Project description:ZFAS1 suppression in HepG2 cells

Project description:Numerous long noncoding RNAs (lncRNAs) are generated in response to external stimuli, but the scope and functions of such activity are not known. Here, we provide insight into how the transcription of lncRNAs are connected to DNA damage response by identifying a lncRNA ZFAS1, which is required for cell cycle arrest, transcription regulation and DNA repair. Mechanistically, ZFAS1 facilitates the changing hyperphosphorylated forms of the large subunit of RNAPII around transcription initiation sites by directly targeting the regulated genes. We revealed extensive transcription shutdown and concomitant stimulated engagement of RNAPII-Ser2P are crucial for repair and cell survival upon genotoxic stress. Finally, ZFAS1 knockout in mice dampened transcription-coupled nucleotide excision repair (TC-NER) and led to kidney dysplasia. Our study extends the understanding of lncRNAs in DNA damage repair (DDR) and implies a protective role of lncRNA against DDR-deficient developmental disorders.

Project description:Numerous long noncoding RNAs (lncRNAs) are generated in response to external stimuli, but the scope and functions of such activity are not known. Here, we provide insight into how the transcription of lncRNAs are connected to DNA damage response by identifying a lncRNA ZFAS1, which is required for cell cycle arrest, transcription regulation and DNA repair. Mechanistically, ZFAS1 facilitates the changing hyperphosphorylated forms of the large subunit of RNAPII around transcription initiation sites by directly targeting the regulated genes. We revealed extensive transcription shutdown and concomitant stimulated engagement of RNAPII-Ser2P are crucial for repair and cell survival upon genotoxic stress. Finally, ZFAS1 knockout in mice dampened transcription-coupled nucleotide excision repair (TC-NER) and led to kidney dysplasia. Our study extends the understanding of lncRNAs in DNA damage repair (DDR) and implies a protective role of lncRNA against DDR-deficient developmental disorders.

Project description:Numerous long noncoding RNAs (lncRNAs) are generated in response to external stimuli, but the scope and functions of such activity are not known. Here, we provide insight into how the transcription of lncRNAs are connected to DNA damage response by identifying a lncRNA ZFAS1, which is required for cell cycle arrest, transcription regulation and DNA repair. Mechanistically, ZFAS1 facilitates the changing hyperphosphorylated forms of the large subunit of RNAPII around transcription initiation sites by directly targeting the regulated genes. We revealed extensive transcription shutdown and concomitant stimulated engagement of RNAPII-Ser2P are crucial for repair and cell survival upon genotoxic stress. Finally, ZFAS1 knockout in mice dampened transcription-coupled nucleotide excision repair (TC-NER) and led to kidney dysplasia. Our study extends the understanding of lncRNAs in DNA damage repair (DDR) and implies a protective role of lncRNA against DDR-deficient developmental disorders.

Project description:Numerous long noncoding RNAs (lncRNAs) are generated in response to external stimuli, but the scope and functions of such activity are not known. Here, we provide insight into how the transcription of lncRNAs are connected to DNA damage response by identifying a lncRNA ZFAS1, which is required for cell cycle arrest, transcription regulation and DNA repair. Mechanistically, ZFAS1 facilitates the changing hyperphosphorylated forms of the large subunit of RNAPII around transcription initiation sites by directly targeting the regulated genes. We revealed extensive transcription shutdown and concomitant stimulated engagement of RNAPII-Ser2P are crucial for repair and cell survival upon genotoxic stress. Finally, ZFAS1 knockout in mice dampened transcription-coupled nucleotide excision repair (TC-NER) and led to kidney dysplasia. Our study extends the understanding of lncRNAs in DNA damage repair (DDR) and implies a protective role of lncRNA against DDR-deficient developmental disorders.

Project description:Investigation of whole genome gene expression level changes in hepatocellular carcinoma cell line hepG2 in regular culture, hepG2-slug in regular culture and hepG2-slug on Matrigel. Whole genome gene expression level changes have been compared in hepatocellular carcinoma cell line hepG2 in regular culture, hepG2-slug in regular culture and hepG2-slug on Matrigel. Roche NimbleGen micro-array analysis was employed to assess global genome expression in HepG2 in regular culture, HepG2-slug in regular culture and HepG2-slug on Matrigel. The results demonstrated that the up-regulated genes and the down-regulated genes increased significantly when HepG2-slug cells with VM forming ablity were cultured on Matrigel and formed VM.

Project description:The hereditary information encoded in DNA sequence is intrinsically susceptible to alterations, being continually threatened by a variety of genotoxic perturbations. To safeguard the stability of the genome, eukaryotic cells have evolved a set of sophisticated surveillance system that controls several aspects of the cellular response, including the detection of DNA lesions, a temporary cell cycle arrest, regulation of transcription, and the repair of the damaged DNA. However, it is still poorly understood how the DNA damage checkpoints and stalled RNAPII molecules convert a very limited amount of molecular-level information (even a single DNA lesion) in the context of an otherwise genome into regulation that halts and resumes the cell-cycle engine in a coordinated way. In this study, we reveal a map of extensive lncRNA transcription during DDR by using synchronized cells, leading to the unexpected identification of a poorly characterized mammalian lncRNA-ZFAS1. We describe that ZFAS1 functions as a key player of cellular response to DNA damage in both human and rodent cells by fine tuning RNAPII kinetics, suggesting a lncRNA-dependent transcriptional regulatory axis that maintains genomic stability upon DNA damage in mammalian cells.

Project description:The hereditary information encoded in DNA sequence is intrinsically susceptible to alterations, being continually threatened by a variety of genotoxic perturbations. To safeguard the stability of the genome, eukaryotic cells have evolved a set of sophisticated surveillance system that controls several aspects of the cellular response, including the detection of DNA lesions, a temporary cell cycle arrest, regulation of transcription, and the repair of the damaged DNA. However, it is still poorly understood how the DNA damage checkpoints and stalled RNAPII molecules convert a very limited amount of molecular-level information (even a single DNA lesion) in the context of an otherwise genome into regulation that halts and resumes the cell-cycle engine in a coordinated way. In this study, we reveal a map of extensive lncRNA transcription during DDR by using synchronized cells, leading to the unexpected identification of a poorly characterized mammalian lncRNA-ZFAS1. We describe that ZFAS1 functions as a key player of cellular response to DNA damage in both human and rodent cells by fine tuning RNAPII kinetics, suggesting a lncRNA-dependent transcriptional regulatory axis that maintains genomic stability upon DNA damage in mammalian cells.

Project description:Increasing evidence suggested that small nucleolar RNAs (snoRNAs) and long non-coding RNAs (LncRNAs) were master regulators of gene regulation at epigenetic modification level, however, the underlying mechanism in colorectal cancer (CRC) have not been investigated. To demonstrate the involvement of LncRNA and snoRNAs in 2’-O-methylation (Me) in tumorigenesis, we develop the LncRNAs-snoRNAs microarray of paired CRC tissues, and found an unrecognized ZFAS1-NOP58- SNORD12C/78 signaling axis in CRC tumorigenesis through recognizing the consensus AAGA motif of ZFAS1 which directly binds to NOP58 protein, and accelerating the snoRNPs assemble for further guiding 2’-O-Me of 28S rRNA. Strikingly, overexpression SNORD12C/78 induces 2’-O-Me modification upon ZFAS1, and affects RNA stability and translation activity of their downstream targets (e.g., EIF4A3,LMAC2, etc.), thereby promoted CRC cell proliferation, invasion and inhibited apoptosis in vitro and in vivo. Thus, these results sheds new light on our understanding of lncRNAs-snoRNPs mediated rRNA 2'-O-methylations in CRC tumorigenesis.

Project description:Cultured primary human hepatocytes treated with antisense oligonucleotides