Project description:The PAR-CLIP sample was separated by SDS-PAGE, RNA were recovered from the gel by D-tubeTM Dialyzer Midi(Millipore).The mixture were digested by 4 μg/μl proteinase K (Roche, 03115828001) and precipitated in ethanol with the help of glycogen (Thermo, R0551). RNAs in ethanol were used for the small RNA library construction (NEB, E7300L). Finally, the library was sequenced on the Illumina HiSeq X-Ten platform with paired-end 150 bp (PE150) kits. Only the forward reads were used in the data analysis and uploaded. Bowtie was applied to map sequencing reads against hg19 genome with up to two mismatches allowed. PARalyzer software was used to define proteins binding clusters.

Project description:In order to identify YBX1 binding sites on endogenous RNA, we performed HITS-CLIP on endogenous YBX1 We used a previously published method to perform HITS-CLIP on endogenous YBX1 (Licatalosi D, et al. 2008, Nature 456:464-U22)

Project description:In order to identify YBX1 binding sites on tRNA fragments, we performed small-RNA HITS-CLIP on endogenous YBX1 We used a previously published method to perform HITS-CLIP on endogenous YBX1 (Chi SW, et al. 2009, Nature 460:479)

Project description:YBX1 is a multifunctional protein involved in the control of transcription and translation. We identified YBX1 as an target of MEK/ERK signaling in colorectal cancer cell lines. We performed a ChIP-chip analysis of HCT116 cells to identify new potential target genes of YBX1. Comparison of input DNA fragments with fragments coprecipitated with YBX1 in HCT116 cells.

Project description:In order to identify YBX1-dependent targets that are modulated under hypoxic conditions, we used control and YBX1 knockdown cells grown under normoxia and hypoxia to profile gene expression levels. Control and YBX1-knockdown cells were grown and profiled under hypoxia and normoxia to identify YBX1-dependent hypoxia-induced target transcripts.

Project description:In order to identify YBX1-dependent targets that are modulated upon changing the levels of endogenous tRFs, we used transient transfection of antisense locked-nucleic acids (LNAs) against tRFAsp, tRFGly, tRFGlu, and tRFTyr followed by microarray profiling. Synthetic antisense locked-nucleic acids (LNAs) targeting the YBX1 binding site on tRFAsp, tRFGly, tRFGlu, and tRFTyr were transfected into control and YBX1-knockdown cells to identify YBX1-dependent targets that are modulated due to tRF loss-of-function.

Project description:The RNA methyltransferase Aly/REF export factor (ALYREF) is considered one type of “reader” protein located in the nucleus that recognizes and binds directly with m5C sites in RNA and facilitates the export of RNA from the nucleus to the cytoplasm. Notably, ALYREF is considered a promising target for diagnosis and prognosis prediction. However, until now, the low number of related studies has limited the understanding of the mechanism of the HCC-promoting effects of ALYREF. To further elucidate the oncogenic roles of ALYREF in hepatocellular carcinoma (HCC), we assessed the expression levels of ALYREF in clinical samples and HCC cell lines and explored the effects of ALYREF deficiency by both in vitro experiments and m5C-methylated RNA immunoprecipitation sequencing (m5C-MeRIP-Seq)

Project description:We have identified Alyref and Gabpb1 as developmentally important genes by siRNA screening. Gene knockout (KO) of Alyref and Gabpb1 by the CRISPR/Cas9 system resulted in early developmental arrest in mice. To gain mechanistic insight into the developmental role of Alyref and Gabpb1, we performed RNA sequencing (RNA-seq) analysis of the KO embryos.

Project description:The TREX complex (TREX) plays key roles in nuclear export of mRNAs. However, little is known about its transcriptome-wide binding targets. We used individual cross-linking and immunoprecipitation (iCLIP) to identify the binding sites of ALYREF, an mRNA export adaptor in TREX, in human cells. As expected, iCLIP reads are mainly mapped to exons of mRNAs. Globally, ALYREF binding shows two apparent enrichments on the mRNA, one is near the 5’ end and the other is very close to the 3’ end. In addition, numerous middle exons harbor ALYREF binding sites. CBP80 and PABPN1 mainly affect ALYREF binding at the 5’ and the 3’ region, respectively. Interestingly, we found that the 3’ processing factor CstF64 directly interacts with ALYREF and is required for the overall binding of ALYREF on the mRNA. Sequence analysis led to the identification of multiple

Project description:In order to identify YBX1-dependent targets that are modulated upon changing the levels of endogenous tRFs, we used transient transfection of antisense locked-nucleic acids (LNAs) against tRFAsp, tRFGly, tRFGlu, and tRFTyr followed by alpha-amanitine treatment, RNA extraction at time points 0 and 8hr post-treatment, and transcriptomic profiling. Synthetic antisense locked-nucleic acids (LNAs) targeting the YBX1 binding site on tRFAsp, tRFGly, tRFGlu, and tRFTyr were transfected into control and YBX1-knockdown cells to identify YBX1-dependent targets whose stabilities are modulated due to tRF loss-of-function. We used alpha-amanitine mediated inhibition of RNA-polymerase to measure transcript stability across the entire transcriptome.