Project description:Accumulating evidence suggests that DEAD-box proteins are essential in RNA metabolism and play pivotal roles in cancer progression. However, the mechanisms underlying how DDX24 drives hepatocellular carcinoma (HCC) remain largely unknown. In this study, we demonstrated that DDX24 was an oncogene and identified RFX8 as a DDX24 promoter-binding protein that transcriptionally upregulated DDX24 expression.

Project description:Hepatocellular carcinoma (HCC) is not only the fifth most prevalent cancer, presenting a major global health problem, but also among the leading causes of cancer-related deaths worldwide as its therapeutic targets are limited. To identify novel therapeutic targets, elucidate its oncogenic activities and molecular mechanism in HCC is urgent. We used R language edgeR package screened the expression profiles of 374 tissue samples obtained from patients with HCC and 50 samples of normal liver tissues obtained from The Cancer Genome Atlas (TCGA) database. Focusing on DDX24, we explored the functional effect and clinical significance of DDX24 in HCC. We provided evidence that DDX24 was a potential pro-tumorigenic gene in HCC. DDX24 knockdown inhibited HCC cell growth in vitro and in vivo. Mechanistically, RFX8 was proved to be DDX24 promoter-binding protein that transcriptionally upregulated DDX24 expression. Furthermore, we found that DDX24 bound to, and increased the stability of, LAMB1 mRNA by RNA immunoprecipitation (RIP) sequencing and RNA sequencing. Survival analysis indicated that HCC patients with high DDX24, RFX8, or LAMB1 expression exhibited poor prognosis. Our results demonstrated that DDX24 promoted HCC via RFX8/DDX24/LAMB1 pathway, which can be exploited as potential therapeutic target against HCC.

Project description:Hepatocellular carcinoma (HCC) is not only the fifth most prevalent cancer, presenting a major global health problem, but also among the leading causes of cancer-related deaths worldwide as its therapeutic targets are limited. To identify novel therapeutic targets, elucidate its oncogenic activities and molecular mechanism in HCC is urgent. We used R language edgeR package screened the expression profiles of 374 tissue samples obtained from patients with HCC and 50 samples of normal liver tissues obtained from The Cancer Genome Atlas (TCGA) database. Focusing on DDX24, we explored the functional effect and clinical significance of DDX24 in HCC. We provided evidence that DDX24 was a potential pro-tumorigenic gene in HCC. DDX24 knockdown inhibited HCC cell growth in vitro and in vivo. Mechanistically, RFX8 was proved to be DDX24 promoter-binding protein that transcriptionally upregulated DDX24 expression. Furthermore, we found that DDX24 bound to, and increased the stability of, LAMB1 mRNA by RNA immunoprecipitation (RIP) sequencing and RNA sequencing. Survival analysis indicated that HCC patients with high DDX24, RFX8, or LAMB1 expression exhibited poor prognosis. Our results demonstrated that DDX24 promoted HCC via RFX8/DDX24/LAMB1 pathway, which can be exploited as potential therapeutic target against HCC.

Project description:Accumulating evidence suggests that DEAD-box proteins are essential in RNA metabolism and play pivotal roles in cancer progression. However, the mechanisms underlying how DDX24 drives hepatocellular carcinoma (HCC) remain largely unknown. In this study, we demonstrated that DDX24 was an oncogene and identified DDX24 promoted HCC development via interacting with NCL.

Project description:DDX24 Mutations Associated with Vascular Malformations

Project description:To investigate the role of DDX24 in vascular smooth muscle cells, RNA-seq of HASMC with DDX24 knockdown was performed.

Project description:In order to understand the contribution of autophagy and alternative NF-kappaB signalling to transcriptional output in A549 lung cancer cells, RNAi was used to knockdown the expression of core autophagy genes (ATG5, ULK1) or the key subunit of alternative NF-kappaB RELB.

Project description:RBM5, a regulator of alternative splicing of apoptotic genes, and its close homologues, RBM6 and RBM10, are RNA binding proteins frequently deleted or mutated in lung cancer. We report that RBM5/6 and RBM10 antagonistically regulate the proliferative capacity of cancer cells and display distinct positional effects in alternative splicing regulation. We identify the Notch pathway regulator NUMB as a key target of these factors in the control of cell proliferation. NUMB alternative splicing, which is frequently altered in lung cancer, can regulate colony and xenograft tumor formation and its modulation recapitulates or antagonizes the effects of RBM5, 6 and 10 in cell colony formation. RBM10 mutations identified in lung cancer cells disrupt NUMB splicing regulation to promote cell growth. Our results reveal a key genetic circuit in the control of cancer cell proliferation. CLIP-Seq analysis of RBM5, RBM6 and RBM10, with 2 biological replicates and one non-specific control for each protein.

Project description:Changes in alternative splicing are associated with several pathological conditions, including cancer. Microarrays strategies, which allow for the characterization of thousands of alternative splice forms in a single test, can be applied to identify differential alternative splicing events. In this study, a novel splice array platform was developed, including the design of a high-density oligonucleotide array, a labeling procedure, and an algorithm to identify splice events. The array consists of exon probes and thermodynamically balanced junction probes. Suboptimal probes are tagged and considered in the final analysis. An unbiased labeling protocol was developed using random primers. The algorithm used to distinguish changes in expression from changes in splicing was calibrated using internal non-spliced control sequences. The performance of this splice array was first validated with artificial constructs for CDC6, VEGF, and PCBP4 isoforms. The platform was then applied to the analysis of differential splice forms for 8000 genes in lung cancer samples compared to matched normal lung tissue. The expression of lung cancer-associated splice isoforms was validated by RT-PCR. Overexpression of splice isoforms was identified for genes encoding CEACAM1, FHL-1, MLPH, and SUSD2. None of these splicing isoforms had been previously associated with lung cancer. In conclusion, this highly accurate methodology enables the detection of alternative splicing events in complex biological samples, providing a powerful tool to identify novel diagnostic and prognostic biomarkers for cancer and other pathologies. 20 normal/tumor paired specimens. Tumor samples are from non-small cell lung cancer (NSCLC) whereas normals are from adjacent normal lung tissue.

Project description:To investigate the factor produced by CSCC cells to facilitate lymphangiogenesis, we analyzed the transcriptomics of CSCC cells upon DDX24 has been knocked down by siRNA. We then performed gene expression profiling analysis using data obtained from RNA-seq of 2 different cell lines.