Project description:Our RNA-seq experiment and subsequent in vitro analysis suggested that snoRD50a is a trans-acting RNA that can function in mRNA 3' processing. To test this hypothesis at transcriptomic level, we performed PAS-seq experiments to compare the polyA+ transcripts profile between negative control ASO (nc ASO) and snoRD50a ASO treated Hela cells
Project description:Our RNA-seq experiment (E-MTAB-5383) and subsequent in vitro analysis suggested that snoRD50a is a trans-acting RNA that can function in mRNA 3' processing. To test this hypothesis at transcriptomic level, we performed PAS-seq experiments to compare the polyA+ transcripts profile between negative control ASO (nc ASO) and snoRD50a ASO treated Hela cells, ASO (antisense oligonucletode) technique is a commonly used technique to deplete nuclear RNAs. snoRD50a ASO is used to deplete endogenous snoRD50a. See related experiments: E-MTAB-5383; E-MTAB-5384.
Project description:We aimed to compare the Fip1/RNA interaction at transcriptomic level upon snoRD50a knockdown. To this goal, we utilized Fip1 iCLIP-seq protocol in both control and snoRD50a KD hela cells.
Project description:We aimed to discover trans-acting RNA molecules involved in mRNA 3 processing. We reasoned that, if there exist such functional RNAs, they must directly associate with the key machinery responsible for mRNA 3 processing. Therefore, it would be of great value to comprehensively identify RNAs interacting with pre-mRNA 3 processing complex. To this goal, we took advantage of previously well-characterized system combined with high-throughput sequencing to investigate the target RNAs at the transcriptomic level. Fip1 protein is an essential mRNA 3' processing factor. Our in vitro data suggested that snoRD50a affects Fip1/RNA interaction in SV40 late (SVL) polyA site 3' processing. To determine whether snoRD50a influences Fip1/RNA interaction at transcriptomic level in vitro, we performed Fip1 iCLIP-seq experiments in Hela cells transfected with control NC ASO (negative control anti-sense DNA) or snoRD50a ASO.
Project description:Antisense oligonucleotide (ASO) has the potential to induce hybridization-dependent effects by inadvertent binding of ASOs to RNA with sequences similar to that of the target RNA. In the present study, we examined the effects of the nucleobase derivatives introduced into the gapmer ASOs on gene expression. We performed microarray analysis using NMuLi cells (mouse liver-derived cells) treated with LNA gapmer ASO containing nucleobase modification.