Project description:Polyadenylation - the cleavage of the nascent mRNA and the addition of a tract consisting of adenine bases in a non-template-dependent manner - is a post-transcriptional modification characteristic of the majority of eukaryotic transcripts. In this study we explore PAT-seq, an Illumina-based poly(A) tail assay, based on the low-throughput G-tailing approach. Briefly, our approach is based on G-tailing poly(A) selected mRNA followed by fragmentation and reverse transcription using a mixture of primers targeting the poly(A)-tail/G-tag junction and the polyadenylation site and the body of the transcripts. The resulting cDNA fragments are sequenced using standard Illumina RNA-seq protocol.

Project description:In mammals, translational control plays critical roles during oocyte-to-embryo transition (OET) when transcription ceases. However, the underlying regulatory mechanisms remain challenging to study. Here, using low-input Ribo-seq (Ribo-lite), we investigated translational landscapes during OET using 30-150 mouse oocytes or embryos per stage. Ribo-lite can also accommodate single oocytes. Combining PAIso-seq to interrogate poly(A) tail lengths, we found a global switch of translatome that closely parallels changes of poly(A) tails upon meiotic resumption. Translation activation correlates with polyadenylation and is supported by polyadenylation signal proximal cytoplasmic polyadenylation elements (papCPEs) in 3' untranslated regions. By contrast, translation repression parallels global de-adenylation. The latter includes transcripts containing no CPEs or non-papCPEs, which encode many transcription regulators that are preferentially re-activated before zygotic genome activation. CCR4-NOT, the major de-adenylation complex, and its key adaptor protein BTG4 regulate translation downregulation often independent of RNA decay. BTG4 is not essential for global de-adenylation but is required for selective gene de-adenylation and production of very short-tailed transcripts. In sum, our data reveal intimate interplays among translation, RNA stability and poly(A) tail length regulation underlying mammalian OET.

Project description:The Poly(A)-Tail focused RNA-seq, or PAT-seq approach was utilised to determine the gene expression, poly(A)-site and polyadenylation state of the transcriptome of early C. elegans embryos having been depleated for a series of RNA binding proteins. Namely; pos-1 and mex-5 were independently knocked down using dsRNA expressing E. coli HT115(DE3) fed to ~100,000 starved/synchronized L1 larvae. When half of the population reached adulthood and half were still in the L4 stage, worms were bleached and embryos harvested and stored in Trizol. This ensured an enrichment of early embryos between 1 and 24 cell stage. mex-6(pk440) were synchronized and grown on OP50 until the same time point and embryos harvested in the same manner. Since prolonged gld-3 and gld-2 RNAi result in sterility, starved/synchronized L1 larvae were fed diluted OP50 (200uL of concentrated OP50 diluted in 2mL of M9 and starved L1s) for 16 hours. At that point the OP50 had been mostly consumed by the larvae and concentrated gld-3 or gld-2 dsRNA expressing E. coli were added to the plates. When half of the population reached adulthood and half were still in the L4 stage, worms were bleached and embryos harvested and stored in Trizol. Total RNA was isolated using standard procedures. Analysis of poly(A) dynamics in early C. elegans embryos reponding to depletion of specific RNA binding proteins and adneylation state regulators

Project description:Changes in gene expression are required to orchestrate changes in cell state during development. Most cells change patterns of gene expression through transcriptional regulation. In contrast, oocytes are transcriptionally silent and use changes in mRNA poly-A tail length to control protein production. Recent technical advances have enabled genome-wide measurement of poly-A tail length. Poly-A tail lengthening is correlated with translational activation and poly-A tail shortening is correlated with translational repression at a global level during early development. However, it is not clear how poly-A tail changes affect mRNA translation at a global level during vertebrate oocyte maturation. We used TAIL-seq and polyribosome analysis to measure poly-A tail and translational changes during oocyte maturation in Xenopus laevis. We found that the transcriptome undergoes large-scale poly-A and translational changes during oocyte maturation and that poly-A tail length and translation are well-correlated. Interestingly, we found that poly-A tail changes precede translation changes. Additionally, we identified a family of U-rich sequence elements that are enriched near the polyadenylation signal of polyadenylated and translationally activated mRNAs. Interestingly, we found that cytoplasmic polyadenylation is not sufficient to activate translation, which requires a specific density and spacing of U-rich elements. Collectively, our data shows that changes in mRNA polyadenylation are the dominant mechanism controlling protein expression during vertebrate oocyte maturation and that these changes are controlled by a group of cis-acting sequence elements. Our results provide insight into mechanisms of translational control in oocytes and identify novel proteins important for the completion of meiosis.

Project description:Poly(A)-ClickSeq is a new methodology for the sequencing of the 3'UTR/poly(A) tail junction of RNA. We analysed both wild-type and CF25Im knock-down HeLa cells in culture using Poly(A)-ClickSeq to find the distribution of poly(A) sites in these samples and determine the role of CF25Im in poly(A) site selection (alternative poly-adenylation, APA).

Project description:Poly(A) tail length is regulated in both the nucleus and cytoplasm. One factor that controls polyadenylation in the cytoplasm is CPEB1, an RNA binding protein that associates with specific mRNA 3’UTR sequences to tether enzymes that add and remove poly(A). Two of these enzymes, the noncanonical poly(A) polymerases Gld2 (TENT2, PAPD4, Wispy) and Gld4 (TENT4B, PAPD5, TRF4, TUT3), interact with CPEB1 to extend poly(A). To identify additional RNA binding proteins that might anchor Gld4 to RNA, we expressed double tagged Gld4 in U87MG cells, which was used for sequential immunoprecipitation and elution followed by mass spectrometry. We identified several RNA binding proteins that co-precipitated with Gld4, among which was FMRP. To assess whether FMRP regulates polyadenylation, we performed TAIL-seq from WT and FMRP-deficient HEK293 cells. Surprisingly, loss of FMRP resulted in an overall increase in poly(A), which was also observed for several specific mRNAs. Conversely, loss of CPEB1 elicited an expected decrease in poly(A), which was examined in cultured neurons. We also examined polyadenylation in wild type (WT) and FMRP-deficient mouse brain cortex by direct RNA Nanopore™ sequencing, which identified RNAs with both increased and decreased poly(A). Our data show that FMRP has a role in mediating poly(A) tail length, which adds to its repertoire of RNA regulation.

Project description:To obtain global data on polyadenylation of mRNAs, we fractionated the mRNAs according to their poly(A) tail length using a poly-U sepharose column followed by differential elution at five temperatures. Five mRNA fractions with distinct ranges of poly(A) tail length were then hybridized to microarrays using total eluate as a reference.

Project description:The Poly(A)-Test RNA-seq, ( PAT-seq ) approach was utilized to determine gene expression and poly(A)-site change in S. cerevisiae during colony maturation.

Project description:The Poly(A)-Tail focused RNA-seq, or PAT-seq approach was utilised to determine the gene expression, poly(A)-site and polyadenylation state of the transcriptome of early C. elegans embryos having been depleated for a series of RNA binding proteins. Namely; pos-1 and mex-5 were independently knocked down using dsRNA expressing E. coli HT115(DE3) fed to ~100,000 starved/synchronized L1 larvae. When half of the population reached adulthood and half were still in the L4 stage, worms were bleached and embryos harvested and stored in Trizol. This ensured an enrichment of early embryos between 1 and 24 cell stage. mex-6(pk440) were synchronized and grown on OP50 until the same time point and embryos harvested in the same manner. Since prolonged gld-3 and gld-2 RNAi result in sterility, starved/synchronized L1 larvae were fed diluted OP50 (200uL of concentrated OP50 diluted in 2mL of M9 and starved L1s) for 16 hours. At that point the OP50 had been mostly consumed by the larvae and concentrated gld-3 or gld-2 dsRNA expressing E. coli were added to the plates. When half of the population reached adulthood and half were still in the L4 stage, worms were bleached and embryos harvested and stored in Trizol. Total RNA was isolated using standard procedures.

Project description:Cytoplasmic polyadenylation is a mechanism to promote mRNA translation in a wide variety of biological contexts.The conserved RNA-binding protein family CPEB has been shown to mediate canonical cytoplasmic polyadenylation of target transcripts. We have previously reported evidence for RNA-interference factor Dicer-2 as a component of a non-canonical complex, that operates independent of CPEB in Drosophila. In this study, we investigate Dicer-2 mRNA targets and protein co-factors in cytoplasmic polyadenylation. Using RIP‐Seq analysis we identify hundreds of potential Dicer-2 target transcripts, ~60% of which were previously found as targets of the cytoplasmic poly(A) polymerase Wispy, suggesting widespread roles of Dicer-2 in cytoplasmic polyadenylation. Large-scale immunoprecipitation and mass spectrometry revealed Ataxin-2 and Twenty-four among the high-confidence interactors of Dicer-2. Complex analyses indicated that both factors form an RNA‐independent complex with Dicer‐2, and mediate interactions of Dicer‐2 with Wispy. Functional poly(A)‐test analyses showed that Twenty‐four and Ataxin-2 are required for cytoplasmic polyadenylation of a subset of Dicer‐2 targets. Our results reveal components of a novel cytoplasmic polyadenylation complex that operates during Drosophila early embryogenesis.