Project description:Through alternative polyadenylation, human mRNAs acquire longer or shorter 3' untranslated regions, the latter typically associated with higher transcript stability and increased protein production. To understand the dynamics of polyadenylation site usage, we mapped transcriptome?wide both binding sites of 3' end processing factors CPSF?160, CPSF?100, CPSF?73, CPSF?30, Fip1, CstF?64, CstF-64tau, CF Im25, CF Im59, and CF Im68 and 3' end processing sites in HEK293 cells. We found that although binding sites of these factors generally cluster around the poly(A) sites most frequently used in cleavage, CstF?64/CstF-64tau and CF Im proteins have much higher positional specificity compared to CPSF components. Knockdown of CF Im68 induced a systematic use of proximal polyadenylation sites, indicating that changes in relative abundance of a single 3' end processing factor can modulate the length of 3' untranslated regions transcriptome-wide, and suggesting a mechanism behind the previously observed increase in tumor cell invasiveness upon CF Im68 knockdown. 3' ends of transcripts were profiled by high-throughput sequencing in HEK 293 cells under normal conditions, and in HEK 293 cells depleted of 3' end processing factors CF Im 68 and CstF-64.

Project description:This SuperSeries is composed of the following subset Series: GSE37037: Genome-wide analysis of pre-mRNA 3' end processing reveals a decisive role of human cleavage factor I in the regulation of 3' UTR length: A-seq GSE37398: Genome-wide analysis of pre-mRNA 3' end processing reveals a decisive role of human cleavage factor I in the regulation of 3' UTR length: CLIP Refer to individual Series

Project description:In eukaryotes, the 3' ends of RNA polymerase II-generated transcripts are made in the majority of cases by site-specific endonucleolytic cleavage, followed by the addition of a poly(A) tail. By alternative polyadenylation, a gene can give rise to multiple mRNA isoforms that differ in the length of their 3' UTRs and hence in their susceptibility to post-transcriptional regulatory factors such as microRNAs. A series of recently conducted high-throughput studies of poly(A) site usage revealed an extensive tissue-specific control of 3’ UTR length and drastic changes in 3’ UTR length of mRNAs upon induction of proliferation in resting cells. To understand the dynamics of polyadenylation site usage, we recently identified binding sites of the major pre-mRNA 3’ end processing factors - cleavage and polyadenylation specificity factor (CPSF), cleavage stimulation factor (CstF), and cleavage factor Im (CF Im) - and mapped cleaved polyadenylation sites in HEK293 cells. Our present study extends previous findings on the role of CF Im in alternative polyadenylation and reveals that subunits of the CF Im complex generally control 3’ UTR length. More specifically, we demonstrate that the  loss-of-function of CF Im68 and CF Im25 but not of CF Im59 leads to a transcriptome-wide increase of the use of proximal polyadenylation sites.

Project description:Through alternative polyadenylation, human mRNAs acquire longer or shorter 3' untranslated regions, the latter typically associated with higher transcript stability and increased protein production. To understand the dynamics of polyadenylation site usage, we mapped transcriptome‐wide both binding sites of 3' end processing factors CPSF‐160, CPSF‐100, CPSF‐73, CPSF‐30, Fip1, CstF‐64, CstF-64tau, CF Im25, CF Im59, and CF Im68 and 3' end processing sites in HEK293 cells. We found that although binding sites of these factors generally cluster around the poly(A) sites most frequently used in cleavage, CstF‐64/CstF-64tau and CF Im proteins have much higher positional specificity compared to CPSF components. Knockdown of CF Im68 induced a systematic use of proximal polyadenylation sites, indicating that changes in relative abundance of a single 3' end processing factor can modulate the length of 3' untranslated regions transcriptome-wide, and suggesting a mechanism behind the previously observed increase in tumor cell invasiveness upon CF Im68 knockdown. We performed PAR-CLIP experiments for 3' end processing factors including CPSF-30, CPSF-73, CPSF-100, CPSF-160, Fip1, CF Im25, CF Im59, CF Im68, CstF-64, and CstF-64tau.

Project description:Alternative polyadenylation is an important cellular mechanism that enables generation of mRNA isoforms that differ in their 3' untranslated regions (3' UTRs) and consequently in their susceptibility to miRNA and RNA binding protein mediated regulation. A dramatic change in polyadenylation site usage, leading to the systematic expression of short 3’ UTR isoforms is known to occur upon induction of proliferation in resting cells. To understand the functional consequences of short 3’ UTR isoform expression we used 3' end sequencing and quantitative mass spectroscopy to determine polyadenylation site use, mRNA and protein levels in murine and human naive and activated T cells. We found that while the process and its impact on the susceptibility to miRNA and RNA binding protein mediated regulation are evolutionarily conserved, the conservation is poor at the level of individual orthologous genes. Contrary to the common belief, we did not find that transcriptome-wide 3' UTR shortening leads to a matched increase in mRNA and protein levels of genes with tandem polyadenylation sites. 3' ends of transcripts were profiled by high-throughput sequencing in murine and human naive and activated T cells.

Project description:Through alternative polyadenylation, human mRNAs acquire longer or shorter 3' untranslated regions, the latter typically associated with higher transcript stability and increased protein production. To understand the dynamics of polyadenylation site usage, we mapped transcriptome‐wide both binding sites of 3' end processing factors CPSF‐160, CPSF‐100, CPSF‐73, CPSF‐30, Fip1, CstF‐64, CstF-64tau, CF Im25, CF Im59, and CF Im68 and 3' end processing sites in HEK293 cells. We found that although binding sites of these factors generally cluster around the poly(A) sites most frequently used in cleavage, CstF‐64/CstF-64tau and CF Im proteins have much higher positional specificity compared to CPSF components. Knockdown of CF Im68 induced a systematic use of proximal polyadenylation sites, indicating that changes in relative abundance of a single 3' end processing factor can modulate the length of 3' untranslated regions transcriptome-wide, and suggesting a mechanism behind the previously observed increase in tumor cell invasiveness upon CF Im68 knockdown.

Project description:Through alternative polyadenylation, human mRNAs acquire longer or shorter 3' untranslated regions, the latter typically associated with higher transcript stability and increased protein production. To understand the dynamics of polyadenylation site usage, we mapped transcriptome‐wide both binding sites of 3' end processing factors CPSF‐160, CPSF‐100, CPSF‐73, CPSF‐30, Fip1, CstF‐64, CstF-64tau, CF Im25, CF Im59, and CF Im68 and 3' end processing sites in HEK293 cells. We found that although binding sites of these factors generally cluster around the poly(A) sites most frequently used in cleavage, CstF‐64/CstF-64tau and CF Im proteins have much higher positional specificity compared to CPSF components. Knockdown of CF Im68 induced a systematic use of proximal polyadenylation sites, indicating that changes in relative abundance of a single 3' end processing factor can modulate the length of 3' untranslated regions transcriptome-wide, and suggesting a mechanism behind the previously observed increase in tumor cell invasiveness upon CF Im68 knockdown.

Project description:mPAT approach was used to determine changes to 3'UTR length in yeast upon mutation of cleavage and polyadenylation factor subunits compared to wild type cells

Project description:Cleavage Factor Im as a key regulator of 3’ UTR length

Project description:Swd2.2 is associated with the Cleavage and Polyadenylation Factor (CPF) in fission yeast. The CPF is required for the 3'end processing of RNAs. To establish the contribution of Swd2.2 to gene expression, we used single-strand tiling array hybridization. The results show that 47 genes are significantly down-regulated (FCM-bM-^IM-$1,9, p<0,01) and 14 are up-regulated (FCM-bM-^IM-%1,9, p<0,01) when Swd2.2 is missing. To establish the contribution of Swd2.2 to transcription termination, we also used these data as follows: for every gene in the genome whose 3'UTR was annotated (4727 genes), the average RNA signal intensity observed in the 3'UTR of the gene was compared to the average signal intensity observed in the ORF of the gene. This ratio was named &quot;UTR ratio&quot;. This UTR ratio was calculated for every gene, in swd2.2+ or swd2.2delta cells. The UTR ratio observed in swd2.2delta cells was then compared to the UTR ratio observed in swd2.2+ cells. When this ratio is superior to 1.5, it means that there was proportionnally a 50% increase of the RNA signal in the 3'UTR of this gene when Swd2.2 was missing. We interpreted this observation as a transcription termination defect. We detected 780 genes (out of 4727) for which this was the case. This list is highy enriched for convergent, overlapping genes. RNA extracted from swd2.2+ and swd2.2delta cells were retrotranscribed and labelled. These were then hybridized on an Affymetrix S. pombe Tiling 1.0FR Array (accession GPL7715). The data were established in triplicates.