Project description:Epstein-Barr virus (EBV) expresses several mRNAs produced from intronless genes that could be unfavorably translated in front of cellular spliced mRNAs. To overpass these limitations, the virus encodes a RNA-binding protein (RBP), EB2, which is already known to facilitate nuclear mRNAs export and to increase their translational yield. Here we show that EB2 binds both nuclear and cytoplasmic cap-binding complexes (respectively, CBC and eIF4F), and the poly(A)-binding protein (PABP) to enhance translation initiation of a given mRNP. Interestingly, such effect can be obtained only if EB2 was initially bound to the native mRNPs in the nucleus. We also demonstrate that the EB2-eIF4F-PABP association renders the translation of these mRNPs less sensitive to inhibitors of initiation. Taken together, our new data suggest that EB2 binds and stabilizes cap-binding complexes to increase mRNP translation and demonstrate the importance of the mRNP assembly process in the nucleus to promote translation in the cytoplasm.

Project description:Gene expression results from mRNA - RNA-binding protein (RBP) interactions within messenger ribonucleoprotein (mRNP) particles. We identified heterogeniety of nuclear mRNP composition involved in mRNA biogenesis and export with different occupancy and stoichiometry of RNA-binding proteins. Especially, mRNA export adopter protein Yra1 showed large variation of its stoichiometry on single mRNPs. We identified stoichiometry of Yra1 in the nuclear cap binding complex (Cbp80) bound mRNPs and it can be dissected into two categories (one and multiple Yra1 bound mRNPs). Multiple Yra1 containing mRNPs specifically co-occupied with THO complex (Hpr1). To investigate gene dependency to form different Yra1 stoichiometry mRNPs, we performed RNA-IP experiment for Yra1 with two step purification by Cbp80/Yra1 and Hpr1/Yra1.

Project description:Biogenesis of eukaryotic messenger ribonucleoprotein complexes (mRNPs) involves the synthesis, splicing, and 3M-bM-^@M-^Y-processing of pre-mRNA, and the assembly of mature mRNPs for nuclear export. We mapped 23 mRNP biogenesis factors onto the newly synthesized yeast transcriptome, providing ~10^5-10^6 high-confidence RNA interaction sites per factor. PAR-CLIP data of 23 mRNP biogenesis factors in Saccharomyces cerevisiae

Project description:Biogenesis of eukaryotic messenger ribonucleoprotein complexes (mRNPs) involves the synthesis, splicing, and 3’-processing of pre-mRNA, and the assembly of mature mRNPs for nuclear export. We mapped 23 mRNP biogenesis factors onto the newly synthesized yeast transcriptome, providing ~10^5-10^6 high-confidence RNA interaction sites per factor.

Project description:Expression of the RNA-binding protein is increased upon megakaryocyte commitment, and may coordinate with mRNA stability and translation during megakaryopoiesis. Reduced expression of ATXN2 in human megakaryocytic cells decreased protein synthesis and total protein content despite equal mRNA expression. Genome-wide comparision of subpolysomal versus polysomal mRNA showed that both protein synthesis and protein degradation are derailed in absence of ATXN2. Furthermore, ATXN2 was associated with PABP and DDX6, proteins that control mRNA stability through the polyA-tail. These findings indicate that ATXN2 is involved in protein metabolism in megakaryocytes and platelet function.

Project description:This experiment captures the poly(A)RNAs co-immunoprecipated with Isw1 in WT and npl3-1 cells. Chromatin remodelers play an essential role in regulating DNA transaction processes. The yeast chromatin remodeling complex ISW1 displays an unexpected function in nuclear mRNP surveillance, retaining premature mRNPs in proximity to their transcription site. This activity of ISW1 requires its recruitment onto chromatin, its interaction with mRNPs but not its nucleosome sliding activity. In npl3-1 cells, mRNA export is compromised resulting in an increased association of mRNAs with Isw1.

Project description:The poly(A) tail appended to the 3’ end of many eukaryotic transcripts plays a key role in the stability, nuclear transport, and translation of the RNA. These roles are largely mediated by the Poly(A) Binding Proteins (PABPs) that coat the poly(A) tails and interact with various proteins involved in the biogenesis and function of the RNA. While it is well established that the nuclear PABP (PABPN) binds newly synthesized poly(A) tails and is apparently replaced by the cytoplasmic PABP (PABPC) on transcripts exported to the cytoplasm, the distribution of transcripts for different genes or isoforms of the same gene on these distinct PABPs has not been investigated on a genome-wide scale. Here, we analyzed the identity, splicing status, poly(A) tail size, and translation status of RNAs co-immunoprecipitated with endogenous PABPN or PABPC in human cells. At steady state, many protein coding and non-coding RNAs exhibit strong bias for association with PABPN or PABPC. While PABPN-enriched transcripts more often were incompletely spliced and harbored longer poly(A) tails and PABPC-enriched RNAs tended to have longer half-lives and higher translation efficiency, there are curious outliers. Overall, our study reveals the landscape of RNAs bound by PABPN and PABPC, providing new details that support and advance the current understanding of the roles these proteins play in poly(A) tail synthesis, maintenance and function.

Project description:The poly(A) tail appended to the 3’ end of many eukaryotic transcripts plays a key role in the stability, nuclear transport, and translation of the RNA. These roles are largely mediated by the Poly(A) Binding Proteins (PABPs) that coat the poly(A) tails and interact with various proteins involved in the biogenesis and function of the RNA. While it is well established that the nuclear PABP (PABPN) binds newly synthesized poly(A) tails and is apparently replaced by the cytoplasmic PABP (PABPC) on transcripts exported to the cytoplasm, the distribution of transcripts for different genes or isoforms of the same gene on these distinct PABPs has not been investigated on a genome-wide scale. Here, we analyzed the identity, splicing status, poly(A) tail size, and translation status of RNAs co-immunoprecipitated with endogenous PABPN or PABPC in human cells. At steady state, many protein coding and non-coding RNAs exhibit strong bias for association with PABPN or PABPC. While PABPN-enriched transcripts more often were incompletely spliced and harbored longer poly(A) tails and PABPC-enriched RNAs tended to have longer half-lives and higher translation efficiency, there are curious outliers. Overall, our study reveals the landscape of RNAs bound by PABPN and PABPC, providing new details that support and advance the current understanding of the roles these proteins play in poly(A) tail synthesis, maintenance and function.

Project description:The poly(A) tail appended to the 3’ end of many eukaryotic transcripts plays a key role in the stability, nuclear transport, and translation of the RNA. These roles are largely mediated by the Poly(A) Binding Proteins (PABPs) that coat the poly(A) tails and interact with various proteins involved in the biogenesis and function of the RNA. While it is well established that the nuclear PABP (PABPN) binds newly synthesized poly(A) tails and is apparently replaced by the cytoplasmic PABP (PABPC) on transcripts exported to the cytoplasm, the distribution of transcripts for different genes or isoforms of the same gene on these distinct PABPs has not been investigated on a genome-wide scale. Here, we analyzed the identity, splicing status, poly(A) tail size, and translation status of RNAs co-immunoprecipitated with endogenous PABPN or PABPC in human cells. At steady state, many protein coding and non-coding RNAs exhibit strong bias for association with PABPN or PABPC. While PABPN-enriched transcripts more often were incompletely spliced and harbored longer poly(A) tails and PABPC-enriched RNAs tended to have longer half-lives and higher translation efficiency, there are curious outliers. Overall, our study reveals the landscape of RNAs bound by PABPN and PABPC, providing new details that support and advance the current understanding of the roles these proteins play in poly(A) tail synthesis, maintenance and function.

Project description:Gene expression is tightly regulated at the levels of both mRNA translation and stability. The poly(A) binding protein (PABP) plays a role in regulating these processes by binding the mRNA 3´ poly(A) tail and interfacing with both the translation initiation and mRNA deadenylation machineries. Here we directly investigate the impact of PABP on the translation and stability of endogenous mRNAs in human cell lines. Remarkably, our transcriptome-wide analysis does not generally detect changes to mRNA translation in PABP-depleted cells. In contrast, rapidly depleting PABP alters transcriptome abundance and stability, albeit non-uniformly. Transcripts with long half-lives and short 3’UTRs are preferentially depleted in PABP-depleted cells. PABP depletion induces cell death; however, disrupting the mRNA decapping and 5’-3’ decay machinery can partially suppress this lethality. Finally, we show that disrupting the LSM1-7 complex prevents the premature decay of mRNAs that are destabilized in PABP-depleted cells. Taken together, these findings suggest that PABP plays an important role in preventing the untimely decay of select mRNA populations in human cells.