Project description:Analysis of adenovirus-mediated USF1 overexpression in liver at gene expression level. Results provide important information of the response of mouse liver to USF1 overexpression, such as specific USF1-induced, suppressed, up- or down-regulated genes invovled in metabolism and immune responses.

Project description:Overexpression of USF1 in HEK293T cells in vitro to ascertain the genes downstream of USF1. Will identify direct targets as well as indirect targets of USF1. Keywords: Overexpression of transcription factor to determine downstream targets.

Project description:Overexpression of USF1 in HEK293T cells in vitro to ascertain the genes downstream of USF1. Will identify direct targets as well as indirect targets of USF1. Keywords: Overexpression of transcription factor to determine downstream targets. Cloned USF1 from cDNA and transiently transfected into HEK293T cells. Total RNA collected 48 hours after transfection. Empty vector used as control. Expression of USF1 was validated using western blot, and qRT-PCR was used to validate differential expression.

Project description:Hypothesis is that NAMPT overexpression alters liver transcriptomics in genetically diabetic, obese db/db mice. We treated db/db mice n = 4 with adenovirus encoding GFP or NAMPT by tail-vein delivery.

Project description:Med1 overexpression leads to induction of a wide spectrum of genes. Adenovirally-driven overexpression of Med1 in mouse liver stimulates hepatocyte DNA synthesis with enhanced expression of DNA replication, cell cycle control and liver specific genes as observed at day 3 and day 5 post injection. Med1 gene is amplified in a number of cancers so in this study we tested the hypothesis that Med1 by itself has the capacity to induce cell proliferation. Analysis of the Med1- induced gene expression showed a robust induction of a wide spectrum of genes involved in hepatocellular proliferation. Med1 floxed mice (Med1fl/fl) were injected with Ad-His-Med1 (adenovirus expressing Med1 gene) via tail vein and killed 3 or 5 days after injection. Ad-LacZ (adenovirus expression beta-galactosidase gene) injected mouse liver served as control. Total RNA were isolated from the liver and subjected to the microarray.

Project description:We identified PDK4 as a gene with adaptive transcriptional response to chemical stress. Although PDK4 is an energy resource regulator induced by starvation, expression of other fasting-inducible genes was unaffected, indicating additional physiological role of PDK4 for liver adaptation to the chemical stress. We used microarrays to determine genes with altered transcriptional level by PDK4 overexpression. Mice were infected with Ad-control (empty adenovirus vector) or Ad-PDK4 (PDK4 overexpressing adenovirus vector) at a dose of 10^9 PFU/mouse by tail vein injection. 3 days after the infection, mice were sacrificed for RNA preparation from the liver. Ad-control infected = 4, Ad-PDK4 infected = 3. Specimens from mice of each group were pooled, and 10 ug RNA from each pool was used for cRNA synthesis.

Project description:Liver cancer, including hepatocellular carcinoma (HCC), is a malignant tumor type with high metastasis and mortality rate in worldwide. Upstream transcription factor 1 (USF1) is a canonical transcription factor (TF) and associated with the pathogenesis of several cancers, while its biological functions and molecular targets in HCC are not clear. In this study, we overexpressed USF1 in Huh7 cells and used whole transcriptome profile sequencing (RNA-seq) and chromatin immunoprecipitation sequencing (ChIP-seq) methods to systematically investigate the downstream targets of USF1. Following polymerase chain reaction (PCR) was used to validate the downstream targets. Based on the results, we found USF1 significantly regulated 350 differentially expressed genes (DEGs). Up DEGs were mainly protein coding genes, and enriched in immune and inflammation response pathways; while down DEGs were mainly lncRNAs, indicating the regulatory feature of USF1. We also detected USF1 directly bound to the promoter region of 2492 genes, which may deeply participate in the viral progression and cell proliferation pathways. By integrating these two datasets, we detected 16 overlapped genes, including down lncRNA-NEAT1 and up TF-ETV5. Down lncRNA-NEAT1 showed reverse expression pattern and prognosis result to USF1 in liver cancer patients, while up TF-ETV5 showed consistent result to USF1. Promoter region motif analysis indicated that ETV5 had more binding motifs and genes than USF1 itself for USF1-regulated DEGs, indicating that USF1 may indirectly modulate gene expression by regulating ETV5 expression in Huh7 cells. Finally, we validated the direct interaction between USF1 and the promoter of ETV5 using ChIP-qPCR. In summary, our results demonstrated that USF1 binds to the promoter region of thousands of genes, and affects large part of DEGs by indirectly manner. The downstream genes, including lncRNA-NEAT1 and TF-ETV5, may also tightly participate in the regulated network by USF1 and have potential functions in the progression of HCC. The USF1 and its downstream targets could be used as potential targets for HCC therapy in future.

Project description:Liver cancer, including hepatocellular carcinoma (HCC), is a malignant tumor type with high metastasis and mortality rate in worldwide. Upstream transcription factor 1 (USF1) is a canonical transcription factor (TF) and associated with the pathogenesis of several cancers, while its biological functions and molecular targets in HCC are not clear. In this study, we overexpressed USF1 in Huh7 cells and used whole transcriptome profile sequencing (RNA-seq) and chromatin immunoprecipitation sequencing (ChIP-seq) methods to systematically investigate the downstream targets of USF1. Following polymerase chain reaction (PCR) was used to validate the downstream targets. Based on the results, we found USF1 significantly regulated 350 differentially expressed genes (DEGs). Up DEGs were mainly protein coding genes, and enriched in immune and inflammation response pathways; while down DEGs were mainly lncRNAs, indicating the regulatory feature of USF1. We also detected USF1 directly bound to the promoter region of 2492 genes, which may deeply participate in the viral progression and cell proliferation pathways. By integrating these two datasets, we detected 16 overlapped genes, including down lncRNA-NEAT1 and up TF-ETV5. Down lncRNA-NEAT1 showed reverse expression pattern and prognosis result to USF1 in liver cancer patients, while up TF-ETV5 showed consistent result to USF1. Promoter region motif analysis indicated that ETV5 had more binding motifs and genes than USF1 itself for USF1-regulated DEGs, indicating that USF1 may indirectly modulate gene expression by regulating ETV5 expression in Huh7 cells. Finally, we validated the direct interaction between USF1 and the promoter of ETV5 using ChIP-qPCR. In summary, our results demonstrated that USF1 binds to the promoter region of thousands of genes, and affects large part of DEGs by indirectly manner. The downstream genes, including lncRNA-NEAT1 and TF-ETV5, may also tightly participate in the regulated network by USF1 and have potential functions in the progression of HCC. The USF1 and its downstream targets could be used as potential targets for HCC therapy in future.

Project description:The mice were injected via tail vein with either shBmal1 adenovirus or shLacz adenocirus as control (n=5 for each group), following 10 days of 5% ethanol diet feeding. Then the mice were dissected and liver tissues were flash freezed. 25mg liver tissues from each mouse of the same group were pooled.

Project description:Comparison of gene expression for individuals affected with FCHL exhibiting the USF1 susceptibility haplotype and FCHL affected indiviuals carrying the protective haplotype Keywords: ordered