes by differential subtractive chain reactions (DSC) from strong AIG to AIG negative cells, we sequenced 2304 clones and identified 245 genes. After four stringent criteria for selection of transforming genes among DSC clones, our results of quantitative RT-PCR analysis indicated that six genes, DDX3, EIF3S2, CLIC1, HDGF, GPC3, and HSPCA were overexpressed in 64%, 62%, 60%, 58%, 49%, and 47%, respectively, of 45 hepatocellular carcinoma (HCC) tissues. The results of cellular transformation capability by AIG assays indicated that the transfectants of EIF3S2 showed the strongest (> 100-fold), DDX3 and CLIC1 were moderate, GPC3 and HSPCA were weak, and HDGF was none in forming colonies in soft agar. Together, our results suggested that Tong is a suitable human cell line for screening of overexpressed and/or cellular transforming genes. In addition, our results suggested that diverse functions of cellular transforming genes in various biological pathways could transform human Tong cells and potentially reveal new targets for drug development of HCC.
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PMID:Diverse cellular transformation capability of overexpressed genes in human hepatocellular carcinoma. 1498 4

Persistent infection with the hepatitis C virus (HCV) is a major global health problem. Around 2-3% of the world's population are chronically infected, and infected individuals are at high risk of developing steatosis, fibrosis, and liver cirrhosis. The latter is a major predisposing factor for the development of hepatocellular carcinoma (HCC). It is generally accepted that an inflammatory response triggered by persistent HCV infection leads to increased cell proliferation and fibrogenesis that in turn promotes cirrhosis and ultimately HCC development. This indirect mechanism of tumor induction would explain the long incubation period from primary HCV infection to HCC and the requirement for additional cofactors such as toxins or drugs (most notably alcohol), metabolic liver diseases, steatosis, nonalcoholic liver disease, or diabetes. With the advent of adequate cell culture systems for HCV it is, however, becoming increasingly clear that the virus also contributes directly to HCC formation. Examples are the continuous induction of stress response or the massive accumulation of intracellular lipids. Moreover, viral proteins can bind to and sequester cell cycle control factors such as the retinoblastoma protein or the tumor suppressor DDX3. Thus, HCV-associated liver cancer is most likely promoted by the combined action of long-term chronic inflammation and targeted perturbations of cellular key pathways involved in metabolic homeostasis as well as cell cycle control.
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PMID:Promotion of hepatocellular carcinoma by hepatitis C virus. 2310

The current therapeutic regimen to combat chronic hepatitis C is not optimal due to substantial side effects and the failure of a significant proportion of patients to achieve a sustained virological response. Recently developed direct-acting antivirals targeting hepatitis C virus (HCV) enzymes reportedly increase the virologic response to therapy but may lead to a selection of drug-resistant variants. Besides direct-acting antivirals, another promising class of HCV drugs in development include host targeting agents that are responsible for interfering with the host factors crucial for the viral life cycle. A family of host proteins known as DEAD-box RNA helicases, characterized by nine conserved motifs, is known to play an important role in RNA metabolism. Several members of this family such as DDX3, DDX5 and DDX6 have been shown to play a role in HCV replication and this review will summarize our current knowledge on their interaction with HCV. As chronic hepatitis C is one of the leading causes of hepatocellular carcinoma, the involvement of DEAD-box RNA helicases in the development of HCC will also be highlighted. Continuing research on the interaction of host DEAD-box proteins with HCV and the contribution to viral replication and pathogenesis could be the panacea for the development of novel therapeutics against HCV.
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PMID:Understanding the interaction of hepatitis C virus with host DEAD-box RNA helicases. 2465 82

RNA helicases are a large family of proteins with a distinct motif, referred to as the DEAD/H (Asp-Glu-Ala-Asp/His). The exact functions of all the human DEAD/H box proteins are unknown. However, it has been consistently demonstrated that these proteins are associated with several aspects of energy-dependent RNA metabolism, including translation, ribosome biogenesis, and pre-mRNA splicing. In addition, DEAD/H box proteins participate in nuclear-cytoplasmic transport and organellar gene expression.A member of this RNA helicase family, DDX3, has been identified in a variety of cellular biogenesis processes, including cell-cycle regulation, cellular differentiation, cell survival, and apoptosis. In cancer, DDX3 expression has been evaluated in patient samples of breast, lung, colon, oral, and liver cancer. Both tumor suppressor and oncogenic functions have been attributed to DDX3 and are discussed in this review. In general, there is concordance with in vitro evidence to support the hypothesis that DDX3 is associated with an aggressive phenotype in human malignancies. Interestingly, very few cancer types harbor mutations in DDX3, which result in altered protein function rather than a loss of function.Efficacy of drugs to curtail cancer growth is hindered by adaptive responses that promote drug resistance, eventually leading to treatment failure. One way to circumvent development of resistant disease is to develop novel drugs that target over-expressed proteins involved in this adaptive response. Moreover, if the target gene is developmentally regulated, there is less of a possibility to abruptly accumulate mutations leading to drug resistance. In this regard, DDX3 could be a druggable target for cancer treatment. We present an overview of DDX3 biology and the currently available DDX3 inhibitors for cancer treatment.
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PMID:DDX3, a potential target for cancer treatment. 2654 25